High-Frequency Oscillation: New Directions

High-Frequency Oscillation:
New Directions for 2009
Niall D. Ferguson, MD, FRCPC, MSc
Assistant Professor
Interdepartmental Division of Critical Care Medicine
University of Toronto

Outline
• Background on HFO
• Ventilator-induced Lung Injury (VILI)
• Implementing HFO to prevent VILI
 Who
 When
 How
 Oxygenation & Recruitment
 Ventilation
 Transition back to CV

Pressure-Time Curve
CMV
HFOV
P
r
e
s
s
u
r
e
Time

Patient
HFOV Gas-flow Circuit
Humidified Bias Flow
Active Expiration R
Humidifier

HFOV - Setup
Settings
• PAW
• P (Power)
• Frequency
• Bias Flow, I:E

In Adults – HFOV is safe & improves
oxygenation - appropriate as
rescue therapy

High-frequency oscillatory ventilation for adult
respiratory distress syndrome: Let's get it right this
time! AB Froese Crit Care Med 1997; 25:906-908

ARDS Network
• High Stretch
 VT: 11.8
 PPLAT: 32-34
 RR: 18
 VMIN: 13
 PEEP: 8
• Mortality 40%
• Low Stretch
 VT: 6.2 ml/kg
 PPLAT: 25 cm H2O
 RR: 29
 VMIN: 13 L/min
 PEEP: 9 cm H2O
• Mortality 31%*
*p=0.005
N Engl J Med 2000 342:1301-8

Can We Reduce VILI
any Further?

Preventing VILI - Principles
• Limit overdistention
• Maintain EELV
• Minimize oxygen toxicity
• HFOV benefits:
 margin of error for overdistention /
derecruitment
- Decoupling of ventilation & oxygenation
- Improved oxygenation  FIO2
Employ early

Alveolar (In)stability
JM Steinberg et al. AJRCCM 2004; 169:57-63 DiRocco, Nieman AARC 2005

14/0 45/0
Experimental pulmonary edema due to intermittent positive pressure ventilation
with high inflation pressures. Protection by positive
end-expiratory pressure. HH Webb & DF Tierney ARRD 1974; 110:556-65

14/0 45/10 45/0
Experimental pulmonary edema due to intermittent positive pressure ventilation
with high inflation pressures. Protection by positive
end-expiratory pressure. HH Webb & DF Tierney ARRD 1974; 110:556-65

HFO vs. Injurious CV in Animals

HFO vs. ‘protective’ CV in animals

Outcomes
30 Day Mortality
HFOV: 37%
CMV: 52%
Absolute Risk Reduction: 15%
Relative Risk Reduction: 29%
p=0.102
p=0.057 30 d
p=0.078 90 d
HFOV in adults with ARDS is safe and may
improve outcome – more study is needed

Background
 HFO is theoretically ideal for lung protection
 early RCTs suggest HFO is safe and may reduce deaths
Design
 multicentre RCT
Population
 72 patients with ARDS, at 12 participating sites
Interventions
 HFO
 conventional ventilation - a low tidal volume, open lung approach
Primary outcome
 hospital mortality
Pilot study goals
 assess recruitment, and barriers to recruitment
 assess adherence to explicit ventilation protocols
 measure and understand reasons for crossovers

Outline
• Ventilator-induced Lung Injury (VILI)
• Background on HFO
• Implementing HFO
 Who
 When
 How
 Oxygenation & Recruitment
 Ventilation
 Transition back to CV

HFOV compared with CMV for Respiratory
Failure in Preterm Infants HIFI Group N Engl J Med 1989;320
673 preterms with respiratory failure within 12 hrs of CMV
346 CMV, 327 HFOV
HFOV - MAP as with CMV, FiO2 was increased first
Results:
Similar Bronchopulmonary Dysplasia & Mortality
Increased pneumoperitoneum, intracranial bleeds,
periventricular leukomalacia

Reflections on HIFI
Bryan & Froese Pediatrics 1991;87
1. Goals were not to increase lung volume.
2. PAW weaned before FiO2.
3. Cross centre differences in adverse events.

Volume-Pressure Curve
CMV
HFO
V
o
l
u
m
e
Pressure
Lower
Inflection
Point
Upper
Infection
Point

RMs with Conventional Ventilation
• Multiple studies – inconsistent results
 Timing
 Type of manoeuvre
 Cause of lung injury
 How PEEP was set afterwards
• With HFO
 Theoretically RMs may be of more use (because
of lack of tidal recruitment)
 and may be more effective (because of ability to
set a very high PEEP)

PaO2
Time (min.)
HFO - Recruitment Manoeuvres
• Oleic Acid Lavaged
Rabbits
• Conventional
Ventilation followed
by HFOV
 With and without
Sustained Inflation
(30 cm H2O for 10 s)
Relationship Between
PaO2 and Lung Volume
During HFOV
Suzuki et al. Acta Pedr Jpn 1992

0
100
200
300
400
Standardized CMV HFOV + 1-3 RMs
(1.5 Hours)
PaO2/FIO2
Individual & Mean PaO2/FIO2 Values

Conclusions
• HFO theoretically ideal for preventing VILI –
if used with a strategy to maintain EELV
• On balance the potential for benefit with RMs
in HFO seems to outweigh downsides
• Lung recruitment is a good thing - If it can be
achieved
 Ineffective attempts at lung recruitment:
no benefit vs. harmful

HFOV - background
• Respiratory frequencies 180-900 / min
• Tidal volumes (VT) < dead space (VD)
• Ventilation (CO2) dependent on:
 VT  P frequency
• Oxygenation dependent on:
 PAW / lung volume
 FIO2
Decoupling
of O2 / CO2

Slutsky & Drazen NEJM 2002, 347:630-1

Crit Care Med 2003; 31:227-231
< 1.2 - 2 ml/kg ?

Crit Care Med 2006; 34:751-757
Hot-wire Anemometer

Conclusions
• In addition to targeting lung
recruitment we need to deliver the
lowest VT possible
 Higher frequencies (facilitated by higher
power / delta P)
 Controlled cuff leak?
 Accept a ‘reasonable’ pH

Implementing HFO 2009
• Who should we consider as candidates for
HFO?
 Sick ARDS patients in need of recruitment
• When should we use HFO?
 Rescue therapy for now
 Maybe earlier rather than later
• How we use HFO?
 Oxygenation = Target lung recruitment
 Ventilation = Keep tidal volume minimal

n.ferguson@utoronto.ca
October 25 – 29, 2009
Metro Toronto Convention Centre

High-Frequency Oscillation: New Directions

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