This editorial discusses advances and future directions in research on congenital heart disease (CHD). It notes that survival after surgery for CHD has dramatically improved over the past few decades, from near universal fatality to over 96% expected survival today. However, outcomes are now measured not just by survival but also long-term quality of life. Future areas of focus include tissue engineering to create biological implants that grow with the patient, understanding and preventing neurological impacts of in utero blood flow abnormalities, and identifying causes and potential treatments for CHD at the molecular level before birth. Continued multidisciplinary research holds promise to further improve lives of those born with CHD.

1. Editorial Correspondence: Katherine Ji, Managing Editor, Translational Pediatrics. HK
office: 9A Gold Shine Tower, 346-348 Queen’s Road Central, Sheung Wan, Hong Kong.
Tel: +852 3488 1279; Fax: +852 3488 1279. Email: editor@thetp.org
July2016.Volume5Number3Pages109-184TranslationalPediatrics
ISSN 2224-4336
Vol 5, No 3
July 2016
tp.amegroups.com
TRANSLATIONAL PEDIATRICSTRANSLATIONAL PEDIATRICSTRANSLATIONAL PEDIATRICS
Focus issue on Trends and Innovations in Caring for Patients with Congenital Heart Defects
Guest Editor: Ali Dodge-Khatami, MD, PhD, University of Mississippi Medical Center, USA
Indexed
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2. Aims and Scope
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Editor-in-Chief
Yu-Jia Yang, MD, PhD
Xiangya Hospital of Central South University, China
Deputy Editor-in-Chief
Zhanhe Wu, MD, PhD, FFSc (RCPA)
Western Sydney Genome Diagnostics, Western Sydney Genetic Program, The
Children’s Hospital at Westmead, Sydney, Australia.
Editorial Board
Stuart B. Bauer, MD
Boston, USA
Robert J. Bollo, MD
Salt Lake City, USA
Andrew L. Chang, MD
San Diego, USA
Patrick HY Chung, MBBS
(HK), FRCSEd (Paed), FCSHK,
FHKAM
Hong Kong, China
Amanda Dixon-McIver, BMLSc,
MSc, PhD
Auckland, New Zealand
Ali Dodge-Khatami, MD, PhD,
Professor
Jackson, USA
Ciro Esposito, MD, PhD, MFAS
Naples, Italy
Douglas D. Fraser, MD, PhD,
FRCPC
Ontario, Canada
Ira H Gewolb, MD
East Lansing, United States
Walter A Hall, MD, MBA
Syracuse, USA
Michelle Henderson, PhD
Randwick, Australia
Anna Marie Kenney, PhD
Atlanta, USA
Martin C J Kneyber, MD, PhD
Groningen, The Netherlands
Haruki Komatsu
Chiba, Japan
Shoo K. Lee, MBBS, FRCPC, FAAP,
PhD
Toronto, Canada
Giuseppe A. Marraro, MD
Milan, Italy
Rajen Mody, MD, MS
Ann Arbor, USA
James H. Moller, MD
Minneapolis, USA
Kirsten K. Ness, PT, PhD
Memphis, USA
Ender Ödemiş, MD, Prof., Chief
Istanbul, Turkey
Todd A. Ponsky, MD
Akron, USA
Xiangming Qiu, MD
Edmonton, Canada
William D. Rhine, MD
Stanford, USA
Koravangattu Sankaran, MD
Saskatoon, Canada
Kris Sekar, MD, FAAP
Oklahoma City, USA
Arabella Ellie Smith, MB BS Hons
II (Sydney), DipRCPath (UK),
FHGSA, FRCPA
Sydney, Australia
Christian P. Speer, MD, FRCPE
Würzburg, Germany
Varsha Tembe, MS, BSc, PhD
Sydney, Australia
Amy L. Throckmorton, PhD,
Associate Professor, Director
Philadelphia, USA
Hiroo Uchida, MD, PhD
Nagoya, Japan
Chi Dung Vu, MD
Hanoi, Vietnam
Shawn C. West, MD, MSC
Pittsburgh, USA
Gary Wing Kin Wong, MD,
FRCPC, FHKAM, Professor
Hong Kong, China
Atsuyuki Yamataka (Yama), MD,
PhD
Tokyo, Japan
Tsu-Fuh Yeh, MD, PhD
Taipei, Taiwan
Bing Yu, MD, PhD, FFSc (RCPA),
FHGSA, FACBS
Camperdown, Australia
Section Editor
Xicheng Deng, MD, PhD, Staff
surgeon (Pediatric Cardiothoracic
Surgery)
Changsha, China
Xian-Gang Yan, MD, Associate
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Shanghai, China
Zhiqun Zhang, MD (Neonatal
Medicine)
Zhejiang, China
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Science Editors
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Melanie C. He
Lucille L. Ye

3. © Translational Pediatrics. All rights reserved. Translational Pediatrics Vol 5, No 3 July 2016
Table of Contents
Editorial
109 Advances and research in congenital heart disease
Ali Dodge-Khatami
112 The battleground of the stenotic branch pulmonary arteries: the surgical approach of “less is more”
Damien P. Kenny, Jonathan McGuinness, Ziyad M. Hijazi
Original Article
114 Antegrade cerebral perfusion at 25 ℃ for arch reconstruction in newborns and children preserves
perioperative cerebral oxygenation and serum creatinine
Bhawna Gupta, Ali Dodge-Khatami, Juan Tucker, Mary B. Taylor, Douglas Maposa, Miguel Urencio, Jorge D. Salazar
125 How to set-up a program of minimally-invasive surgery for congenital heart defects
Juan-Miguel Gil-Jaurena, Ramón Pérez-Caballero, Ana Pita-Fernández, María-Teresa González-López, Jairo Sánchez,
Juan-Carlos De Agustín
Review Article
134 Goal-directed-perfusion in neonatal aortic arch surgery
Robert Anton Cesnjevar, Ariawan Purbojo, Frank Muench, Joerg Juengert, André Rueffer
142 Hypoplastic left heart syndrome: current perspectives
Christopher E. Greenleaf, J. Miguel Urencio, Jorge D. Salazar, Ali Dodge-Khatami
148 Prophylactic arrhythmia surgery in association with congenital heart disease
Constantine Mavroudis, Barbara J. Deal
160 Critical cardiac care in children: looking backward and looking forward
Paul A. Checchia
Case Report
165 Reverse Szabo technique for stenting a single major aorto-pulmonary collateral vessel in pulmonary
atresia with ventricular septal defect
Igor V. Polivenok, John P. Breinholt, Sri O. Rao, Olga V. Buchneva
Pediatric Epilepsy Column (Review Article)
169 Preoperative evaluation and surgical decision-making in pediatric epilepsy surgery
Katrina Ducis, Jian Guan, Michael Karsy, Robert J. Bollo
Pediatric Epilepsy Column (Editorial)
180 Surgical advancements in pediatric epilepsy surgery: from the mysterious to the minimally invasive
Robert J. Bollo
Correspondence
183 Klinefelter syndrome: fertility considerations and gaps in knowledge
Leena Nahata, Richard N. Yu, Laurie E. Cohen

4. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):109-111tp.amegroups.com
The fate of babies born with congenital heart disease
(CHD) has dramatically changed in the last 4–5 decades,
going from a universally fatal condition in the vast
majority of patients in the absence of diagnosis or
intervention, to an entity whose outcome, at least in
terms of peri-operative/hospital stay, has improved to an
expected survival of about 96%. Indeed, since the first
surgical solution for any type of congenital heart defect in
1938, ligation of a patent ductus arteriosus by Dr. Robert
Gross at Boston Children’s Hospital (1), followed by the
pioneering work of Alfred Blalock and Helen Taussig in
the palliation of “blue babies” with tetralogy of Fallot
in 1944 (2), to the critical breakthrough of open heart
surgery with inflow occlusion and repair of an atrial
septal defect by F. John Lewis in 1952 (3), then the first
operation done with the support of extracorporeal pump
oxygenation by John Gibbon in 1953 (4), and cross-
circulation championed by C. Walton Lillehei in 1954 (5),
the field of surgical and interventional treatment and
palliation for CHD has exploded into the success story we
know today.
While these heroic pioneering surgical feats were
necessary to break the ice, parallel developments such
as cardiac catheterization and echocardiography in the
1950’s needed 2 decades to mature and become clinical
mainstream in the sixties to seventies, leading to further
precision in diagnosis, real-time imaging, and follow-up of
the heart. With the birth of pediatric critical care in the late
seventies, improvements in cardiopulmonary bypass (CPB)
perfusion hardware, the advent of percutaneous catheter-
based cardiac interventions and refinements in anatomical
and physiological understanding of single ventricle defects,
the stage has been set since the 1980’s for the current era
of multidisciplinary treatment of CHD. Thus, guidelines
and milestones have been established in the treatment
of virtually every single congenital cardiovascular defect
encountered in nature, ranging from near 100% survival
and freedom from reintervention or repeat surgery for the
more simple malformations, such as atrial or ventricular
septal defects, patent ductus arteriosus and coarctation, to
more complex defects with correspondingly lower peri-
operative survival and the need for continuous follow-up
and care.
Currently, in developed countries with established
programs built with the sole responsibility to care for
patients with congenital heart defects, surviving any given
intervention or surgical procedure is really expected by
caregivers and parents alike, but really comes to taking care
of what CHD really represents, which is not a cure in most
instances. Indeed, outcomes are no longer only measured by
survival to discharge from the hospital, or even by freedom
from complications which is of course an important
measure of quality of care. Now that these immediate peri-
operative goals are achieved in the vast majority of patients
who go on not only to survive, but to grow up and become
adolescents and then adults with treated CHD, the focus
has shifted towards quality of life in the mid to long-term,
developmental and learning processes, and a vast array of
medical and social issues relating to what it means to live
with “a treated heart condition”. Tremendous technological
feats at a macroscopic level which are obvious to the naked
eye have already been achieved, are still being discovered, or
being adapted and accordingly refined to help those patients
already born and treated for CHD. More importantly,
current and future focus are directed towards understanding
the genesis, genetics, and corresponding earlier diagnosis
with eventual new therapeutic strategies and targets at the
fetal stage and/or even at the molecular level, for those
Editorial
Advances and research in congenital heart disease
Ali Dodge-Khatami
Pediatric and Congenital Heart Surgery, Children’s Heart Center, University of Mississippi Medical Center, Jackson, MS, USA
Correspondence to: Ali Dodge-Khatami, MD, PhD. Chief, Pediatric and Congenital Heart Surgery, Children’s Heart Center, University of Mississippi
Medical Center, Jackson, MS, USA. Email: adodgekhatami@umc.edu.
Submitted May 19, 2016. Accepted for publication May 24, 2016.
doi: 10.21037/tp.2016.05.01
View this article at: http://dx.doi.org/10.21037/tp.2016.05.01

5. 110 Dodge-Khatami. Advances in congenital heart surgery
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):109-111tp.amegroups.com
patients yet unborn.
What are some of the future directions which research
could heavily influence? In many surgical repairs, from
the newborn period to adulthood, somatic growth of the
heart and vessels parallel to that of the patient must be
taken into consideration. Prosthetic materials and implants
are willingly avoided, with preference given to biological
ones. While autologous tissue from the patient itself is the
ideal material, having the advantages of being living tissue,
thereby allowing for somatic growth, resisting infection, not
requiring anticoagulation, and not inducing any rejection
phenomenon, it is not always available in the appropriate
amount or shape. The extant research and results of tissue
engineering, using various combinations of biological
scaffolds seeded with autologous stem or mature cells
are most promising, but still have a ways to go. Although
various living bio-engineered tissues have been produced
and shown to function in vitro and in vivo, either in the
myocardium, as valve substitutes, or as patch material, they
have to date failed to endure the mechanical wear and tear
of time, and therefore still need to stand the ultimate test
of acceptable longevity. Furthermore, time constraints
pertinent to harvesting cells from a given patient, treating
and culturing them in vitro and seeding onto a scaffold
which will eventually result in a functioning tissue ready for
implantation back into the patient itself, make the current
bio-engineered tissues unpractical, or definitely not a “real
time” alternative. Ideally, such autologous bio-materials
should instantly be “ready to use” in an off-the-shelf,
custom-made, tailored-to-the-patient’s-size manner, which
will hopefully be achieved through technological advances
in the near future.
In the field of neurological development, enhanced neuro-
imaging modalities have allowed better documentation of
the insults, injuries and malformations, or lack thereof, in
neonates with CHD. Indeed, it is increasingly becoming
apparent that in utero blood flow patterns specific to certain
cardiac lesions which create a relative steal of blood flow
away from the brain lead to significant cerebral lesions by
birth, and therefore already exist prior to any surgical or
interventional procedure on the heart. Although enhanced
imaging and neuro-monitoring capabilities allow for better
spatio-temporal documentation of what has already happened
and how it may evolve in time with follow-up, more needs
to be achieved in understanding exactly what processes lead
to the neurological insults, and more importantly, what
can eventually be done to influence the course of events, or
more ideally, even prevent any harm in the first place. Huge
research efforts are still needed to fully identify, understand
and hopefully influence the patho-physiology of neurological
injury and capacity for repair/regeneration in the heart-brain
axis of patients with CHD.
As the various intricate and delicate stages of embryogenesis
of the heart are better defined and understood, so also has
advanced the bold strategy to intervene and hopefully
influence certain critical key structures and blood flow
patterns in the developing heart. Intrauterine intervention,
either by percutaneous/trans-uteral catheter balloon
dilatation or by open surgical technique, has been successfully
performed, most notably on the aortic valve, in fetuses
with aortic valve stenosis, hypoplasia or atresia and variants
of hypoplastic left heart syndrome (6). The risk-benefit
ratio should take into consideration treating two patients,
the mother and the fetus, since both of the patients could
potentially suffer, and only one (the fetus) benefits. Whether
in-utero treatment techniques can reliably result in favour of
both mother and fetus remains to be demonstrated, which is
why only a few highly specialized centers are undertaking it
with promising results (6).
Although major advances have been made in the field
of genetics with regards to diagnosis which then influences
prognosis and genetic counselling, the vast majority of the
etiology of congenital heart defects remains incompletely
understood or unknown (7). Roughly 30% of CHD patients
have phenotypes which fit into syndromes including
extracardiac manifestations. That leaves about 70% of cases
in which no syndrome exists, and for whom only some have
known Mendelian inheritance (dominant or recessive).
This leaves a lot of room for the interplay of multifactorial
etiologies such as the interactions between multiple genes,
environmental factors, and spontaneous mutations, just
to name a few. Therefore, currently, there is still a time-
lag between the objectives of genetical testing in clinical
practice with a goal to assist in diagnosis, help define
prognosis and aid in parent counselling, or their value for
research purposes which may lead to insights into a disease
entity and potential future therapeutics targets. The future
interplay between clinicians and research laboratories
to bring together patterns of knowledge that fit will be
of paramount value and provide additional keys to the
understanding of the genesis/genetics of CHD.
In conclusion, the field of care for congenital heart
defects has made tremendous strides in its young infancy.
In no other field of science or medicine has so much been
accomplished in so little time, with heart defects that
were an unconditional death sentence 60 years ago, to

6. 111Translational Pediatrics, Vol 5, No 3 July 2016
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):109-111tp.amegroups.com
the current operative survival rates of more than 96% for
all defects considered together. We must give tribute to
bold pioneers in the early days of the 1940’s and 1950’s for
taking the biggest steps, with further refinements in the
1970’s and 1980’s to reach the point where we are today.
However, for certain defects, we are only scratching the
surface, and short-term as well as long-term outcomes
are still unsatisfactory. Owing to huge advances in
perinatal care, increasingly premature babies with complex
syndromes involving multiple organs are no longer
subject to “natural selection” and are surviving, bringing
with them an array of cardiac and associated non-cardiac
malformations that confound not only cardio-pulmonary
physiology, but require a more holistic approach to patient
care. Furthermore, although surviving an operation or
intervention for a congenital heart condition is now
expected for the vast majority of patients as neonates and
infants, the focus is shifting towards quality of life, long-
term issues, and treatment/care algorithms for adults
having survived their initial hurdles, who now represent
the majority of patients with CHD, a new fast-growing
population. Much collaboration, vision and innovation
is still needed to tackle and understand congenital heart
defects, giving providers who are privileged to be involved
in the care of these patients and families challenges for
many decades to come.
Acknowledgements
None.
Footnote
Conflicts of Interest: The author has no conflicts of interest to
declare.
References
1. Gross RE. Surgical management of the patent ductus
arteriosus: with summary of four surgically treated cases.
Ann Surg 1939;110:321-56.
2. Taussig HB, Blalock A. The tetralogy of Fallot; diagnosis
and indications for operation; the surgical treatment of the
tetralogy of Fallot. Surgery 1947;21:145.
3. Lewis FJ, Taufic M. Closure of atrial septal defects with the
aid of hypothermia; experimental accomplishments and the
report of one successful case. Surgery 1953;33:52-9.
4. Gibbon JH Jr. Application of a mechanical heart and lung
apparatus to cardiac surgery. Minn Med 1954;37:171-85;
passim.
5. Lillehei CW, Cohen M, Warden HE, et al. The direct-
vision intracardiac correction of congenital anomalies by
controlled cross circulation; results in thirty-two patients
with ventricular septal defects, tetralogy of Fallot, and
atrioventricularis communis defects. Surgery 1955;38:11-29.
6. Freud LR, McElhinney DB, Marshall AC, et al. Fetal
aortic valvuloplasty for evolving hypoplastic left heart
syndrome: postnatal outcomes of the first 100 patients.
Circulation 2014;130:638-45.
7. Chaix MA, Andelfinger G, Khairy P. Genetic testing in
congenital heart disease: A clinical approach. World J
Cardiol 2016;8:180-91.
Cite this article as: Dodge-Khatami A. Advances and research
in congenital heart disease. Transl Pediatr 2016;5(3):109-111.
doi: 10.21037/tp.2016.05.01

7. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):112-113tp.amegroups.com
The achievements of congenital cardiac surgery over the
past two decades are remarkable. However success comes
at a price and occasionally the “sacrificial lamb” in this
discipline are the branch pulmonary arteries. This is not
to suggest intentional “sacrifice” however the necessity
to provide pulmonary blood flow particularly in single
ventricle palliation requires manipulation and potential
distortion of the branch pulmonary arteries (BPA’s). In a
large randomized trial assessing initial surgical palliation
for hypoplastic left heart syndrome, although antegrade
pulmonary blood flow through a Sano shunt provided an
early survival benefit over a systemic arterial-pulmonary
shunt, re-intervention rates on the BPA’s were significantly
higher in the Sano cohort (1). The impact of pulmonary
artery distortion on long-term survival in single-ventricle
patients dependent on passive pulmonary blood flow is
unclear, however, unlikely to be negligible. The optimal
approach to relieve pulmonary artery narrowing is yet to
be determined. No randomized trials comparing surgical
versus transcatheter options have been published although
non-randomized studies suggest that patients undergoing
surgical branch pulmonary arterioplasty are more likely to
require re-intervention compared to those undergoing stent
placement (2). Equally it is difficult to argue that stents
in their current format are the ideal long-term solution.
Surgical techniques and patch material may vary and hence
influence outcomes, with disappointing recent results seen
with the use of a porcine extracellular matrix patch when
used to patch the pulmonary arteries (3). The ideal material
for surgical patching, which should be pliable and easy to
handle, resistant to tearing, calcification or shrinkage, with
the potential for growth and restoration of vascular function
without the induction of scar tissue may be some way off
yet. In the meantime approaches to circumvent some of the
consequences of suture induced scaring are required.
In this issue of Translational Pediatrics, we review a
recently published novel approach to surgical reconstruction
of the BPA’s in patients with congenital heart disease (4).
Kim et al. described their use of “sutureless” patch
angioplasty for postoperative pulmonary artery narrowing
in 28 patients with a median weight of 7.3 kg, two-thirds
of whom had previous palliation for hypoplastic left heart
syndrome and 85% of whom had a concomitant superior
cavopulmonary anastomosis. The procedure involves
longitudinal opening of the stenosed BPA and enucleation
of the pre-existing patch material from the surrounding
fibrotic tissue. Multiple intimal incisions were made and
followed by stretching the vessel manually with a dilator. In
some cases the entire stenotic area was excised leaving just
the perivascular fibrotic tissue intact. The patch (bovine
pericardium) was then sutured to the perivascular fibrotic
tissue and to the aortic wall to avoid suture mediated
scaring of the intima of the pulmonary artery. Technical and
operative outcomes were excellent. The procedure avoids
extensive dissection of the pulmonary arteries which has
previously proved challenging with retro-aortic stenosis
and may also risk damage to surrounding structures.
Re-intervention was required in only one patient over
the medium-term, with follow-up imaging [computed
tomography (CT) or angiography] demonstrating some
increase in pulmonary artery dimensions at the area of
sutureless patching.
Editorial
The battleground of the stenotic branch pulmonary arteries: the
surgical approach of “less is more”
Damien P. Kenny1
, Jonathan McGuinness1
, Ziyad M. Hijazi2
1
Department of Cardiology and Cardiac Surgery, Our Lady’s Children’s Hospital, Dublin, Ireland; 2
Weill Cornell Medicine, Sidra Medical and
Research Center, Doha, Qatar
Correspondence to: Damien P. Kenny, MD. Department of Cardiology and Cardiac Surgery, Our Lady’s Children’s Hospital, Crumlin, Dublin 12,
Ireland. Email: damien.kenny@olchc.ie.
Submitted May 06, 2016. Accepted for publication May 16, 2016.
doi: 10.21037/tp.2016.05.03
View this article at: http://dx.doi.org/10.21037/tp.2016.05.03

8. 113Translational Pediatrics, Vol 5, No 3 July 2016
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):112-113tp.amegroups.com
The benefit of “sutureless” techniques have evolved from
pulmonary venous reconstruction surgery where exposure
of the vein to suture based trauma may lead to excessive scar
formation and restenosis (5). It is unclear if this approach
will provide similar benefits for mitigating against branch
pulmonary artery distortion in the longer-term. Some
concerns have yet to be addressed. It is unclear if the absence
of intimal tissue will promote true growth of the BPA’s, with
only patch and scar tissue remaining. The impact of suturing
to surrounding vessels, particularly the aorta may distort
the vasculature with growth or increase risk of vascular
compromise if further transcatheter intervention were to
be required. The cause of the sudden massive hemoptysis
in one patient on follow-up raises some questions about the
potential for fistula formation with less integrity to the neo-
pulmonary wall. It is also unclear if loss of vascular function
with near complete excision of the vessel, in the setting of
a circulation dependent of passive pulmonary blood flow,
may have longer-term implications. No mention is made of
the impact of the patch on follow-up surgeries, particularly
completion of the total cavopulmonary anastomosis where
distinguishing the true plane of the pulmonary artery wall
with dissection may be challenging. All things considered
however, this approach is certainly a welcome addition to the
challenge of treating complex BPA narrowing, particularly
in the context of irregular long segment stenoses where
moulding a patch to the native vessel wall, often variable
in diameter, is technically very difficult. It is also likely to
help with accessing a retro-aortic stenosis without extensive
dissection. In the end, the victor in the race to provide the
optimal solution to BPA narrowing is the one most likely to
provide the best long-term impact on normal vessel growth,
and although this technique may provide a preferable
approach in certain anatomical substrates, much work
remains to be done.
Acknowledgements
None.
Footnote
Provenance: This is a Guest Editorial commissioned
by the Section Editor Xicheng Deng (Department of
Cardiothoracic Surgery, Hunan Children’s Hospital,
Changsha, China).
Conflicts of Interest: The authors have no conflicts of interest
to declare.
Comment on: Kim H, Chan Sung S, Choi KH, et al.
Sutureless Patch Angioplasty for Postoperative Pulmonary
Artery Stenosis in Congenital Cardiac Surgeries. Ann
Thorac Surg 2016;101:1031-6.
References
1. Ohye RG, Sleeper LA, Mahony L, et al. Comparison of
shunt types in the Norwood procedure for single-ventricle
lesions. N Engl J Med 2010;362:1980-92.
2. Patel ND, Kenny D, Gonzalez I, et al. Single-center
outcome analysis comparing reintervention rates of
surgical arterioplasty with stenting for branch pulmonary
artery stenosis in a pediatric population. Pediatr Cardiol
2014;35:419-22.
3. Padalino MA, Quarti A, Angeli E, et al. Early and mid-
term clinical experience with extracellular matrix scaffold
for congenital cardiac and vascular reconstructive surgery:
a multicentric Italian study. Interact Cardiovasc Thorac
Surg 2015;21:40-9.
4. Kim H, Chan Sung S, Choi KH, et al. Sutureless Patch
Angioplasty for Postoperative Pulmonary Artery Stenosis
in Congenital Cardiac Surgeries. Ann Thorac Surg
2016;101:1031-6.
5. Yun TJ, Coles JG, Konstantinov IE, et al. Conventional
and sutureless techniques for management of the
pulmonary veins: Evolution of indications from
postrepair pulmonary vein stenosis to primary
pulmonary vein anomalies. J Thorac Cardiovasc Surg
2005;129:167-74.
Cite this article as: Kenny DP, McGuinness J, Hijazi ZM.
The battleground of the stenotic branch pulmonary arteries:
the surgical approach of “less is more”. Transl Pediatr
2016;5(3):112-113. doi: 10.21037/tp.2016.05.03

9. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):114-124tp.amegroups.com
Original Article
Antegrade cerebral perfusion at 25 ℃ for arch reconstruction
in newborns and children preserves perioperative cerebral
oxygenation and serum creatinine
Bhawna Gupta1
, Ali Dodge-Khatami1
, Juan Tucker1
, Mary B. Taylor2
, Douglas Maposa3
, Miguel Urencio1
,
Jorge D. Salazar1
1
Division of Cardiothoracic Surgery, 2
Divisions of Pediatric Critical Care and Pediatric Cardiology, 3
Division of Pediatric Anesthesiology, The
Children’s Heart Center, The University of Mississippi Medical Center, Jackson, Mississippi, USA
Contributions: (I) Conception and design: All authors; (II) Administrative support: B Gupta, A Dodge-Khatami, JD Salazar; (III) Provision of
study materials or patients: B Gupta, A Dodge-Khatami, J Tucker, JD Salazar; (IV) Collection and assembly of data: None; (V) Data analysis and
interpretation: B Gupta, A Dodge-Khatami, J Tucker, JD Salazar; (VI) Manuscript writing: All authors; (VII) Final approval of manuscript: All
authors.
Correspondence to: Jorge D. Salazar, MD. Division of Cardiothoracic Surgery, University of Mississippi Medical Center, 2500 North State Street,
Jackson, MS 39216, USA. Email: jsalazar@umc.edu.
Background: Antegrade cerebral perfusion (ACP) typically is used with deep hypothermia for cerebral
protection during aortic arch reconstructions. The impact of ACP on cerebral oxygenation and serum
creatinine at a more tepid 25 ℃ was studied in newborns and children.
Methods: Between 2010 and 2014, 61 newborns and children (<5 years old) underwent aortic arch
reconstruction using moderate hypothermia (25.0±0.9 ℃) with ACP and a pH-stat blood gas management
strategy. These included 44% Norwood-type operations, 30% isolated arch reconstructions, and 26%
arch reconstructions with other major procedures. Median patient age at surgery was 9 days (range,
3 days–4.7 years). Cerebral oxygenation (NIRS) was monitored continuously perioperatively for 120 hours.
Serum creatinine was monitored daily.
Results: Median cardiopulmonary bypass (CPB) and cross clamp times were 181 minutes (range,
82–652 minutes) and 72 minutes (range, 10–364 minutes), respectively. ACP was performed at a mean
flow rate of 46±6 mL/min/kg for a median of 48 minutes (range, 10–123 minutes). Cerebral and somatic
NIRS were preserved intraoperatively and remained at baseline postoperatively during the first 120 hours.
Peak postoperative serum creatinine levels averaged 0.7±0.3 mg/dL for all patients. There were 4 (6.6%)
discharge mortalities. Six patients (9.8%) required ECMO support. Median postoperative length of
hospital and intensive care unit (ICU) stay were 16 days(range, 4–104 days) and 9 days (range, 1–104 days),
respectively. Two patients (3.3%) received short-term peritoneal dialysis for fluid removal, and none required
hemodialysis. Three patients (4.9%) had an isolated seizure which resolved with medical therapy, and none
had a neurologic deficit or stroke.
Conclusions: ACP at 25 ℃ preserved perioperative cerebral oxygenation and serum creatinine for
newborns and children undergoing arch reconstruction. Early outcomes are encouraging, and additional
study is warranted to assess the impact on late outcomes.
Keywords: Antegrade cerebral perfusion (ACP); moderate hypothermia; circulatory arrest; infants; aortic arch
Submitted Apr 28, 2016. Accepted for publication May 26, 2015.
doi: 10.21037/tp.2016.06.03
View this article at: http://dx.doi.org/10.21037/tp.2016.06.03

10. 115Translational Pediatrics, Vol 5, No 3 July 2016
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Introduction
Complex aortic arch reconstruction in neonates and
children is performed typically under deep hypothermic
circulatory arrest (DHCA). This approach has enabled
successful outcomes over many decades (1), with cerebral
protection achieved by reducing brain metabolism and
oxygen requirements. The risk of injury associated with
DHCA is not clear, although long periods have been
associated with seizures and choreoathetosis (2,3). Long-
term neurological complications may manifest as impaired
neurodevelopment, with the worst outcomes being
observed in newborns with complex congenital heart lesions
in need for aortic arch reconstruction under prolonged
periods of DHCA (2,4-7). With the intent of maximizing
cerebral protection, surgical and perfusion strategies have
been developed to selectively perfuse the brain during these
operations.
Antegrade cerebral perfusion (ACP) at deep hypothermia
emerged as an adjunctive perfusion strategy to DHCA
aiming to minimize the use of circulatory arrest and offer
additional cerebral protection during arch operations.
During ACP, blood flow is supplied to the brain selectively
during the critical period of arch reconstruction, while at
least partial somatic flow is achieved through collaterals.
Somatic ischemia is theoretically lessened during arch
reconstruction and the risks of neurological and cognitive
deficits following operation are presumably reduced (8,9).
With increased experience with ACP in the field of adult
aortic arch reconstruction, a more recent evolution from
deep hypothermia toward the use of warmer temperatures
has occurred (10-12).
The use of tepid temperatures for ACP potentially
may reduce the deleterious effects associated with deep
hypothermia and rewarming (13). But this cannot be at
the expense of cerebral and somatic protection. In the
absence of a standardized nomenclature, a recent consensus
panel categorized the temperatures into ‘deep’ for a
nasopharyngeal temperature of 14.1–20 ℃, ‘moderate’ for
20.1–28 ℃ and ‘mild’ for 28.1–34 ℃ (14). Mild-moderate
hypothermia with ACP is now utilized widely in adults,
and although not supported by formal and prospective
neurocognitive outcomes data, appears to be a safe and
effective strategy for both neurological and somatic
protection for periods of less than 60 minutes (10,15,16).
In newborns and infants, extended end-to-end repair of
coarctation is performed routinely at near-normothermia
with all cerebral and systemic perfusion achieved via the
innominate artery for periods of approximately 20 minutes,
without clinically significant neurological or end-organ
injury (17). Notwithstanding, few reports evaluate the use
of moderate hypothermia for ACP in neonates and children
undergoing aortic arch reconstructions (11,12,18-20).
To this end, our specific aim was to further assess
the perioperative impact of ACP at 25 ℃ on cerebral
oxygenation and serum creatinine in newborns and children
undergoing arch reconstructions. Herein, we report our
experience and outcomes.
Methods
Institutional Review Board approval was obtained for this
retrospective study and patient/parent consent was waived.
Between 2010 and 2014, 61 patients less than 5 years of age
underwent complex aortic arch operation using moderate
hypothermia with ACP (40–60 mL/kg/min) and a pH-stat
blood gas management strategy. The medical records were
reviewed for demographics, preoperative diagnosis, and
perioperative course. The patients were categorized into
three groups: Stage I or Norwood-type operations (Stage I),
isolated aortic arch reconstructions (Arch), and aortic
arch reconstructions with other major cardiac procedures
(Arch++). Patients with obstructed pulmonary venous return
were excluded from this study.
Surgical technique
All operations were performed using a physiologic blood-
prime followed by cooling with full-flow cardiopulmonary
bypass (CPB) (150 mL/kg/min) using a 6 ℃ temperature
gradient to moderate hypothermia (25 ℃). A pH-stat
blood gas management strategy, pO2 of 150 mmHg, and
hematocrit of 30% were maintained. ACP was delivered
via the innominate artery or equivalent with flow rates of
40–60 mL/kg/min, maintaining a mean arterial pressure
appropriate for the age of the child (25–55 mmHg). During
ACP, the arch branches and descending thoracic aorta
were controlled with snares or fine clamps to maintain a
bloodless field and maintain cerebral and systemic perfusion
pressure. Upon completion of the reconstruction, de-airing,
and removal of snares or clamps, ACP was followed by re-
warming with full-flow CPB at a maximum gradient of 6 ℃.
Cerebral and somatic oxygenation monitoring
Bilateral cerebral and single somatic oximetry were

11. 116 Gupta et al. ACP at 25 ℃
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monitored continuously and recorded by near-infrared
spectroscopy (NIRS) (Somanetics, INVOS 5100C,
Covidien) in all patients, both intraoperatively and
postoperatively for 120 hours or until discharge from
the intensive care unit (ICU). The non-invasive NIRS
probe measures the regional oxygen saturation (rSO2) as a
percentage on a scale from 15% to 95%. The probes were
placed on both sides of the forehead for cerebral (left and
right) readings, and over the right flank for somatic rSO2
readings. For this study, the data were recorded at the
following time points: baseline (before CPB), start of CPB,
cooling, aortic cross-clamping, start of ACP, during ACP,
end of ACP, un-clamping, re-warming, end of CPB, and
postoperatively for 120 hourly intervals.
Clinical outcomes and serum creatinine
The intraoperative variables assessed were CPB time,
aortic cross-clamp time, ACP flow and time, and lactate
levels. Serum creatinine and lactate levels were recorded
preoperatively and postoperatively on a daily basis until
hospital discharge. Postoperative variables analyzed
included postoperative length of ICU and hospital stay,
need for extracorporeal membrane oxygenation (ECMO),
need for postoperative peritoneal dialysis or dialysis, need
for gastrostomy tube, neurological complications (seizures,
neurological deficit and stroke), and discharge mortality.
Statistical analysis
Data are shown as mean ± standard deviation (SD), median
and range (minimum, maximum), or N (%). Given the
number of patients and low incidence of complications,
additional statistical analysis was not meaningful clinically
or statistically.
Results
Patient characteristics
The characteristics for all 61 patients are outlined in Table 1.
Median age at surgery was 9 days, with 72% being neonates
and 20% infants between 1 month and 1 year of age.
Thirty-two patients were male. Among the three groups
analyzed, 27 patients (44%) underwent a Norwood-type
(Stage I) operation for hypoplastic left heart syndrome
(HLHS) or single ventricle variants with arch hypoplasia
[unbalanced atrioventricular canal, truncus arteriosus with
hypoplastic arch, transposition of the great arteries (TGA)
with hypoplastic arch, or interrupted arch]. Of these,
25/27 (93%) Stage I operations received a right ventricle-
to-pulmonary artery shunt (Sano). In the second group,
eighteen patients (30%) underwent isolated reconstruction
of the aortic arch (Arch). In the third group (Arch++),
sixteen (26%) patients underwent aortic arch reconstruction
along with other major procedures such as a Damus-
Kaye-Stansel reconstruction with bidirectional Glenn
(Comprehensive stage II), subaortic resection, ventricular
septal defect closure, aortic/truncal root replacement, or
supravalvular aortic stenosis repair.
Operative outcomes
The operative outcomes are summarized in Table 2. All
aortic arch operations were performed at a mean rectal
temperature of 25.0±0.9 ℃. Mean CPB and aortic cross-
clamp times for all sixty-one patients were 195±95 and
87±61 min, respectively. ACP was performed at a mean flow
rate of 46±6 mL/min/kg for 52±22 minutes.
Cerebral and somatic oxygenation
The cerebral and somatic NIRS (rSO2) readings are shown
Table 1 Patient characteristics
Variable All patients (N=61)
Age at surgery
Median (range) 9 days
(3 days–4.7 years)
≤1 month, N [%] 44 [72]
1–6 months, N [%] 8 [13]
6-mo–1 year, N [%] 4 [7]
1–5 years, N [%] 5 [8]
Gestational age, weeks (for ≤1 month) 38.4±1.2
Gender, male/female, N 32/29
Birth weight, kg 3.2±0.5
Prematurity <37 weeks, N 8
Birth weight <2.5 kg, N 5
Type of procedure
Stage I: Stage I or Norwood type (93%
Sano), N (%)
27 [44]
Arch: isolated aortic arch reconstruction,
N (%)
18 [30]
Arch++
: arch plus other major, N (%) 16 [26]

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in Figures 1-3. Cerebral NIRS readings stayed above
baseline throughout surgery, with no clinically-significant
differences in the intraoperative NIRS readings between
the left and right cerebral hemispheres for all patients
(Figure 1). Somatic NIRS stayed above baseline during
cooling, dropped somewhat during ACP, and rebounded
quickly after ACP.
Postoperatively, cerebral and somatic NIRS remained
near or at baseline during the first 24 hours and beyond for
all groups (Figures 2,3).
Postoperative course
The postoperative outcomes for all 61 patients and by
procedure group are described in Table 3. Of the 61
patients, a total of 6 (9.8%) required ECMO. Three were
in the Stage I (Norwood) group, and the other three had
Arch++ procedures. Median postoperative lengths of
hospital and ICU stay for all sixty-one patients were 16 days
(range, 4–104 days) and 9 days (range, 1–104 days),
respectively. Two patients in the Stage I group received
temporary peritoneal dialysis postoperatively for fluid
removal. No patient required hemodialysis. None of the
patients demonstrated evidence of liver dysfunction. Three
patients (4.9%) had an isolated seizure after surgery, two
of which were confirmed by electroencephalogram. None
persisted after initiation of medical therapy. None of the
patients had a neurologic deficit or stroke. Although not the
focus of this study, representative pre- and post-operative
brain MRI imaging is demonstrated in Figure 4.
Table 2 Operative characteristics
Operative outcome All patients (N=61) Stage I (N=27) Arch (N=18) Arch++
(N=16)
Age at surgery, days 9 [3, 4.7 y] 7 [3, 47] 12.5 (4, 3.2 y) 131 (3, 4.7 y)
Weight at surgery, kg 3.5 [2.0, 16.0] 3.1 [2.0, 4.1] 3.8 [2.6, 14.0] 4.2 [2.0, 16.0]
Peak preoperative serum creatinine, mg/dL 0.5±0.1 0.5±0.2 0.4±0.1 0.4±0.1
Peak preoperative serum lactate, mmol/L 1.8±1.1 2.0±1.4 1.6±0.5 1.6±0.6
Cross clamp time, min 72 [10, 364] 86 [47, 184] 39 [10, 104] 107 [43, 364]
ACP time, min 48 [10, 123] 63 [32, 123] 36 [10, 62] 44 [22, 102]
ACP flow, mL/kg/min 46±6 44±5 48±6 48±5
Total CPB time, min 181 [82, 652] 205 [139, 328] 109 [82, 194] 192 [97, 652]
Peak intraoperative serum lactate, mmol/L 5.2±2.4 5.8±1.7 4.2±2.7 5.3±2.9
Creatinine, lactate and ACP flow are presented as mean ± SD. Age, weight, cross clamp time, ACP time and CPB time are presented as
median and range (min, max). ACP, antegrade cerebral perfusion; CPB, cardiopulmonary bypass; SD, standard deviation.
Figure 1 Intraoperative cerebral/somatic NIRS for all patients.

13. 118 Gupta et al. ACP at 25 ℃
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Figure 2 Mean cerebral and somatic NIRS during surgery broken down into subgroups. (A) Perioperative mean cerebral and somatic NIRS
for Stage I group; (B) perioperative mean cerebral and somatic NIRS for Arch group; (C) perioperative mean cerebral and somatic NIRS for
Arch++ group.
A
B
C

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Figure 3 (A) Perioperative mean cerebral left NIRS by reconstruction group; (B) perioperative mean cerebral right NIRS by reconstruction
group; (C) perioperative mean somatic NIRS by reconstruction group.
A
B
C
Serum creatinine
The mean of the peak serum creatinine levels is shown
in Figure 5. The peak creatinine for all patients averaged
0.7±0.3 mg/dL. The highest postoperative creatinine of any
single patient was 1.48 mg/dL.
Discharge mortality
Overall, there were four discharge mortalities (6.6%).
One patient underwent Stage I with a 3.5-mm modified
Blalock-Taussig shunt. After an uneventful postoperative
course and chest closure, the patient was placed on ECMO

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Figure 4 Pre- and Postoperative MRI brain imaging.
Table 3 Postoperative outcomes
Postoperative outcome All patients (N=61) Stage I (N=27) Arch (N=18) Arch++ (N=16)
Discharge mortality, N (%) 4 (6.6%) 2 (7.4%) 0 2 (12.5%)
Need for ECMO, N (%) 6 (9.8%) 3 (11.1%) 0 3 (18.8%)
ICU stay, days 9 [1, 104] 12 [6, 104] 5 [1, 43] 8 [2, 63]
Postop hospital stay, days 16 [4, 104] 22 [11, 104] 11 [4, 45] 10 [4, 78]
Peak postop serum creatinine until discharge, mg/dL 0.7±0.3 0.8±0.3 0.6±0.2 0.6±0.2
Peak 24 hr postoperative serum lactate, mmol/L 3.9±2.3 5.0±2.7 2.8±1.3 3.4±1.6
Use of temporary peritoneal dialysis, N (%) 2 (3.3%) 2 (7.4%) 0 (0%) 0 (0%)
Need for G-tube, N (%) 15 (24.6%) 11 (40.0%) 3 (20.0%) 1 (6.2%)
Postoperative seizures, N (%) 3 (4.9%) 1 (3.7%) 1 (5.5%) 1 (6.2%)
Neurologic deficit/stroke, N (%) 0 (0%) 0 (0%) 0 (0%) 0 (0%)
Serum creatinine and lactate are presented as mean ± SD. ICU and postoperative hospital stay are presented as median and range (min,
max). ECMO, extracorporeal membrane oxygenation; ICU, intensive care unit; Postop, postoperative; G-tube, gastrostomy tube; SD,
standard deviation.
Pre-op MRI (Baby M)
Post-op MRI (Baby M)
on postoperative day (POD) 6 for respiratory distress
and ultimately expired on POD 55. The second patient
underwent late stage I with Sano after presenting at 6 weeks
of age. Despite a favorable neurological and hemodynamic
result, the child died of chronic respiratory failure on POD
104. The third patient underwent Stage I and interrupted
aortic arch repair. Initially the child did well neurologically
and hemodynamically but was placed on ECMO on POD 4
for sudden cardiac arrest. During ECMO wean, the circuit
clotted acutely and the child died on POD 8. The fourth
patient underwent redo truncal valve replacement and arch
reconstruction. The patient was placed on post-operative
ECMO for bleeding and inability to separate from CPB
from pulmonary dysfunction. The child separated from

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ECMO but ultimately expired on POD 35.
Discussion
Deep hypothermic circulatory arrest is the traditional
approach for operations involving aortic arch reconstruction
in adults and children, acknowledging the potential for
neurological complications including cognitive deficits. The
transition from the DHCA paradigm toward ACP with deep
hypothermia was aimed to maximize cerebral protection
during arch operations while minimizing any morbidity.
Antegrade cerebral perfusion is used now by many centers
as a perfusion adjunct under deep hypothermia to minimize
the use of circulatory arrest during neonatal aortic arch
reconstruction (21), with the expectation of mitigating
neurological and somatic morbidity. A comparison of
DHCA alone versus continuous low-flow cerebral perfusion
in infants has suggested more neurological perturbations
and a greater likelihood of clinical seizures in the early
postoperative period of the DHCA alone group (3). Other
reports advocate the use of ACP over DHCA alone to not
only attenuate neurological morbidity but also to achieve
somatic protection during arch reconstruction (5,22-25).
However, other reports question the advantage of ACP
over DHCA alone, detecting no difference in the incidence
of new white matter injury or cerebral ischemic lesions
postoperatively, nor any benefit on psychomotor and mental
development status between the two groups of ACP versus
DHCA alone (26-30).
It is worth mentioning that even though ACP is used
routinely in many centers, there exist wide variations in the
specific details of the perfusion strategy. ACP flow rates,
blood gas temperature correction (pH versus alpha stat), time
required for the repair, hematocrit, pO2, and even cannulation
strategies vary significantly, making it challenging to evaluate
the benefit of cerebral perfusion during arch repairs. Despite
the lack of a standardized protocol for ACP and some
inconsistency in the reported results, there does appear to be
an increasing trend toward ACP (with deep hypothermia)
over DHCA for neonatal arch reconstruction (31).
The optimal temperature for complex aortic arch
reconstructions with ACP remains a topic of debate. Many
adult centers have shifted toward the use of mild-to-moderate
temperatures with encouraging results (10,15,32-35).
While conclusive evidence is lacking, these encouraging
outcomes coupled with shorter CPB times and avoiding the
morbidity of deep hypothermia have led to the increasing
clinical acceptance of tepid ACP for arch repair in adults.
Moderate hypothermia with ACP has been explored in
Europe and Asia for neonatal arch operations, although
the typical practice in North America has been to use deep
hypothermia with ACP or DHCA alone. Oppido et al.
reported 17% early mortality and 8.5% late deaths over a
follow-up of up to 50 months in a group of 70 consecutive
neonates who underwent the Norwood procedure or aortic
arch repair at a nasopharyngeal temperature of 25 ℃ with
ACP (18). Only one patient had postoperative seizures.
The authors suggested ACP to be an effective and reliable
perfusion strategy that provides a longer safe period for arch
repairs and minimizes neurological complications without
Figure 5 Peak perioperative creatinine for all patients.

17. 122 Gupta et al. ACP at 25 ℃
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the need for deep hypothermia. Likewise, Lim et al. (11),
Dodge-Khatami et al. (12), Miyaji et al. (20) and Ly et al. (36)
demonstrated in neonates and infants the effectiveness of
antegrade cerebral perfusion at moderate hypothermia at
preserving both cerebral and somatic tissue oxygenation.
Previously, we evaluated moderate (25 ℃) and deep
(18 ℃) hypothermia with ACP in a piglet model for arch
operation (37-39). These studies demonstrated improved
neuroprotection at 18 and 25 ℃ with ACP as compared
to DHCA alone, with shorter CPB times at 25 ℃, and
laid the foundation for our clinical practice of moderate
hypothermia with ACP during neonatal aortic arch repair.
We have employed moderate hypothermia (25 ℃) with
ACP for all aortic arch reconstructions at the University
of Mississippi Medical Center since program inception in
April of 2010.
The ideal flow rate for ACP is dependent on many factors
and remains to be established. Although the cited literature
varies widely in range for ACP from 10 to 100 mL/kg/min,
studies utilizing NIRS technology or visual light spectroscopy
have indicated that ACP flow rates of greater than
30 mL/kg/min are sufficient to maintain adequate cerebral
and somatic oxygen saturations (12,19,40). Admittedly, these
findings must be evaluated within the context of temperature
and blood gas management (pH versus alpha stat) among
other factors. We use ACP at a flow rate of 40–60 mL/kg/min
under NIRS guidance to monitor both cerebral and
somatic oxygen levels. In the current study, NIRS supports
the effectiveness of ACP at 25 ℃ systemic cooling in
maintaining adequate cerebral and lower body perfusion.
Although somatic NIRS dropped during ACP, they remained
close to baseline levels, suggesting that an ACP flow at
40–60 mL/kg/min was sufficient in maintaining adequate
perfusion through collaterals to the lower body and
attenuating somatic ischemia during arch operation at 25 ℃.
This is further supported by favorable postoperative lactate
and serum creatinine levels.
Conclusions
The present study suggests that moderate hypothermia
(25 ℃) with ACP preserves perioperative cerebral
oxygenation and serum creatinine in neonates, infants, and
children for complex aortic arch operations.
Limitations
The study is limited by the lack of a control group with
DHCA alone or ACP at deep hypothermia. Intra-operative
electroencephalogram, which does not always correlate with
right and left cerebral NIRS, was not performed, and could
have disclosed abnormal neurological activity undetected by
NIRS. Long-term neurodevelopmental follow-up of these
children is required to evaluate the late outcomes of ACP
with warmer temperatures and make formal comparison
with strategies at 18 ℃.
Acknowledgements
None.
Footnote
Conflicts of Interest: The authors have no conflicts of interest
to declare.
Ethical Statement: Institutional Review Board (2014-0107)
approval was obtained for this retrospective study and
patient/parent consent was waived.
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intestinal injury during neonatal aortic arch reconstruction.
J Thorac Cardiovasc Surg 2012;144:1323-8, 1328.
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27. Dent CL, Spaeth JP, Jones BV, et al. Brain magnetic
resonance imaging abnormalities after the Norwood
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28. Visconti KJ, Rimmer D, Gauvreau K, et al. Regional low-
flow perfusion versus circulatory arrest in neonates: one-
year neurodevelopmental outcome. Ann Thorac Surg
2006;82:2207-11; discussion 2211-3.
29. Goldberg CS, Bove EL, Devaney EJ, et al. A randomized
clinical trial of regional cerebral perfusion versus deep
hypothermic circulatory arrest: outcomes for infants with
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2007;133:880-7.
30. Algra SO, Jansen NJ, van der Tweel I, et al. Neurological
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19. 124 Gupta et al. ACP at 25 ℃
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Cite this article as: Gupta B, Dodge-Khatami A, Tucker J,
Taylor MB, Maposa D, Urencio M, Salazar JD. Antegrade
cerebral perfusion at 25 ℃ for arch reconstruction in newborns
and children preserves perioperative cerebral oxygenation
and serum creatinine. Transl Pediatr 2016;5(3):114-124. doi:
10.21037/tp.2016.06.03
controlled trial of 2 perfusion techniques. Circulation
2014;129:224-33.
31. Ohye RG, Goldberg CS, Donohue J, et al. The quest
to optimize neurodevelopmental outcomes in neonatal
arch reconstruction: the perfusion techniques we use
and why we believe in them. J Thorac Cardiovasc Surg
2009;137:803-6.
32. Pacini D, Di Marco L, Leone A, et al. Antegrade selective
cerebral perfusion and moderate hypothermia in aortic
arch surgery: clinical outcomes in elderly patients. Eur J
Cardiothorac Surg 2012;42:249-53; discussion 253.
33. Leshnower BG, Myung RJ, Chen EP. Aortic arch surgery
using moderate hypothermia and unilateral selective
antegrade cerebral perfusion. Ann Cardiothorac Surg
2013;2:288-95.
34. Urbanski PP, Lenos A, Bougioukakis P, et al. Mild-
to-moderate hypothermia in aortic arch surgery
using circulatory arrest: a change of paradigm? Eur J
Cardiothorac Surg 2012;41:185-91.
35. Tian DH, Wan B, Bannon PG, et al. A meta-analysis
of deep hypothermic circulatory arrest versus moderate
hypothermic circulatory arrest with selective antegrade
cerebral perfusion. Ann Cardiothorac Surg 2013;2:148-58.
36. Ly M, Roubertie F, Belli E, et al. Continuous cerebral
perfusion for aortic arch repair: hypothermia versus
normothermia. Ann Thorac Surg 2011;92:942-8;
discussion 948.
37. Salazar JD, Coleman RD, Griffith S, et al. Selective
cerebral perfusion: real-time evidence of brain oxygen
and energy metabolism preservation. Ann Thorac Surg
2009;88:162-9.
38. Salazar J, Coleman R, Griffith S, et al. Brain preservation
with selective cerebral perfusion for operations requiring
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Cardiothorac Surg 2009;36:524-31.
39. Allibhai T, DiGeronimo R, Whitin J, et al. Effects of
moderate versus deep hypothermic circulatory arrest
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bypass. J Thorac Cardiovasc Surg 2009;138:1290-6.
40. Amir G, Ramamoorthy C, Riemer RK, et al. Visual
light spectroscopy reflects flow-related changes in brain
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hypothermic circulatory arrest. J Thorac Cardiovasc Surg
2006;132:1307-13.

20. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):125-133tp.amegroups.com
Original Article
How to set-up a program of minimally-invasive surgery for
congenital heart defects
Juan-Miguel Gil-Jaurena1,2
, Ramón Pérez-Caballero1,2
, Ana Pita-Fernández1,2
, María-Teresa González-
López1,2
, Jairo Sánchez3
, Juan-Carlos De Agustín4
1
Department of Pediatric Cardiac Surgery, Hospital Gregorio Marañón, Madrid, Spain; 2
Department of Instituto de Investigación Sanitaria Gregorio
Marañón, Madrid, Spain; 3
Department of Pediatric Cardiac Surgery, Instituto Cardiológico, Bucaramanga, Colombia; 4
Department of Pediatric
Surgery, Hospital Gregorio Marañón, Madrid, Spain
Contributions: (I) Conception and design: JM Gil-Jaurena; (II) Administrative support: R Pérez-Caballero, JC De Agustín; (III) Provision of study
materials or patients: A Pita-Fernández , MT González-López; (IV) Collection and assembly of data: JM Gil-Jauren, MT González-López; (V) Data
analysis and interpretation: JM Gil-Jaurena, JC De Agustín; (VI) Manuscript writing: All authors; (VII) Final approval of manuscript: All authors.
Correspondence to: Juan-Miguel Gil-Jaurena. Pediatric Cardiac Surgery, Hospital Gregorio Marañón, C/O´Donnell nº50, 28009, Madrid, Spain.
Email: giljaurena@gmail.com.
Background: Mid-line sternotomy is the commonest incision for cardiac surgery. Alternative approaches
are becoming fashionable in many centres, amidst some reluctance because of learning curves and overall
complexity. Our recent experience in starting a new program on minimally invasive pediatric cardiac surgery
is presented. The rationale for a stepwise onset and the short-medium term results for a three-year span are
displayed.
Methods: A three-step schedule is planned: First, an experienced surgeon (A) starts performing simple
cases. Second, new surgeons (B, C, D, E) are introduced to the minimally invasive techniques according
to their own proficiency and skills. Third, the new adopters are enhanced to suggest and develop further
minimally invasive approaches. Two quality markers are defined: conversion rate and complications.
Results: In part one, surgeon A performs sub-mammary, axillary and lower mini-sternotomy approaches
for simple cardiac defects. In part two, surgeons B, C, D and E are customly introduced to such incisions. In
part three, new approaches such as upper mini-sternotomy, postero-lateral thoracotomy and video-assisted
mini-thoracotomy are introduced after being suggested and developed by surgeons B, C and E, as well as an
algorithm to match cardiac conditions and age/weight to a given alternative approach. The conversion rate
is one out of 148 patients. Two major complications were recorded, none of them related to our alternative
approach. Four minor complications linked to the new incision were registered. The minimally invasive to
mid-line sternotomy ratio rose from 20% in the first year to 40% in the third year.
Conclusions: Minimally invasive pediatric cardiac surgery is becoming a common procedure worldwide.
Our schedule to set up a program proves beneficial. The three-step approach has been successful in our
experience, allowing a tailored training for every new surgeon and enhancing the enthusiasm in developing
further strategies on their own. Recording conversion-rates and complications stands for quality standards. A
twofold increase in minimally invasive procedures was observed in two years. The short-medium term results
after three years are excellent.
Keywords: Sternotomy; minimally invasive; sub-mammary; axillary; thoracoscopy; video-assisted
Submitted Apr 19, 2016. Accepted for publication May 25, 2016.
doi: 10.21037/tp.2016.06.01
View this article at: http://dx.doi.tp/10.21037/tp.2016.06.01

21. 126 Gil-Jaurena et al. Setting-up a congenital minimally-invasive program
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):125-133tp.amegroups.com
Introduction
Surgical closure of cardiac defects via a full mid-line
sternotomy has been considered the gold standard for over
50 years. The rise of interventional cardiology and new
techniques like laparoscopy or thoracoscopy have prompted
some groups to explore alternative approaches to median
sternotomy (1-7). New adopters and reluctant ones have
their own reasons. Added complexity, longer overall and
ischemic times and even results account for the balance of
the latter.
Among the most frequent alternative approaches (Figure 1)
we find: lower mini-sternotomy (8-11), right sub-mammary
(1,12-16), postero-lateral thoracotomy (17,18) and right
axillary incisions (19-23). Main advantages are cosmesis and
earlier recovery, as well as saving blood products and lower
infection rates. On the other hand, a steep learning curve
and technical difficulties in handling some steps (myocardial
protection, de-airing maneuvers, and so on) discourage
many surgeons to include these minimally invasive
procedures within their routine practice.
Trying to schedule a program for starting and teaching
minimally invasive pediatric cardiac surgery is a step
forward. Few reports can be found in the literature on
the topic, if any, except for the right mini-thoracotomy
approach employed for mitral repair (23-27) in adult
cardiac surgery. In the next paragraphs, we will depict our
experience in developing a minimally invasive pediatric
cardiac surgery program, pointing out the steps followed as
well as the insights provided by the new adopters.
Methods
Upon arrival to a medium-volume centre in which
approximately two hundred pump cases per year are
carried out, Surgeon A is expected to develop a program
of minimally-invasive pediatric cardiac surgery. He has
been performing minimally invasive procedures for twelve
years in two previous institutions and has produced several
papers on the topic (6,16,22,23,28,29) , as well as many
presentations in local meetings.
The strategy to establish a new program is split in three
parts, assuming some overlapping rather than a formal
schedule in a three year analysis:
(I) Performing minimally invasive cases (surgeon A)
with every member of the surgical team (surgeons,
anesthesiologists, perfusionists, scrub nurses) to let
them become familiar and confident with the new
approaches;
(II) Introducing new surgeons to minimally invasive
surgery in a stepwise and customized way,
according to expertise and skills;
(III) Developing new strategies together, particularly
enhanced by the young staff members.
On the other hand, some quality indicators will be
measured, such as:
(I) Conversion rate. If so, was it to sternotomy or
another incision?
(II) Complications. Trying to figure out whether the
alternative approach is to blame for the drawback
or if any other cause was responsible for it.
To begin with, a minimally invasive incision will be
A B
C D
Figure 1 Range of approaches introduced by the leading surgeon.
(A) Full mid-line sternotomy; (B) lower mid-line sternotomy;
(C) right sub-mammary approach; (D) right axillary incision.

22. 127Translational Pediatrics, Vol 5, No 3 July 2016
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defined as “surgical approach other than full mid-line sternotomy
to perform open heart surgery with extracorporeal circulation”.
Three main surgical approaches were introduced by
surgeon A: sub-mammary, axillary and lower mini-
sternotomy. A single alternative incision gives way either to
cannulation maneuvers and correction, with the philosophy
of “same steps, same tools, same risks, different approach”. Later
in the program (as will be thoroughly displayed in Results
and Discussion) several new approaches were added: upper
mini-sternotomy, postero-lateral thoracotomy and video-
assisted mini-thoracotomy (for which several ports were
necessary). Not included in the tables, some off-pump cases
via thoracotomy and thoracoscopy were performed, as some
experience was acquired by the team.
Before starting any procedure, the proposed incision is
drawn with a sterile pen for teaching purposes. Should an
enlargement or conversion be needed, security margins
are settled (e.g., lower mini-sternotomy enlargement to
full sternotomy, or axillary incision conversion to postero-
lateral one). Brief description of the minimally invasive
approaches:
(I) Sub-mammary. Supine position with the right
shoulder slightly elevated and the right arm
suspended over the head. Skin incision under the
right sub-mammary crease (or 6th intercostal space
in children). En-block dissection of subcutaneous
tissue and pectoral muscle (30,31). Cage-rib entry
in the 4th intercostal space. Full cannulation and
correction under cardioplegic arrest (Figures 1C,2);
(II) Axillary. Decubitus lateral position with the right
arm suspended over the head. Skin incision in the
axillary groove, between anterior and posterior lines.
Serratus and latissimus dorsi muscles sparing (28)
technique. Cage-rib entry in the 4th intercostal
space. Full cannulation and correction under
cardioplegic arrest (Figures 1D,3);
(III) Lower mini-sternotomy. Supine position. Skin
vertical incision below an imaginary line connecting
both nipples. Partial lower sternotomy. Regular
spreader plus cephalad traction of the sternum.
Full cannulation and correction under cardioplegic
arrest (Figures 1B,4);
(IV) Upper mini-sternotomy. Supine position. Skin vertical
incision above an imaginary line connecting both
nipples. Partial upper sternotomy. Full cannulation
and correction under cardioplegic arrest;
(V) Postero-lateral thoracotomy. Decubitus lateral
position with the right arm suspended over the
head. Skin incision between anterior axillary line
and spine (the tip of the scapula being the mid-
point). Cage-rib entry in the 4th intercostal space.
Full cannulation and correction under cardioplegic
arrest (Figure 3A);
(VI) Video-assisted mini-thoracotomy. Supine position
with the right shoulder slightly elevated and the
right arm secured below the axilla. Mini-skin
incision under the right sub-mammary crease.
Right jugular and right femoral (arterial and
venous) cannulation to institute by-pass. Additional
ports for video-assistance, aortic clamp and others.
A B
A B
Figure 2 Sub-mammary approach in an adolescent female. Note
the landmarks (A) and final aesthetic result (B).
Figure 3 Right horizontal axillary incision. Note the landmarks
between the nipple and the tip of the scapulla as well as the
proposed conversion to a postero-lateral incision if needed (A).
Final result six months later (B).

23. 128 Gil-Jaurena et al. Setting-up a congenital minimally-invasive program
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):125-133tp.amegroups.com
Correction under cardioplegic arrest.
Results
Part one
Surgeon A began his program with sub-mammary, axillary
and lower mini-sternotomy cases alternatively, according
to age/weight and cardiac condition of every patient. This
way, ventricular septal defect (VSD) cases were corrected by
mini-sternotomy, atrial septal defect (ASD) patients through
an axillary approach, and women with well-defined sub-
mammary groove were entered by a sub-mammary incision.
The initial three months was time enough to get everyone
in the cardiac team comfortable with the changes.
Part two
Surgeons B, C and D were sequentially introduced to
lower mini-sternotomy and sub-mammary approaches,
according to their own interest and skills. Simple cases
(ostium secundum ASD) were selected for this purpose to
begin with, followed by VSD closure through lower mini-
sternotomy in a customized pattern for every surgeon. By
the end of the first year, all surgeons had already performed
ASD and VSD cases through lower mini-sternotomy and
some ASD closures through a sub-mammary approach.
Surgeon D moved to a different Center in another
Country and was substituted by surgeon E, who took up
quickly the same method of learning, following the way of
surgeons B and C.
On the other hand, Surgeons B and C considered the
axillary approach rather cumbersome, and suggested
starting a postero-lateral one before attempting the former.
Part three
Surgeon C introduced the upper mini-sternotomy approach
for aortic valve surgery with the advice of an adult cardiac
surgeon.
As previously stated, the right postero-lateral thoracotomy
was suggested by surgeons B and C (and surgeon E, later on)
as an initial step before taking up the axillary incision.
Surgeon B suggested moving forward and attempting a
thoracoscopic approach. He reviewed the literature (32-37)
and contacted a pediatric surgeon with experience in
the field from our own Center. After assisting him in
thoracoscopic patients (pediatric surgery) and attending a
specific course in minimally-invasive thoracoscopy (surgeons
B and C), a new program was started.
Surgeon E displayed a sort of algorithm for case-approach,
according to age/weight & cardiac defect, resulting in a
tailored minimally invasive approach for any given patient.
Table 1 depicts the amount of patients operated on by
a minimally invasive approach by every surgeon during
the three consecutive years. When compared to the total
amount of patients, the ratio of mini-invasive to total pump-
cases increased twofold between 2013 and 2015. We have
to take into account that 2014 was the first year for Surgeon
E, which could explain why the figures are so close between
2013 (20%) and 2014 (22.5%), rather than displaying a
steady progression along the three year span.
Increase in percentage of mini-invasive pump cases.
(I) 2013: 40/201 (20%)
(II) 2014: 40/178 (22.5%)
(III) 2015: 68/166 (40%)
Table 2 displays the different approaches by every
Table 1 Number of procedures performed by surgeon and year
Surgeon
Year
Total
2013 2014 2015
A 15 12 21 48
B 7 8 6 21
C 10 12 22 44
D 8 8
E 8 19 27
Total 40 40 68 148
Figure 4 Lower mid-line sternotomy. Full mid-line sternotomy
(upper left) as compared to lower mini-sternotomy (lower left).
Result at discharge on 7th
postoperative day.
A
B
C

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surgeon. All of us are confident with the lower mini-
sternotomy and sub-mammary ones. Only surgeon A is
performing the axillary incision up to now, because the
remaining staff members feel more comfortable with the
postero-lateral approach. The upper mini-sternotomy,
introduced by surgeon C, has been taken up by surgeons
B and E as well, for aortic valve patients. The video-
assisted thoracotomy, led by surgeon B, is applied for ostium
secundum ASD patients by surgeons B and C.
Table 3 shows the distribution of diagnosis and surgeons.
Simple conditions, like ASD (ostium secundum, sinus venosus,
ostium primum) and VSD have been performed by every
surgeon (excepting surgeon D, who left earlier). To sum
up, these simple cases account for more than 80% of the
whole number of minimally-invasive pump cases. Regarding
VSD’s alone, which has been approached by lower mini-
sternotomy, the progression has been steady along the three
years with a well-defined step up:
(I) 2013: 32/40 (80%)—12 VSD
(II) 2014: 35/40 (87%)—12 VSD
(III) 2015: 58/68 (82%)—20 VSD
More complex cases (complete atrio-ventricular septal
defect, subaortic myectomy (Morrow), scimitar syndrome,
tricuspid valve repair) have been performed by surgeon A,
expanding the indications of minimally invasive surgery as
experience is gained.
Table 4 summarizes the data relating to the approach
and cardiac defect, independently of the surgeon. ASD and
VSD are the commonest conditions, as expected. Lower
mini-sternotomy is the most prevalent approach, given its
simplicity (in fact, it is the first alternative incision learned)
and the wide range of cardiac defects corrected through this
pathway. The sub-mammary incision has been used for any
type of ASD and few others; the axillary approach for ostium
secundum and sinus venosus ASD, only. At the moment, the
upper mini-sternotomy is indicated for aortic valve purposes
and the video-assisted thoracotomy for ostium secundum
defects.
Not included in Table 4 which describes pump cases
only, some patients were operated on via left thoracotomy
without cardio-pulmonary by-pass (one sling left pulmonary
artery, two patients with anomalous drainage of left upper
pulmonary veins) and video-assisted thoracoscopy [one
pericardial window and one left atrial appendage ablation (38)
plus clip-exclusion].
Conversion rate
An axillary approach for a sinus venosus ASD had to be
converted to a postero-lateral one (just enlarging the skin
incision backwards and splitting the latissimus dorsi muscle).
Despite the conversion, the postero-lateral approach can
still be considered a minimally invasive one. No other
conversion was required.
Complications
An ostium primum patient died because progression of
diffuse pulmonary vein stenosis three months after repair. A
VSD patch-closure developed aortic regurgitation (excessive
trimming of redundant tricuspid tissue which happened to
be stuck to an aortic cusp) and was re-operated two days
later. A valve repair proved unsuccessful and ended up in
a Ross-Konno procedure. Two patients (ASD and VSD)
required revision for bleeding. The initial approach in all
four cases had been via lower mini-sternotomy.
One ASD patient approached via sub-mammary incision
developed transient phrenic palsy and continuous pleural
effusions. An analysis of the pleural fluid showed lidocaine
and, after removal of the trans-thoracic anesthetic line
Table 2 Number of procedures performed by surgeon and approach
Surgeon
Approach
Total
Lower mini-sternotomy Sub-mammary Axillary
Lateral-posterior
thoracotomy
Upper mini-sternotomy Thoracoscopy
A 17 6 22 3 48
B 10 4 3 1 3 21
C 25 11 2 4 2 44
D 7 1 8
E 19 4 2 2 27
Total 78 26 22 10 7 5 148

25. 130 Gil-Jaurena et al. Setting-up a congenital minimally-invasive program
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(which was dislodged), both effusion and phrenic palsy
resolved. A 55-kg child developed compartment syndrome
in the right leg after peripheral cannulation for a video-
assisted thoracotomy ASD repair. It was the only case in
whom the femoral artery was directly cannulated instead of
a graft interposition.
Discussion
Many groups have shifted towards the minimally invasive
surgical approaches in pediatrics (1-7). The rationale,
beyond cosmesis, is offering the same results with new
incisions, when catheter-based interventional procedures
are also difficult or contra-indicated. Maybe the future
will rely on totally robotic (32) or endoscopic (33-37)
surgery, but, for the time being, offering alternative
approaches is interesting. Some teams are keen on a single
particular approach, whereas others prefer to be familiar
with many of them (4-6). Whether this is a strategy or
a matter of evolution is beyond the scope of this paper.
Currently, the range of incisions different from a full
mid-line sternotomy is rich enough to provide us many
options. Interestingly, among the literature reviewed,
some papers underline the steps to set up programs
(24-27). Particularly relevant is the publication by
Bonaros et al. (32), in which the authors split every
procedure in several parts and analyze them separately, so
as to accurately depict anyone´s learning curve. Not only
did we need to start a new program, but also to teach and
enhance our young staff to develop their own ideas.
The three-step approach to introduce a program of
minimally invasive surgery in a new place has proved
successful for several reasons. First of all, the results are
good and patients/parents are satisfied. Part one (surgeon A
introducing the program) allows all members in theatre to
get in touch with the novelty, and surgeon A to realize who is
enthusiastic and who is reluctant. This way, approaches could
be decided according to individual skills and preferences in
customized patterns in part two (surgeons B, C, D and E
being introduced). Most important was the honest attitude of
Table 3 Number of procedures performed by surgeon and diagnosis
Surgeon
Procedure
Total
OS ASD SV ASD OP ASD VSD CAVSD Aortic Others
A 18 5 4 11 7 3 48
B 8 2 3 7 1 21
C 18 3 5 14 4 44
D 6 1 1 8
E 8 4 5 8 2 27
Total 58 14 18 41 7 7 148
ASD, atrial septal defect; OS, ostium secundum; SV, sinus venosus; OP, ostium primum; VSD, ventricular septal defect; CAVSD, complete
atrio-ventricular septal defect.
Table 4 Relationship between approach and diagnosis along the study period
Approach
Procedure
Total
OS ASD SV ASD OP ASD VSD Others
Lower mini-sternotomy 17 1 15 41 4 78
Sub-mammary 16 4 3 3 26
Axillary 17 5 22
Upper mini-sternotomy 7 7
Lat-post thoracotomy 3 4 3 10
Thoracoscopy 5 5
Total 58 14 18 41 17 148
ASD, atrial septal defect. OS, ostium secundum; SV, sinus venosus; OP, ostium primum; VSD, ventricular septal defect.

26. 131Translational Pediatrics, Vol 5, No 3 July 2016
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the staff, not assuming to tackle incisions considered difficult
(e.g., axillary one) and suggesting new approaches (part three).
As responsible of the team, surgeon A considered not to get
involved in the new programs of upper mini-sternotomy for
aortic valve cases and video-assisted thoracotomy for ASD
patients. The rationale was to let surgeons B and D lead
their own projects before incorporating new forthcoming
members (E and A): pupils became teachers.
More complex cases were added as experience was gained.
Thus, particularly in the last of the three years, the young
surgeons were taking up simple cases while surgeon A was
performing difficult ones (AVSD, scimitar). As a result, the
percentage of minimally invasive cases rose to 40%, doubling
the initial rate of 20% during the first year. The lesson is to
couple any single patient to a surgeon who is keen either on
the defect or on a particular approach, so as to match them in
the algorithm of mini-invasive surgery (6,38,39).
Regarding the conversion rate, only one patient had
to be switched. The take-home message in a minimally
invasive program is trying to convert any patient (when
needed) to another minimally invasive approach in an
expeditious way. The incision was converted from axillary
to postero-lateral incision (again, minimally invasive) by just
prolonging posteriorly the already drawn surgical mark and
severing the latissimus dorsi muscle. The new program of
video-assisted mini-thoracotomy is growing-up under the
readiness to convert incisions to a full sub-mammary one, if
needed. To date, it has not been necessary to covert a mini-
thoracotomy to full mid-line sternotomy.
Before embarking on a minimally invasive program, one
has to assume that any drawback is going to be regarded as
linked to the alternative approach. Whether it is true or not
is irrelevant, unless invasive and minimally-invasive patients
are matched. Some of the minor complications we found
were definitely related to the approach, like the transient
phrenic palsy and the compartment syndrome (40). We
have learned how to avoid them (41) in the future.
After gathering some experience, the question is how to
move forward with the program? There is no clear answer,
since not all surgeons are at the same level of proficiency,
or are still in their learning curve. Thinking in terms of
contraindications rather than indications, as a last step of
training, could be a reasonable marker. In other words,
we are not expecting for the “perfect patient” to come and
be an ideal candidate for a minimally invasive approach.
We rather think about the contraindications, if any, for a
minimally invasive procedure in every patient.
The enthusiasm showed by the team members towards
new alternative approaches was overwhelming. Not only
did the young surgeons take up the new methods quickly
(part two), but they quickly suggested new ones to be
introduced (part three). To be honest, I had to change
my mind from the aphorism “same steps, same tools, same
risks, different approach” after the video-assisted mini-
thoracotomy program was started. The shift from a
different single incision to multi-small approaches one
was not in my mind previously, but deserves all credit
because it stands for a new paradigm of surgery. The more
alternative approaches (5,39) we can offer, the better for
the cosmesis of the patients.
Conclusions
Minimally invasive pediatric cardiac surgery is currently
becoming a routine practice in many centers worldwide.
The different approaches need their own learning
curve, either straightforward or a steep one. Our recent
experience demonstrates that a comprehensive, three-step
schedule allows a safe and custom-made approach to train
new surgeons in the field. and enhances enthusiasm in
developing further strategies on their own.
A record of conversion-rate and complications should be
used as marker of performance and quality standard. The
new adopters can take their own training pace according
to their level and skills. Interestingly, the wider the offer
of approaches, the more ideas come up for new alternative
minimally invasive methods. A twofold increase in minimally
invasive procedures was observed in two years. The short-
medium term results after three years are excellent.
Acknowledgements
The authors would thank the theatre staff for their patience
and suggestions.
Footnote
Conflicts of Interest: The authors have no conflicts of interest
to declare.
Ethical Statement: The study was approved by our
institutional ethics committee.
References
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27. 132 Gil-Jaurena et al. Setting-up a congenital minimally-invasive program
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Cite this article as: Gil-Jaurena JM, Pérez-Caballero R, Pita-
Fernández A, González-López MT , Sánchez J, De Agustín JC.
How to set-up a program of minimally-invasive surgery for
congenital heart defects. Transl Pediatr 2016;5(3):125-133. doi:
10.21037/tp.2016.06.01

29. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):134-141tp.amegroups.com
Introduction
Mortality and morbidity of congenital cardiac procedures
have always been an issue for cardiac surgeons since
the very first operation on cardiopulmonary bypass.
Technical improvement in extracorporeal circulation,
increased knowledge in physiology and pathophysiology
of cardiopulmonary bypass and special organ protection
strategies have helped to reduce the incidence of
complications and death to an acceptable rate. However,
they are still present and need to be tackled every day. Since
Bellinger, Newburger and Jonas published their landmark
studies about neurological outcomes after arterial switch
operations (1-4), perfusion strategies, especially for aortic
arch corrections, have been more and more modified to
avoid the potential deleterious effects of deep hypothermic
circulatory arrest (DHCA) (5-9). Several alternative
perfusion regimens of body and brain have been suggested
and were implemented into clinical practice more or less
successfully, so that we have learned a lot about possible
benefits and potential new complications when mal- or
hypo-perfusion of organs occur. To our opinion, monitoring
and visualization of end organ oxygen supply and blood-
flow is of utmost importance and not only of scientific
interest.
Cerebral protection during aortic arch repair is currently
performed by either deep hypothermic circulatory arrest or
regional cerebral perfusion (RCP) via the innominate artery.
Both completely distinct cardiopulmonary bypass techniques
were unable to demonstrate a significant difference in
randomized controlled trials regarding the incidence
of perioperative cerebral injury or neurodevelopmental
Review Article
Goal-directed-perfusion in neonatal aortic arch surgery
Robert Anton Cesnjevar1
, Ariawan Purbojo1
, Frank Muench1
, Joerg Juengert2
, André Rueffer1
1
Department of Pediatric Cardiac Surgery, 2
Department of Pediatrics, University Hospital Erlangen, Friedrich Alexander University Erlangen-
Nuernberg, Erlangen, Germany
Contributions: (I) Conception and design: All authors; (II) Administrative support: RA Cesnjevar, A Rueffer; (III) Provision of study materials
or patients: All authors; (IV) Collection and assembly of data: All authors; (V) Data analysis and interpretation: RA Cesnjevar, A Rueffer; (VI)
Manuscript writing: All authors; (VII) Final approval of manuscript: All authors.
Correspondence to: Robert Cesnjevar, MD, PhD. Department of Pediatric Cardiac Surgery, University Hospital Erlangen, Friedrich Alexander
University Erlangen-Nuernberg, Loschgestraße 15, 91054 Erlangen, Germany. Email: robert.cesnjevar@uk-erlangen.de.
Abstract: Reduction of mortality and morbidity in congenital cardiac surgery has always been and remains
a major target for the complete team involved. As operative techniques are more and more standardized and
refined, surgical risk and associated complication rates have constantly been reduced to an acceptable level
but are both still present. Aortic arch surgery in neonates seems to be of particular interest, because perfusion
techniques differ widely among institutions and an ideal form of a so called “total body perfusion (TBP)”
is somewhat difficult to achieve. Thus concepts of deep hypothermic circulatory arrest (DHCA), regional
cerebral perfusion (RCP/with cardioplegic cardiac arrest or on the perfused beating heart) and TBP exist
in parallel and all carry an individual risk for organ damage related to perfusion management, chosen core
temperature and time on bypass. Patient safety relies more and more on adequate end organ perfusion on
cardiopulmonary bypass, especially sensitive organs like the brain, heart, kidney, liver and the gut, whereby
on adequate tissue protection, temperature management and oxygen delivery should be visualized and
monitored.
Keywords: Congenital heart disease; regional cerebral perfusion (RCP); organ protection; neonatal arch surgery
Submitted Jun 12, 2016. Accepted for publication Jul 06, 2016.
doi: 10.21037/tp.2016.07.03
View this article at: http://dx.doi.org/10.21037/tp.2016.07.03

30. 135Translational Pediatrics, Vol 5, No 3 July 2016
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outcome (10,11). Several studies suggested that longer
duration of deep hypothermic circulatory arrest is associated
with neurocognitive impairment (12-14), but despite the
missing evidence of a clear time limit (12,15), perioperative
seizures with impaired motor development (16) and brain
damage evident on MRI were consistent with RCP as well
(10,17,18). Nevertheless, improved outcome reports (early
and late) about shorter postoperative ventilation, improved
renal function and adequate time-related neurodevelopment
have been subsequently published after using RCP
(15,19,20).
The question of an effective distribution and ideal
quantity of cerebral blood flow, particularly in the
contralateral left hemisphere, is one of the main issues
about RCP, and effective neuro-monitoring in addition
to visualization of flow could lower this burden (21,22).
The same hypothesis pertains to the amount of infra-
diaphragmatic perfusion which is potentially provided
via pre-existing collaterals (via subclavian and intercostal
arteries to the descending aorta), which could be different
in size and may not be adequate if the patient’s core
temperature is kept “too warm” (Figure 1).
The level of concern in our group, especially in complex
aortic arch repair with longer arch clamping times,
has brought us to the concept of total body perfusion
(TBP) using an additional separate arterial pump for
infradiaphragmatic perfusion of the descending aorta.
Both regional cerebral oxygen saturation from the frontal
cortex (rSO2) (23,24) and time average velocity (TAV) of
blood flow in the medial cerebral artery (MCA) (21,22,24-29)
have been interpreted as potential surrogate indicators
for cerebral perfusion during infant cardiac surgery.
Low intraoperative rSO2-level may impact psychomotor
development (15,30,31) and correlate with postoperative
cerebral lesions diagnosed by magnetic resonance imaging
(15,17,18,23,31-33). On the other hand, particularly in the
context of aortic arch surgery using RCP, measuring TAV
may avoid the potential dangers of excessive cerebral blood
flow resulting in cerebral edema or intracranial hemorrhage
(22,34).
TAV in one MCA is usually displayed continuously by
transcranial Doppler ultrasonography from the temporal
window. Nowadays, transfontanellar ultrasound has become
routine analysis in pediatric patients whose fontanelles are
not closed. It can be applied as a point-of-care method
during cardiac surgery (35) and provides additional
information regarding morphology of the whole brain,
including detection of brain lesions, measurement of TAV
and 3-dimensional (3D)-imaging of various blood vessels.
It is currently our routine to investigate cerebral blood
flow to both hemispheres during RCP, using combined
transfontanellar/transtemporal ultrasound and bilateral
frontal rSO2.
In addition, regional oxygenation below the diaphragm
(rSO2) with an additional left renal somatic reflectance
oximetry pad is monitored as well, but we have not yet tried
to visualize renal blood flow with selective ultrasound tools
(Figure 2).
This review focuses mainly on practical and theoretical
Figure 1 Somatic reflectance oximetry during RCP without
descending aorta cannulation. Measurement of rSO2 (%) is
performed by continuous plotting of the somatic reflectance
oximetry in both frontal hemispheres [1 and 2] and subdiaphragmatic
[3]. Here displayed during pure RCP (30% pump flow via the
innominate artery at 25–28 ℃). rSO2, INVOS®
; Somanetics
Corporation, Troy, MI, USA. RCP, regional cerebral perfusion.
Figure 2 Patient monitoring. Systemic pressure is monitored
in one femoral artery and the right radial artery [1 and 2].
Measurement of rSO2 (%) is performed by continuous plotting of
the somatic reflectance oximetry in both frontal hemispheres [3] and
subdiaphragmatic area below the left kidney [4].

31. 136 Cesnjevar et al. Antegrade cerebral perfusion
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):134-141tp.amegroups.com
issues on how to protect organs from ischemic or
hypoxemic damage during complex aortic arch surgery by
adequate monitoring of tissue oxygen supply, thus providing
relatively adequate blood flow to target perfusion regions
[goal-directed-perfusion (GDP)].
Methods
Monitoring
Perioperative perfusion monitoring for aortic arch repair in
neonates and young infants with open fontanelles includes
intraoperative combined transfontanellar/transtemporal
2D- and 3D-ultrasound imaging of both blood flow
intensity in both hemispheres, and assessment of mean TAV
displayed in the basilar artery (BA), bilateral internal carotid
arteries (ICA), bilateral anterior cerebral arteries (ACA) and
bilateral MCAs, respectively. Additionally, bilateral cerebral
frontal rSO2 and subdiaphragmatic rSO2 (left kidney) are
measured.
Surgical technique
After initiation of anesthesia, arterial blood pressure
monitoring lines are placed in the right radial artery and in
one femoral artery. Measurement of rSO2 (%) is performed
by continuous plotting of the somatic reflectance oximetry
in both frontal hemispheres and subdiaphragmatic (rSO2,
INVOS®
; Somanetics Corporation, Troy, MI, USA). After
midline sternotomy and heparinization, a 3.5-mm PTFE-
tube (Gore-Tex®
, Flagstaff, AZ, USA) is anastomosed to
the innominate artery and cannulated with a 10F arterial
cannula.
CPB is started with an estimated flow of 3.0 L/m² BSA
(175–200 mL/kg) after bicaval cannulation and patients
are cooled to 28 ℃ rectal temperature. The pericardium is
opened posterior and to the left of the inferior vena cava
(IVC). The descending aorta is identified in the left pleural
space after mobilization of the lingula to the left of the
esophagus. In case of ductal dependent descending aortic
circulation, both pulmonary arteries are snared, distal aortic
perfusion is accomplished by selective cannulation of the
descending aorta above the diaphragm and connected to
a second roller pump: in this way, perfusion is secured to
both the head and neck vessels, as well as to the lower body
vasculature below the diaphragm during isolation of the
arch for reconstruction. Mean radial and femoral arterial
pressures are kept in the range of 35–50 mmHg. In order
to induce cerebral vasodilatation for homogenous cerebral
tissue cooling, a modified alpha-stat strategy with pCO2
elevation around 50–60 mmHg is used (Figure 3).
Arch vessels and the descending aorta are clamped.
Cerebral protection via RCP is commenced with 30%
estimated flow (52–60 mL/kg/min). The same amount
of flow is provided to the infradiaphragmatic aorta and
monitored via femoral arterial pressure and somatic
reflectance oximetry (Figures 4,5).
Myocardial protection is ensured by either continuous
myocardial perfusion with 10% estimated flow after
connecting another arterial line to the aortic root cannula
(beating heart), or by cardioplegic arrest using a single
shot (40 mL/kg) of cardioplegia. Arch repair includes
coarctation-resection and augmentation of the aortic
concavity with a patch of bovine pericardium. Patients
undergoing the Norwood procedure additionally undergo
atrial septectomy, division of the main pulmonary artery
and Damus-Kaye-Stansel anastomosis; pulmonary perfusion
is ensured by either right ventricle to pulmonary artery
conduit in hypoplastic left heart syndrome or by modified
Blalock-Taussig-shunt in patients with a systemic left
ventricle. After the aortic and supra-aortic cross-clamps
are removed, reperfusion is started until the patients are
Figure 3 Cannulation descending aorta. Selective cannulation of
the descending aorta above the diaphragm. The pericardium is
opened posterior and to the left of the IVC. The descending aorta
is identified after opening the left pleural space to the left of the
esophagus. An 8-F 135°-angled cannula (Stoeckert, Muenchen,
Germany) is inserted into the vessel and connected to a separate
roller pump using 30–40% flow. IVC, inferior vena cava.

32. 137Translational Pediatrics, Vol 5, No 3 July 2016
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Figure 4 Somatic reflectance oximetry during RCP with descending
aorta cannulation. Continuous rSO2 (%) measurements during arch
reconstruction with RCP (30% pump flow via the innominate artery
at 25–28 ℃) and additional abdominal perfusion via the descending
aorta (30–40% pump flow at 25–28 ℃). rSO2, INVOS®
; Somanetics
Corporation, Troy, MI, USA. RCP, regional cerebral perfusion.
Figure 5 Pressure monitoring during RCP with descending aorta
cannulation. Continuous ECG monitoring during beating heart
aortic arch reconstruction. Pressure monitoring in the radial [1] and
femoral [2] artery during RCP (30% pump flow via the innominate
artery at 28 ℃), selective myocardial perfusion (10–15% blood
flow via cardioplegic system into the aortic root) and additional
abdominal perfusion via descending aorta (30–40% pump flow).
RCP, regional cerebral perfusion; ECG, electrocardiogram.
warmed up to 36 ℃. Weaning from CPB is performed in
the usual fashion.
Ultrasound imaging
Transfontanellar ultrasonography is investigated with a
multifrequent sector probe S 4–10 (7MHz), 3D/4D curved
array probe RNA 5-9-D (8MHz) and transtemporal
Doppler ultrasound uses a M5S sector probe (3 MHz).
Transfontanellar examination includes B-mode scan,
2D and 3D Power- or Color-Doppler ultrasound of both
hemispheres. Two-D Power- and Color-Doppler ultrasound
visualizes the intensity of vessel perfusion of the main blood
vessels and illustrates a functioning communication in the
Circle of Willis. 3D Power- and Color-Doppler via the
anterior fontanelle allows 0.5 mm cerebral tomography,
and glass-body rendering of the main cerebral vessels.
Pulsed-wave (Pw)-Doppler is used to measure mean TAV
for intervals of 3–5 seconds. The probes are placed over
the anterior fontanelle or over the right and left temporal
area. The positioning and measurement with the best Color
Doppler signal is selected. Ultrasound imaging with the
above mentioned techniques is currently not applicable for
monitoring infradiaphragmatic perfusion.
Collected data at given standard time points are
compared between hemispheres (left vs. right), and
between two perfusion time points (FF versus RCP) in each
ipsilateral hemisphere.
Observations
Patient characteristic and outcome
Fourteen patients were monitored with a complete data-set
as specified above. One patient out of this group died after
the procedure; all other patients were discharged home
without clinical signs of impaired neurologic function.
Cerebral sonography
Two-D and 3D Color/Power-Doppler ultrasound showed
regular anatomy with a communicating Circle of Willis in
all infants, with near symmetric distribution of blood flow
intensity in vessels of both hemispheres during both RCP
and TBP.
Comparing TAVs in contralateral vessels during
both TBP and RCP, no significant differences between
hemispheres were calculated, except for higher TAV in right
ICA during TBP. Comparing TAVs in each vessel depending
on perfusion methods, no significant differences between FF
and RCP were observed. Comparison of contralateral mean
levels of rSO2 did not reveal significant differences between
both hemispheres, regardless of the perfusion method.
Comparing rSO2 in each hemisphere between perfusion
methods, there was a significant difference regarding rSO2
measured in the right frontal cortex, with higher levels

33. 138 Cesnjevar et al. Antegrade cerebral perfusion
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):134-141tp.amegroups.com
during TBP when compared to RCP.
Discussion
The main concern regarding the efficiency of RCP is
about adequate perfusion of the left hemisphere and the
quality of subdiaphragmatic perfusion. We are one of
the first groups to publish a prospective study evaluating
combined transtemporal/transfontanellar ultrasound in an
intraoperative setting during aortic arch repair, showing
a functioning Circle of Willis for all studied patients,
pointing to symmetric distribution of blood flow intensity
to both cerebral hemispheres during both TBP and RCP.
This impression was confirmed by bilateral comparison of
cerebral TAVs and rSO2.
An exception was found for ICA-flow during TBP,
which was substantiated by significantly higher TAVs in
the right vessel when compared to the left. Divergent
blood flow directions between patients indicate that the
left ICA is being supplied from both sites, either antegrade
via the hypoplastic aortic arch, or retrograde via the Circle
of Willis, which is probably related to the size of the
transverse arch by reflecting the amount of antegrade aortic
flow. Therefore, calculated difference in TAV between
both contralateral ICAs during TBP may be a result of
counteracting blood flow directions in the left ICA, leading
to reduction or flow signal extinction for TAV.
Difference between contralateral TAVs in both carotid
arteries was evident even during RCP, however, without
reaching statistical significance and with an exclusively
retrograde flow-direction in the left ICA at this time point.
As an explanation for that difference in flow intensity,
it should be kept in mind, that even with an effective
perfusion of the left hemisphere during RCP, the left ICA,
when perfused from the right via Circle of Willis, presents
the end of the cerebral vasculature with a “blind end” due
to proximal clamping at its origin from the aortic arch,
and limited run-off into the left external carotid, BA and
ophthalmic artery.
Changes in direction of blood flow in the ICA following
occlusion of the ipsilateral common carotid artery have
been reported previously (36,37). Divergent flow-directions
in the left ICA during both TBP and RCP may mirror the
non-physiologic perfusion of blood vessels originating from
the distal aortic arch in neonates with aortic arch hypoplasia
and ductal-dependent lower body perfusion even as an
inherent phenomenon. We have performed transfontanellar
ultrasound sporadically in our cohort in the perioperative
context and could verify a normalization of flow velocity
in the left ICA and changing flow-direction in left the
vertebral artery after surgery in one infant.
Assessment of bilateral SO2 did not reveal a significant
difference when compared between hemispheres. Both,
increased rSO2 in the right frontal cortex by comparing
both methods of perfusion, and higher TAV in the right
ICA by contralateral comparison during TBP, raises
suspicion of increased blood flow to the right hemisphere
especially during TBP. The potential dangers of excessive
cerebral blood flow include cerebral edema and intracranial
hemorrhage (22,25). We believe that initiation of “full-flow”
bypass over the innominate artery might be responsible for
early hyper-perfusion especially of the right hemisphere,
which may explain why an alpha stat strategy with limitation
of cerebral vasodilatation is beneficial in these patients
to avoid excessive overflow. Initial “overperfusion” of the
right hemisphere seems to persist during cooling despite
introduction of distal aortic perfusion and adjustment of
TBP between both arterial lines.
With regard to infradiaphragmatic perfusion and oxygen
supply it is difficult to support statements that conclude
that RCP provides adequate somatic perfusion via native
collaterals, as suggested by some authors (9). After more
than 15 years’ experience (including animal lab experiment
and subsequent later patient observation), it is even
more difficult to believe that this holds true and has been
questioned by us in the past (5). A special subset of patients
with large intercostal arteries may be well perfused on
both sites of the diaphragm by RCP, but we would not rely
on them, especially if surgery is performed under warmer
conditions of moderate hypothermia around 28 ℃. If you
do not follow an effective strategy to perfuse the lower body
with bypass, some patients will suffer from postoperative
renal failure or mesenteric ischemia. We therefore rely on
regional saturation plotting and femoral artery pressure
monitoring during RCP, and feel very safe since we have
introduced our infradiaphragmatic cannulation technique.
It is our personal bias that continuous rSO2-monitoring
(NIRS) as a point of care measurement of tissue oxygenation
has given us a substantial surplus in procedure safety. In
analogy to our anesthesiology colleagues, we think that NIRS
has become the pulse oximetry of perfusionists and cardiac
surgeons.
One limitation to our observations is that TAV is only
a surrogate indicator for perfusion, considering a fixed
diameter of cerebral vessels during measurements. Further,
the technique of transfontanellar ultrasound is investigator-

34. 139Translational Pediatrics, Vol 5, No 3 July 2016
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dependent, and can be affected by suboptimal positioning or
covering of the patient. This variation in color distribution
can depend on the direction of the vessel and corresponding
blood flow direction regarding the position to the probe. If
the blood flow is vertical to the ultrasonic waves, a movement
of blood cannot be detected. It remains unclear whether
our results can be extrapolated to other RCP strategies
including “real” pH-stat regime and deep hypothermia
(10,12,14,15,19,22,34). A superiority to other modes of
RCP or neuroprotective strategies as deep hypothermic
circulatory arrest cannot be derived from our experience
to date, but may become likely when gathering data from
an increasing number of patients. To date, postoperative
transfontanellar morphologic cerebral evaluation in five
of our patients did not reveal side-dependent structural
abnormalities, and did not show evidence of hyper- and/or
hypo-perfusion-related injury.
In conclusion, the hypothesis of a homogenous
distribution of cerebral blood flow to both hemispheres
during RCP is being strengthened, using a combined
transfontanellar/transtemporal approach, with 2D and
3D Color- and Power-Doppler ultrasound to visualize
the Circle of Willis and the intensity of cerebral vessel
perfusion during aortic arch repair. By indirect and non-
invasive estimations of effective cerebral blood flow using
the transcranial ultrasound methods described in our study,
and regional cerebral tissue oxygenation with NIRS, it is
hoped to make arch reconstruction using cardiopulmonary
bypass even safer.
Acknowledgements
Most of the data and figures are related to the work by
the interdisciplinary research group of Andre Rueffer and
colleagues.
Footnote
Conflict of Interest: The authors have no conflicts of interest
to declare.
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7. Rüffer A, Klopsch C, Münch F, et al. Aortic arch repair: let
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10. Algra SO, Jansen NJ, van der Tweel I, et al. Neurological
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11. Goldberg CS, Bove EL, Devaney EJ, et al. A randomized
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12. Algra SO, Kornmann VN, van der Tweel I, et al.
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13. Gaynor JW, Nicolson SC, Jarvik GP, et al. Increasing
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14. Myung RJ, Petko M, Judkins AR, et al. Regional low-flow
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16. Gunn JK, Beca J, Penny DJ, et al. Amplitude-integrated
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17. Dent CL, Spaeth JP, Jones BV, et al. Brain magnetic
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18. McQuillen PS, Barkovich AJ, Hamrick SE, et al. Temporal
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29. van der Linden J, Priddy R, Ekroth R, et al. Cerebral
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30. Hoffman GM, Brosig CL, Mussatto KA, et al.
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cerebral physiologic monitoring to guide low-flow cerebral
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Thorac Cardiovasc Surg 2003;125:491-9.
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direction of internal carotid artery blood flow by occlusion
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Cite this article as: Cesnjevar RA, Purbojo A, Muench F,
Juengert J, Rueffer A. Goal-directed-perfusion in neonatal
aortic arch surgery. Transl Pediatr 2016;5(3):134-141. doi:
10.21037/tp.2016.07.03

37. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):142-147tp.amegroups.com
Hypoplastic left heart syndrome (HLHS): current
perspective
The term HLHS describes a heterogeneous group of
diagnoses that encompass a wide array of pathophysiology.
The term potentially pertains to any malformation that
involves underdevelopment of the left sided cardiac
structures from aortic stenosis and coarctation of the aorta
to the other extreme of aortic atresia, mitral atresia, and
hypoplasia of the ascending aorta. The Congenital Heart
Surgery Nomenclature and Database Committee (1)
attempted to precisely define those abnormalities. The
proposed definition is that “HLHS is a spectrum of cardiac
malformations, characterized by a severe underdevelopment of the
left heart-aorta complex, consisting of aortic and/or mitral valve
atresia, stenosis, or hypoplasia with marked hypoplasia or absence
of the LV, and hypoplasia of ascending aorta and of the aortic
arch.” The treatment options for these malformations are
discussed in this manuscript.
It is estimated that each year about 960 babies in the
United States are born with HLHS (2). Since the first
successful intervention for HLHS was undertaken by
Norwood in 1983 (3), there have been many advancements
in the pre-, intra-, and postoperative care. Just 25 years ago,
this diagnosis would certainly be a fatal one. Currently there
are five options and paths of treatment for these neonates.
The potential interventions include staged palliation that
starts with a Norwood procedure, a hybrid treatment
strategy, a hybrid-bridge-to-Norwood, transplant, or
compassionate care.
There is a subset of HLHS patients who have a mild
form and could potentially undergo a biventricular repair.
This complex decision-making process is out of the scope of
the current manuscript.
Norwood procedure
The goal of staged palliation for HLHS is to end up with a
Fontan circulation, also known as a total cavo-pulmonary
connection (TCPC). This is typically done in three stages.
The three stages include the Norwood stage I procedure,
the middle stage is a partial cavo-pulmonary connection
(PCPC), also known as a bidirectional Glenn anastomosis
or Hemi-Fontan, and the final stage is a TCPC. The goal
of the Norwood procedure is to relieve systemic ventricular
outflow obstruction, have unrestricted pulmonary venous
Review Article
Hypoplastic left heart syndrome: current perspectives
Christopher E. Greenleaf, J. Miguel Urencio, Jorge D. Salazar, Ali Dodge-Khatami
University of Mississippi Medical Center, 2500 North State Street, Jackson MS 39216, USA
Contributions: (I) Conception and design: CE Greenleaf, A Dodge-Khatami; (II) Administrative support: CE Greenleaf, A Dodge-Khatami; (III)
Provision of study materials or patients: CE Greenleaf, A Dodge-Khatami; (IV) Collection and assembly of data: CE Greenleaf, A Dodge-Khatami; (V)
Data analysis and interpretation: CE Greenleaf, A Dodge-Khatami; (VI) Manuscript writing: All authors; (VII) Final approval of manuscript: All authors.
Correspondence to: Ali Dodge-Khatami, MD, PhD. Chief, Pediatric and Congenital Heart Surgery, Children’s Heart Center; Professor of Surgery,
University of Mississippi Medical Center, 2500 North State Street, Room S345, Jackson MS 39216, USA. Email: adodgekhatami@umc.edu.
Abstract: Since the first successful intervention for hypoplastic left heart syndrome (HLHS) was
undertaken by Norwood in 1983, there have been many advancements in the pre-, intra-, and postoperative
care of these children for a diagnosis that just 25 years ago was almost certainly a fatal one. This paper
aims to describe the most recent trends and perspectives on the treatment of HLHS. In particular, we will
discuss the five current options for HLHS, including Norwood stage I as the beginning to 3-stage palliation,
transplant, true hybrid, hybrid-bridge-to-Norwood, and compassionate care.
Keywords: Hypoplastic left heart syndrome (HLHS); single ventricle; congenital cardiac anomalies
Submitted May 23, 2016. Accepted for publication May 25, 2016.
doi: 10.21037/tp.2016.05.04
View this article at: http://dx.doi.org/10.21037/tp.2016.05.04

38. 143Translational Pediatrics, Vol 5, No 3 July 2016
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):142-147tp.amegroups.com
return, and controlled pulmonary arterial perfusion. This is
accomplished with a Damus-Kaye-Stansel (DKS) procedure,
an ascending arch aortoplasty, an atrial septectomy, and a
source of pulmonary blood flow (PBF), either a systemic to
pulmonary artery shunt or a right ventricle-pulmonary artery
(RV-PA) conduit.
The source of PBF initially used and still used frequently
today is the modified Blalock-Taussig (MBT) shunt, which
is a Gore-Tex graft between the innominate artery and
the right pulmonary artery. This was the predominant
shunt until Sano revived the RV-PA modification, initially
described by Norwood, but long ignored (4). The RV-PA
conduit has seen a dramatic revival in popularity since its
reintroduction, and the choice between the two sources
of PBF is currently surgeon/institution-dependent. There
have been multiple retrospective, single-center studies
comparing the outcomes between the two shunts (5-7),
with contradictory results, and no definitive advantage
of one technique versus the other. The MBT shunt gives
continuous flow to the right pulmonary artery from the
innominate artery even during diastole. The concern is
for diastolic runoff leading to coronary steal that could
potentially cause death during the initial hospitalization or
in the interstage period. The RV-PA shunt requires a right
ventriculotomy which could potentially lead to ventricular
dysfunction in an already stressed univentricular heart.
The Pediatric Heart Network published a multicenter,
randomized trial on infants with HLHS undergoing
the Norwood procedure, known as the Single Ventricle
Reconstruction (SVR) trial (8). Infants were randomized
to either a MBT shunt or an RV-PA conduit. Between
May 2005 and July 2008, 555 patients were enrolled in
the study. The primary outcome was the rate of death or
cardiac transplantation 12 months after randomization.
There were 72 deaths or cardiac transplants in the RV-
PA shunt group, and 100 deaths or cardiac transplants in
the MBT shunt group. On the basis of the data, the RV-
PA shunt as compared to the MBT was associated with an
improved transplantation free-survival at 12 months. When
using all available data and not stopping at the pre-specified
12 months end point, the primary outcome approached
but did not cross statistical significance (P=0.06). After
12 months, 10 deaths and 6 transplantations occurred in
the RV-PA shunt group, as compared with 7 deaths and
0 transplantations in the MBT shunt group.
A study that investigated complications after the
Norwood stage I used the Society of Thoracic Surgeons
database to find preoperative risk factors that led to
postoperative complications (9). These risk factors were
relatively uniform across multiple studies and included
weight less than 2.5 kg, preoperative shock, non-cardiac/
genetic abnormality, and preoperative mechanical ventilator
or circulatory support. Two studies from the Pediatric Heart
Network Investigators described in hospital and inter-stage
mortality associated with the Norwood procedure. The
hospital mortality rate during the Norwood stage I was
16%, irrespective of shunt type. The inter-stage mortality
between stages I and II was 6% for the RV-PA conduit,
and 18% for the MBT shunt. The 3-year follow-up to the
SVR trial was published in 2014 (10). Transplantation-free
survival did not differ by shunt type.
In the largest and most recent study from the Congenital
Heart Surgeons’ Society (11) propensity scores were used
to match 169 RV-PA conduit patients with 169 MBT shunt
patients. Six year survival was better after RV-PA conduit (70%)
versus the MBT shunt (55%). In contradistinction to the SVR
trial, there was also more moderate or severe atrioventricular
valvular regurgitation and right ventricular dysfunction and
lower transplant-free survival in the MBT shunt group.
The Norwood procedure is undertaken during a time
when the pulmonary vascular resistance is too elevated to
allow a cavo-pulmonary anastomosis. The second stage is
usually undertaken between 4–6 months of age. The goal
of the second stage is to unload the right ventricle. This is
accomplished with either a bidirectional Glenn or a Hemi-
Fontan. The advantages of the bidirectional Glenn is that
it can potentially be performed off-pump and is an easier
connection. The Hemi-Fontan makes the final stage more
straightforward.
This second stage originally was proposed as an interim
palliation only for high risk babies before undergoing the
Fontan operation (12,13), instead of proceeding directly
from a shunted physiology to TCPC in one step, which
is a huge physiological change associated with high risk
of failure. After staged palliation with an interim Glenn
operation, breaking the adaptation to new cardio-pulmonary
flows into two lower-risk steps with better results, the
Glenn operation became a standard staging procedure even
in babies with a low-risk profile, leading to the current
3-stage approach. The goal is to unload the ventricle as
early as possible, minimize potential steal from coronary
blood flow, and limit the amount of time the pulmonary
vasculature is exposed to systemic pressures before the baby
can tolerate a Fontan (14).
Traditionally, the bidirectional Glenn anastomosis was
between the superior vena cava and the pulmonary arteries.

39. 144 Greenleaf et al. HLHS: current perspectives
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):142-147tp.amegroups.com
The inferior vena cava to pulmonary artery anastomosis was
abandoned in the animal lab by Dr. Glenn after repeated
failure in an animal model. In patients with unfavorable
upper body systemic venous anatomy, the SVC-PA
connection is suboptimal or not feasible, and an alternative
is needed to unload the heart. We have found that this
subset of patients can benefit from a primary IVC-PA
connection, the “Southern Glenn”, which we have
performed successfully in two patients (15).
The Fontan operation typically connects the IVC to
the RPA leading to a total cavopulmonary connection so
that all PBF is achieved passively. In-series circulation is
restored and saturations achieve near-normal levels. This
typically happens between 24 and 48 months of age. There
is a wide breadth of single-institution series looking at short
and long-term outcomes and predictors of mortality and
morbidity after Fontan completion (16-18). The consistent
predictors of poor outcome across multiple studies are
longer cross-clamp times, longer length of hospital stays,
heterotaxy, and atrioventricular valve anomaly.
Despite studies showing the success of either type of
PBF, MBT or RVPA conduit for the Norwood stage I,
the majority of centers have not changed their practice.
Those centers that have solid technical and postoperative
results with either the RV-PA conduit or the MBT shunt
have continued to palliate the patients in the same way
they always have. Current expected benchmark results
for Norwood stage I palliation, as harvested by the STS
congenital heart surgery database, is 85.1% in-hospital
survival (19).
The “true” hybrid approach
Concerns about placing a neonate on cardiopulmonary
bypass with significant cardiac and non-cardiac
comorbidities, especially neurological ones, which could
lead to intracranial hemorrhage, led to the advent of hybrid
approaches to the HLHS baby. High risk factors included
weight less than 2.5 kg, preoperative shock, non-cardiac/
genetic abnormality, preoperative mechanical ventilator or
circulatory support, small ascending aorta, intact/restrictive
interatrial septum, and the variant of HLHS with aortic
atresia and mitral stenosis. The goals of the first stage are
the same as the standard Norwood procedure including
securing adequate systemic perfusion, unrestricted
pulmonary venous return, and controlling PBF; relief of
systemic ventricular outflow obstruction with a DKS, which
requires cardiopulmonary bypass, is not performed. Using
a conjunction of catheter-based intervention and surgery
without cardiopulmonary bypass, systemic perfusion is
maintained with a ductal arteriosus stent, unrestricted
pulmonary venous return is accomplished with a balloon
atrial septostomy if needed and controlled (diminished) PBF
is accomplished with bilateral PA bands. The concern with
this approach is that the ductal stent could potentially limit
retrograde blood flow into the ascending aorta, leading to
coronary compromise and myocardial ischemia.
After the inter-stage period, the comprehensive stage
I + II includes removal of the PA bands, removal of the
ductal stent, connecting the ascending aorta with the
pulmonary valve (DKS), and repair of the aortic arch and
pulmonary arteries. Removing the ductal stent is probably
the most challenging. It takes a technique similar to an
endarterectomy to safely extract the stent without injuring
the descending thoracic aorta. Initially, the hybrid approach
was used for high risk infants. With formal or relative
contraindications to a Norwood stage I operation, single
center studies showed the feasibility of the approach,
and others started using it on standard risk patients as an
alternative to the Norwood stage I procedure (20,21).
Pioneering work by Galantowicz and colleagues (22) has
been very illustrative in what can be accomplished with the
hybrid approach for HLHS. Sixty-two patients underwent
a hybrid stage I procedure between 2002 and 2007. High
risk patients were excluded from their study so that the
cohort of patients would have a more typical risk profile to
the usual HLHS patient. The results are impressive, with a
hospital survival after the hybrid stage I reaching 97.5%. The
interstage I–II interval had two deaths. The hospital survival
during the comprehensive stage I + II was 92%. The most
important point from this early experience is that in certain
patients with unfavorable anatomy, namely those with aortic
atresia and no antegrade flow to the coronary arteries, jailing
by the ductal stent may create stenosis of the retrograde
orifice to the transverse arch. These patients should be
identified before intervention, because a ductal stent can
acutely lead to head vessel and/or coronary artery flow
compromise, potentially leading to death from myocardial
infarction and circulatory collapse. The options are to offer
these patients a standard Norwood procedure or to stent the
retrograde orifice at the time of the PDA stent (23).
The group in Giessen recently described 182 babies that
underwent this hybrid strategy (24,25). At 10 years, the
probability of survival is 77.8%. Aortic arch reinterventions
were only needed in 16.7% of patients. A benefit of this
approach is that several of the patients were able to be

40. 145Translational Pediatrics, Vol 5, No 3 July 2016
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transitioned to a biventricular repair after the hybrid
approach instead of the single ventricle palliation.
The hybrid approach is theoretically attractive by reducing
the early insult to an already stressed neonate while limiting
pulmonary overcirculation and securing systemic perfusion.
Uneven results in other centers and concerns with the
technical aspects of the comprehensive stage I + II have kept
the true hybrid approach from garnering widespread support
for low to intermediate risk patients.
Hybrid-bridge-to-Norwood
In the above study by Galantowicz there were 12
reinterventions in the catheterization lab during the
interstage I to II interval. The majority (n=7) dealt with
issues with regards to the position of the ductal stent to
improve antegrade systemic flow, and four were placed
to relieve retrograde stenosis into the transverse aortic
arch. Despite the need for reintervention, all patients went
on to a comprehensive stage I + II. The need for more
catheterizations and the concerns with removing the stent
during the comprehensive stage I + II has led to the revival
of another sequence of operations once described by Dr.
Norwood, coined the hybrid-bridge-to-Norwood or the
“salvage-bridge-to-Norwood” (26).
In high-risk HLHS neonates with concomitant cardiac
and non-cardiac comorbidities, in whom an initial Norwood
stage I operation is deemed prohibitive, the sequence starts
with bilateral pulmonary artery bands in the early period after
birth. The ductus is kept open with prostaglandins, instead of
a mechanical stent. The Norwood stage I is then performed
after the baby is stabilized, typically at about 2 weeks.
We described our experience with 47 consecutive babies
with HLHS between April 2010 and June 2014. Nine of
these patients had a hybrid-bridge-to-Norwood. Seven
of these high-risk patients had significant preoperative
cardiac and non-cardiac comorbidities, including severe
seizure disorders with cerebral infarction, and great vessel
arrangements that precluded ductal stenting. Two patients
were salvaged intraoperatively with the hybrid-bridge-
to-Norwood: one had severe abdominal distension and
suspected sepsis with total anomalous pulmonary venous
return, and another baby with standard risk HLHS had
hemo-pericardium and tamponade upon sternal entry.
Seven of the patients required extracorporeal membrane
oxygenation support postoperatively. Eight patients went on
to a deferred Norwood stage I at a mean of 14.3 days. Six
survived to hospital discharge.
The Great Ormond Street group had 17 of 147 patients
between January 2006 and October 2011 who underwent
what they label as the “rapid 2-stage Norwood strategy” (27).
These patients were defined as high risk by having multiple
risk factors, including age >2 weeks, weight <2.5 kg,
prolonged mechanical ventilation, systemic sepsis, necrotizing
enterocolitis, cardiac, renal or hepatic failure, coagulopathy,
pulmonary edema, sustained hypotension, significant inotropic
requirements, generalized edema, and previous cardiac arrest.
Five patients died after the bilateral PA bands. The other 12
patients underwent a Norwood stage I procedure.
The “hybrid-bridge-to-Norwood” or “salvage-to-
Norwood” approach gives the baby time to recover and
allows time for the surgeon to undertake the Norwood stage
I at a more advantageous moment. Although the in-hospital
mortality with the “salvage-to-Norwood” approach is high
compared to other approaches in neonates with HLHS, it
is the only alternative to certain death in an otherwise very
high-risk and unstable situation.
Cardiac transplantation
Cardiac transplantation is an attractive option in the sense
that there is a dramatic change in the patient’s physiology to
that of a normal one. The downsides are the use of an organ
in short supply for a disease that has other options, life-long
immunosuppression, a 20% mortality rate while on the
waiting list, and the almost inevitable prospect of future
retransplantation beyond the first one to two decades of life.
If transplantation is undertaken after staged palliation, the
outcomes are similar to those who undergo transplantation
as their primary therapy (28).
Despite these hurdles, since Bailey’s first description in
1986 (29), cardiac transplantation remains a valid option for
some patients with HLHS. The main difference between
transplantation of a heart into a patient with HLHS and
other pathologic conditions is that the donor arch and
proximal descending aorta must be procured to reconstruct
the recipient’s arch past the isthmus. The 5-year survival
is comparable between staged palliation and cardiac
transplantation. As mentioned, cardiac transplantation
has an upfront cost due to the shortage of available organs
and potential attrition while on the waiting list. This has
led some centers to palliate these patients with pulmonary
artery bands to allow a more stable and safe waiting period.
The Loma Linda group has probably published the
most on the subject of primary transplantation (30). In
their series, only 64% of patients listed for transplantation

41. 146 Greenleaf et al. HLHS: current perspectives
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):142-147tp.amegroups.com
completed and survived through transplantation. The risk
factors for mortality with transplantation are pretransplant
circulatory support, posttransplant mechanical circulatory
support, and donor heart cross-clamp time.
Given the shortage of organs required for this age and
size of patients and the high mortality while waiting for
an organ, most centers have abandoned this approach. It
is now offered in only a handful of highly specialized and
geographically centralized high-volume referral centers in
the world.
Compassionate care
With the advent of multiple options for these complex
patients, the decision “to do nothing” has been a less
frequently sought option, making this line of parent
counseling rarer for the majority of practitioners.
When other major, uncorrectable genetic, anatomic, or
physiologic cardiac or non-cardiac malformations preclude
a satisfactory final outcome, comfort care may be an
option. If no intervention is chosen, the mortality is about
98% in the first 6 weeks of life. The keys to this discussion
should encompass counseling, facts, and ultimately letting
the family decide.
Conclusions
Before 1980, HLHS was a uniformly fatal diagnosis.
There have been great advancements with the treatment of
these patients, which have led to an initial survival rate of
90–92% in the neonatal period for standard-risk patients
undergoing surgery. There are now four viable pathways for
these patients to become long-term survivors. The future
holds refinement of surgical techniques, lessening of risks,
catheter-based advancements, and improved perioperative
care with a better understanding of the physiology. Factors
influencing the long-term prognosis of these patients after
successfully undergoing all three stages of palliation remain
to be determined.
Acknowledgements
None.
Footnote
Conflicts of Interest: The authors have no conflicts of interest
to declare.
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Cite this article as: Greenleaf CE, Urencio JM, Salazar JD,
Dodge-Khatami A. Hypoplastic left heart syndrome: current
perspectives. Transl Pediatr 2016;5(3):142-147. doi: 10.21037/
tp.2016.05.04

43. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):148-159tp.amegroups.com
Introduction
The idea that prophylactic arrhythmia surgery should be
incorporated into reparative open heart procedures stems
from the reality that many patients with specific congenital
cardiac anatomic substrates are subject to atrial arrhythmia
development in the course of their lives, which will impact
negatively on ventricular function, physical well being,
and long-term survival (1-3). Patients presenting later
in life with any form of atrial septal defect (ASD) have a
30% to 50% incidence of atrial arrhythmias [mostly atrial
fibrillation (AF)] with or without operative repair (4-8).
Patients with Ebstein anomaly of the tricuspid valve and
patients undergoing repeat surgery for tetralogy of Fallot
(TOF) are at significantly increased risk of atrial arrhythmia
development (9-11). Patients who have had staged
procedures en route to Fontan physiology also have a high
incidence of atrial arrhythmias whether the connections be
atriopulmonary, total cavopulmonary, or extracardiac/lateral
tunnel (12-15). Others with complex atrial baffles such as
atrial switch procedures in association with arterial switch
(double switch for congenitally corrected transposition
of the great arteries) are associated with a predictable
incidence of atrial arrhythmias, which theoretically can be
ameliorated or neutralized (mitigated) by a prophylactic
maze procedure.
Review Article
Prophylactic arrhythmia surgery in association with congenital
heart disease
Constantine Mavroudis1
, Barbara J. Deal2
1
Johns Hopkins Children’s Heart Surgery, Florida Hospital for Children, Orlando, Florida, USA; 2
Ann & Robert H Lurie Children’s Hospital of
Chicago, Chicago, Illinois, USA
Contributions: (I) Conception and design: All authors; (II) Administrative support: All authors; (III) Provision of study materials or patients: None;
(IV) Collection and assembly of data: All authors; (V) Data analysis and interpretation: All authors; (VI) Manuscript writing: All authors; (VII) Final
approval of manuscript: All authors.
Correspondence to: Constantine Mavroudis, MD. Professor of Surgery, Johns Hopkins University Medical School; Site Director, Johns Hopkins
Children’s Heart Surgery, Florida Hospital for Children, 2501 N Orange Ave, Suite 540, Orlando, Florida 32804, USA.
Email: Constantine.Mavroudis.MD@flhosp.org.
Abstract: Certain congenital heart anomalies make patients more susceptible to arrhythmia development
throughout their lives. This poses the question whether prophylactic arrhythmia surgery should be
incorporated into reparative open heart procedures for congenital heart disease. There is currently no
consensus on what constitutes a standard prophylactic procedure, owing to the questions that remain
regarding lesions to be performed; energy sources to use; proximity of energy source or incisions to
coronary arteries, sinoatrial node, atrioventricular node; circumstances for right atrial, left atrial, or biatrial
appendectomy; and whether to perform a right, left, or biatrial maze procedure. These considerations are
important because prophylactic arrhythmia procedures are performed without knowing if the patient will
actually develop an arrhythmia in his or her lifetime. By reviewing and summarizing the literature, congenital
heart disease patients who are at risk for developing atrial arrhythmias can be identified and lesion sets can be
suggested in an effort to standardize experimental protocols for prophylactic arrhythmia surgery.
Keywords: Atrial fibrillation (AF); atrial flutter (AFL); atrial septal defect (ASD); Ebstein anomaly; univentricular
physiology
Submitted May 05, 2016. Accepted for publication Jun 01, 2016.
doi: 10.21037/tp.2016.06.04
View this article at: http://dx.doi.org/10.21037/tp.2016.06.04

44. 149Translational Pediatrics, Vol 5, No 3 July 2016
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):148-159tp.amegroups.com
Presently, there is emerging consensus regarding
indications for prophylactic arrhythmia surgery in
congenital heart disease (16). The surgical community has
not reached unanimity of opinion as to what constitutes a
standard prophylactic maze procedure (1,17-21). While the
operation was conceived to be complication-free owing to
the lesions being placed in areas that theoretically do not
interfere with normal sinus rhythm mechanism and one-to-
one conduction, the reality is that there have been reported
cases of sinus node dysfunction resulting in nodal rhythm
following maze procedures (21,22). Understandably, one
must approach such a conundrum with a rationale as to
which forms of heart disease are associated with sufficiently
high risk of developing arrhythmia (Table 1) (16) to warrant
consideration for prophylactic arrhythmia surgery, as well
as clarity regarding the set of prophylactic lesions to be
performed, the appropriate lesion sets, and techniques.
These considerations are important in light of the fact
that prophylactic arrhythmia therapy may be performed
without advanced knowledge that the patient in question
will actually develop an arrhythmia during the course of
his or her life. Invocation of bioethical principles of non-
maleficence, beneficence, patient autonomy, and justice all
come to mind and apply (1,23-25). The idea is to establish
the historic incidence of these arrhythmias, identify the
arrhythmia (right-sided, left-sided, both right and left
sided) and offer a safe, effective, and complication-free
prophylactic procedure (4,22,26-28).
The aim of this review is to identify preoperative
congenital heart surgery patients who are at risk for
developing future atrial arrhythmias, assess the efficacy of
techniques of arrhythmia surgery in treating the specific
arrhythmia substrate, and assess the risk/benefit of
prophylactic arrhythmia surgery. Concomitant prophylactic
arrhythmia surgery in association with reparative procedures
is discussed based on a literature review and considered
application of safe lesion sets for standardization and future
interprogram comparisons.
Arrhythmias and congenital heart disease
The natural history of unrepaired and repaired congenital
heart disease is fraught with late arrhythmogenic
complications and therefore is an important field of
inquiry. As the complexity of types of congenital heart
disease undergoing surgery advanced, the recognition of
associated arrhythmia development as a significant source
of late morbidity evolved. The marked improvement in
survival among patients with congenital heart disease has
been associated with the recognition that late arrhythmias
and heart failure account for over half of late deaths
(29,30). Among adults with congenital heart disease, the
development of atrial arrhythmias is associated with a 50%
increase in early mortality, a two-fold increase in stroke and
congestive heart failure, and a three-fold increase in the
need for cardiac interventions (31). Lesions associated with
the highest prevalence of supraventricular tachycardia (SVT)
include Ebstein anomaly, atrial repairs of transposition of
Table 1 Reoperation rates and estimated prevalence of arrhythmias in adults with congenital heart disease
Congenital heart disease lesion Reoperation Atrial arrhythmias Ventricular tachycardia
Ebstein anomaly 30–50% 33–60% >2%
Single ventricle >25% 40–60% >5%
Tetralogy of Fallot 26–50% 15–25% 10–15%
Transposition of the great arteries, atrial switch 15–27% 26–50% 7–9%
Transposition of the great arteries, arterial l switch 12–20% <2% 1–2%
Congenitally corrected transposition of the great arteries 25–35% >30% >2%
Truncus arteriosus 55–89% >25% >2%
Atrioventricular septal defect 19–26% 5–10% <2%
Atrial septal defect <2% 16–28% <2%
Reproduced with permission from Khairy P, et al. PACES/HRS Expert Consensus Statement on the Recognition and Management of
Arrhythmias in Adult Congenital Heart Disease. Heart Rhythm 2014;11:e102-e165. Copyright © 2014 with permission from Elsevier (16).

45. 150 Mavroudis and Deal. Prophylactic arrhythmia surgery for CHD
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):148-159tp.amegroups.com
the great arteries, univentricular hearts, ASDs, and right
heart obstructive lesions such as TOF and double outlet
right ventricle (31). Of these defects, more than 25%
of patients with right heart obstructive lesions, Ebstein
anomaly, and univentricular hearts undergo reoperations
(10,32). Patients with ASDs may present for intervention
in adulthood (1,6,8). Clearly, a surgical intervention that
reduces the risk of later arrhythmia development by the
inclusion of successful prophylactic arrhythmia surgery
should result in improved quality of life for a significant
number of patients (1).
ASDs, although technically straightforward substrates
for surgical repair, are associated with late atrial flutter
(AFL) and AF in as many as 20% to 35% of patients
(6,26,33). In 1990, Murphy et al. studied 123 patients
with ostium secundum or sinus venosus ASD in an effort
to determine the natural history of surgically corrected
ASDs, 27 to 32 years following the repair (6). Patients
repaired before age 25 had excellent prognosis; patients
aged 25 to 41 had good survival but less than age matched
controls; and patients greater than 41 years had poor
survival and more frequent late cardiac failure, stroke,
and AF. Their results indicate “that age at operation is
the most powerful independent predictor of long-term
survival”. The idea that ASD closure after 40 years of
age is associated with increased risk of late complications
and arrhythmias was heralded by this study (6). Gatzoulis
and associates [1999] from Toronto retrospectively
identified 213 adults who underwent surgical ASD
closure owing to symptoms or substantial left-to-right
shunt (ratio of pulmonary to systemic blood flow >1.5:1),
or both (26). In comparison with patients who did not
have preoperative AF or AFL, the 40 patients with AF
or AFL were older and had higher pulmonary artery
pressure, and 24 of the 40 patients (60%) continued
with AF or AFL after mean follow-up of 3.8 years.
New onset AF or AFL was found at follow up at greater
frequency in patients who were older than 40 years at the
time of surgery, echoing Murphy’s 1990 report (6). The
authors concluded via multivariate analysis that older
age at time of surgery (>40 years; P=0.001); presence of
preoperative AF or AFL; and presence of postoperative
AF, AFL, or junctional rhythm were predictive of late
postoperative AF or AFL in adults with ASD (26). In
Belgium, 155 patients who underwent ASD closure were
selected from 3 databases (33). All patients were 18 years
or older; 24 were surgically repaired, and 131 underwent
transcatheter device closure (33). Over a median follow-
up of 25 months (range, 1–289 months), 25% developed
atrial arrhythmia. Risk factors for arrhythmia development
were preoperative or early postoperative atrial tachycardia,
female gender, and mean pulmonary artery pressure ≥25
Torr (33).
Arrhythmia development following surgical repair
of TOF was initially focused on the risk of ventricular
tachycardia, related to ventriculotomy, fibrosis, scarring
and ventricular dilatation and hypertrophy. Subsequently,
as surgical techniques evolved and repairs were performed
at younger ages, atrial arrhythmias were recognized in over
40% of patients, which contributed to important morbidity
and hospitalizations (11). Ebstein anomaly of the tricuspid
valve is associated with SVT in 20% to 50% of patients,
related to accessory connections as well as AF and AFL
(9,19,34). Perhaps the most challenging patients are those
with postoperative Fontan complications who develop atrial
arrhythmias with increasing incidence over time which
can be as high as 50% (32,35). Oftentimes, these patients
present with gigantic right atria, atrial reentry tachycardia,
AF, and hemodynamically important lesions requiring
surgery such as: venous and arterial pathway obstructions,
valvar insufficiency, aneurysms, and intracavitary clot
formation. Modification of the Fontan operation has
decreased the incidence of late atrial tachycardia to
approximately 8% to 15% in extracardiac connections, 13%
to 60% in lateral tunnel connections, and over 60% in the
earlier atriopulmonary connection repairs (36). Incidence of
late arrhythmias in patients with modified connections can
be expected to rise with longer follow-up. Catheter ablation
in the Fontan patient has acute success rates of about 50%
with at least 70% recurrence of tachycardia within two years
(37,38). Catheter access to the right atrium in patients with
extracardiac connections is limited to the transhepatic or
transthoracic approach with potential morbidity. Certainly
patients with prior Fontan surgery undergoing reoperations
should be considered for prophylactic lesion sets, taking on
greater importance in light of limited transcatheter access.
Arrhythmia surgery
The historic record of arrhythmia surgery has been mostly
confined to therapeutic application of specific lesion sets
developed to treat existing refractory arrhythmias with
or without associated intracardiac repair. Sealy and Cox
originated the descriptions of surgical treatment of accessory
connections and successfully applied the techniques to
hundreds of patients (39). Guiradon et al. extended surgical

46. 151Translational Pediatrics, Vol 5, No 3 July 2016
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therapy to patients with AFL by developing the isthmus lesion
from the coronary sinus to the inferior vena cava (IVC) (40).
Theodoro and colleagues applied the techniques of the right
sided maze as described by Cox to patients with congenital
heart disease and atrial arrhythmias (21). Mavroudis extended
the application of surgical treatment of both AFL and AF
to patients with congenital heart disease of all ages and to
patients with prior Fontan surgeries (1,15,41-43). During
preoperative electrophysiologic studies the recognition of
three dominant reentrant circuits for atrial tachycardia in
Fontan patients led to the development of the modified right
atrial maze, which included an isthmus lesion that was not
part of the Cox right atrial maze (12,15). Multiple centers
have successfully applied these various operative arrhythmia
techniques to patients with congenital heart lesions.
In 2006, Karamlou and colleagues have demonstrated
efficacy of concomitant atrial arrhythmia surgery in TOF
patients with preexisting atrial arrhythmias who were
undergoing pulmonary valve surgery and or tricuspid
valve repair (44). In patients without arrhythmia by
18 years of age, reported SVT prevalence during long-
term follow-up was over 15% (3). Giamberti and colleagues
published their cumulative experience of 50 adults with
congenital heart disease in 2006 (8) and 2008 (45). Patients
underwent irrigated radiofrequency ablation concomitantly
(31 right-sided maze procedures; 13 Cox-maze III
procedures; 6 right ventricular ablations; and additional
14 pacemakers). Two patients died from causes not related
to intraoperative ablation. During average follow up of
28 months, 48 patients were alive and in New York Heart
Association class I or II. All patients were discharged with
antiarrhythmic medication for 3 months. Forty three
patients were still in sinus rhythm, 2 were in sinus rhythm
and taking permanent antiarrhythmic medication for
recurrent AF, 2 were in stable AF, and 1 was in pacemaker
rhythm at the time of publication (45). The authors found
irrigated radiofrequency ablation to be effective to control
arrhythmias in adults with congenital heart disease (45).
Recognizing the increasing contribution of arrhythmias
to long-term morbidity, three recent groups have published
recommendations for concomitant arrhythmia surgery in
patients with existing arrhythmias undergoing planned
surgical repairs (Table 2) (16,46). The 2015 American
College of Cardiology/American Heart Association/Heart
Rhythm Society guidelines for the management of SVT in
adults include a class I recommendation for assessment of
associated hemodynamic abnormalities for potential repair
in adults with congenital heart disease as part of therapy for
SVT (46). In the consensus statement for management of
arrhythmias in adults with congenital heart disease, surgical
ablation of associated atrial tachycardia is recommended
in patients undergoing planned surgical repair, and a left
atrial Cox-maze III procedure with right atrial cavotricuspid
isthmus ablation is recommended for adults with congenital
heart disease and AF. Guidelines for the management of AF
in adults consider it reasonable to perform surgical ablation
for AF in select patients undergoing cardiac surgery for other
indications. These guidelines were made in recognition of
the efficacy of surgical techniques for treating AFL and AF,
as well as SVT related to accessory connections (16,46).
Arrhythmia surgery techniques
AF
The original maze procedures for AF were characterized
as Cox-maze I, II, and III (47-49). Because original lesion
sets were designed as “cut and sew”, energy ablative
sources were introduced to shorten the procedure and limit
bleeding complications, termed the Cox-maze IV. Lesion
sets were designed to isolate left atrial macro and micro-
reentry and prevent AF, while preserving conduction from
the sinoatrial node to the atrioventricular node to maintain
atrioventricular synchrony, preserve left atrial transport
function, and reduce thromboembolism. The left atrial maze
procedure is effective owing to the specific lesions designed
to encircle the pulmonary veins and to limit reentry circuits
that would occur in the left atrioventricular valve isthmus,
reentry via the coronary sinus, and reentry via Bachmann’s
bundle in the dome of the left atrium (1). Originally, the
Cox-maze procedure included left atrial appendectomy and
an incision to the confluence of pulmonary vein encircling
lesion(s). Resection of the left atrial appendage was thought
to remove the source of thrombi known to occur in AF; it is
not clear whether the left atrial appendectomy plays a role
in arrhythmia ablation.
Cox articulated the following observations regarding
AFL/AF and the maze procedure (50):
(I) The local effective refractory periods of the left
atrium are shorter than in the right atrium;
(II) AFL most likely occurs on the basis of reentry in
the right atrium (longer effective refractory periods
and larger reentrant circuits);
(III) AF likely occurs on the basis of reentry in the left
atrium (shorter effective refractory periods and
smaller reentrant circuits);

47. 152 Mavroudis and Deal. Prophylactic arrhythmia surgery for CHD
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):148-159tp.amegroups.com
Table 2 2014 ACC/AHA/HRS Guidelines and Consensus Statements
Class of
recommendation
Level of
evidence
Recommendation
2014 Guidelines for arrhythmia management in adult congenital heart disease
I B A modified right atrial maze procedure is indicated in adults undergoing Fontan conversion with symptomatic
right atrial IART
A modified right atrial maze procedure in addition to a left atrial Cox maze III procedure is indicated in
patients undergoing Fontan conversion with documented AF
IIa B Concomitant atrial arrhythmia surgery should be considered in adults with Ebstein anomaly undergoing
cardiac surgery
A (modified) right atrial maze procedure can be useful in adults with CHD and clinical episodes of sustained
typical or atypical right atrial flutter
A left atrial Cox maze III procedure with right atrial cavotricuspid isthmus ablation can be beneficial in adults
with CHD and AF
2014 Guidelines for the management of AF in adult congenital heart disease
IIa C An AF surgical ablation procedure is reasonable for selected patients with AF undergoing cardiac surgery for
other indications
2015 Guidelines for the management of SVT in adult congenital heart disease
I C-LD Assessment of associated hemodynamic abnormalities for potential repair of structural defects is
recommended in ACHD patients as part of therapy for SVT
IIa B-NR Preoperative catheter ablation or intraoperative surgical ablation of accessory pathways or AT is reasonable
in patients with SVT who are undergoing surgical repair of Ebstein anomaly
Surgical ablation of AT or atrial flutter can be effective in ACHD patients undergoing planned surgical repair
Recommendations for prophylactic arrhythmia surgery in adult congenital heart disease
IIa B A modified right atrial maze procedure should be considered in adults undergoing Fontan conversion or
revision surgery without documented atrial arrhythmias
Concomitant atrial arrhythmia surgery should be considered in adults with Ebstein anomaly undergoing
cardiac surgery
IIb B Adults with CHD and inducible typical or atypical right atrial flutter without documented clinical sustained
atrial tachycardia may be considered for (modified) right atrial maze surgery or cavotricuspid isthmus ablation
C Adults with CHD undergoing surgery to correct a structural heart defect associated with atrial dilatation may
be considered for prophylactic atrial arrhythmia surgery
Adults with CHD and left-sided valvar heart disease with severe left atrial dilatation or limitations of venous
access may be considered for left atrial maze surgery in the absence of documented or inducible atrial
tachycardia
Closure of the left atrial appendage may be considered in adults with CHD undergoing atrial arrhythmia
surgery
III C Prophylactic arrhythmia surgery is not indicated in adults with CHD at increased risk of surgical mortality
from ventricular dysfunction or major co-morbidities, in whom prolongation of cardiopulmonary bypass or
cross clamp times owing to arrhythmia surgery might negatively impact outcomes
Empiric ventricular arrhythmia surgery is not indicated in adults with CHD and no clinical or inducible sustained VT
Reproduced with permission from Khairy P, et al. PACES/HRS Expert Consensus Statement on the Recognition and Management of
Arrhythmias in Adult Congenital Heart Disease. Heart Rhythm 2014;11:e102-e165. Copyright © 2014 with permission from Elsevier (16)
and Page RL, et al. 2015 ACC/AHA/HRS Guideline for the Management of Adult Patients With Supraventricular Tachycardia: A Report of
the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines and the Heart Rhythm Society.
J Am Coll Cardiol 2016:67;e27-e115. Copyright © 2016 with permisson from Elsevier (46). ACC, American College of Cardiology; AHA,
American Heart Association; HRS, Heart Rhythm Society; IART, intra-atrial reentrant tachycardia; AF, atrial fibrillation; CHD, congenital
heart disease; SVT, supraventricular tachycardia; LD, limited data; NR, nonrandomized; ACHD, adult congenital heart disease; AT, atrial
tachycardia; VT, ventricular tachychardia.

48. 153Translational Pediatrics, Vol 5, No 3 July 2016
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(IV) Maze incisions confined to the left atrium are likely
to ablate AF but not AFL (50).
Subsequent modifications to the maze procedure,
all developed to shorten the operation, allow epicardial
approaches without cardiopulmonary bypass and facilitate
a transcatheter ablation (1,51,52). Further, because AF
typically originates in the left atrium, potential exclusion of
the right-sided lesions was introduced (50,51). Subsequent
efforts to minimize the pulmonary vein and left atrial
lesions resulted in procedures labeled as mini-maze,
“modified” maze, “right atrial” maze, ”left atrial” maze,
and “biatrial” maze. “Maze” became synonymous with any
modified lesion set that was applied to the atria as therapy
for reentrant atrial arrhythmias.
The original “cut and sew” Cox-maze III procedure
resulted in long-term freedom from AF in greater than
97% of patients (1,49,53). All subsequent modifications
have achieved varying degrees of efficacy, approaching 93%
(1,54-56). The superiority of a biatrial maze procedure for
AF prevention has been demonstrated in several studies
(1,17,55,56). In a review of many different lesion sets for
AF, Barnett and Ad [2006] reviewed 69 studies and 5,885
patients who underwent surgical ablation (67% biatrial
and 33% left atrial) for AF lasting >6 or 12 months (56).
Survival rates were similar for both procedures, however,
the biatrial maze ablation demonstrated superior long-term
freedom from AF at all time points.
AFL
The classic “cut and sew” right-sided maze procedure (49)
involves a linear incision from the superior vena cava (SVC)
to the IVC, right atrial appendectomy, incision from the
base of the resected right atrial appendage to the midpoint
of the right atrial anterior wall not in communication with
the SVC-IVC incision, an incision posteriorly from the base
of the right atrial appendage to the anterior tricuspid valve
annulus, and a communicating incision from the SVC-IVC
incision to the posterior tricuspid valve annulus (1). It is
important to recognize that these lesions were developed
from animal models without congenital heart disease or
previous operations.
Subsequent electrophysiology studies have demonstrated
the key role played by the right atrial isthmus in typical
right AFL (isthmus dependent right atrial macroreentry)
(1,57-60). The right atrial isthmus is considered the area
between the tricuspid valve annulus and the coronary sinus
and the IVC. Targeted ablation of this isthmus region
transforms the area of “slow conduction” to an area of “no
conduction” and effectively terminates typical AFL (1,61).
In the congenital heart disease population, additional
right atrial macroreentrant circuits have been identified
commonly referred to as “non-isthmus” dependent
tachycardia (1,62). These circuits may involve reentry
around prior incisions (“incisional tachycardia”) or
prosthetic material such as ASD patches. The lateral right
atrial wall at the inferior aspect of the crista terminalis is
often an area of unexcitable atrial tissue with low voltage
electrograms and is labeled as “scar”. This area of “slow
conduction” or scar can contribute to an additional
macroreentrant circuit. Elimination of the isthmus of slow
conduction between these incisions, patches, or electrical
scars forms the basis of ablation strategies for non-isthmus-
dependent right atrial tachycardia. These alternative
lesion sets are referred to as “modified right atrial maze
procedures” and appear to be responsible for elimination of
right atrial tachycardia in the setting of complex congenital
heart disease (14,62). The lesion sets of the modified right
atrial maze (Figures 1,2) (1,63) may not be appropriate to
employ as prophylactic lesion sets as the evidence for first
time arrhythmia occurrence favors an isthmus-dependent
circuit. In light of the accumulated retrospective studies, we
favor an isthmus lesion (Figure 1) for right atrial arrhythmia
prophylaxis (1,63).
Energy sources
Technical concerns relative to the “cut and sew” maze
include the length of the procedure and risk of perioperative
bleeding (1). Energy sources have been developed to
minimize the need for incisions and subsequent bleeding
complications (1,8,48-51,53,64).
Khargi and colleagues [2005] compared alternative
sources of energy (radiofrequency-microwave and
cryoablation; group I) for treating AF with a classic cut and
sew Cox-maze III (group II), which claims 97% to 99%
sinus rhythm success rate (1,65). Forty eight studies were
reviewed with 3,832 patients (2,279 in group I and 1,553
in group II). There was no difference in mean duration of
preoperative AF, left atrial diameter and left ventricular
ejection fraction. Freedom from AF was 78% (group I),
85% (group II), and not statistically significant, implying
no significant difference in the two sources of energy (1).
Schuessler et al. [2009] summarized their experience in
porcine models with 9 different unidirectional devices to
create continuous transmural lines of ablation from the

49. 154 Mavroudis and Deal. Prophylactic arrhythmia surgery for CHD
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):148-159tp.amegroups.com
atrial epicardium and thereby replace the cut and sew
lesions with lines of ablation and perform the procedure
without cardiopulmonary bypass (66). The devices included
radiofrequency, microwave, lasers, and a cryothermia device.
The maximum penetration of any device was 8.3 mm
and therefore all devices except one (a radiofrequency
device) failed to penetrate 2.0 mm in some non-transmural
sections.
It appears that depth of lesions by whatever means is
more important than the energy sources/incisions that are
used to achieve the result. Patients with congenital heart
disease have varying degrees of atrial thickness owing to the
specific heart defect and the adaptive mechanisms over a
lifetime of perturbed hemodynamics. For example, patients
with tricuspid atresia have thick atrial walls, while patients
with double inlet left ventricle tend to have thin atrial
walls. These anatomic variances become important when a
transmural lesion needs to be accomplished.
What we know about lesion sets for atrial
tachycardia
The right-sided maze procedure as described by Cox et al.
[1991] has a number of lesion sets that are performed by
the classic “cut and sew” technique (47). The traditional
surgical lesions in the classical right atrial maze include
right atrial appendectomy, a lesion between the amputated
right atrial appendage and the anterior tricuspid annulus,
and the lesion from the SVC to the IVC (63). In particular,
the lesion between the SVC and the IVC is similar to the
incision that is oftentimes performed to repair a sinus
venosus ASD (63). This incision is commenced in the upper
third of the right atrial free wall and extends through the
area of the sinoatrial node into the SVC. This repair, when
performed in this manner has a high incidence of sinus node
dysfunction, resulting in nodal rhythm.
Subsequent development of the modified right atrial
Figure 1 A right atrial view of potential prophylactic ablative
lesions after aortobicaval cardiopulmonary bypass and cardioplegic
arrest. The two cryoablation lines (cryoablation or radiofrequency
ablation) connect the coronary sinus with the os of the inferior
vena cava and the tricuspid annulus with the os of the inferior vena
cava, respectively. Reproduced with permission from Mavroudis
C, et al. Prophylactic atrial arrhythmia surgical procedures with
congenital heart operations: review and recommendations. Ann
Thorac Surg 2015;99:352-59. Copyright © 2015 with permission
from Elsevier (1).
Figure 2 Right and left atrial views of potential prophylactic
ablative lesions after aortobicaval cardiopulmonary bypass and
cardioplegic arrest. Added to the lesion set in Figure 1 are the
lesion sets that comprise the left sided maze procedure without
performing a left atrial appendectomy. Shown in the left atrium
are circumferential isolation of the pulmonary vein confluence,
connection of the pulmonary vein confluence with the P3
location of the posterior mitral valve annulus, and connection
of the pulmonary vein confluence with the base of the left atrial
appendage. Reproduced with permission from Mavroudis C,
et al. Prophylactic atrial arrhythmia surgical procedures with
congenital heart operations: review and recommendations. Ann
Thorac Surg 2015;99:352-59. Copyright © 2015 with permission
from Elsevier (1).

50. 155Translational Pediatrics, Vol 5, No 3 July 2016
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):148-159tp.amegroups.com
maze includes lesions between the IVC and the tricuspid
valve, the coronary sinus and the tricuspid valve, and
between the IVC and the coronary sinus. The right
atrial cavotricuspid isthmus represents areas of “slow
conduction” which together with an area of unidirectional
block contribute to atrial reentry tachycardia (1,61,63).
Converting these locations from areas of slow conduction to
areas of no conduction using transcatheter radiofrequency
ablation techniques can be effective. This area at the
so-called “isthmus” is usually the first set of applied
radiofrequency lesions that are delivered by transcatheter
techniques in a hierarchical series that includes the area
between the fossa ovalis and the lateral wall crista terminalis,
the base of the atrial appendage and the tricuspid annulus,
as well as other areas of slow conduction that are identified
by electrophysiologic mapping.
Because of the severity of the tachycardia in patients with
complex congenital heart disease such as Fontan patients,
arrhythmia ablation tends to be more important than the
risk of nodal rhythm, which can be treated by pacemaker
therapy (63). In addition, surgical ablation in these
populations does not lend itself to a step wise hierarchical
treatment plan because access to the anatomic areas of
interest often require extending the cross clamp time
under some type of systemic hypothermia. Separation from
cardiopulmonary bypass, remapping and recommencement
of cardiopulmonary bypass/aortic cross clamp to ablate
the next area of interest increases the risks of myocardial
ischemia, systemic inflammation, and air embolism (63). As
a result, surgeons are more likely to ascribe to the axioms
“more is better” and “getting it right the first time”. These
tenets are not operative, however, when considering simple
cases of atrial tachycardia or recent onset of AF in patients
with two ventricles and congenital heart disease. This is
especially true when considering prophylactic arrhythmia
surgery, which raises the tenet of “do no harm”.
In light of evidence of sinus node dysfunction following
the classic right atrial maze in the ASD population, it seems
unwise to include the lesion between the SVC to IVC to
prevent atrial tachycardia as a prophylactic procedure,
especially because there is little proof as to the validity of
this lesion when compared with the isthmus ablation line.
The same is true for the lesion that is sometimes placed
from the fossa ovalis to the posterior atrial flap of the
atriotomy, when an atriotomy is required for right atrial
access. While this lesion might be indicated for treatment of
incessant atrial tachycardia, there is very little evidence that
such a lesion might be effective as a prophylactic measure.
Proposed lesions sets for prophylactic
arrhythmia surgery
Prophylactic arrhythmia surgery in humans with congenital
heart disease has not been tested by a prospective,
randomized, clinical study owing to non-standardized lesion
sets, variable patient populations, and lack of unanimity
for the need of this additive procedure, which requires a
measurable amount of cardiopulmonary bypass and cross-
clamp times (1). In addition to these impediments are the
paucity of retrospective clinical studies, which can help to
define various approaches to certain patient populations and
can form the basis for clinical equipoise and the need for an
organized multi-institutional study (1).
There have been very few studies that have applied
therapeutic lesion sets as prophylactic measures in
humans (1,5,17,21). Based on animal studies that induce
atrial tachycardia and lysis with one incision, Collins and
associates applied a single incision in the anterior atrial flap
to the anterior tricuspid annulus in Fontan patients (67).
The idea was that this lesion would mitigate against the
incidence of atrial tachycardia. The short-term results failed
to show efficacy, which was perhaps related to the small
number of patients with limited follow up or alternatively
related to a lesion set that did not address the right atrial
cavotricuspid isthmus (1).
Based on the limited clinical studies, retrospective surgical
and transcatheter ablation results, and the debated opinion
of surgeons, prophylactic arrhythmia lesion sets are offered
for diagnostic subsets with predictive arrhythmia occurrence
that are undergoing a primary or secondary therapeutic
anatomic surgical intervention (Table 3, Figures 1,2) (1,63).
Based on the historic data regarding populations with the
highest incidence of atrial arrhythmia development, targeted
populations for prophylactic arrhythmia surgery in the right
atrium include patients with unrepaired ASDs presenting
over 40 years of age (1,5), patients with Ebstein anomaly (1),
tetralogy patients presenting for pulmonary valve insertion
(1,68,69), and single-ventricle patients who present for
Fontan operations (1,16,32,70-72). Prophylactic surgery for
AF would be considered for patients with significant left-
sided atrioventricular disease and severe left atrial dilatation
undergoing planned surgery, with lesions including left atrial
maze and right-sided cavotricuspid isthmus ablation (16).
Figure 1 shows a lesion set that interrupts the potential
areas of slow conduction at the “isthmus” (1,63). This is the
first area that is approached for therapeutic transcatheter
radiofrequency ablation in patients with atrial reentry

51. 156 Mavroudis and Deal. Prophylactic arrhythmia surgery for CHD
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):148-159tp.amegroups.com
tachycardia, which is successful in 75% of cases. The area
of interest is easy to locate, easy to ablate and has minimal
risks. Figure 2 shows the lesion set for prevention of AF.
Lesion sets should be standardized not only for
therapeutic measures but also for prophylactic applications
for patients with congenital heart disease undergoing
repair. The principles of prophylactic procedures should be
preserved, namely that the prophylactic procedure should
be simple to perform, should be attended by a minimum of
complications, and be supportive of potential problems that
can cause significant hemodynamic problems to the patient
over the long term.
Acknowledgements
None.
Footnote
Conflicts of Interest: The authors have no conflicts of interest
to declare.
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Congenital heart
disease
Type of arrhythmia at
risk
Prophylactic lesion set Timing of procedure
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operations performed in adolescents and adults
ART, large right and left
atria
See Figure 2 (1,63) Primary repair in patients without arrhythmias; not enough data
to recommend prophylactic operations in neonates and infants
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Atrial septal defect Atrial fibrillation See Figures 1,2 (1,63) Patients >40 years without arrhythmias
Tetralogy of Fallot ART See Figure 1 (1,63) Reoperation for older patients without arrhythmias
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Cite this article as: Mavroudis C, Deal BJ. Prophylactic
arrhythmia surgery in association with congenital heart disease.
Transl Pediatr 2016;5(3):148-159. doi: 10.21037/tp.2016.06.04

55. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):160-164tp.amegroups.com
Introduction
Pediatric Cardiovascular Intensive Care has become
increasingly organized as a subspecialty over the past two
decades. The pediatric cardiac intensivist plays a central role
in the critical care of these patients, as well as continuous
quality improvement and family centered care. This growth
of the subspecialty comes in response to the explosion of
knowledge and research in the patient with critical cardiac
disease, the increasing complexity of cardiac lesions and
procedures to treat them, and the growing numbers of
patients of a younger age requiring cardiac intensive care.
Indeed an international subspecialty society, the Pediatric
Cardiac Intensive Care Society, was organized in 2003 to
address the issues facing practitioners.
Within this review, we take the opportunity to examine
the subspecialty’s past accomplishments with pride, take
stock in its current state, and look forward with excitement
to its future. Additionally, it gives the opportunity to
applaud those who attempt to innovate in order to radically
improve the future care of these children.
Looking backward
It is clear that we have had rapid advancement in all outcome
measures (1). However, the danger of always looking
backward is that we are subject to either positive or negative
revisionist history. Additionally, hindsight is always 20/20.
The reality is, as with all history, truth is found somewhere in
the middle ground between the superlative and stupidity. We
were never as good, nor as bad, as we think.
An interesting conceptual framework that is important
in medicine is that throughout the history of care, at the
time and in the present, we were convinced that we were
doing the right thing for our patients. However, many of
these truths have subsequently proved to be false. In the
modern world facts change all of the time, according to
Samuel Arbesman, author of The Half-Life of Facts: Why
Everything We Know Has an Expiration Date (2). Since
scientific knowledge is still growing by a factor of ten
every 50 years, it should not be surprising that many of the
facts people learned in school and universities have been
overturned and are now out of date. But at what rate do
former facts disappear? Applying the concept of half-life to
facts, Arbesman cites research that looked into the decay in
the truth of clinical knowledge about cirrhosis and hepatitis.
“The half-life of truth was 45 years,” reported the researchers.
An example of the changing “truth” occurred in relation
to George Washington, the former President and senior
leader of our nascent country. On December 12, 1799,
Review Article
Critical cardiac care in children: looking backward and looking forward
Paul A. Checchia
Pediatric Cardiovascular Intensive Care, Texas Children’s Hospital, Baylor College of Medicine, Houston, Texas, USA
Correspondence to: Paul A. Checchia, MD, FCCM, FACC, Professor, Director. Pediatric Critical Care Medicine and Cardiology, Pediatric Cardiovascular
Intensive Care, Texas Children’s Hospital, Baylor College of Medicine, 6621 Fannin st. W6006, Houston, Texas 77030, USA. Email: checchia@bcm.edu.
Abstract: The growth of Pediatric Cardiovascular Intensive Care as a subspecialty has been incredible.
Outcomes have improved, care delivery has matured, and research has made advances. Within this review, we
take the opportunity to examine the subspecialty’s past accomplishments with pride, take stock in its current
state, and look forward with excitement to its future. While outcomes in general have improved dramatically,
we must always be aware of the outcomes that matter to families and patients. Additionally, we must
constantly ask ourselves to improve. Research into neuroprotection and individual therapeutic strategies
based in genomic medicine provide the next opportunity for the subspecialty to improve.
Keywords: Pediatric; cardiac; congenital heart disease (CHD); outcomes
Submitted Jun 16, 2016. Accepted for publication Jun 24, 2016.
doi: 10.21037/tp.2016.06.07
View this article at: http://dx.doi.org/10.21037/tp.2016.06.07

56. 161Translational Pediatrics, Vol 5, No 3 July 2016
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Washington suffered from an upper respiratory infection (3).
His physicians applied a painful “blister of cantharides”,
better known as “Spanish fly”, to Washington’s throat to
cause “counter-irritation”. They justified the removal of
more than 80 ounces of his blood (2.365 liters or 40 percent
of his total blood volume) over a 12-hour period in order
to reduce the massive inflammation of his windpipe and
constrict the blood vessels in the region.
Of course, this is seen as ridiculous in today’s scientific
understanding. However, as stated, in their present it was
the most justifiable approach. So with this as background,
what are some of the “truths” in the care of critically ill
children with cardiac disease that will be questioned in the
future. I propose discussion pertaining to three present day
“truths”. First, we think surgeons actually matter. Second,
we think doctors actually matter. Finally, we think we know
which outcomes matter.
We examined the influence of surgical volume on outcome
in a recent investigation of the Norwood procedure (4).
Lower mortality following the Norwood procedure was
associated with high institutional volume. However,
lower mortality was not associated with the number of
cases performed by a surgeon. We concluded that a well-
experienced surgeon was necessary but insufficient to truly
impact positive outcomes. The impact of the institution, the
team, had a greater influence on outcomes.
Ultimately, cardiovascular critical care is a team sport.
Every participant has a role in the care of each child.
Everyone from physicians, to nurses, to therapists, to
family members, all influence the success of complex care.
However, there is a struggle within this team concept.
The team is important, but ultimately the individual is
accountable for their performance. As stated by former
coach Phil Jackson, “The strength of the team is each
individual member...the strength of each member is the team”.
It is incumbent on the specialty as a whole to develop care
models that enhance teamwork while maintaining a culture
of individual skill, pride and accountability.
Another team member that is viewed as important in
today’s truth construct is the physician. I would contend
that doctors are not as important as we believe ourselves to
be in today’s cardiovascular intensive care unit. The most
important member of today’s unit team is the bedside nurse.
While we continually rely on technology in the form of
monitors, diagnostic imaging, and laboratory surveillance,
all data gained from monitors must be integrated with
the information gained by physical exam. An experienced
clinician must accomplish this integration. While
technology can serve to aid in the care of the patient,
nothing can replace the experience of a clinician. Bernard
Lown, writing in Scientific American, outlined such a balance
over 40 years ago. “Neither monitors nor the most complicated
electronic gear makes a coronary care unit. The fundamental
ingredient is a properly indoctrinated nursing staff. The reason
for this is obvious. The nurse is usually the only trained medical
professional at the bedside during important clinical events.
The time for effective action is brief and does not usually allow
delay for the arrival of a physician. The nurse is trained in the
recognition of arrhythmias and is delegated the authority for
enacting the entire repertory of lifesaving techniques In fact,
many well-functioning coronary care units have been successful
because of the elite spirit and competence of the nursing staff.” (5).
As was apparent in the infancy of cardiac critical care,
the presence at the bedside by experienced clinicians was
paramount to success. However, this paradigm is currently
under attack. We are forced to limit the experience gained
by trainees and bedside nurses. While we profess the desire
to avoid monitors acting as a replacement to experienced
clinicians, we are forced to re-examine their utility when
faced with shifts covered by residents and fellows who are
restricted by work hours, and young nurses who have just
graduated nursing school. This represents a new challenge
to the continued growth and success of our care delivery
models.
Finally, we think we know the outcomes that matter.
Boneva et al. (1) reviewed population-based mortality data
of congenital heart disease (CHD) from 1979–1997, from
the Center for Disease Control and Prevention (CDC).
Overall mortality decreased 39%. Yet there was a smaller
decline in HLHS—7.5%, and TOF—10%. The decrease
for TGV was 40.6% in infants <1 year and 74.4% in
children 1–4 years of age. In fact, our center has reported
overall outcomes of surgical procedures improved to <1%
mortality. While individual lesions, risk categories, and co-
morbid conditions impact this low mortality leading to
variations within risk subcategories, the improvement is
obvious. We are not alone in this staggering improvement.
It is safe to say that, as a community, we have moved
CHD from an expected mortality to an expected survival.
However, this creates risks, opportunities, and consequences,
not the least of which is a loss of perspective of meaningful
outcome.
In 1986, Lillehei et al. reported long term follow up on his
first operations conducted from 1954 to 1960 (6). Of course,
he was proud of an actuarial survival at 30 years of 77%.
However, he also went on to highlight other outcomes. In his

57. 162 Checchia. Critical cardiac care: looking backward and forward
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):160-164tp.amegroups.com
cohort of patients, 32% completed college, ten completed
graduate school, 40 patients had children with 93% of
those being live births, and 7.3% with cardiac defects. He
understood that these are the outcomes that truly matter.
This pre-dates the latest attention to neurodevelopmental
outcomes.
Ever since Alfred Blalock reported how successful the
original interventions were at improving quality of life (7),
we, as a community, thought we were great. However,
that greatness was short lived. Ignorance, it seems, truly
was bliss. As these children aged, we realized the impact
of CHD, surgical interventions, cardiopulmonary bypass
(CPB), and medications on the neurodevelopmental
outcomes of these children (8). Our historical success has
allowed us to realize that the road to an adult survivor of
CHD is one that is far from linear. It is now incumbent on
our entire field to cooperate, coordinate, and collaborate
to determine how best to protect the neurologic status of
our patients, and allow them to become the type of adult
survivor we hope for when we first meet with families.
Looking forward
This easily transitions to looking forward in our subspecialty.
Where do we go from here? How do we improve? The
path to improvement in care involves education, research,
and innovation. It is through the combined work of the
committees and the Board of Directors of the PCICS
that will soon yield training pathways for physicians and
nurses seeking additional experience in cardiac critical care,
international quality improvement initiatives, online journal
clubs, and a research structure that will provide robust
collaboration and mentorship opportunities. Innovation
requires pushing boundaries, changing perspective on
current problems, and taking risks. Three areas that have
promise to do just that involve protection during CPB, data
management, and the promise of individualized medicine.
In a recent study, we evaluated the impact of delivery of the
gas nitric oxide (gNO) to the membrane oxygenator of the
CPB circuit on postoperative outcome measures in children
undergoing cardiac surgery for CHD (9). Children who
received gNO during CPB had an improved postoperative
course, as demonstrated by significantly reduced myocardial
injury and shortened duration of mechanical ventilation
and length of stay in the pediatric CICU. This has been
reproduced by colleagues in Australia (10). Our premise is
that NO added to the circuit has effect distal to the entry site.
This is a novel concept and one that fits the requirement of
pushing boundaries for innovation. It is possible that through
this type of novel, innovative application of existing drugs or
therapies, we may impact outcomes in ways not previously
realized.
Innovation is also necessary to adequately capture and
interpret the ever-expanding wealth of data generated
by each individual patient or event within a critical care
hospitalization. Ultimately, data equals power. Data gives us
the power to do the right thing well, at the right time and
with the minimum of resources. Do it well, once, and with
no complications.
For example, monitoring patients allows us to gauge the
effectiveness of our efforts. Our goal is to monitor, and then
intervene, in order to avoid progression to a decompensated
shock state. It is the cornerstone of modern critical care
medicine that intervening prior to the development of end-
organ dysfunction or damage yields improved outcomes
for the patients in our care. While monitoring can guide
intervention, one effect of this approach is the generation
of increasing volumes of data. As an intensivist, we must
manage an enormous amount of information each moment
we care for patients. These data must ultimately guide
interventions. Yet with the growing volume of data, how
do we know what information is meaningful? How do
we separate the wheat from the chafe? This is the role of
effective monitoring and effective data management in a
modern ICU setting.
The second challenge for innovation comes in the
integration of the overwhelming amount of data presented
in a modern pediatric cardiac intensive care setting. We
not only manage patients, we manage data. We need to
develop the means to adequately monitor trends and pick
up a signal when one is present. Monitoring in the pediatric
cardiac intensive care environment should be an intuitive
and analytic process. As noted above, there are numerous
monitoring modalities available, both physiologic and
laboratory based. The clinician at the bedside needs to be
able to integrate this information to track the trajectory of
the patient, and decide on interventions when necessary.
Further, we do not know the impact of specific monitoring
on patient recovery and outcome, on cost effectiveness
and on the longer term quality of life; we assume we are
monitoring the right predictors of outcome and that the
target ranges are correct as well.
We have assumed that more is better although there are
clear problems with fixation on specific abnormal results
that deflect critical decisions. We now work in very complex
environments. There is a huge amount of information

58. 163Translational Pediatrics, Vol 5, No 3 July 2016
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coming to the clinicians from physiologic and laboratory
data, yet we do not collect, store and analyze this data in
real time. In addition, there are multiple distractions at the
bedside with continual interruptions to workflow. In short,
we have not leveraged information systems to our benefit,
and have not leveraged our common knowledge within
the field and between institutions to standardize care and
resource utilization. We need to leverage monitoring data
to move away from the traditional “chain-of-event” analysis
following adverse outcomes, which focuses primarily on
patient characteristics and human error, and also move away
from a “failure to rescue” analysis which focuses on unit-
based team structure and function. Rather, we should focus
on “failure to predict” an evolving clinical picture, which
really evaluates systems characteristics and data integration.
We need to understand how we function as a system and
leverage the information systems to support our workflow.
In addition to information systems and data management,
there has been an explosion of genetic data and power in
the past two decades. We now have the ability, through
whole genome informatics, to analyze the information found
in literally thousands of genes within minutes. Data from
investigators such as Hector Wong and Perren Cobb (11,12),
to name but two, indicate that blood transcriptional and
proteomic profiles can distinguish between host responses to
different types of injuries in different age groups. They are
demonstrating that information at the genome (DNA) level
provides information about predisposition to a given outcome,
while data at the transcriptome (RNA) (13) and proteome
(protein) levels can be harnessed to make diagnoses, and finally
gauge the response to therapy (prognoses). The promise of
this line of investigation is that these patterns of change in
gene and protein expression, in effect, become new, genomic
“vital signs” (14). Additionally, we now have the computational
power to not only analyze these data at a single point in the
time course of a patient, but also across the time spectrum
of the entire disease and healing trajectory (15,16). Through
these discoveries, we finally have the potential for truly
personalized diagnosis and intervention. Within these lines of
investigation lies the opportunity for providing the right care
to the right person at the exact right time. What if we applied
this approach and this technology to other outcome questions
such as sedation and analgesia postoperatively, nutrition, and
neurodevelopmental outcomes?
Conclusions
There have been incredible advances in the care of
children with cardiac disease. We should all take pause and
recognize the advancements that have been made. I would
contend that there are very few areas of medicine that have
achieved the same degree of success over the past 50 years.
However, it is now incumbent on each of us in the field to
build upon these advances so that the next generation of
practitioners will be just as proud to look back on our latest
accomplishments.
Acknowledgements
None.
Footnote
Conflicts of Interest: The author has no conflicts of interest to
declare.
References
1. Boneva RS, Botto LD, Moore CA, et al. Mortality
associated with congenital heart defects in the United
States: trends and racial disparities, 1979-1997. Circulation
2001;103:2376-81.
2. Arbesman S. The half-life of facts: why everything we
know has an expiration date. New York: Current, 2012.
3. Witt CB Jr. The health and controversial death of George
Washington. Ear Nose Throat J 2001;80:102-5.
4. Checchia PA, McCollegan J, Daher N, et al. The effect
of surgical case volume on outcome after the Norwood
procedure. J Thorac Cardiovasc Surg 2005;129:754-9.
5. Lown B. Intensive heart care. Sci Am 1968;219:19-27.
6. Lillehei CW, Varco RL, Cohen M, et al. The first open
heart corrections of tetralogy of Fallot. A 26-31 year
follow-up of 106 patients. Ann Surg 1986;204:490-502.
7. Taussig H, Blalock A. Surgery of congenital heart disease.
Br Med J 1947;2:462.
8. Marino BS. New concepts in predicting, evaluating, and
managing neurodevelopmental outcomes in children with
congenital heart disease. Curr Opin Pediatr 2013;25:574-84.
9. Checchia PA, Bronicki RA, Muenzer JT, et al. Nitric
oxide delivery during cardiopulmonary bypass reduces
postoperative morbidity in children--a randomized trial. J
Thorac Cardiovasc Surg 2013;146:530-6.
10. James CS, Horton S, Brizard C, et al. Abstract 14827:
Nitric Oxide During Cardiopulmonary Bypass Improves
Clinical Outcome: A Blinded, Randomized Controlled
Trial. Circulation 2015;132:A14827.

59. 164 Checchia. Critical cardiac care: looking backward and forward
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11. Chung TP, Laramie JM, Province M, et al. Functional
genomics of critical illness and injury. Crit Care Med
2002;30:S51-7.
12. Wong HR. Genetics and genomics in pediatric septic
shock. Crit Care Med 2012;40:1618-26.
13. McDunn JE, Muenzer JT, Rachdi L, et al. Peptide-
mediated activation of Akt and extracellular regulated
kinase signaling prevents lymphocyte apoptosis. FASEB J
2008;22:561-8.
14. Cobb JP, Brownstein BH, Watson MA, et al. Injury in the
era of genomics. Shock 2001;15:165-70.
15. Wong HR, Cvijanovich N, Allen GL, et al. Genomic
expression profiling across the pediatric systemic
inflammatory response syndrome, sepsis, and septic shock
spectrum. Crit Care Med 2009;37:1558-66.
16. McDunn JE, Husain KD, Polpitiya AD, et al. Plasticity
of the systemic inflammatory response to acute infection
during critical illness: development of the riboleukogram.
PLoS One 2008;3:e1564.
Cite this article as: Checchia PA. Critical cardiac care in
children: looking backward and looking forward. Transl Pediatr
2016;5(3):160-164. doi: 10.21037/tp.2016.06.07

60. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):165-168tp.amegroups.com
Introduction
Pulmonary atresia with ventricular septal defect (PA-VSD)
is a complex heart lesion, occurring 2% of all congenital
malformations (1,2). Management of patients with PA-VSD
in the neonatal period presents numerous challenges (3).
The primary aim of intervention for these patients is to
provide reliable pulmonary blood flow in order to prevent
life-threatening desaturation and promote further growth of
the pulmonary arteries. The traditional approach includes
a prostaglandin E infusion started shortly after birth with
subsequent surgical systemic-to-pulmonary artery shunting.
However, in 25% of cases with this lesion, the source
of pulmonary blood supply are collateral vessels, either
single or multiple, instead of the ductus arteriosus. These
collateral vessels are typically not amenable to the effects of
prostaglandin, and tend to be stenotic, making conservative
management of such patients fairly unpredictable.
In addition, application of an aorto-pulmonary shunt,
particularly in the setting of right aortic arch, which
occurs in 40% of patients with PA-VSD, is technically
more challenging, often requires a sternotomy with
cardiopulmonary bypass, and could create significant PA
distortion (1,4).
Recently, endovascular stenting of the ductus arteriosus
or of a collateral vessel in ductal-dependent pulmonary
circulation as an alternative to the BT-shunt has become
increasingly popular (5-7). In PA-VSD, the pulmonary
trunk is usually absent or severely hypoplastic. This results
in changing the pulmonary artery bifurcation geometry,
which makes positioning of the distal end of the stent
particularly difficult without the risk to compromise blood
flow in to the PA branches.
We describe the reverse Szabo (anchor-wire) technique,
which is used for precise proximal stent positioning at the
main branch in bifurcation coronary stenting (8,9). In the
available literature, we found only a very limited description
of the similar technique in congenital heart defects, by
Girona et al., describing a similar concept but with a slightly
different modification (10).
Case presentation
Patient M., 2 days of age, 2.5 kg, with a prenatal diagnosis
of “Tetralogy of Fallot” and without any significant
Case Report
Reverse Szabo technique for stenting a single major aorto-
pulmonary collateral vessel in pulmonary atresia with ventricular
septal defect
Igor V. Polivenok1,2
, John P. Breinholt3
, Sri O. Rao2
, Olga V. Buchneva1
1
Zaitcev Institute for General and Urgent Surgery NAMS of Ukraine, Kharkiv, Ukraine; 2
William Novick Global Cardiac Alliance, Memphis, TN,
USA; 3
University of Texas Health Science Center at Houston, TX, USA
Correspondence to: Igor V. Polivenok, MD, FSCAI. Zaitcev Institute for General and Urgent Surgery NAMS of Ukraine, 1 Balakireva entr., 61103,
Kharkiv, Ukraine. Email: polivenok@gmail.com.
Abstract: Management of pulmonary atresia with ventricular septal defect (PA-VSD) in the neonatal
period presents numerous challenges. Endovascular stenting of the ductus arteriosus or of a collateral vessel
in ductal-dependent pulmonary circulation as an alternative to the Blalock-Taussig (BT) shunt has become
increasingly popular in the last decades. The utilization of the reverse Szabo (anchor-wire) technique for
single collateral vessel stenting in a case of PA-VSD is described.
Keywords: Congenital heart disease, pediatrics; stenting technique; pediatric intervention
Submitted Jun 01, 2016. Accepted for publication Jun 24, 2016.
doi: 10.21037/tp.2016.07.02
View this article at: http://dx.doi.org/10.21037/tp.2016.07.02

61. 166 Polivenok et al. Reverse Szabo technique for PDA stenting
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comorbidities, was referred from the neonatal hospital
in clinically stable condition with saturation of 90%.
Transthoracic echocardiography revealed pulmonary atresia
with ventricular septal defect, and a continuous infusion
20 ng/kg/min of PGE1 was started. During the following
10 days the patient’s condition remained stable, but the
saturations gradually decreased to 70% without significant
response on to increased prostaglandins.
On the 12th
day of life, the baby was taken for
catheterization, which confirmed PA-VSD, single major
aorto-pulmonary collateral artery (MAPCA) and, right-
sided aortic arch (Figure 1). No other significant sources of
pulmonary flow were found.
Venous access was obtained via the right common
femoral vein with a 4 Fr introducer sheath (Terumo, Tokyo,
Japan) and IV Heparin 100 IU/kg was administered. A 4-Fr
JR catheter over 0.035'' hydrophilic angled guide wire
(Radifocus, Terumo, Tokyo, Japan) was advanced through
the VSD into the ascending aorta. A 0.018'' guide wire
(V-18, Boston Scientific, Marlborough, MA, USA) was then
inserted into the descending aorta, after which the 4-Fr
introducer sheath was exchanged for a long 4-Fr sheath
(Cook Medical, Bloomington, IN, USA) positioning the
tip in the ascending aorta opposite the innominate artery.
The innominate artery was engaged by rotating of the
sheath, and the 0.018'' guide wire was advanced through the
collateral vessel into the distal pulmonary artery followed
by the sheath, deeper to the ostium of the collateral vessel.
To facilitate further insertion of the sheath further and
establish a more stable position, we used the “mother
and child” technique by introducing the 4-Fr JR catheter
through the sheath deeper into the collateral vessel. Then
the pulmonary arteries were wired with two 0.014’’ guide
wires (Runthrough NS, Terumo, Tokyo, Japan) as distally
as possible, in order to achieve a stable position of the
assembly (Figure 2). After measuring collateral vessel length
and considering patient weight, the coronary bare metal
stent 3.5×22 mm2
was selected (Integrity, Medtronic, Santa
Rosa, CA, USA).
The proximal end of the right pulmonary artery guide
wire was introduced into the lumen of the balloon. Then
the protective tube over the stent was slightly withdrawn
to uncover two rows of stent cells. The balloon was gently
inflated to expand the most distal rows of stent cells
(Figure 3A). The second left pulmonary artery guide
wire (anchor wire) was inserted through the most distal,
expanded stent cell (Figure 3B) and the stent was manually
crimped over the balloon again (Figure 3C). The stent was
then advanced to the branch pulmonary artery bifurcation
(Figure 2B) and, after confirming its location with
angiography, deployed at nominal pressure (Figure 2C).
With this technique, the anchor wire delivers the
distal position of the stent at the bifurcation precisely
and prevents undesired distal sliding of the stent during
inflation (Figure 2D). At the same time, we can safely apply
continuous forward force on the whole assembly to prevent
the stent from missing the bifurcation, which typically is the
most stenotic segment.
The post-intervention course was without complications.
After the procedure, the patient developed moderate
pulmonary over-circulation with saturations of 96%,
which were easily controlled with conservative medical
management. The patient was extubated the following
morning, his condition was stable with saturations of
88–90% without heart failure or systemic hypoperfusion.
Two days after the procedure, he was transferred to the
neonatal hospital on Aspirin 5 mg/kg per day.
Discussion
The anchor-wire technique, originally described by Szabo,
was used in coronary stenting for precise positioning of
the stent in the ostium of the main vessel (8). The Reverse
Szabo technique at V-stenting of the coronary arteries
was described by Lo and Kern (9). Nonetheless, the use
of anchor-wire technique for stenting in congenital heart
diseases has been limited. Only Girone et al. described the
use of an extended anchor-wire concept in the treatment of
congenital malformations (10). However, in their original
description, to anchor the distal end of the stent, the
Figure 1 Angiography of PA-VSD, a single collateral vessel takes
off from a right-sided aortic arch with pulmonary trunk hypoplasia.

62. 167Translational Pediatrics, Vol 5, No 3 July 2016
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anchor wire was passed through the entire stent. In our
modification, the anchoring wire was passed through the
most distal stent cell. As this is a pre-mounted assembly, we
were able to minimize the risk of the stent sliding from the
balloon while advancing.
Conclusions
The utilization of the described technique for PDA/
collateral vessel stenting has the following advantages over
the traditional approach: (I) precise positioning of the distal
end of the stent exactly at the bifurcation without the risk
of stent protrusion into the one of the branch pulmonary
arteries; (II) minimization of the risk of missing the usual
stenosis at the insertion of the vessel at the pulmonary
artery bifurcation by allowing safe continuous forward
pressure application on the stent-balloon assembly before
Figure 2 Reverse Szabo technique of single collateral vessel stenting: (A) 0.014’’ guide wires in both PAs; (B) stent-balloon assembly
advanced to the desired position. The anchor wire fixes the distal end of the stent exactly at the carina level; (C) stent deployment; (D) final
position of the stent.
Figure 3 Stent preparation: (A) gentle inflation of the balloon to
expand the most distal rows of the stent cells; (B) insertion of the
proximal end of anchor guide wire through a most distal stent cell;
(C) stent crimped again over the balloon and anchor guide wire.
A
B
C
C
A
D
B

63. 168 Polivenok et al. Reverse Szabo technique for PDA stenting
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):165-168tp.amegroups.com
and during deployment; (III) and facilitate advancement of
the stent-balloon assembly due to the presence of a buddy-
wire.
Acknowledgements
None.
Footnote
Conflicts of Interest: The authors have no conflicts of interest
to declare.
Informed Consent: Written informed consent was obtained
from the patient for publication of this mauscript and any
accompanying images.
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7. Okubo M, Benson LN. Intravascular and intracardiac
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2001;16:84-91.
8. Szabo S, Abramowits B, Vaitkuts PT. New technique
for aorto-ostial stent placement (Abstr) Am J Cardiol
2005;96:212 H.
9. Lo H, Kern MJ. Use of a branch wire to anchor stents
for exact placement proximal to bifurcation stents: the
reverse Szabo technique. Catheter Cardiovasc Interv
2006;67:904-7.
10. Girona J, Martí G, Betrian P, et al. Extended Szabo
(anchor-wire) technique concept for stent implantation in
congenital heart lesions. Pediatr Cardiol 2012;33:1089-96.
Cite this article as: Polivenok IV, Breinholt JP, Rao SO,
Buchneva OV. Reverse Szabo technique for stenting a single
major aorto-pulmonary collateral vessel in pulmonary atresia
with ventricular septal defect. Transl Pediatr 2016;5(3):165-168.
doi:10.21037/tp.2016.07.02

64. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):169-179tp.amegroups.com
Introduction
Epilepsy is a common yet rarely discussed chronic disease.
In the United States, 5.1 million individuals carry the
diagnosis of a seizure disorder or epilepsy (1-3). In 2012,
direct medical cost of epilepsy treatment amounted to
$9.6 billion (4); the cost of community services, lost wages
of individuals and caregivers, and immense social stress of
patients and their families add to the toll. The age of onset
of epilepsy is bimodal. Of the 5.1 million Americans with a
seizure disorder or epilepsy, 460,000 are age 17 or younger
and are actively undergoing epilepsy treatment (2,3).
Underlying etiologies of epilepsy include neonatal hypoxia,
congenital anomalies, traumatic brain injury, meningitis,
brain tumor, and stroke. Frequently, however, an underlying
cause is never identified.
Several modalities for epilepsy treatment exist. Medical
management in the form of antiepileptic drugs (AEDs) is
the first line of treatment and is successful in seizure control
in 60–80% of cases (5). At present, the United States
Food and Drug Administration (FDA) lists 18 AEDs, with
several drugs having short-acting and extended-release
preparations. Drug-resistant epilepsy (DRE) is defined by
the International League Against Epilepsy (ILAE) as an
adequate trial of two or more appropriately selected AEDs,
alone or in combination, with failure of treatment resulting
in continued seizures or intolerable side effects (6).
Pediatric Epilepsy Column (Review Article)
Preoperative evaluation and surgical decision-making in pediatric
epilepsy surgery
Katrina Ducis1,2
, Jian Guan2
, Michael Karsy2
, Robert J. Bollo2,3
1
Department of Neurosurgery, University of Vermont School of Medicine, Burlington, VT, USA; 2
Department of Neurosurgery, University of Utah
School of Medicine, Salt Lake City, UT, USA; 3
Division of Pediatric Neurosurgery, Primary Children’s Hospital, Salt Lake City, UT, USA
Contributions: (I) Concept and design: RJ Bollo, K Ducis; (II) Administrative support: All authors; (III) Provision of study materials: None; (IV)
Collection and assembly of data: None; (V) Data analysis and interpretation: None; (VI) Manuscript writing: All authors; (VII) Final approval of
manuscript: All authors.
Correspondence to: Robert J. Bollo. Department of Neurosurgery, University of Utah, Primary Children’s Hospital, 100 Mario Capecchi Drive, Salt
Lake City, UT 84113, USA. Email: neuropub@hsc.utah.edu.
Abstract: Epilepsy is a common disease in the pediatric population, and the majority of cases are controlled
with medications and lifestyle modification. For the children whose seizures are pharmacoresistant, continued
epileptic activity can have a severely detrimental impact on cognitive development. Early referral of children
with drug-resistant seizures to a pediatric epilepsy surgery center for evaluation is critical to achieving
optimal patient outcomes. There are several components to a thorough presurgical evaluation, including
a detailed medical history and physical examination, noninvasive testing including electroencephalogram,
magnetic resonance imaging (MRI) of the brain, and often metabolic imaging. When necessary, invasive
diagnostic testing using intracranial monitoring can be used. The identification of an epileptic focus may
allow resection or disconnection from normal brain structures, with the ultimate goal of complete seizure
remission. Additional operative measures can decrease seizure frequency and/or intensity if a clear epileptic
focus cannot be identified. In this review, we will discuss the nuances of presurgical evaluation and decision-
making in the management of children with drug-resistant epilepsy (DRE).
Keywords: Drug-resistant; epilepsy; seizure focus; pediatric; surgery
Submitted May 21, 2016. Accepted for publication May 25, 2016.
doi: 10.21037/tp.2016.06.02
View this article at: http://dx.doi.org/10.21037/tp.2016.06.02

65. 170 Ducis et al. Preoperative evaluation and decision-making in epilepsy
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Uncontrolled seizures represent an important public
health problem. A recent study published by Berg et al. (7)
prospectively analyzed 198 children based on age of first
seizure, pharmacoresistance, and cognitive outcomes. Patients
with DRE had statistically worse processing speed and verbal
comprehension scores, freedom from distractibility, and
overall intelligence quotients (IQs). Furthermore, among
children with DRE, younger age of seizure onset correlated
negatively with IQ. As these children age, continued epileptic
activity can prevent reaching major social milestones,
including driving and living independently.
Options for the treatment of DRE include lifestyle
modification and surgery. The ketogenic diet, consisting of
a combination of high fat and low carbohydrate content, has
been used to treat DRE with some success. It is the first-line
treatment for patients with glucose transporter type 1 and
pyruvate dehydrogenate complex deficiencies (8,9). The
ketogenic diet’s success depends on the ability of the patient
to maintain it. Among 59 patients initially enrolled in a recent
study, only 24 were able to maintain the ketogenic diet for
12 months. Although only a minority of patients were able to
sustain the diet for the entire study, 21 of those 24 children
experienced at least a 50% reduction in seizure frequency.
Independent of the ketogenic diet, children with persistent
seizures (due to failure to control seizures or intolerable
medication side effects) should be referred for surgical
evaluation as soon as they meet ILAE criteria for DRE (10).
Timing is critical because of the impact of persistent
seizures on the developing brain and because of the greater
neuroplasticity in younger children. If surgical intervention
necessitates resection or disconnection of eloquent areas of
brain and loss of function, potential for reorganization is
optimal at younger ages. Furthermore, continued epileptic
activity can lead to the spread of seizure activity to previously
normal areas of brain, an effect called “kindling”, leading to
further neurologic deficit and multifocal epilepsy, which may
be less amenable to surgical cure. Early patient assessment
is critical, especially in patients with developmental delay.
The factor most consistently associated with seizure freedom
is the ability to completely remove the epileptogenic zone
(11-13), which can often be identified through precise
preoperative planning.
Preoperative evaluation
There are several components to a thorough presurgical
evaluation. The core components include a detailed medical
history, physical examination, electroencephalography
(EEG), and structural brain magnetic resonance
imaging (MRI). Other noninvasive tests including
magnetoencephalography (MEG) and metabolic studies are
often complementary. In the context of discordant data from
noninvasive studies, epileptic foci near eloquent cortex,
or in patients with a normal structural MRI, intracranial
EEG recordings with subdural electrode arrays and depth
electrodes may also be required.
Electroencephalography
Ictal scalp EEG can be useful for localization of an epileptic
zone as it is widely available and relatively cost effective.
Among children with DRE and normal structural findings
MRI, EEG is critical for localization of the epileptic zone
or at least hemispheric lateralization. Scalp EEG is less
sensitive for epileptic foci located in the interhemispheric,
basal, or mesial temporal locations. In addition, although
interictal signal abnormalities may exist either remote
from a cortical lesion or in a multifocal pattern, this should
not influence eligibility or extent of resection if a solitary
structural lesion is demonstrated by MRI (14-16). Video
EEG is also useful in capturing and verifying auras. For
example, forced turning of the head and eyes with neck
extension localizes to the contralateral frontal eye fields
and can be the first indication of frontal lobe epilepsy (17).
Video EEG is also helpful in confirming whether
stereotypic, episodic behaviors are a manifestation of
seizure activity or are nonepileptic. If rapid seizure spread
is present, localization of the initial epileptic zone may
be limited, and additional modalities may be necessary
to augment localization. In specific regard to infantile
spasms, video EEG should be of sufficient length to capture
wakefulness, sleep, and wakening (18); 24-hour video EEG
monitoring has the best chance of capturing epileptic
spasms and detecting hypsarrhythmia (19).
Magnetic resonance imaging
The Pediatric Epilepsy Surgery Task Force created by
the ILAE recently published guidelines for evaluation of
surgical candidates. Of all the proposed testing, only two
modalities were uniformly agreed-upon core tests: scalp
EEG and MRI. A single lesion on MRI corresponding to
an EEG epileptogenic focus is a common situation with a
potentially straightforward surgical plan, but more complex
scenarios are frequently encountered. For example, in
patients with tuberous sclerosis complex, several cortical

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tubers may be present on imaging, making it more difficult
to determine the epileptogenic lesion noninvasively. In
addition, adult patterns of myelination do not appear until
18 months of age (20), and it is often difficult to resolve
subtle abnormalities including focal cortical dysplasia in
infants. Finally, while MRI is a widely available diagnostic
modality, barriers do exist. Strict contraindications include
cochlear implants and cardiac pacemakers, and images
can be degraded by presence of dental braces, ventricular
shunts, and any patient motion. Any image degradation
can be detrimental when attempting to detect subtle
abnormalities on high-resolution scans.
Functional MRI (fMRI) is another tool frequently
employed in the evaluation of patients with epilepsy.
Classically, fMRI has been used to map motor, speech,
auditory, and visual areas with the goal of avoiding them
during surgical resection. Areas of activation are identified
by blood-oxygen-level-dependent (BOLD) response
or increased blood flow to an identified region while
performing a specific task. It is critical that the specific tasks
used during fMRI are appropriate to the age and education
level of the patient, as responses are partially dependent
on this (21) and responses may be attenuated by tasks that
are too simple or too complex (22,23). Functional MRI is
limited in terms of seizure localization, as only a few case
reports exist of patients incidentally having a seizure while
undergoing BOLD sequence imaging. More commonly,
reflexive seizures, those that occur following a stimulus,
such as flashing lights or excessive heat, can be provoked
during imaging for localization purposes, as increased
blood flow will be present to the epileptogenic region.
The simultaneous use of scalp EEG and fMRI to localize
interictal discharges was successful in identifying the
epileptogenic region in 60% of cases in one report (24).
Magnetoencephalography
MEG is a more recent noninvasive method of epileptic
focus identification. This imaging modality detects magnetic
fields produced by the brain’s electrical activity. The signal
is created by cortical dendrites and is best detected when
oriented tangentially to the skull’s surface; signals from
deeper structures are not detected as well as those from
more superficial cortical regions. This modality is limited
by regional availability and cost, but has some advantages
in comparison to EEG. First, MEG is more sensitive than
EEG in detecting smaller epileptic foci, with a threshold
of 4–8 vs. 10–15 cm2
for scalp EEG (25). Interictal MEG
epileptiform discharges, including activity from insular
cortex (26-28), may be seen in approximately 50% of
patients without detectable interictal epileptiform discharges
on scalp EEG (29-31), which makes MEG particularly
useful in guiding the placement of intracranial electrodes
in patients without a structural lesion detectable by MRI. It
is also advantageous compared with scalp EEG recordings
for the detection and lateralization of interhemispheric
epileptiform activity (32-34) and can detect interictal mesial
temporal lobe discharges in as many as 85% of patients with
mesial temporal lobe epilepsy (35). In summary, MEG may
provide critical noninvasive localizing data when this cannot
be done with EEG and MRI alone (36).
Positron emission tomography (PET)
PET using fluorine 18 fluorodeoxyglucose (FDG) is a study
of brain metabolism and has a role in epileptogenic focus
localization, especially when structural MRI is unrevealing.
The brain’s primary energy source is glucose, and the
labeled glucose may reveal areas of relative hypo- or hyper-
metabolism with PET imaging. Hypometabolism occurs
at an epileptic focus in an interictal state and is the result
of neuronal loss, decreased synaptic activity, or decreased
activity of blood–brain barrier glucose transport receptors
(37-39). Because of the typical infrequency of seizure
activity, the test is typically performed in an interictal state,
but EEG is usually performed concurrently to determine
whether seizure activity occurs during the examination. If a
seizure occurs during the study, the EEG can correlate areas
of possible glucose hypermetabolism and the epileptic focus.
One limitation of FDG-PET imaging is that the area of
glucose hypometabolism, or functional deficit zone, is often
larger than the focal epileptic zone (40). PET localization
plays the greatest role in MRI-occult epilepsy or in children
with discordant noninvasive data between MRI and EEG
studies. It is critical to note that regions of hypometabolism
cannot differentiate the primary epileptogenic zone from
secondary foci (41).
Single-photon emission computed tomography (SPECT)
SPECT is a noninvasive, metabolic imaging study similar
to PET, with the distinction that it can be performed
peri-ictally. Ictal SPECT is completed by injection of a
radioisotope at the time of seizure onset. To conduct the
study, children are admitted to the hospital, and long-term
video EEG is placed. A seizure is confirmed by EEG and

67. 172 Ducis et al. Preoperative evaluation and decision-making in epilepsy
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at that time the radioisotope is injected, and imaging is
completed within subsequent hours. Interictal imaging
is completed at a separate time for digital subtraction to
identify areas of hypermetabolism during seizure onset.
If SPECT and PET localization are concordant with
EEG and MRI results, seizure freedom after surgery
is more likely than if these studies are discordant (42).
However, technical details may confound interpretation of
the results, including the length of time between seizure
onset and radioisotope administration, during which
propagation of the seizure may occur. Children with
focal cortical dysplasia, including those with a “normal”
structural MRI, have higher rates of seizure freedom with
complete resection of the perfusion abnormality identified
by SPECT (43).
Intracranial electroencephalography (EEG)
Intracranial EEG is an invasive measure to identify an
epileptic zone that incorporates subdural EEG strip,
grid, and depth electrode placement via craniotomy and
stereotactic depth electrode insertion (Figure 1). Intracranial
EEG is often required if lateralization or localization of an
epileptic focus has not been identified using noninvasive
methods and also facilitates cortical stimulation mapping
of functionally eloquent cortex. Although this modality is
the gold standard of epileptic focus localization, limitations
exist. For example, general anesthesia, the definitive
treatment of status epilepticus, is required for intracranial
electrode placement and has a variable impact on seizure
activity (44).
Stereo EEG (SEEG), which involves the placement of
multiple (often bilateral) depth electrodes, is commonly
used in children in whom accurate lateralization or
localization cannot be achieved with noninvasive diagnostic
means. In one report from a single institution, 18 children
underwent depth electrode placement because scalp EEG
results were unclear or indicated discordant localization
of an epileptic focus. An epileptic zone was identified in
15/18 patients, and resection of an area encompassing the
epileptic zone plus 5 mm in all directions was undertaken
without further electrocorticography. All patients who
underwent resection were seizure-free at the one-year time
point (45). Subdural strip electrodes have a similar goal of
lateralization or localization but can be placed through burr
holes only. Regardless of the technique, intracranial surveys
often require subsequent craniotomy and grid placement
for more precise localization once regional seizure onset is
identified.
Craniotomy with insertion of large subdural electrode
arrays requires general localization of the epileptic zone,
either based on concordant noninvasive data or from a
previous intracranial survey operation. Various electrode
combinations are available, including dense grid electrodes
(5 mm between platinum contacts) or double-sided
interhemispheric grid electrodes. In certain cases, interictal
recordings under total intravenous anesthesia in the
operating room are sufficient to make surgical decisions.
Frequently, however, staged craniotomy with long-
term seizure monitoring to capture ictal onset and allow
cortical stimulation mapping of functional eloquent cortex
is required (46,47). Nearly two decades ago, Davies and
colleagues described their experience using MRI to evaluate
subdural and depth electrodes without complication (48).
At our institution, an MRI is completed on postoperative
day 1 to verify grid location and to identify possible
surgical complications including hemorrhage or ischemia
(Figure 1).
The advantages to grid placement include dense electrode
coverage in the absence of a structural lesion identified by
MRI, resolution of discordant noninvasive testing, evaluating
the relationship of a structural lesion to an epileptic zone,
evaluation of patients with dual pathology or multifocal
epilepsy, and extraoperative awake cortical stimulation
mapping to identify primary cortex and map eloquent
function (49). The risks of staged craniotomy and placing
large electrode arrays include intracranial hemorrhage,
compression of cortical vascular structures causing cerebral
edema and ischemia, as well as cerebrospinal fluid leak and
meningitis. Large single-center series report complication
rates between 10% and 20% (50,51).
Surgical decision-making
Epilepsy surgery requires a multidisciplinary team including
a pediatric epileptologist, a pediatric neurosurgeon, and
a neuropsychologist. Pediatric neuroradiologists, critical
care specialists, behavioral health specialists, and a program
coordinator are extremely valuable adjuncts. Dedicated
pediatric epilepsy surgery conferences for detailed review
of all component tests of the presurgical evaluation
together with multidisciplinary clinics facilitate optimizing
surgical decisions and communication with patients and
families. Prior to surgical intervention, neuropsychological
evaluation is mandatory. Neuropsychologists provide
objective, baseline testing to identify individual cognitive

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strengths and deficits, anticipate postoperative deficits, and
provide information regarding postoperative rehabilitation
and education (25).
Because the primary goal of epilepsy surgery in children
is seizure freedom, the previous section concentrated
on methods for localizing an epileptic focus in patients
with partial seizures with the goal of resection of the
epileptogenic zone. Secondary goals of epilepsy surgery
include palliation by decreasing seizure frequency and
improving quality of life, cognitive development, and
functional independence.
Focal lesions
In the context of a discrete lesion on MRI with a
corresponding epileptic focus on EEG, the goal is
typically gross total resection of the lesion. If suspicion
exists that the ictal focus may extend beyond the borders
of the MRI abnormality, further testing with intracranial
EEG is possible. This may also be desirable if the
lesion is near eloquent cortex. Noninvasive functional
mapping such as fMRI is often useful to localize eloquent
function preoperatively and determine whether cortical
Figure 1 Intracranial eletroencephalography in two patients. (A) Intraoperative photograph before closure after right craniotomy and
placement of intracranial electrodes for long-term seizure monitoring in a 15-month-old girl showing a dense central 64-contact grid
electrode with 5 mm between contacts (arrow). This “mini-grid” is frequently used near eloquent cortex to optimize extraoperative cortical
stimulation mapping of motor function in very young children with immature myelination; (B) axial and (C) coronal T1-weighted spoiled
gradient (SPGR) MR images for patient in A on postoperative day 1; (D) intraoperative photograph before closure after right craniotomy
and placement of intracranial electrodes for seizure monitoring in a 17-year-old girl showing 32-contact double-sided interhemispheric
electrode array (arrows); (E) coronal and (F) sagittal T1-weighted SPGR MR images for patient in B on postoperative day 1.
A B C
D E F

69. 174 Ducis et al. Preoperative evaluation and decision-making in epilepsy
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stimulation mapping is required. In younger children,
task-based fMRI may be especially challenging. A wide
range of heterogeneous pathology may represent the ictal
substrate in the setting of a solitary structural lesion such
as focal cortical dysplasia, brain tumors including World
Health Organization grade 1 developmental tumors such
as ganglioglioma or dysembryoplastic neuroepithelial
tumors (DNET), vascular lesions including cavernous
malformations and arteriovenous malformations, and
postinfectious etiologies and perinatal insults (25,52-55).
Hypothalamic hamartomas, which are usually
characterized clinically as gelastic seizures, are other discrete
lesions encountered in children with DRE. EEG may
demonstrate different patterns of focal or generalized seizure
onset, but disconnection or resection of the hamartoma
usually confers seizure freedom regardless of the patterns on
the EEG. Previous microsurgical and endoscopic treatments
for hypothalamic hamartoma have carried high morbidity,
but over the past several years, the combination of laser
ablation and disconnection with real-time MR thermography
has emerged as a minimally invasive treatment option
associated with excellent preliminary results (56).
Lobar lesions
Mesial temporal sclerosis is a frequent cause of DRE in
adults, but less commonly identified in children. When
it occurs in the pediatric population, it is most frequently
in older children and adolescents (57-59). In younger
children, temporal lesions including cortical dysplasia and
developmental tumors like ganglioma and DNET are more
common. When younger children present with mesial
temporal sclerosis, dual pathology should be suspected and
carefully investigated (25). In patients with a larger, more
diffuse epileptogenic zone, including poorly defined cortical
dysplasia as well as DRE with a normal MRI, larger regions
of resection may be considered, including a lobar resection
extending to the borders of primary cortex. This poses
minimal risk beyond simple lesion removal if the anterior
temporal and frontal lobes are involved, especially in the
nondominant hemisphere. Careful functional and seizure
mapping is mandatory when eloquent areas, including
primary vision, language, or motor cortex, are adjacent to
the ictal onset zone or possibly involved (25).
Hemispheric and multifocal lesions
Disease affecting an entire cerebral hemisphere requires
special consideration. Many patients present with
catastrophic epilepsy, developmental delay, and focal
neurologic deficits including hemiparesis and hemianopsia.
Disconnection of the dysfunctional hemisphere will prevent
further seizure propagation and allow for stable and
possibly improved function of the contralateral hemisphere.
Hemispheric dysplasia such as hemimegalencephaly,
encephalomalacia in the context of remote middle cerebral
artery infarction, Sturge-Weber syndrome, and Rasmussen
encephalitis are common causes of DRE that may require
hemispherectomy (60,61). Patients with pre-existing focal
manifestations of hemispheric dysfunction, including
hemiplegia and hemianopia, may not need additional testing
if scalp EEG and MRI are convincing of a dysfunctional
hemisphere, especially if it is the nondominant hemisphere.
Extensive presurgical evaluation should be conducted
in patients with less severe neurologic deficits, and
preoperative functional mapping of language function is
mandatory, especially in older children with DRE localized
to the left hemisphere.
Vagus nerve stimulation (VNS)
VNS is currently FDA-approved in children 12 years and
older to decrease seizure frequency. VNS is considered a
second-line treatment as it is not does not produce seizure
freedom but does result in a reduction of seizures. Its use is
indicated in patients with DRE who are not candidates for
resection or disconnection procedures. In 2011, a single-
center retrospective study from New York University
reviewed 141 consecutive patients who underwent VNS,
61% under the age of 12 years, with a minimum of one-
year follow-up (mean, 5 years) (62). Seizure frequency was
reduced by at least 50% in 64.8% of patients and was reduced
by 75% in 41.4% of patients. The complication rate was
6.4%, and two-third of complications were minor. Despite
the successful reduction in seizure frequency, the number
of seizure medications (average 3) was not reduced (62).
VNS therapy is an excellent palliative therapy in all children,
including those under 12 years, who have persistent seizures
after surgery or who are not candidates for focal resection
with curative intent.
Corpus callosotomy
The corpus callosum, the largest white matter tract
connecting the two cerebral hemispheres, allows rapid
seizure propagation. Children with atonic seizures or

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“drop attacks” often fall, which may lead to severe brain
injury and bodily harm. Atonic seizures are a frequent
component of Lennox-Gastaut syndrome and other epileptic
encephalopathies (63,64). Callosotomy of the anterior two-
thirds or complete corpus callosum is a surgical option for
children with pharmacoresistant drop seizures who have
failed or are not candidates for focal resection and who have
failed a trial of VNS therapy (65,66). Corpus callosotomy
has also been successful in patients with recurrent or
medically refractory status epilepticus (67). Preservation of
the splenium, especially in older children with good language
skills, may prevent a disconnection syndrome, characterized
by temporary or permanent language and memory deficits.
A recent study conducted in Sweden prospectively
analyzed 31 patients with DRE treated with corpus
callosotomy (68). The mean age at surgery was 13.3 years,
and only one patient had no clear neurologic deficit
preoperatively. Twenty-five (81%) patients had two or more
different seizure types, and 18 patients suffered from atonic
seizures. All patients were monitored for at least two years,
and 20 patients had follow-up for more than ten years.
For all seizure types, nearly half (15/31) of the patients
had at least a 50% reduction in seizure frequency at two
years, with three patients experiencing worsening seizures.
This benefit was durable, with a mean overall reduction in
seizure frequency of 68% ten years after surgery. One third
of the 18 patients with atonic or drop seizures experienced
complete remission at two years, while two thirds of the
remaining 12 patients had at least a 50% reduction. Ten
years after surgery, 10/18 (56%) patients with atonic
seizures had complete resolution, 6/18 (33%) had at least
50% improvement in atonic seizure frequency, and two
patients were lost to follow-up (68).
Special considerations: infants
Rates of epilepsy are highest in the infant age group (69-77),
with an estimated incidence of 70.1 per 100,000 (77).
Furthermore, in one third of children presenting at less than
36 months of age, the epilepsy will become drug resistant (78).
As surgical and anesthetic techniques continue to improve,
surgery for DRE in infants has become safer. Thus, given the
natural history of DRE with seizure onset in infancy (7), early
surgical intervention is preferred, including relatively large
resections or disconnections when indicated. In addition to
seizure remission, it may be possible to avoid the financial
burden and potentially harmful side effects of antiepileptic
medications during early brain development (79-84). Early
surgery also takes advantage of increased neuroplasticity in
infants, which rapidly decreases with age.
A recent prospective cohort study of 47 children with
a history of DRE who had epilepsy surgery before the
age of four analyzed clinical outcomes at 2 and 10 years
after surgery; 68% of patients had preoperative
neurodevelopmental impairment. The mean age of seizure
onset was 15 months, and the mean frequency was 150 seizures
per month. The mean age at surgery was 25 months. The
most common operations included frontal lobectomy,
temporal lobectomy, and hemispherectomy (12 each); eight
of the 47 patients ultimately required additional epilepsy
surgery. The most common pathological substrates were
malformations of cortical development. The complication
rate was low: one child had an epidural abscess, one
patient had pneumonia, and two children who underwent
hemispherectomy required cerebrospinal fluid diversion with
a shunt. Seventy percent of children (33/47) experienced a
decrease of at least 75% in seizure frequency, and 21 (45%)
achieved complete remission. Four children had worsening
seizures. The best outcomes were seen in patients who
underwent temporal lobectomy or hemispherectomy. In
long-term follow-up, two children achieved late remission
and four had late seizure recurrence (85).
Conclusions
DRE is a significant public health issue, with extremely
high direct and indirect costs. Early age of seizure onset
and DRE are major risk factors for poor cognitive
development (7). Children with DRE face barriers to
social integration and living independently, including
driving and employment. Dedicated multidisciplinary
teams of pediatric subspecialists are necessary to evaluate
and treat these patients early in the course of their disease
to optimize outcome. Seizure localization is important
because it offers the best opportunity for complete
lesion removal and seizure freedom. In patients in whom
noninvasive methods of seizure localization fail to indicate
a seizure focus, invasive methods can provide more detailed
information. Once an epileptic focus is identified, resection
or disconnection of the lesion from normal brain structures
may help achieve the ultimate goal of complete seizure
remission.
Acknowledgements
We thank Kristin Kraus, MSc, for her critical editorial

71. 176 Ducis et al. Preoperative evaluation and decision-making in epilepsy
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assistance with this paper.
Footnote
Conflicts of Interest: The authors have no conflicts of interest
to declare.
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Epilepsia 2009;50:125-37.
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© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):169-179tp.amegroups.com
Cite this article as: Ducis K, Guan J, Karsy M, Bollo RJ.
Preoperative evaluation and surgical decision-making in
pediatric epilepsy surgery. Transl Pediatr 2016;5(3):169-179.
doi: 10.21037/tp.2016.06.02
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75. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):180-182tp.amegroups.com
“Men regard its nature and cause as divine from ignorance and
wonder, because it is not at all like to other diseases. And this
notion of its divinity is kept up by their inability to comprehend
it.”—Hippocrates, On the Sacred Disease, 400 BC
Nearly two and a half millennia ago, Hippocrates described
epilepsy as “the sacred disease.” His hypothesis that seizures
arose from an organic, physical substrate that was not
understood, rather than from the divine or supernatural,
was ahead of his time. Yet, despite centuries of research
and innovation, superstitions about epilepsy remain deeply
embedded in local cultural traditions and belief systems
throughout much of the world (1). More than 50 million
people worldwide have epilepsy, making it the most
prevalent serious chronic neurological disorder. Seizures
disproportionately affect children: the incidence is higher in
infancy compared with any other age group (1,2).
Our understanding of the pathogenesis of epilepsy
and its impact on the developing brain as well as our
armamentarium of anti-epileptic medications to treat
seizures continue to evolve. Despite profound advancements,
one fifth to one third of patients have disease that remains
drug resistant. Seizures that persist despite trials of
two properly selected medications are deemed by the
International League Against Epilepsy criteria as drug-
resistant epilepsy (DRE). Once these criteria are met, it
is critical that children are referred for surgical evaluation
because, at that point, the likelihood of medical control
is extremely low (3). Further, early age of seizure onset
and pharmacoresistance are risk factors for poor cognitive
development (4), and seizure freedom after surgery is
likely to rescue that downward trajectory. Unfortunately,
at this time, most children with DRE still endure years of
seizures before surgical evaluation, and epilepsy surgery
remains among the most under-utilized therapies in modern
medicine (5).
Recent advancements in the diagnosis and treatment
of epilepsy are creating a paradigm shift in the surgical
management of children with DRE and opening the
door to a future of minimally invasive surgical therapy.
High-resolution structural magnetic resonance imaging
(MRI) and voxel-based morphometry algorithms allow
quantitative analysis of brain structure to better identify
malformations of cortical development (6). Resting-state
functional MRI allows the identification of functional brain
circuits and the analysis of connectivity without performing
tasks. Through these techniques and many more, modern
neuroimaging is rapidly evolving to identify previously
undetectable lesions and map functionally eloquent
neuronal circuits (6,7). The use of minimally invasive
intracranial electroencephalography (EEG) recordings
using stereotactic depth electrode placement, or stereo
EEG (SEEG), facilitated by newly developed robotic
technology to allow the efficient, accurate placement of
multiple bilateral electrodes, is replacing large craniotomies
for intracranial EEG recordings. Simultaneously, new
computational algorithms are being developed to model
three-dimensional epileptic networks based on interictal
EEG data, potentially limiting the duration of electrode
recordings required to map the epileptogenic zone (8,9).
Large subdural electrode arrays are still often required
for cortical stimulation mapping of eloquent brain tissue,
Pediatric Epilepsy Column (Editorial)
Surgical advancements in pediatric epilepsy surgery: from the
mysterious to the minimally invasive
Robert J. Bollo
Division of Pediatric Neurosurgery, Department of Neurosurgery, Primary Children’s Hospital, University of Utah School of Medicine, Salt Lake
City, UT, USA
Correspondence to: Robert J. Bollo, MD. Division of Pediatric Neurosurgery, Department of Neurosurgery, Primary Children’s Hospital, University of
Utah School of Medicine, Salt Lake City, UT, USA. Email: neuropub@hsc.utah.edu.
Submitted May 21, 2016. Accepted for publication May 25, 2016.
doi: 10.21037/tp.2016.05.02
View this article at: http://dx.doi.org/10.21037/tp.2016.05.02

76. 181Translational Pediatrics, Vol 5, No 3 July 2016
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):180-182tp.amegroups.com
especially in children who may not be able to tolerate task-
based functional MRI. This is often the case in patients with
epileptic lesions that border motor and language cortex, as
well as for anatomic resections extending to primary cortex
in non-lesional epilepsy. However, recent advancements
in transcranial magnetic stimulation (TMS) are now
facilitating mapping outside the operating room on an
outpatient basis. TMS allows cortical stimulation mapping
through the scalp, and functional maps may be imported
into neuronavigation equipment in the operating room.
These advances have the potential to significantly decrease
the number of patients in whom multi-stage craniotomies
are required for functional mapping of eloquent cortex (10,11).
Finally, the advent of MRI-guided laser interstitial
thermal therapy (LITT) is quickly revolutionizing the
surgical management of DRE in children. The stereotactic
placement of cooled lasers of different sizes, followed by
ablation of the epileptogenic zone monitored in real-time
using MR thermography, has demonstrated promising
efficacy in the management of deep epileptic foci in children
such as hypothalamic hamartomas (12). LITT is now being
used to treat a variety of epileptic lesions in children (13).
Previously, minimally invasive diagnostics like SEEG were
uncoupled with minimally invasive treatment approaches
such as LITT. Many patients requiring SEEG have MRI-
negative disease, and multi-stage craniotomies with cortical
stimulation mapping and large anatomic resections were
required to achieve seizure freedom.
It is easy to see how LITT and SEEG may be used
together in children with multifocal epilepsy, such as
tuberous sclerosis complex. Leveraging multiple new
technologies—including quantitative neuroimaging,
robotic-assisted SEEG, outpatient functional mapping of
eloquent cortex via TMS, and minimally invasive ablation
with LITT—has the potential to usher in a new era of
minimally invasive surgical treatment, with the result of
shorter hospital stays and decreased morbidity. Through
this series of articles on the evaluation, treatment paradigms,
and emerging tools in the surgical management of pediatric
epilepsy, we hope readers of Translational Pediatrics (TP)
come to share not simply our passion about the power of
surgery to cure epilepsy, but also our excitement about the
future of the field. It is our hope that continued surgical
innovation will change surgical treatment strategies for
more and more children from large operations and brain
resections to minimally invasive therapy. Undoubtedly,
such innovation will help change the stigma associated with
epilepsy surgery, allowing more children to realize a life
without seizures, reach their full cognitive potential, and
achieve functional independence.
Acknowledgements
The author thanks Kristin Kraus, MSc, for editorial
assistance with this paper.
Footnote
Conflicts of Interest: The author has no conflicts of interest to
declare.
References
1. Perucca E, Covanis A, Dua T. Commentary: Epilepsy is a
global problem. Epilepsia 2014;55:1326-8.
2. Wilmshurst JM, Gaillard WD, Vinayan KP, et al.
Summary of recommendations for the management
of infantile seizures: Task Force Report for the ILAE
Commission of Pediatrics. Epilepsia 2015;56:1185-97.
3. Kwan P, Arzimanoglou A, Berg AT, et al. Definition of
drug resistant epilepsy: consensus proposal by the ad hoc
Task Force of the ILAE Commission on Therapeutic
Strategies. Epilepsia 2010;51:1069-77.
4. Berg AT, Zelko FA, Levy SR, et al. Age at onset of epilepsy,
pharmacoresistance, and cognitive outcomes: a prospective
cohort study. Neurology 2012;79:1384-91.
5. Engel J Jr. Why is there still doubt to cut it out? Epilepsy
Curr 2013;13:198-204.
6. Kini LG, Gee JC, Litt B. Computational analysis in
epilepsy neuroimaging: A survey of features and methods.
Neuroimage Clin 2016;11:515-29.
7. Vadivelu S, Wolf VL, Bollo RJ, et al. Resting-state
functional MRI in pediatric epilepsy surgery. Pediatr
Neurosurg 2013;49:261-73.
8. Boido D, Kapetis D, Gnatkovsky V, et al. Stimulus-evoked
potentials contribute to map the epileptogenic zone during
stereo-EEG presurgical monitoring. Hum Brain Mapp
2014;35:4267-81.
9. Rummel C, Abela E, Andrzejak RG, et al. Resected brain
tissue, seizure onset zone and quantitative EEG measures:
towards prediction of post-surgical seizure control. PLoS
One 2015;10:e0141023.
10. Narayana S, Rezaie R, McAfee SS, et al. Assessing motor

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function in young children with transcranial magnetic
stimulation. Pediatr Neurol 2015;52:94-103.
11. Babajani-Feremi A, Narayana S, Rezaie R, et al. Language
mapping using high gamma electrocorticography,
fMRI, and TMS versus electrocortical stimulation. Clin
Neurophysiol 2016;127:1822-36.
12. Lewis EC, Weil AG, Duchowny M, et al. MR-guided laser
interstitial thermal therapy for pediatric drug-resistant
lesional epilepsy. Epilepsia 2015;56:1590-8.
13. Wilfong AA, Curry DJ. Hypothalamic hamartomas:
optimal approach to clinical evaluation and diagnosis.
Epilepsia 2013;54 Suppl 9:109-14.
Cite this article as: Bollo RJ. Surgical advancements in
pediatric epilepsy surgery: from the mysterious to the minimally
invasive. Transl Pediatr 2016;5(3):180-182. doi: 10.21037/
tp.2016.05.02

78. © Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):183-184tp.amegroups.com
To the Editor:
We would like to thank Drs. Rogol and Skakkebaek for
their timely and insightful commentary about medical and
ethical issues with regard to sperm retrieval in adolescents
with Klinefelter syndrome (KS) (1); the authors present
key points discussed at the recent International Workshop
on Klinefelter syndrome, in addition to summarizing our
pilot clinical trial investigating sperm retrieval rates in
adolescents and young adults with KS published in The
Journal of Pediatrics (2,3). As was acknowledged in the
original manuscript, Drs. Rogol and Skakkebaek emphasize
potential selection bias in the study, as the sample size
was small and many of the eligible subjects declined to
participate due to “lack of psychological readiness to
focus on fertility”; additionally, none of the patients had
been treated with testosterone, indicating a “milder”
end of the spectrum (1,2). The potential impact of prior
testosterone therapy and other agents on sperm retrieval
in this population was identified as a necessary issue for
investigation (1,4).
Prospective studies in this area have been limited due
to the rarity of making the KS diagnosis early in life, in
addition to challenges associated with recruiting adolescents
and young adults with KS for fertility related research.
According to a 2011 study by Maiburg et al., adults with
KS were interested in fathering children and were willing
to undergo testicular sperm extraction (TESE) (5). Recent
research, however, demonstrates a discrepancy between
attitudes of parents and physicians versus those of younger
individuals with KS; while most parents of children with
KS and pediatricians favored pursuing TESE in a pubertal
minor, adolescents with KS reported a lack of interest in
fertility and required at least three medical consultations
prior to becoming involved in fertility preservation (6,7).
Thus, in order to successfully complete prospective studies
to investigate predictors of successful TESE and the impact
of exogenous testosterone or other treatments on sperm
retrieval, reproductive priorities and potential barriers to
acceptance of fertility preservation procedures need to be
better understood in this particular population.
Most of the pediatric literature with regard to fertility
has been done in oncology, where many males are able
to produce an ejaculate for sperm cryopreservation. It is
notable that this is generally not an option for individuals
with KS, which is in itself, a potential barrier. Additionally,
neurocognitive dysfunction is common in KS, and studies
have shown lower quality of life and self-esteem, all of
which could impact attitudes about reproductive health
and willingness to participate in research studies (8). Thus,
validated surveys and qualitative methodology should
be implemented to further explore key factors such as
reproductive concerns, romantic relationships, sexual
function, and psychosocial well-being among adolescents
and young adults with KS at different ages/developmental
stages.
Based on current literature, the recommended age
range to consider sperm retrieval among individuals
with KS is 15–30 years (3,9,10). Medical professionals
who care for individuals with KS have a responsibility
to become educated on this topic and offer referrals to
fertility specialists to (I) provide comprehensive counseling
about the current options along with acknowledging
their experimental nature; and (II) consider potential
ethical implications in each individual case (6,11). As Drs.
Rogol and Skakkebaek point out, many questions remain
unanswered, including the viability and quality of sperm
Correspondence
Klinefelter syndrome: fertility considerations and gaps in knowledge
Leena Nahata1
, Richard N. Yu2
, Laurie E. Cohen3
1
Division of Endocrinology, Nationwide Children’s Hospital, 700 Children’s Dr, Columbus, USA; 2
Department of Urology, 3
Division of
Endocrinology, Boston Children’s Hospital, Boston, MA, USA
Correspondence to: Leena Nahata, MD. Division of Endocrinology, Nationwide Children’s Hospital, 700 Children’s Dr, Columbus, USA.
Email: leena.nahata@nationwidechildrens.org.
Submitted Jun 08, 2016. Accepted for publication Jun 17, 2016.
doi: 10.21037/tp.2016.06.06
View this article at: http://dx.doi.org/10.21037/tp.2016.06.06

79. 184 Nahata et al. Knowledge of Klinefelter syndrome
© Translational Pediatrics. All rights reserved. Transl Pediatr 2016;5(3):183-184tp.amegroups.com
retrieved from this patient population after many years of
freezing (1). Opportunities for early diagnosis of KS will
likely increase due to increasing use of prenatal testing,
and more patients and families may inquire about the
potential risks/benefits of cryopreservation of sperm. Thus,
longitudinal follow-up to assess utilization of the frozen
sperm, pregnancy rates, and outcomes, will be critical for
informing future research and clinical care.
Acknowledgements
None.
Footnote
Conflict of Interest: The original research (published in
Journal of Pediatrics) was partially supported by the 2012
Boston Children’s Hospital House Officer Development
Award.
Response to: Rogol AD, Skakkebaek NE. Sperm retrieval in
adolescent males with Klinefelter syndrome: medical and
ethical issues. Transl Pediatr 2016;5:104-6.
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Cite this article as: Nahata L, Yu RN, Cohen LE. Klinefelter
syndrome: fertility considerations and gaps in knowledge.
Transl Pediatr 2016;5(3):183-184. doi: 10.21037/tp.2016.06.06