Twin study confirms virtually identical prenatal alcohol exposures can lead to markedly different fetal alcohol spectrum disorder outcomes fetal genetics influences fetal vulnerability
Abstract
Background: Risk of fetal alcohol spectrum disorder (FASD) is not based solely on the timing and level of prenatal alcohol exposure (PAE). The effects of teratogens can be modified by genetic differences in fetal susceptibility and resistance. This is best illustrated in twins.
Objective: To compare the prevalence and magnitude of pairwise discordance in FASD diagnoses across
monozygotic twins, dizygotic twins, full-siblings, and half-siblings sharing a common birth mother.
Methods: Data from the Fetal Alcohol Syndrome Diagnostic & Prevention Network clinical database was used. Sibling pairs were matched on age and PAE, raised together, and diagnosed by the same University of Washington interdisciplinary team using the FASD 4-Digit Code. This design sought to assess and
isolate the role of genetics on fetal vulnerability/resistance to the teratogenic effects of PAE by eliminating
or minimizing pairwise discordance in PAE and other prenatal/postnatal risk factors.
Results: As genetic relatedness between siblings decreased from 100% to 50% to 50% to 25% across the four groups (9 monozygotic, 39 dizygotic, 27 full-sibling and 9 half-sibling pairs, respectively), the prevalence of pairwise discordance in FASD diagnoses increased from 0% to 44% to 59% to 78%. Despite virtually identical PAE, 4 pairs of dizygotic twins had FASD diagnoses at opposite ends of the fetal alcohol spectrum—Partial Fetal Alcohol Syndrome versus Neurobehavioral Disorder/Alcohol-Exposed.
Conclusion: Despite virtually identical PAE, fetuses can experience vastly different FASD outcomes.
Thus, to protect all fetuses, especially the most genetically vulnerable, the only safe amount to drink is none at all.
Lancet.docx comorbidity of fetal alcohol spectrum disorder a systematic revi...BARRY STANLEY 2 fasd
Lancet. January, 2016
Comorbidity of fetal alcohol spectrum disorder: a systematic
review and meta-analysis
Dr Svetlana Popova, PhD Shannon Lange, MPH Kevin Shield, PhD Alanna Mihic, MSc Prof Albert E Chudley, MD
Raja A S Mukherjee, PhD Dennis Bekmuradov, BASc Prof Jürgen Rehm, PhD
Neurobehavioral disorder associated with prenatal alcohol exposureBARRY STANLEY 2 fasd
Children and adolescents affected by prenatal exposure to alcohol who have brain damage that is manifested in functional impairments of neurocognition, self-regulation, and adaptive functioning may most appropriately be diagnosed with neurobehavioral disorder associated with prenatal exposure. This Special Article outlines clinical implications and guidelines for pediatric medical home clinicians to identify, diagnose, and refer children regarding neurobehavioral disorder associated with prenatal exposure. Emphasis is given to reported or observable behaviors that can be identified as part of care in
pediatric medical homes, differential diagnosis, and potential comorbidities. In addition, brief guidance is provided on the management of affected children in the pediatric medical home. Finally, suggestions are given for obtaining prenatal history of in utero exposure to alcohol for the pediatric patient.
Psychiatric concerns about the consequences of prenatal alcohol exposureBARRY STANLEY 2 fasd
Psychiatric concerns about the consequences of prenatal alcohol exposure
I have omitted the references in these papers. They can be downloaded.
In 2014 the US National Institute of Mental Health (NIMH) announced it was going to divert research funding from abstract psychiatry to the neurobiological roots of disease.
This has resulted in identification of the abnormal brain functions relating to the behavioral diagnoses of the DSM5. These brain disfunctions are not the cause of DSM5 mental illnesses: they are the true pathology of those mental illnesses. The question is- what is the cause of those brain disfunctions?
Psychiatry has never explored the role of prenatal alcohol, or preconceptual alcohol in the etiology of mental illnesses.
This is in spite of anecdotal, behavioral, epidemiological, neurological and epigenetic correlations.
Meanwhile mental illness, addictions and suicides continue unabated, in spite of huge expenditures.
The day will come when the genes that control individual aspects of brain function will be identified. Changes in gene expression will be related to clinical presentations, such as those in the DSM5: the generation at which those changes occurred will be determined.
The agent that caused those changes, with other environmental factors, will be identified.
Then we will understand to what degree alcohol has determined the nature of mental illness.
The Potential Impact of Preimplantation Genetic Diagnosis on Discrimination o...blaine_5
The argument that selection against specific genetic traits will lead to increased discrimination is both compelling and troubling. Indeed, it is reasonable to conclude that if a large number of people use PGD to select against traits they consider to be disabilities then the probability of increased discrimination and marginalization would be greatly increased. However, as this Note argues, most participants in the PGD disability debate overlook important limitations of both trait selection and large-scale PGD adoption that will likely mitigate the negative potentially negative impact of PGD technology.
Lancet.docx comorbidity of fetal alcohol spectrum disorder a systematic revi...BARRY STANLEY 2 fasd
Lancet. January, 2016
Comorbidity of fetal alcohol spectrum disorder: a systematic
review and meta-analysis
Dr Svetlana Popova, PhD Shannon Lange, MPH Kevin Shield, PhD Alanna Mihic, MSc Prof Albert E Chudley, MD
Raja A S Mukherjee, PhD Dennis Bekmuradov, BASc Prof Jürgen Rehm, PhD
Neurobehavioral disorder associated with prenatal alcohol exposureBARRY STANLEY 2 fasd
Children and adolescents affected by prenatal exposure to alcohol who have brain damage that is manifested in functional impairments of neurocognition, self-regulation, and adaptive functioning may most appropriately be diagnosed with neurobehavioral disorder associated with prenatal exposure. This Special Article outlines clinical implications and guidelines for pediatric medical home clinicians to identify, diagnose, and refer children regarding neurobehavioral disorder associated with prenatal exposure. Emphasis is given to reported or observable behaviors that can be identified as part of care in
pediatric medical homes, differential diagnosis, and potential comorbidities. In addition, brief guidance is provided on the management of affected children in the pediatric medical home. Finally, suggestions are given for obtaining prenatal history of in utero exposure to alcohol for the pediatric patient.
Psychiatric concerns about the consequences of prenatal alcohol exposureBARRY STANLEY 2 fasd
Psychiatric concerns about the consequences of prenatal alcohol exposure
I have omitted the references in these papers. They can be downloaded.
In 2014 the US National Institute of Mental Health (NIMH) announced it was going to divert research funding from abstract psychiatry to the neurobiological roots of disease.
This has resulted in identification of the abnormal brain functions relating to the behavioral diagnoses of the DSM5. These brain disfunctions are not the cause of DSM5 mental illnesses: they are the true pathology of those mental illnesses. The question is- what is the cause of those brain disfunctions?
Psychiatry has never explored the role of prenatal alcohol, or preconceptual alcohol in the etiology of mental illnesses.
This is in spite of anecdotal, behavioral, epidemiological, neurological and epigenetic correlations.
Meanwhile mental illness, addictions and suicides continue unabated, in spite of huge expenditures.
The day will come when the genes that control individual aspects of brain function will be identified. Changes in gene expression will be related to clinical presentations, such as those in the DSM5: the generation at which those changes occurred will be determined.
The agent that caused those changes, with other environmental factors, will be identified.
Then we will understand to what degree alcohol has determined the nature of mental illness.
The Potential Impact of Preimplantation Genetic Diagnosis on Discrimination o...blaine_5
The argument that selection against specific genetic traits will lead to increased discrimination is both compelling and troubling. Indeed, it is reasonable to conclude that if a large number of people use PGD to select against traits they consider to be disabilities then the probability of increased discrimination and marginalization would be greatly increased. However, as this Note argues, most participants in the PGD disability debate overlook important limitations of both trait selection and large-scale PGD adoption that will likely mitigate the negative potentially negative impact of PGD technology.
Screening prevalence of fetal alcohol spectrum disorders in a region of the u...BARRY STANLEY 2 fasd
Fetal alcohol spectrum disorders (FASDs) are lifelong disabilities caused by prenatal alcohol exposure. Prenatal alcohol use is common in the UK, but FASD prevalence was unknown. Prevalence estimates are essential for informing FASD prevention, identification and support.
We applied novel screening algorithms to existing data to estimate the screening prevalence of FASD. Data were from a population-based cohort study (ALSPAC), which recruited pregnant women with expected delivery dates between 1991 and 1992 from the Bristol area of the UK. We evaluated different missing data strategies by comparing results from complete case, single imputation (which assumed that missing data indicated no exposure and no impairment), and multiple imputation methods.
6.0% of children screened positive for FASD in the analysis that used the single imputation method (total N=13,495), 7.2% in complete case analysis (total N=223) and 17.0% in the analysis with multiply imputed data (total N=13,495). A positive FASD screen was more common among children of lower socioeconomic status and children from unplanned pregnancies. Our analyses showed that the complete case and single imputation methods that are commonly used in FASD prevalence studies are likely to underestimate FASD prevalence.
Although not equivalent to a formal diagnosis, these screening prevalence estimates suggest that FASD is likely to be a significant public health concern in the UK. Given current patterns of alcohol consumption and recent changes in prenatal guidance, active case ascertainment studies are urgently needed to further clarify the current epidemiology of FASD in the general population of the UK.
https://userupload.net/06gt5zcwvh90
Genetic counseling is the process of advising individuals and families affected by or at risk of genetic disorders to help them understand and adapt to the medical, psychological and familial implications of genetic contributions to disease.[1] The process integrates:
Interpretation of family and medical histories to assess the chance of disease occurrence or recurrence
Education about inheritance, testing, management, prevention, resources
Counseling to promote informed choices and adaptation to the risk or condition.
OBSTETRICS & GYNAECOLOGICAL NURSING
GENETIC COUNSELLING DURING PREGNANC
INTRODUCTION-
COUNSELLING-Counselling is consultation, mutual interchange of opinions, deliberating together.A process in which the counsellor assist the counselee .
Provides concrete, accurate information about inherited disorders.
Provides information about prognosis and follow up.
Discuss ways in which disease can be prevented.
Article fetal alcohol spectrum disorder and firesetting behaviors a guide for...BARRY STANLEY 2 fasd
"Fetal Alcohol Spectrum Disorder and Fire setting Behaviors:
A Guide for Criminal Justice, Fire, and Forensic Professionals"
setting fires can be a problem for those with FASD.
IMO it is a means of escaping the chaos of "boredom" by those who have a sensory disability that relates to fire.
Abstract: Fetal alcohol spectrum disorder (FASD) is a significant public health issue in Australia that is poorly diagnosed, chronic and costly.
FASD is a diffuse acquired brain injury secondary to prenatal alcohol exposure. The prevalence rate of FASD among the general population in Australia is currently unknown; however, an Australian study in a selected high-risk population reported some of the highest rates of FASD in the world. A common misconception among clinicians is that a child must have ‘the face’ of FASD to have the disorder. This is incorrect. The three
sentinel facial features only occur in the minority of individuals with FASD. FASD should be considered as a ‘whole body’ disorder as increased susceptibility to chronic health problems suggests suboptimal in utero environments places the individual at risk of later disease. Clinicians are reluctant to consider FASD as a possible diagnosis because of the concern of inducing stigma; however, this concern is neither supported by the
evidence nor patient stories. The Australian Guide to the Diagnosis of FASD is now available to assist health professionals in providing timely and accurate diagnoses, which can lead to improved outcomes via evidence-based intervention and is an important first step in future prevention.
Of the 415 children in the study (195 girls and 220 boys; mean [SD] age, 363.0 [8.3] days), a consistent association between craniofacial shape and prenatal alcohol exposure was observed at almost any level regardless of whether exposure occurred only in the first trimester or throughout pregnancy. Regions of difference were concentrated around the midface, nose, lips, and eyes. Directional visualization showed that these differences corresponded to general recession of the midface and superior displacement of the nose, especially the tip of the nose, indicating shortening of the nose and upturning of the nose tip.
Differences were most pronounced between groups with no exposure and groups with low exposure in the first trimester (forehead), moderate to high exposure in the first trimester (eyes, midface, chin, and parietal region), and binge-level exposure in the first trimester (chin).
CONCLUSIONS AND RELEVANCE Prenatal alcohol exposure, even at low levels, can influence craniofacial development. Although the clinical significance of these findings is yet to be determined, they support the conclusion that for women who are or may become pregnant, avoiding alcohol is the safest option.
Screening prevalence of fetal alcohol spectrum disorders in a region of the u...BARRY STANLEY 2 fasd
Fetal alcohol spectrum disorders (FASDs) are lifelong disabilities caused by prenatal alcohol exposure. Prenatal alcohol use is common in the UK, but FASD prevalence was unknown. Prevalence estimates are essential for informing FASD prevention, identification and support.
We applied novel screening algorithms to existing data to estimate the screening prevalence of FASD. Data were from a population-based cohort study (ALSPAC), which recruited pregnant women with expected delivery dates between 1991 and 1992 from the Bristol area of the UK. We evaluated different missing data strategies by comparing results from complete case, single imputation (which assumed that missing data indicated no exposure and no impairment), and multiple imputation methods.
6.0% of children screened positive for FASD in the analysis that used the single imputation method (total N=13,495), 7.2% in complete case analysis (total N=223) and 17.0% in the analysis with multiply imputed data (total N=13,495). A positive FASD screen was more common among children of lower socioeconomic status and children from unplanned pregnancies. Our analyses showed that the complete case and single imputation methods that are commonly used in FASD prevalence studies are likely to underestimate FASD prevalence.
Although not equivalent to a formal diagnosis, these screening prevalence estimates suggest that FASD is likely to be a significant public health concern in the UK. Given current patterns of alcohol consumption and recent changes in prenatal guidance, active case ascertainment studies are urgently needed to further clarify the current epidemiology of FASD in the general population of the UK.
https://userupload.net/06gt5zcwvh90
Genetic counseling is the process of advising individuals and families affected by or at risk of genetic disorders to help them understand and adapt to the medical, psychological and familial implications of genetic contributions to disease.[1] The process integrates:
Interpretation of family and medical histories to assess the chance of disease occurrence or recurrence
Education about inheritance, testing, management, prevention, resources
Counseling to promote informed choices and adaptation to the risk or condition.
OBSTETRICS & GYNAECOLOGICAL NURSING
GENETIC COUNSELLING DURING PREGNANC
INTRODUCTION-
COUNSELLING-Counselling is consultation, mutual interchange of opinions, deliberating together.A process in which the counsellor assist the counselee .
Provides concrete, accurate information about inherited disorders.
Provides information about prognosis and follow up.
Discuss ways in which disease can be prevented.
Article fetal alcohol spectrum disorder and firesetting behaviors a guide for...BARRY STANLEY 2 fasd
"Fetal Alcohol Spectrum Disorder and Fire setting Behaviors:
A Guide for Criminal Justice, Fire, and Forensic Professionals"
setting fires can be a problem for those with FASD.
IMO it is a means of escaping the chaos of "boredom" by those who have a sensory disability that relates to fire.
Similar to Twin study confirms virtually identical prenatal alcohol exposures can lead to markedly different fetal alcohol spectrum disorder outcomes fetal genetics influences fetal vulnerability
Abstract: Fetal alcohol spectrum disorder (FASD) is a significant public health issue in Australia that is poorly diagnosed, chronic and costly.
FASD is a diffuse acquired brain injury secondary to prenatal alcohol exposure. The prevalence rate of FASD among the general population in Australia is currently unknown; however, an Australian study in a selected high-risk population reported some of the highest rates of FASD in the world. A common misconception among clinicians is that a child must have ‘the face’ of FASD to have the disorder. This is incorrect. The three
sentinel facial features only occur in the minority of individuals with FASD. FASD should be considered as a ‘whole body’ disorder as increased susceptibility to chronic health problems suggests suboptimal in utero environments places the individual at risk of later disease. Clinicians are reluctant to consider FASD as a possible diagnosis because of the concern of inducing stigma; however, this concern is neither supported by the
evidence nor patient stories. The Australian Guide to the Diagnosis of FASD is now available to assist health professionals in providing timely and accurate diagnoses, which can lead to improved outcomes via evidence-based intervention and is an important first step in future prevention.
Of the 415 children in the study (195 girls and 220 boys; mean [SD] age, 363.0 [8.3] days), a consistent association between craniofacial shape and prenatal alcohol exposure was observed at almost any level regardless of whether exposure occurred only in the first trimester or throughout pregnancy. Regions of difference were concentrated around the midface, nose, lips, and eyes. Directional visualization showed that these differences corresponded to general recession of the midface and superior displacement of the nose, especially the tip of the nose, indicating shortening of the nose and upturning of the nose tip.
Differences were most pronounced between groups with no exposure and groups with low exposure in the first trimester (forehead), moderate to high exposure in the first trimester (eyes, midface, chin, and parietal region), and binge-level exposure in the first trimester (chin).
CONCLUSIONS AND RELEVANCE Prenatal alcohol exposure, even at low levels, can influence craniofacial development. Although the clinical significance of these findings is yet to be determined, they support the conclusion that for women who are or may become pregnant, avoiding alcohol is the safest option.
Dna methylation signature of human fetal alcohol spectrum disorder | epigenet...BARRY STANLEY 2 fasd
Results
After correcting for the effects of genetic background, we found 658 significantly differentially methylated sites between FASD
cases and controls, with 41 displaying differences in percent methylation change >5 %. Furthermore, 101 differentially
methylated regions containing two or more CpGs were also identified, overlapping with 95 different genes. The majority of
differentially methylated genes were highly expressed at the level of mRNA in brain samples from the Allen Brain Atlas, and
independent DNA methylation data from cortical brain samples showed high correlations with BEC DNA methylation patterns.
Finally, overrepresentation analysis of genes with up-methylated CpGs revealed a significant enrichment for
neurodevelopmental processes and diseases, such as anxiety, epilepsy, and autism spectrum disorders
Neurobehavioral Disorder Associated with Prenatal Alcohol Exposure (ND-PAE): ...BARRY STANLEY 2 fasd
Neurobehavioral Disorder Associated with Prenatal Alcohol
Exposure (ND-PAE): Proposed DSM-5 Diagnosis
Julie A. Kable1,Mary J. O’Connor2, Heather Carmichael Olson3, Blair Paley2, Sarah N. Mattson4, Sally M. Anderson5, Edward P. Riley.
Abstract Over the past 40 years, a significant body of
animal and human research has documented the teratogenic
effects of prenatal alcohol exposure (PAE). Neurobehavioral
Disorder associated with PAE is proposed as a new
clarifying term, intended to encompass the neurodevelopmental
and mental health symptoms associated with PAE.
Defining this disorder is a necessary step to adequately
characterize these symptoms and allow clinical assessment
not possible using existing physically-based diagnostic
schemes. Without appropriate diagnostic guidelines,
affected individuals are frequently misdiagnosed and treated
inappropriately (often to their considerable detriment)
by mental health, educational, and criminal justice systems.
Three core areas of deficits identified from the available
research, including neurocognitive, self-regulation, and
adaptive functioning impairments, are discussed and
information regarding associated features and disorders,
prevalence, course, familial patterns, differential diagnosis,
and treatment of the proposed disorder are also provided.
A systematic review of prevention interventions to reduce prenatal alcohol ex...BARRY STANLEY 2 fasd
Fetal alcohol spectrum disorder (FASD) is a preventable, lifelong neurodevelopmental disorder caused by prenatal alcohol
exposure. FASD negatively impacts individual Indigenous communities around the world. Although many prevention
interventions have been developed and implemented, they have not been adequately evaluated. This systematic review updates
the evidence for the effectiveness of FASD prevention interventions in Indigenous/Aboriginal populations internationally, and in specific populations in North America and New Zealand, and offers recommendations for future work.
Seminar1240 www.thelancet.com Vol 387 March 19, 2016.docxtcarolyn
Seminar
1240 www.thelancet.com Vol 387 March 19, 2016
Attention defi cit hyperactivity disorder
Anita Thapar, Miriam Cooper
Attention defi cit hyperactivity disorder (ADHD) is a childhood-onset neurodevelopmental disorder with a prevalence
of 1·4–3·0%. It is more common in boys than girls. Comorbidity with childhood-onset neurodevelopmental
disorders and psychiatric disorders is substantial. ADHD is highly heritable and multifactorial; multiple genes and
non-inherited factors contribute to the disorder. Prenatal and perinatal factors have been implicated as risks, but
defi nite causes remain unknown. Most guidelines recommend a stepwise approach to treatment, beginning with
non-drug interventions and then moving to pharmacological treatment in those most severely aff ected. Randomised
controlled trials show short-term benefi ts of stimulant medication and atomoxetine. Meta-analyses of blinded trials
of non-drug treatments have not yet proven the effi cacy of such interventions. Longitudinal studies of ADHD show
heightened risk of multiple mental health and social diffi culties as well as premature mortality in adult life.
Introduction
Attention defi cit hyperactivity disorder (ADHD) is a
childhood-onset neurodevelopmental disorder char ac-
terised by developmentally inappropriate and impairing
inattention, motor hyperactivity, and impulsivity, with
diffi culties often continuing into adulthood. In this
Seminar, we aim to update and inform early career
clinicians on issues relevant to clinical practice and
discuss some controversies and misunderstandings.
Defi nitions of ADHD
ADHD is a diagnostic category in the American
Psychiatric Association’s Diagnostic and Statistical
Manual of Mental Disorders 4th edition (DSM-IV)1 and
the more recent DSM-5.2 The broadly equivalent
diagnosis used predominantly in Europe is hyperkinetic
disorder, which is defi ned in WHO’s International
Classifi cation of Diseases (10th edition; ICD-10).3 This
defi nition captures a more severely aff ected group of
individuals, since reported prevalence of hyperkinetic
disorder is lower than that of DSM-IV ADHD, even
within the same population.4 Key diagnostic criteria are
listed in the panel. DSM-5 has longer symptom
descriptors than those used in DSM-IV; these descriptors
also capture how symptoms can manifest in older
adolescents and adults. DSM-IV distinguished between
inattentive, hyperactive–impulsive, and combined sub-
types of ADHD; a diagnosis of the combined subtype
required the presence of symptoms across the domains
of inattention and hyperactivity–impulsivity. However,
ADHD subtypes are not stable across time,5 and DSM-5
has de-emphasised their distinctions. ICD-10 does not
distinguish subtypes; symptoms need to be present from
the three separate domains of inattention, hyperactivity,
and impulsivity for a diagnosis of hyperkinetic disorder.
The diagnosis of ADHD or hyperkinetic disorder also
requires the pre.
The impact of traumatic childhood experiences on cognitive and behavioural fu...BARRY STANLEY 2 fasd
Early diagnosis and interventions can help to prevent or reduce secondary conditions
associated with FASD: early diagnosis is associated with fewer adverse and more positive life outcomes in individuals with FASD (Streissguth et al., 2011) and emerging data on interventions are showing a similar effect (Carmichael-Olson & Montague, 2011). Interventions generally include pharmacological, behavioural and educational treatments, and many of these have shown promising results, but much more data are required in order to inform and develop theoretical foundations, methods and outcomes (Chandrasena, Mukherjee, & Turk, 2009; Mukherjee, Cook, Fleming, & Norgate, 2016). Moreover, risk factors such as abuse and neglect have received little attention within the FASD literature, leaving a risk that these factors are confounding results and conclusions.
This thesis was proposed in a collaboration between the National FASD Clinic and the University of Salford in order to develop the limited understanding of the expected presentation and development of children with exposure to both prenatal alcohol and postnatal trauma, with the long-term aim of improving interventions in this population.
The utility of psychotropic drugs on patients with fetal alcohol spectrum dis...BARRY STANLEY 2 fasd
ABSTRACT
BACKGROUND: Treatment of the complications arising from Prenatal Alcohol Exposure (PAE) has largely been focused on psychosocial and environmental approaches. Research on the
use of medications, especially psychotropic medications, has lagged behind.
OBJECTIVES: This systematic review sought to investigate psychotropic medication related findings and outcomes in those diagnosed with Fetal Alcohol Spectrum Disorder (FASD).
METHODS: Comprehensive searches were conducted in seven major databases (Medline/
PubMed, Scopus, Web of Knowledge, Embase, PsycINFO, Cochrane Library, and
PsycARTICLES) up to February 2017. Key search terms with synonyms were mapped on these databases. There were no timeline restrictions and no grey literature searches. Two reviewers
independently assessed 25 studies that met the inclusion criteria. Most studies were reviews of treatment and retrospective case series.
RESULTS: Two crossover randomized trials were reported, and the findings were not amenable to meta-analysis. Several conditions (depression, agitation, seizures, and outburst) combined with the most frequent presentation, ADHD, to represent the rationale for prescribing psychotropic medications. Second-generation antipsychotics were found to improve social skills, but the paucity of data limited the extent of clinical guidance necessary for the field.
CONCLUSIONS: The systematic review showed that there are some clinical evidence displaying
the validity of psychopharmacological interventions in people with FASD, which varies across the spectrum of disease severity, age, and gender. There is a need for more clinical evidencebased studies in addition to clinical expert opinions to substantiate an optimal ground for individualized management of FASD.
The study protocol for this review was registered in PROSPERO with registration number
CRD42016045703
Response to the five Danish papers. Submitted but not accepted for publicationBARRY STANLEY 2 fasd
In 2012 the British Journal of Obstetrics and Gynaecology publish five papers from the Danish Lifestyle During Pregnancy Study Group. These publications received a great deal or world wide media coverage. The emphasis of most of this coverage was in support of drinking low to moderate amounts of alcohol during pregnancy.
Over a period of approximately six months I corresponded with the editor of the BJOG to have a letter of response published in the journal. Although I modified my letter as was requested it was not published.
Barry Stanley
Challenges in accurately assessing prenatal alcohol exposure inBARRY STANLEY 2 fasd
Comment on the paper - Challenges in accurately assessing prenatal alcohol exposure in a study of Fetal Alcohol Spectrum Disorder in a youth detention center.
genetic and epigenetic perspectives on the role of fathers in fetal alcohol s...BARRY STANLEY 2 fasd
Given that fathers who consume alcohol at risky levels may contribute to FASD due to sperm abnormalities and genetic and epigenetic influences, it is recommended that fathers as well as mothers be involved in pregnancy planning and in reducing/stoppingat-risk alcohol consumption in the preconception period. Preconception interventions with male partners should be synchronized with those designed to support women in preventing FASD.
Prof. Dr. Vladimir Trajkovski-Etiology and pathogenesis of ASDVladimir Trajkovski
These are slides from webinar which Prof. Dr. Vladimir Trajkovski held for colleagues from India. The title of lecture is Etiology and pathogenesis of autism spectrum disorders. Webionar was on YouTube channel in live od 23.05.2018.
Fetal Alcohol Spectrum Disorder is a clinical condition that has aroused the interest of researchers as it is considered relatively common in the population, with an incidence of approximately 10 cases per 1,000 births. The neurodevelopmental changes that characterize the phenotype of this condition are described by deficits in memory, attention, visual-spatial and executive function, learning disabilities and the presence of spoken language impairment. Considering the language deficit as part of Fetal Alcohol Spectrum Disorder, we proposed to review the literature to identify which procedures are used in the assessment of language and findings reported in language in Fetal Alcohol Spectrum Disorder. The 21 articles selected in this review reflect variability in methodology and commonly used procedures assessment of spoken language. The spoken language profile of individuals diagnosed with Fetal Alcohol Spectrum Disorder is characterized by different performance and with varying degrees of impairment. Several factors influence the variability of spoken language impairment described in Fetal Alcohol Spectrum Disorders, and the amount of alcohol consumed, the gestation period when consumption took place and individual susceptibility of each fetus to metabolize alcohol in the body are often described
Current Topics in CareA Case of Inappropriate ApolipoproteOllieShoresna
Current Topics in Care
A Case of Inappropriate Apolipoprotein E
Testing in Alzheimer’s Disease Due to
Lack of an Informed Consent Discussion
Christian D. Furman, MD, MSPH, AGSF1,
Lori A. Earnshaw, MD2, David J. Doukas, MD3,
Lindsay A. Farrer, MD4, and Robert P. Friedland, MD3
Abstract
Background/Objective: Apolipoprotein E (APOE) genetic testing is used to assist in the diagnosis of Alzheimer’s Disease (AD).
Whenever genetic testing is performed, an informed consent process should occur. Methods: In this case, a patient with memory
loss presented to the neurologist. The neurologist ordered a lumbar puncture (LP). The LP was performed by a neuroradiologist
who also ordered APOE genetic testing. The patient received no genetic counseling, nor was an informed consent document
offered. Results: After the testing was completed, the neurologist faced an ethical dilemma. His solution was to offer the genetic
testing to the patient in order to have an informed consent process. It was clear that the patient and her adult children did not
want the genetic testing and that they would have been burdened with the results. The neurologist opted not to disclose the
results. Conclusion: Genetic counseling and a signed informed consent document are required prior to any genetic testing. In
this case, neither occurred and it led to an ethical dilemma that was ultimately resolved by the neurologist. As the population ages
and AD becomes more prevalent, there is a need to expand the workforce of genetic counselors and educate physicians who
commonly treat AD about genetic testing.
Keywords
genetic testing, Alzheimer’s disease, ethics, informed consent
Introduction
Twenty years ago, the apolipoprotein E (APOE) e4 allele was
found to confer susceptibility to late-onset Alzheimer’s dis-
ease (AD) in caucasians.1 This association was extended to
noncaucasian populations, and the APOE-associated risk of
AD was demonstrated to vary with age and sex.2 Although the
presence of the e4 allele in a person with dementia increases
the probability of AD, this finding is not ‘‘diagnostic’’ of the
disease because more than one-half of e4 carriers surviving
to age 80 years do not develop AD.2,3 Thus, APOE e4 is best
viewed as a genetic risk factor for AD rather than a genetic
marker of the disease4 because the risk of developing AD for
individuals with at least 1 e4 allele by age 80 years is esti-
mated to be 29% compared to 9% for individuals lacking e4.5
Among caucasians, the odds of developing AD are 2 to 3 times
higher for e4 heterozygotes and 12 to 14 times higher for e4
homozygotes compared to persons who are APOE 3/3, the most
common genotype.2 However, these risks are dependent on age
and gender and are lower in some ethnic groups including African
Americans, Indians, and Israeli Arabs.2,6-9 Further, the APOE risk
appears to be attenuated by adequate control of hypertension.10
The 2/3 genotype is associated with an approximately 40%
decreased risk of ...
Similar to Twin study confirms virtually identical prenatal alcohol exposures can lead to markedly different fetal alcohol spectrum disorder outcomes fetal genetics influences fetal vulnerability (20)
Conclusions reached from my involvement with the Canadian criminal justice system. 2011.
amd- 2021
References of papers published by Dr Mansfield Mela, and others regarding FASD, PAE, Mental Health, and the Justice System.
Dr Mela is one of the very few Forensic Psychiatrists who understands and advocates for those with FASD.
The Nomenclature of the Consequences of Prenatal Alcohol Exposure: PAE, and t...BARRY STANLEY 2 fasd
An historical account of the nomenclature relating to the effects of alcohol on the developing fetus.
The significance of facial features; the dose/threshold question; epigenetics, transgenerational consequences, and adult health issues, are raised.
The inadequacy of the present nomenclature is detailed
Effects of Hyperbaric Oxygen Therapy on Brain Perfusion, Cognition and Behavi...BARRY STANLEY 2 fasd
Abstract
A 15-year-old girl diagnosed with FASD underwent 100 courses of hyperbasic oxygen therapy (HBOT). Prior to HBOT, single motion emission compute tomographic begin imaging (SPECT)
revealed areas of hypo-perfusion bilaterally in the orbitofrontal region, temporal lobes and right dorsolateral—frontal, as well the medial aspect of the left cerebellum. Following two sets of HBOT treatments (60 plus 40), over 6 months, there was improvement in perfusion to the left cerebellum as well as the right frontal lobe. This was paralleled by improvement in immediate cognitive tests and an increase in functional brain volume. A follow-up 18 months after HBOT showed sustained
improvement in attention with no need for methylphenidate, as well as in math skills and writing.
This year as a priority of Proof Alliance’s legislative platform, major legislation that requires all children entering foster care be screened for prenatal exposure to alcohol in Minnesota was passed and signed into law. It is believed Minnesota is the first state in the nation to pass this legislation.
Four year follow-up of a randomized controlled trial of choline for neurodeve...BARRY STANLEY 2 fasd
Abstract
Background
Despite the high prevalence of fetal alcohol spectrum disorder (FASD), there are few interventions targeting its core neurocognitive and behavioral deficits. FASD is often conceptualized as static and permanent, but interventions that capitalize on brain plasticity and critical developmental windows are emerging. We present a long-term follow-up study evaluating the neurodevelopmental effects of choline supplementation in children with FASD 4 years after an initial efficacy trial
Abstract
This presentation includes a brief review of research into boredom, normal brain resting state and corresponding default mode[s].
The possible equivalence to the brain activity of those with FASD in relation to “being bored” is explored, with reference to brain anatomy and function.
Actual FASD clinical cases are presented to illustrate what individuals with FASD mean by “boredom”: describing the role of perseveration as a relief process.
Finally, the manner in which these processes are misinterpreted is explored, with implications for Psychiatry and the Justice System.
Association Between Prenatal Exposure to Alcohol and Tobacco and Neonatal Bra...BARRY STANLEY 2 fasd
IMPORTANCE Research to date has not determined a safe level of alcohol or tobacco use during pregnancy. Electroencephalography (EEG) is a noninvasive measure of cortical function that has previously been used to examine effects of in utero exposures and associations with
neurodevelopment.
OBJECTIVE To examine the association of prenatal exposure to alcohol (PAE) and tobacco smoking (PTE) with brain activity in newborns.
CONCLUSIONS AND RELEVANCE These findings suggest that even low levels of PAE or PTE are
associated with changes in offspring brain development.
Submitted to –
National Institute for Health and Care Excellence Fetal alcohol spectrum disorder
Consultation on draft quality standard – deadline for comments 5pm on 03/04/20
Clinical course and risk factors for mortality of adult inpatients with covid...BARRY STANLEY 2 fasd
Interpretation The potential risk factors of older age, high SOFA score, and d-dimer greater than 1 μg/mL could help
clinicians to identify patients with poor prognosis at an early stage. Prolonged viral shedding provides the rationale
for a strategy of isolation of infected patients and optimal antiviral interventions in the future.
Outcomes of Online Mindfulness-Based Cognitive Therapy for Patients With Residual Depressive SymptomsA Randomized Clinical Trial
Zindel V. Segal, PhD1; Sona Dimidjian, PhD2; Arne Beck, PhD3; et alJennifer M. Boggs, PhD3; Rachel Vanderkruik, MA2; Christina A. Metcalf, MA2; Robert Gallop, PhD4; Jennifer N. Felder, PhD5; Joseph Levy, BA2
Author Affiliations
JAMA Psychiatry. Published online January 29, 2020. doi:10.1001/jamapsychiatry.2019.4693
Significance for fasd
NVBDCP.pptx Nation vector borne disease control programSapna Thakur
NVBDCP was launched in 2003-2004 . Vector-Borne Disease: Disease that results from an infection transmitted to humans and other animals by blood-feeding arthropods, such as mosquitoes, ticks, and fleas. Examples of vector-borne diseases include Dengue fever, West Nile Virus, Lyme disease, and malaria.
Recomendações da OMS sobre cuidados maternos e neonatais para uma experiência pós-natal positiva.
Em consonância com os ODS – Objetivos do Desenvolvimento Sustentável e a Estratégia Global para a Saúde das Mulheres, Crianças e Adolescentes, e aplicando uma abordagem baseada nos direitos humanos, os esforços de cuidados pós-natais devem expandir-se para além da cobertura e da simples sobrevivência, de modo a incluir cuidados de qualidade.
Estas diretrizes visam melhorar a qualidade dos cuidados pós-natais essenciais e de rotina prestados às mulheres e aos recém-nascidos, com o objetivo final de melhorar a saúde e o bem-estar materno e neonatal.
Uma “experiência pós-natal positiva” é um resultado importante para todas as mulheres que dão à luz e para os seus recém-nascidos, estabelecendo as bases para a melhoria da saúde e do bem-estar a curto e longo prazo. Uma experiência pós-natal positiva é definida como aquela em que as mulheres, pessoas que gestam, os recém-nascidos, os casais, os pais, os cuidadores e as famílias recebem informação consistente, garantia e apoio de profissionais de saúde motivados; e onde um sistema de saúde flexível e com recursos reconheça as necessidades das mulheres e dos bebês e respeite o seu contexto cultural.
Estas diretrizes consolidadas apresentam algumas recomendações novas e já bem fundamentadas sobre cuidados pós-natais de rotina para mulheres e neonatos que recebem cuidados no pós-parto em unidades de saúde ou na comunidade, independentemente dos recursos disponíveis.
É fornecido um conjunto abrangente de recomendações para cuidados durante o período puerperal, com ênfase nos cuidados essenciais que todas as mulheres e recém-nascidos devem receber, e com a devida atenção à qualidade dos cuidados; isto é, a entrega e a experiência do cuidado recebido. Estas diretrizes atualizam e ampliam as recomendações da OMS de 2014 sobre cuidados pós-natais da mãe e do recém-nascido e complementam as atuais diretrizes da OMS sobre a gestão de complicações pós-natais.
O estabelecimento da amamentação e o manejo das principais intercorrências é contemplada.
Recomendamos muito.
Vamos discutir essas recomendações no nosso curso de pós-graduação em Aleitamento no Instituto Ciclos.
Esta publicação só está disponível em inglês até o momento.
Prof. Marcus Renato de Carvalho
www.agostodourado.com
Prix Galien International 2024 Forum ProgramLevi Shapiro
June 20, 2024, Prix Galien International and Jerusalem Ethics Forum in ROME. Detailed agenda including panels:
- ADVANCES IN CARDIOLOGY: A NEW PARADIGM IS COMING
- WOMEN’S HEALTH: FERTILITY PRESERVATION
- WHAT’S NEW IN THE TREATMENT OF INFECTIOUS,
ONCOLOGICAL AND INFLAMMATORY SKIN DISEASES?
- ARTIFICIAL INTELLIGENCE AND ETHICS
- GENE THERAPY
- BEYOND BORDERS: GLOBAL INITIATIVES FOR DEMOCRATIZING LIFE SCIENCE TECHNOLOGIES AND PROMOTING ACCESS TO HEALTHCARE
- ETHICAL CHALLENGES IN LIFE SCIENCES
- Prix Galien International Awards Ceremony
Explore natural remedies for syphilis treatment in Singapore. Discover alternative therapies, herbal remedies, and lifestyle changes that may complement conventional treatments. Learn about holistic approaches to managing syphilis symptoms and supporting overall health.
Ozempic: Preoperative Management of Patients on GLP-1 Receptor Agonists Saeid Safari
Preoperative Management of Patients on GLP-1 Receptor Agonists like Ozempic and Semiglutide
ASA GUIDELINE
NYSORA Guideline
2 Case Reports of Gastric Ultrasound
New Drug Discovery and Development .....NEHA GUPTA
The "New Drug Discovery and Development" process involves the identification, design, testing, and manufacturing of novel pharmaceutical compounds with the aim of introducing new and improved treatments for various medical conditions. This comprehensive endeavor encompasses various stages, including target identification, preclinical studies, clinical trials, regulatory approval, and post-market surveillance. It involves multidisciplinary collaboration among scientists, researchers, clinicians, regulatory experts, and pharmaceutical companies to bring innovative therapies to market and address unmet medical needs.
Title: Sense of Smell
Presenter: Dr. Faiza, Assistant Professor of Physiology
Qualifications:
MBBS (Best Graduate, AIMC Lahore)
FCPS Physiology
ICMT, CHPE, DHPE (STMU)
MPH (GC University, Faisalabad)
MBA (Virtual University of Pakistan)
Learning Objectives:
Describe the primary categories of smells and the concept of odor blindness.
Explain the structure and location of the olfactory membrane and mucosa, including the types and roles of cells involved in olfaction.
Describe the pathway and mechanisms of olfactory signal transmission from the olfactory receptors to the brain.
Illustrate the biochemical cascade triggered by odorant binding to olfactory receptors, including the role of G-proteins and second messengers in generating an action potential.
Identify different types of olfactory disorders such as anosmia, hyposmia, hyperosmia, and dysosmia, including their potential causes.
Key Topics:
Olfactory Genes:
3% of the human genome accounts for olfactory genes.
400 genes for odorant receptors.
Olfactory Membrane:
Located in the superior part of the nasal cavity.
Medially: Folds downward along the superior septum.
Laterally: Folds over the superior turbinate and upper surface of the middle turbinate.
Total surface area: 5-10 square centimeters.
Olfactory Mucosa:
Olfactory Cells: Bipolar nerve cells derived from the CNS (100 million), with 4-25 olfactory cilia per cell.
Sustentacular Cells: Produce mucus and maintain ionic and molecular environment.
Basal Cells: Replace worn-out olfactory cells with an average lifespan of 1-2 months.
Bowman’s Gland: Secretes mucus.
Stimulation of Olfactory Cells:
Odorant dissolves in mucus and attaches to receptors on olfactory cilia.
Involves a cascade effect through G-proteins and second messengers, leading to depolarization and action potential generation in the olfactory nerve.
Quality of a Good Odorant:
Small (3-20 Carbon atoms), volatile, water-soluble, and lipid-soluble.
Facilitated by odorant-binding proteins in mucus.
Membrane Potential and Action Potential:
Resting membrane potential: -55mV.
Action potential frequency in the olfactory nerve increases with odorant strength.
Adaptation Towards the Sense of Smell:
Rapid adaptation within the first second, with further slow adaptation.
Psychological adaptation greater than receptor adaptation, involving feedback inhibition from the central nervous system.
Primary Sensations of Smell:
Camphoraceous, Musky, Floral, Pepperminty, Ethereal, Pungent, Putrid.
Odor Detection Threshold:
Examples: Hydrogen sulfide (0.0005 ppm), Methyl-mercaptan (0.002 ppm).
Some toxic substances are odorless at lethal concentrations.
Characteristics of Smell:
Odor blindness for single substances due to lack of appropriate receptor protein.
Behavioral and emotional influences of smell.
Transmission of Olfactory Signals:
From olfactory cells to glomeruli in the olfactory bulb, involving lateral inhibition.
Primitive, less old, and new olfactory systems with different path
Report Back from SGO 2024: What’s the Latest in Cervical Cancer?bkling
Are you curious about what’s new in cervical cancer research or unsure what the findings mean? Join Dr. Emily Ko, a gynecologic oncologist at Penn Medicine, to learn about the latest updates from the Society of Gynecologic Oncology (SGO) 2024 Annual Meeting on Women’s Cancer. Dr. Ko will discuss what the research presented at the conference means for you and answer your questions about the new developments.
- Video recording of this lecture in English language: https://youtu.be/lK81BzxMqdo
- Video recording of this lecture in Arabic language: https://youtu.be/Ve4P0COk9OI
- Link to download the book free: https://nephrotube.blogspot.com/p/nephrotube-nephrology-books.html
- Link to NephroTube website: www.NephroTube.com
- Link to NephroTube social media accounts: https://nephrotube.blogspot.com/p/join-nephrotube-on-social-media.html
Ethanol (CH3CH2OH), or beverage alcohol, is a two-carbon alcohol
that is rapidly distributed in the body and brain. Ethanol alters many
neurochemical systems and has rewarding and addictive properties. It
is the oldest recreational drug and likely contributes to more morbidity,
mortality, and public health costs than all illicit drugs combined. The
5th edition of the Diagnostic and Statistical Manual of Mental Disorders
(DSM-5) integrates alcohol abuse and alcohol dependence into a single
disorder called alcohol use disorder (AUD), with mild, moderate,
and severe subclassifications (American Psychiatric Association, 2013).
In the DSM-5, all types of substance abuse and dependence have been
combined into a single substance use disorder (SUD) on a continuum
from mild to severe. A diagnosis of AUD requires that at least two of
the 11 DSM-5 behaviors be present within a 12-month period (mild
AUD: 2–3 criteria; moderate AUD: 4–5 criteria; severe AUD: 6–11 criteria).
The four main behavioral effects of AUD are impaired control over
drinking, negative social consequences, risky use, and altered physiological
effects (tolerance, withdrawal). This chapter presents an overview
of the prevalence and harmful consequences of AUD in the U.S.,
the systemic nature of the disease, neurocircuitry and stages of AUD,
comorbidities, fetal alcohol spectrum disorders, genetic risk factors, and
pharmacotherapies for AUD.
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Triangles of Neck and Clinical Correlation by Dr. RIG.pptx
Twin study confirms virtually identical prenatal alcohol exposures can lead to markedly different fetal alcohol spectrum disorder outcomes fetal genetics influences fetal vulnerability
2. Advances in Pediatric Research 2 Hemingway et al. 2019 | 5 : 23
and behavioral deficits observed among individuals
with PAE are not dichotomous, that is either normal
or clearly abnormal. Rather, the outcomes all range
along separate continua from normal to clearly
abnormal [2]. This full range of outcomes caused
by PAE is called Fetal Alcohol Spectrum Disorders
(FASD). Diagnoses like FAS, Partial FAS (PFAS),
Static Encephalopathy/Alcohol Exposed (SE/AE)
and Neurobehavioral Disorder/Alcohol Exposed
(ND/AE) fall broadly under the umbrella of FASD
[2,3].
Fetal risk of damage from PAE is not just
dependent on the timing, frequency, and quantity of
exposure. Fetal alcohol spectrum disorders (FASD)
are caused by a complex interaction of genes and
environment, and are regulated by both parental and
fetal genes [4]. Fetal genetics influences a fetus’
vulnerability to the teratogenic effects of PAE [5].
In a 1993 study of 16 monozygotic and dizygotic
twin pairs, Streissguth and Dehaene [6] reported
100% pairwise concordance in FASD diagnoses
among monozygotic twin pairs, while dizygotic
twins were only 64% concordant. The outcomes of
that study strongly suggested that genetic loci
regulate susceptibility to, or resistance against
FASD. This 1993 study was conducted prior to the
creation of rigorous FASD diagnostic systems.
Patients were diagnosed as FAS or Fetal Alcohol
Effects. If two fetuses exposed to identical levels of
alcohol can experience vastly different FASD
outcomes, this would have important implications
for public health messaging and the setting of
exposure thresholds in FASD diagnostic guidelines.
The purpose of this study was to compare the
prevalence and magnitude of pairwise discordance
in FASD diagnoses across four groups of sibling
pairs: monozygotic twins, dizygotic twins, full-
siblings, and half-siblings sharing a common birth
mother. All sibling pairs had virtually identical or
reportedly similar levels of PAE, were raised
together, were diagnosed by the same
interdisciplinary team using the 4-Digit Diagnostic
Code and were identical or similar in age at the
time of diagnosis. This sibling-pair design sought to
more fully assess and isolate the role of genetics on
fetal vulnerability to the teratogenic effects of PAE
by eliminating or minimizing pairwise discordance
in age, PAE and other prenatal and postnatal risk
factors.
Specific aims
1. To determine if the prevalence of FASD
diagnostic discordance was higher among
dizygotic twin pairs than among monozygotic
twin pairs.
2. To determine if the prevalence of FASD
diagnostic discordance increases as the
proportion of genome shared between sibling-
pairs decreases across the four study groups:
monozygotic twins, dizygotic twins, full-
siblings, and half-siblings sharing a common
birth mother.
3. To document the greatest magnitude of FASD
diagnostic discordance observed between twin
pairs with virtually identical PAE. Can twins
with virtually identical PAE present at opposite
ends of the fetal alcohol spectrum?
4. To estimate the proportion of phenotypic
variance in FASD diagnoses due to genetic
factors (heritability).
Methods
A retrospective study was conducted using data
collected from twin and sibling pairs that received a
FASD diagnostic evaluation at the University of
Washington Fetal Alcohol Syndrome Diagnostic &
Prevention Network (FASDPN).
FASD diagnostic method
FASD diagnoses were rendered using the FASD 4-
Digit Diagnostic Code. It is described in full by
Astley [2,7]. Briefly, the 4 digits of the FASD 4-
Digit Code reflect the magnitude of expression of
the 4 key diagnostic features of FASD, in the
following order: 1) growth deficiency, 2) FAS facial
phenotype, 3) CNS structural/functional
abnormalities, and 4) PAE (Figure 1). The
magnitude of expression of each feature is ranked
independently on a 4-point Likert scale, with 1
reflecting complete absence of the FASD feature
and 4 reflecting a strong “classic” presence of the
FASD feature. Each Likert rank is specifically case
defined. There are a total of 102 4-Digit Codes that
fall broadly under the umbrella of FASD (Figure1 A-
D).
3. Advances in Pediatric Research 3 Hemingway et al. 2019 | 5 : 23
4-Digit Codes within each FASD Diagnostic Category
Figure1: FASD 4-Digit Diagnostic Code. A)Abbreviated case-definitions for the fetalalcohol spectrum disorder (FASD) 4-Digit Code
[2]. The 4-Digit Code 3434 is one of 12 4-Digit Codes that fall underthe diagnostic categoryFAS. B) The Rank 4 FAS facial phenotype
requires 3 features: I) palpebral fissurelengths 2 ormorestandard deviations below the mean;2)a smoothphiltrum (Rank 4 or 5 onthe
University of WashingtonLip-Philtrum Guide);and 3)a thinupperlip(Rank 4 or 5 on the University of WashingtonLip· Philtrum Guide).
C andD) The 4-Digit Code producesfour-diagnosticsubgroups under the umbrella of FASD: FAS(Diagnostic Categories A,B);PFAS
(DiagnosticCategory C);SE/AE (Diagnostic CategoriesE,F); and ND/AE(Diagnostic Categories G,H). Abbreviations: CNS: central
nervous system;H: height percentile; W: weight percentile.
4. Advances in Pediatric Research 4 Hemingway et al. 2019 | 5 : 23
These codes cluster under four clinically
meaningful FASD diagnoses: fetal alcohol
syndrome (FAS) (4-Digit Code Diagnostic
Categories A, B): Partial FAS (PFAS) (Diagnostic
Category C); Static Encephalopathy/Alcohol-
Exposed (SE/AE) (Diagnostic Categories E, F); and
Neurobehavioral Disorder/Alcohol-Exposed
(ND/AE) (Diagnostic Categories G, H) (Figure 1D).
Individuals that did not meet criteria for one of
these FASD diagnostic classifications were
identified in this study as Not FASD/Alcohol-
Exposed (Diagnostic Categories I, J).
Study groups
The sibling pairs were partitioned into four study
groups: 1. monozygotic twins, 2. dizygotic twins, 3.
full-siblings, and 4. half-siblings sharing a common
birth mother. Monozygotic twin pairs share
virtually 100% of their genome. Dizygotic twin
pairs and full-sibling pairs share, on average,
50% of their genome. Half-sibling pairs with a
common birth mother share, on average, 25% of
their genome [8,9].
Data from all twin and sibling pairs that met the
following inclusion criteria were used in this
study:
Sibling pairs were monozygotic twins, dizygotic
twins, full-siblings, or half-siblings sharing
the same birth mother.
Both siblings received an FASD diagnostic
evaluation at an FASDPN clinic by the same
interdisciplinary team using the 2004 FASD 4-
Digit Diagnostic Code.
Siblings did not present with another genetic
syndrome.
Age at diagnosis could range from newborn to
adult. Effort was made to select pairs that both
fit into one of three age ranges at the time of
diagnosis (0-3 years, 4-8 years, 9 or more years).
This minimized the chance that FASD
diagnostic contrasts between pairs may be due to
one sibling being too young to fully assess
or comparably assess brain function.
All siblings had confirmed PAE. Twin
pairs, by definition, had virtually identical
PAE. Full sibling pairs and half-sibling
pairs had to have concordant Alcohol Ranks
(e.g., both siblings had to have Rank 3
alcohol exposure or both had to Rank 4
alcohol exposure).
Effort was made to select siblings raised together
who experienced identical or similar other
prenatal and postnatal risk factors.
Siblings could be of any gender or race.
Data set
All data collected during an FASD diagnostic
evaluation at the FASDPN are entered into the
FASDPN database with patient consent and
University of Washington Human Subjects Division
approval. Approximately 3,000 patients have been
evaluated in the clinic to date. The data document
patient demographics, PAE, all other reported
prenatal and postnatal adverse exposures and events
and measures of growth, facial features, and
structural and/or functional brain abnormalities
used to derive the FASD 4-Digit Code. These data
are recorded on three standardized diagnostic
forms: the New Patient Information Form, FASD
Diagnostic Form, and FAS Facial Photographic
Analysis Report posted on the FASDPN website
www.FASDPN.org [2,8].
Key data used in this study included the patient’s
FASD 4-Digit Code, FASD diagnostic category
(FAS, PFAS, SE/AE, ND/AE and Not FASD/AE),
and their Growth, Face, CNS and Alcohol Ranks
(Figure 1). The CNS Rank in the 4-Digit Code
serves two purposes: 1) Ranks 1 through 4
document the probability of underlying CNS
structural abnormality (Rank 1: unlikely; Rank 2:
possible; Rank 3: probable; and Rank 4: definite).
2) Ranks 1 through 3 also document the magnitude
of CNS dysfunction as measured using standardized
neuropsychological tools (Rank 1: no dysfunction;
Rank 2: moderate dysfunction; and Rank 3 severe
dysfunction). The CNS functional Ranks 1-3
introduced by the 4-Digit Code were case-defined
to predict increasing likelihood of structural CNS
abnormality—a predictive correlation that was
subsequently confirmed through magnetic
resonance imaging [7]. To distinguish these two
CNS measures in the current study, they are labeled
CNS1-4 and CNS1-3. PAE is ranked by the 4-Digit
Code on a 4-point Likert scale (Figure 1A). Only
subjects with Rank 3 or Rank 4 PAE were enrolled
in this study. An Alcohol Rank 4 is assigned when
PAE is confirmed and reported to be high risk
(generally high peak blood alcohol concentrations
5. Advances in Pediatric Research 5 Hemingway et al. 2019 | 5 : 23
delivered at least weekly in early pregnancy). An
Alcohol Rank 3 is assigned when PAE is
confirmed, but the amount reported is low to
moderate risk (designated as PAE Rank 3b in this
study) or the details on the amount and timing are
unknown (designated as PAE Rank 3a in this
study). The information used to generate the
Alcohol Rank is presented on page 8 of the 4-Digit
Code FASD Diagnostic Form [2]. In preparation for
a FASD diagnostic evaluation, efforts are made to
document the quantity, frequency and timing of
maternal alcohol use before and during the index
pregnancy. Although 99.5% of patients evaluated at
the FASDPN clinic have confirmed PAE, only 30 to
40% have quantity, frequency and/or timing of
exposure detailed in their records [10]. Recall error
and reporting bias likely impact the accuracy of this
more detailed information, therefore the more
global measure of PAE “Alcohol Rank” was used
as the primary measure of PAE risk in this study. In
addition to the risk posed by PAE, measures of
other prenatal and postnatal risks were also used in
this study. Other prenatal risk factors documented
in the FASDPN clinical database include poor
prenatal care, pregnancy complications, presence of
other syndromes/genetic abnormalities, and
prenatal exposure to other substances (e.g.,
medications, tobacco, illicit drugs, and/or other
teratogens). The 4-Digit Code ranks the magnitude
of these other prenatal risks in a single composite
measure labeled “Other Prenatal Risks Rank”. Rank
1 equals no risk; Rank 2 equals unknown risk; Rank
3 equals some risk; and Rank 4 equals high risk.
Rank 4 is assigned when there is exposure to
another teratogen (e.g., Dilantin) or when another
syndrome or genetic condition is present (e.g.,
Down syndrome, Fragile X, etc.). Rank 3 is
assigned to all other prenatal risks. Postnatal risk
factors documented in the FASDPN database
include perinatal complications, number of home
placements, physical and/or sexual abuse, neglect,
and trauma. The 4-Digit Code ranks the magnitude
of these other postnatal risks in a single composite
measure labeled “Other Postnatal Risks Rank”.
Rank 1 equals no risk; Rank 2 equals unknown risk;
Rank 3 equals some risk; and Rank 4 equals high
risk. Rank 4 is used to note severe postnatal
circumstances that have been shown to have a
significant adverse effect on development in most
instances. Examples include physical/sexual abuse,
multiple home placements, trauma, and severe
neglect) [2]. Rank 3 is used to note conditions akin
to those in Rank 4, but the circumstances are less
severe.
Statistical analyses
The primary focus of the study was to compare the
prevalence of discordant FASD diagnoses between
sibling pairs across the 4 study groups. Descriptive
statistics (means, SD, and proportions expressed as
valid percentages (e.g., subjects with missing data
are not included in the denominator)) were used to
profile the demographic and clinical outcomes of
the 4 study groups. The chi-square test with tests
for linear trend was used to compare proportions
between the study groups. One-way ANOVA was
used to compare outcomes measured on
a continuous scale between the study groups. Two-
tailed p-values less than 0.05 were
interpreted as statistically significant.
Heritability is formally defined as the proportion of
phenotypic variation that is caused by genotypic
variation in a population. FASD is not a genetic
disorder, but fetal genetics appears to modify the
teratogenic effects of PAE [5,6]. Heritability has
historically been estimated from studies of twins.
Monozygotic twin pairs share essentially 100% of
their genome. Dizygotic twin pairs share, on
average, 50% of their genome. If a trait appears to
be more similar in monozygotic twins than in
dizygotic twins (when the twin pairs were raised
together in the same environment), genetic factors
likely play an important role in determining (or
modifying) that trait. By comparing a trait in
monozygotic twins versus dizygotic twins, one can
calculate an estimate of its heritability. Heritability
estimates range from 0% to 100%. A heritability
close to 0% indicates that almost all of the
variability in a trait is due to environmental factors
(e.g., PAE and other prenatal and postnatal risk
factors), with very little influence from genetic
differences. A heritability estimate close to 100%
indicates that almost all of the variability in a trait
comes from genetic differences, with very little
contribution from variability in environmental
factors. When a phenotype is determined by a
combination of genetic and environmental factors,
heritability will be somewhere between 0% and
100%. Comparing discordance for monozygotic
versus dizygotic twins allows an indirect estimate
of the importance of genetic factors in producing
the phenotype. Heritability estimates based on twin
discordance studies can be simplistically viewed as:
6. Advances in Pediatric Research 6 Hemingway et al. 2019 | 5 : 23
percent heritability = ((dizygotic discordance minus
monozygotic discordance) / dizygotic discordance)
*100 [9,11]. It is important to understand that
heritability does not indicate what proportion of a
trait is determined by genes and what proportion
is determined by environment. A heritability of 80%
does not mean that a trait is 80% caused by genetic
factors; it means that 80% of the variability in the
trait in a population is due to genetic differences.
Heritability measures the fraction of variation
between individuals in a population that is due to
their genotypes.
Results
Demographic and clinical profiles of the four
study groups
The study selection criteria generated 84 sibling
pairs broken into four study groups (monozygotic
twins, dizygotic twins, full siblings and half sibling
sharing the same birth mother) with key factors that
defined and differentiated the groups (Table 1).
Table 1. Key factors that defined and differentiated the 4 study groups.
Study Groups
Features shared between
sibling pairs
Monozygotic twins Dizygotic twins Full-siblings Half-siblings
9 pairs 39 pairs 27 pairs 9 pairs
Birth mother identical identical identical identical
Birth father identical identical identical different
Genome shared ~100% ~50% ~50% ~25%
Prenatal alcohol exposure virtually identical virtually identical 100% same Rank 100% same Rank
Other prenatal risks virtually identical virtually identical 100% same Rank 88% same Rank
Siblings raised together 100% 100% 96% 100%
Other postnatal risks 100% same Rank 87% same Rank 83% same Rank 75% same Rank
Matched in age within one of 3
age ranges (0-3; 4-8, 9+ years)
100% 100% *93% *89%
* 2 pairs of full-siblings and 1 pair of half-siblings had one sibling that was in a younger age category. In each of these 3
pairs, the younger sibling had the more severe FASD diagnostic outcome.
The demographic and FASD diagnostic profiles of
the study sample (Table 2) were highly
representative of the entire FASDPN clinic
population (n = 3,000) from which it was selected
[10]. The gender and age distributions were
comparable between the 4 study groups. Race was
100% concordant across all 84 twin/sibling pairs.
The number of full and half sibling pairs included
in the study may appear smaller than one would
expect from a patient population of 3,000. A
number of factors inherent in the FASDPN clinical
dataset limited the number of full and half sibling
pairs available for inclusion in the study. In general,
85% of the patients evaluated by the FASDPN are
in foster/adoptive care—no longer living with their
birth parents. Confirmation of full or half sibling
status requires knowledge of both birth parents’
names. This is typically available on only half of
the FASDPN patient population. Of the 54% (n =
1,617) with birth parent names available, 8% (n =
129) were siblings (full or half). Seventy-two of the
7. Advances in Pediatric Research 7 Hemingway et al. 2019 | 5 : 23
129 full and half siblings met the inclusion criteria
for the study.
The primary reason siblings failed to meet the
study’s inclusion criteria were they were too
different in age (e.g., infant vs adolescent) at the
time of their FASD evaluation to draw valid
conclusions regarding the concordance/discordance
of their diagnoses.
Table 2. Comparison of demographic and FASD clinical profiles between the four study groups.
Demographic and
Clinical Characteristics
Monozygotic Dizygotic Full-siblings Half-siblings Total
N = 18 (9 pairs) N = 78 (39 pairs) N = 54 (27 pairs) N = 18 (9 pairs) N = 168 (84 pairs)
Gender (N pairs; valid %)
female-female 4 44.4 10 25.6 7 25.9 2 22.2 23 27.4
male-male 5 55.6 10 25.6 11 40.7 4 44.4 30 35.7
Mixed gender 0 0.0 19 48.7 9 33.3 3 33.3 31 36.9
Overall proportion of
female subjects
8/18 44.4 37/78 47.4 23/54 42.6 7/18 38.9 75/168 44.6
Race (N; valid %)
Caucasian 4 22.2 32 41.0 32 59.3 14 77.8 82 48.8
African American 0 0.0 0 0.0 0 0.0 0 0.0 0 0.0
Native American 0 0.0 8 10.3 2 3.7 1 5.6 11 6.5
Hispanic 0 0.0 4 5.1 6 11.1 0 0.0 10 6.0
Mixed race 14 77.8 34 43.6 14 25.9 3 16.7 65 38.7
Age at Diagnosis (years) (N, valid %)
0 - 3.9 4 22.2 30 38.5 17 31.5 2 11.1 53 31.5
4 - 8.9 12 66.7 28 35.9 22 40.7 9 50.0 71 42.3
9 - 19.7 2 11.1 20 25.6 15 27.8 7 38.9 44 26.2
Sibling pairs raised together (N pairs; valid %)
yes 9 100.0 39 100.0 26 96.3 9 100.0 83 98.8
Prenatal Alcohol Exposure: 4-Digit Alcohol Rank (N, valid %)
Rank 3a: Exposure
confirmed, amount
unknown
8 44.5 30 38.5 26 48.1 6 33.3 70 41.7
Rank 3b: Exposure
confirmed, amount low to
moderate
4 22.2 0 0.0 4 7.3 0 0.0 8 4.8
Rank 4: Exposure
confirmed and level high
6 33.3 48 61.5 24 44.4 12 66.7 90 53.5
8. Advances in Pediatric Research 8 Hemingway et al. 2019 | 5 : 23
The matching criteria used to select twin and
sibling pairs effectively minimized pairwise
discordance in PAE and other prenatal and postnatal
risk factors (Table 3). By definition, PAE was 100%
concordant (virtually identical) between the
monozygotic and dizygotic twin pairs. The Other
Prenatal Risk Rank was 100% concordant between
the monozygotic, dizygotic and full-sibling pairs,
and 87.5% concordant between the half-sibling
pairs. The Postnatal Risk Rank was highly
concordant across all 4 groups (monozygotic:
100%; dizygotic: 87.2%; full-sibling: 91.3% and
half-sibling: 75.0%), but did decrease linearly as
the proportion of genome shared between siblings
decreased.
Other Prenatal Risks: 4-Digit Rank (N, valid %)
Rank 1: no risk 0 0.0 0 0.0 0 0.0 0 0.0 0 0.0
Rank 2: unknown risk 2 11.1 8 10.3 0 0.0 2 11.1 12 7.1
Rank 3: moderate risk 16 88.9 70 89.7 54 100.0 15 83.3 155 92.3
Rank 4: high risk 0 0.0 0 0.0 0 0.0 1 5.6 1 0.6
Postnatal Risks: 4-Digit Rank (N, valid %)
Rank 1: no risk 0 0.0 2 2.6 1 1.9 0 0.0 3 1.8
Rank 2: unknown risk 2 11.1 0 0.0 5 9.3 1 5.6 8 4.8
Rank 3: moderate risk 6 33.3 37 47.4 31 57.4 4 22.2 78 46.4
Rank 4: high risk 10 55.6 39 50.0 17 31.5 13 72.2 79 47.0
FASD Diagnoses (N, valid %)
FAS 4 22.2 1 1.3 2 3.7 1 5.6 8 4.8
PFAS 0 0.0 5 6.4 3 5.6 2 11.1 10 6.0
SE/AE 8 44.5 15 19.2 12 22.2 5 27.8 41 24.4
ND/AE 4 22.2 48 61.5 23 42.6 9 50.0 84 50.0
Sentinel Physical
Findings/AE
0 0.0 0 0.0 4 7.4 1 5.6 4 2.4
Not FASD/AE 2 11.1 9 11.5 10 18.5 0 0.0 21 12.5
9. Advances in Pediatric Research 9 Hemingway et al. 2019 | 5 : 23
Table 3. Matching criteria effectively minimized pairwise discordance in PAE and other prenatal and postnatal risk factors.
Prenatal and Postnatal Risks
Monozygotic Dizygotic Full-siblings Half-siblings
N = 18 (9 pairs) N = 78 (39 pairs) N = 54 (27 pairs) N = 18 (9 pairs)
N Pairs valid% N Pairs valid% N Pairs valid% N Pairs valid%
Prenatal Alcohol Exposure (PAE): 4-Digit Code Rank
Concordant Ranks between sibling pairs
Overall 9 100.0 39 100.0 27 100.0 9 100.0
Rank 1: Confirmed absence of PAE 0 0.0 0 0.0 0 0.0 0 0.0
Rank 2: PAE unknown 0 0.0 0 0.0 0 0.0 0 0.0
Rank 3a: PAE confirmed, amount
unknown
4 44.5 15 38.5 13 48.1 3 33.3
Rank 3b: PAE confirmed, amount low
to moderate
2 22.2 0 0.0 2 7.3 0 0.0
Rank 4: PAE confirmed, amount high 3 33.3 24 61.5 12 48.6 6 66.7
Discordant Ranks between sibling pairs
Overall 0 0.0 0 0.0 0 0.0 0 0.0
Other Prenatal Risks: 4-Digit Code Rank
Concordant Ranks between sibling pairs
Overall 9/9 100.0 39/39 100.0 27/27 100.0 8/9 88.9
Valid Overall (excluding pairs with
unknown risk)
8/8 100.0 35/35 100.0 27/27 100.0 7/8 87.5
Rank 1: no risk 0 0.0 0 0.0 0 0.0 0 0.0
Rank 2: unknown risk 1 11.1 4 10.3 0 0.0 1 11.1
Rank 3: some risk 8 88.9 35 89.7 27 100.0 7 77.8
Rank 4: high risk 0 0.0 0 0.0 0 0.0 0 0.0
Discordant Ranks between sibling pairs
Overall 0/9 0.0 0/39 0.0 0/27 0.0 1/9 11.1
Valid Overall (excluding pairs with
unknown risk)
0/9 0.0 0/39 0.0 0/27 0.0 1/8 12.5
Rank 4: high risk – Rank 3: some risk 0 0.0 0 0.0 0 0.0 1 11.1
10. Advances in Pediatric Research 10 Hemingway et al. 2019 | 5 : 23
Postnatal Risks: 4-Digit Code Rank
Concordant Ranks between sibling pairs
Overall 9/9 100.0 34/39 87.2 21/27 77.8 6/9 66.7
Valid Overall (excluding pairs with
unknown risk)
8/8 100.0 34/39 87.2 20/23 91.3 6/8 75.0
Rank 1: no risk 0 0.0 1 2.6 0 0.0 0 0.0
Rank 2: unknown risk 1 11.1 0 0.0 1 3.7 0 0.0
Rank 3: some risk 3 33.3 16 41.0 13 48.1 0 0.0
Rank 4: high risk 5 55.6 17 43.6 7 26.0 6 66.7
Discordant Ranks between sibling pairs
Overall 0/9 0.0 5/39 12.8 6/27 22.2 3/9 33.3
Valid Overall (excluding pairs with
unknown risk)
0/8 0.0 5/39 12.8 3/23 13.0 3/8 25.0
Rank 3: some risk –
Rank 2: unknown risk
0 0.0 0 0.0 2 7.4 1 11.1
Rank 3: some risk –
Rank 1: no risk
0 0.0 0 0.0 1 3.7 0 0.0
Rank 3: some risk –
Rank 4: high risk
0 0.0 5 12.8 2 7.4 2 22.2
Rank 4: high risk –
Rank 2: unknown risk
0 0.0 0 0.0 1 3.7 0 0.0
Abbreviation: PAE: prenatal alcohol exposure
Specific aims 1 and 2: Pairwise concordance/
discordance of FASD diagnostic outcomes
FASD diagnoses (FAS, PFAS, SE/AE, ND/AE, Not
FASD/AE) were 100% concordant between
monozygotic twin pairs, but only 56.4% concordant
among dizygotic twin pairs (Table 4). This closely
mirrored the proportion of the genome shared
between twin pairs (monozygotic 100%; dizygotic
56%).
The prevalence of pairwise concordance in FASD
diagnoses decreased significantly and linearly as
the proportion of genome shared between siblings
decreased across the 4 study groups (100% among 9
monozygotic twin pairs sharing 100% of their
genome; 56.4% among 39 dizygotic twin pairs sharing
50% of their genome; 40.7% among 27 pairs of
full-siblings sharing 50% of their genome; and 22.2%
among 9 pairs of half-siblings sharing 25% of their
genome) (Chi2 linear trend = 1.7, p = 0.001) (Table 4
and Figure 2). When looking at the sub components
that define FASD (growth
deficiency, FAS facial phenotype, and CNS
structural and/or functional abnormalities), the
prevalence of pairwise discordance in the 4-Digit
Rank for each of these components increased across
the 4 groups as the proportion of genome shared
between siblings decreased (Table 4 and Figure 2). It
is interesting to note that the prevalence of
pairwise discordance in the Face Rank was the only
component that increased significantly and linearly
as the proportion of genome shared between
siblings across the four groups decreased. The Rank 4
FAS facial phenotype, as defined by the 4-Digit Code,
is the only component of FASD that is confirmed to
be specific to (caused only by) PAE [7]. Other
prenatal and postnatal risks can impact growth and
brain development, but only PAE can cause the FAS
facial phenotype. Thus, even though the prevalence of
pairwise discordance in the Postnatal Risk Rank
increased significantly across the 4 groups
(monozygotic: 0%; dizygotic: 12.8%; full-sibling:
13.0%; and half-sibling: 25.0%) (Table 3 and Figure
2), discordance in postnatal risk factors
11. Advances in Pediatric Research 11 Hemingway et al. 2019 | 5 : 23
cannot influence the pairwise discordance observed
in Face Ranks. It is also interesting to note that the
proportion of twin and sibling pairs within each
study group that have the same (concordant) Face
Ranks closely matches the proportion of the genome
shared between the twin and sibling pairs within
each study group (Figure 2).
There was no evidence in this study population that
gender influenced the severity or pairwise
discordance of FASD diagnostic outcomes. The
severity of the FASD diagnosis was comparable
between males and females across the entire study
sample (n = 168) (Chi2 = 5.4, p = 0.14).
Among the 19 dizygotic twins with discordant
genders:
The female had a more severe FASD outcome
than the male in 31.6% of the pairs (6/19).
The male had a more severe FASD outcome than
the female in 26.3% of the pairs (5/19).
The male and female had the same FASD
outcome in 42.1% of the pairs (8/19).
Figure 2. Twin/Sibling Pairwise Concordance in FASD outcomes and prenatal/postnatal risks. Monozygotic twins, dizygotic
twins, full siblings and half siblings share 100%, 50%, 50% and 25% of their genome respectively as depicted by the first set of
bars. If fetal genetics is modifying the teratogenic impact of PAE, the pattern of pairwise concordance reflected in the bars for
each FASD outcome will more closely resemble the pattern of bars for Genome Shared than the patterns of bars reflecting
pairwise concordance in Alcohol Rank, other Prenatal Risks or Postnatal Risks. The bar patterns across all FASD outcomes are
far more reflective of the pattern of bars for Genome Shared than the pattern of bars for Alcohol Rank, Prenatal Risk Rank or
Postnatal Risk Rank. Although the bar pattern for Postnatal Risk Rank resembles the bar pattern for Face Rank, discordance in
postnatal risk factors cannot be contributing to discordance in Face Rank because only prenatal factors can impact facial
morphology. Since the FAS facial phenotype, as defined by the 4-Digit Code, is so specific to (caused only by) PAE, the most
compelling evidence supporting the role genetics plays in modifying the teratogenic impact of PAE is illustrated in how highly
correlated the bar patterns are between Genome Shared and Face Rank and how poorly correlated the bar patterns are between
Face Rank and Alcohol Rank (especially between monozygotic and dizygotic twins with virtually identical PAE).
Specific aims 1 and 2: Pairwise concordance/
discordance of FASD diagnostic outcomes
FASD diagnostic discordance: Since there was
100% diagnostic concordance between
monozygotic twin pairs, this analysis focused on
the 39 dizygotic twin pairs. Despite virtually
identical PAE, 4 of the 39 dizygotic twin pairs had
FASD diagnostic contrasts as large as PFAS vs
ND/AE (Table 4). The sibling in each sibling pair
with PFAS experienced severe CNS functional
and/or structural abnormalities (i.e., the 3rd digit in
their 4-Digit Code was Rank 3 or 4) while their co-
twin experienced low to moderate CNS dysfunction
dizygotic twins (4344 vs 2324, 1343 vs 1123). The
four twin pairs had virtually identical PAE, were
raised together, and had reportedly comparable
prenatal and postnatal experiences (e.g., prenatal
tobacco exposure, prenatal exposure to illicit drugs,
multiple home placements, neglect, and/or physical/
sexual abuse). In other words, their contrasts in
FASD outcomes would appear to better-explained
by their discordant genetic vulnerability to PAE,
than their discordant environmental influences.
12. Advances in Pediatric Research 12 Hemingway et al. 2019 | 5 : 23
Table 4. Prevalence of FASD diagnostic concordance and discordance between twin and sibling pairs.
Concordance and Discordance
in FASD Outcomes between
Twin and Sibling Pairs
Monozygotic Dizygotic Full-siblings Half-siblings
N = 18 (9 pairs) N = 78 (39 pairs) N = 54 (27 pairs) N = 18 (9 pairs)
N Pairs valid% N Pairs valid% N Pairs valid% N Pairs valid%
Pairwise FASD Diagnoses (FAS, PFAS, SE/AE, ND/AE, Not FASD/AE)
Concordant outcomes between sibling pairs
Total concordant pairs 9 100.0 22 56.4 11 40.7 2 22.2
FAS-FAS 2 22.2 0 0.0 0 40.7 0 0.0
PFAS-PFAS 0 0.0 0 0.0 0 0.0 0 0.0
SE/AE-SE/AE 4 44.4 4 10.3 2 7.4 0 0..0
ND/AE-ND/AE 2 22.2 16 41.0 6 22.2 2 22.2
Not FASD/AE-Not FASD/AE 1 11.2 2 5.1 3 11.1 0 0.0
Discordant Ranks between sibling pairs
*Total discordant pairs 0 0.0 17 43.6 16 59.3 7 77.8
FAS-PFAS 0 0.0 1 2.6 0 0.0. 0 0.0
FAS-SE/AE 0 0.0 0 0.0 0 0.0 1 11.1
# FAS-ND/AE 0 0.0 0 0.0 2 7.4 0 0.0
PFAS-SE/AE 0 0.0 0 0.0 1 3.7 1 11.1
# PFAS-ND/AE 0 0.0 4 10.3 2 7.4 1 11.1
SE/AE-ND/AE 0 0.0 7 17.5 5 18.5 4 44.4
SE/AE-Not FASD/AE 0 0.0 0 0.0 2 7.4 0 0.0
ND/AE-Not FASD/AE 0 0.0 5 12.8 2 7.4 0 0.0
Not FASD/AE-Not FASD/AE 0 0.0 0 0.0 2 7.4 0 0.0
Pairwise FASD Diagnostic Features
Discordant outcomes between sibling pairs
Growth Ranks 1-4 ***1 11.1 17 43.6 10 37.0 4 44.4
**Face Ranks 1-4:
Total discordant pairs
0 0.0 10 25.6 8 29.6 5 55.6
Face Rank 1 vs 4 0 0.0 0 0.0 0 0.0 0 0.0
Face Rank 2 vs 4 0 0.0 1 2.6 1 3.7 2 22.2
Face Rank 3 vs 4 0 0.0 0 0.0 2 7.4 0 0.0
13. Advances in Pediatric Research 13 Hemingway et al. 2019 | 5 : 23
CNS Ranks 1-4:
probability of structural abnormality
(none, possible, probable, definite)
***1 11.1 17 43.6 14 51.9 5 55.6
Alcohol Ranks 3-4 0 0.0 0 0.0 0 0.0 0 0.0
CNS Functional Ranks 1-3:
(no, moderate, severe dysfunction)
0 0.0 17 43.6 10 37.0 5 55.6
Microcephaly
(head circumference <= 3rd
percentile)
***1 11.1 2 5.1 5 18.5 3 33.3
Seizure disorder 0 0.0 4 10.3 1 3.7 1 11.1
Linear trend across 4 study groups: MH Chi2
: *10.7, p 0.001; ** 5.1, p 0.02. *** One twin pair had discordant
growth Ranks in their 4-Digit Codes (3244-1244). Another pair had discordant CNS structural Ranks (1243-1233)
because only one twin presented with microcephaly. Their CNS functional Ranks, however, were both Rank 3.
These contrasts in a single component of the 4-Digit Code did not result in discordant FASD diagnostic
classifications. Both twin pairs had concordant diagnoses of SE/AE. #Large contrast in pairwise FASD diagnostic
outcomes
Four full-sibling pairs and one half-sibling pair also
experienced large contrasts in FASD diagnoses
(FAS vs ND/AE: 4-Digit Codes: 3443 vs 1223 and
3343 vs 1123) and PFAS vs ND/AE: 4-Digit Codes:
2434 vs 2324; 1443 vs 1323 and 2324 vs 4344)
(Table 4). And like the dizygotic twins described
above, these five sibling pairs had the same
Prenatal Alcohol Ranks, were raised together, and
had reportedly comparable prenatal and postnatal
experiences (e.g., prenatal tobacco exposure,
prenatal exposure to illicit drugs, multiple home
placements, neglect, and/or physical/sexual abuse).
Once again, their contrasts in FASD outcomes
would appear to better-explained by their
discordant genetic vulnerability to PAE, than their
discordant environmental influences.
FAS facial phenotype discordance: The 4-Digit
Code ranks the magnitude of expression of the FAS
facial phenotype on a 4-point Likert scale (Rank 1:
absent; Rank 2: mild; Rank 3: moderate; Rank 4:
severe) (Figure 1A). As the proportion of genome
shared between siblings decreased from 100% to
50% to 50% to 25% across the four groups (9
monozygotic, 39 dizygotic, 27 full-sibling and 9
half-sibling pairs, respectively), the prevalence of
pairwise discordance in the FAS Facial Rank
increased from 0.0% to 25.6% to 29.6% to 55.6%
(Table 4). The prevalence of concordance in Facial
Rank across the four groups closely followed the
proportion of genome shared between siblings
across the four groups (Figure 2).
Since the Rank 4 FAS facial phenotype, as defined
by the 4-Digit Code, is the only FASD physical
feature confirmed to be highly specific to (caused
only by) PAE [7] it is interesting to document the
prevalence of pairwise discordance (if any)
involving the Rank 4 FAS facial phenotype (Table
4).
Two of the nine monozygotic twin pairs presented
with the Rank 4 FAS facial phenotype. Both twins
in each pair presented with concordant Rank 4
faces. Three of the 39 dizygotic twin pairs
presented with the Rank 4 FAS facial phenotype;
two pairs presented with concordant Rank 4 facial
phenotypes and one pair presented with discordant
Face Ranks (Rank 4 vs Rank 2). One twin in the
discordant dizygotic twin pair presented with PFAS
and a Rank 4 FAS facial phenotype. All three facial
features of FAS were present—short PFLs, smooth
philtrum and thin upper lip (mean PFL z-score -3.5,
philtrum smoothness Rank 5, upper lip thinness
Rank 4). In contrast, the co-twin presented with
ND/AE and a Rank 2 Facial Phenotype. Only one
of the three FAS facial features was present—a thin
upper lip (mean PFL z-score -1.8, philtrum
smoothness Rank 3, upper lip thinness Rank 4).
The Rank 4 facial phenotype was also observed
among full-siblings and half-siblings (Table 4).
Three of the 27 full-sibling pairs presented with the
Rank 4 facial phenotype—all three pairs were
discordant (Face Ranks 2 vs 4 and Face Ranks 3 vs
4). The Rank 4 facial phenotype was also observed
in two of the 9 half-sibling pairs—both pairs had
discordant Face Ranks (Face Ranks 2 vs 4). Even
though the Alcohol Ranks were concordant for each
of these five full-sibling and half-sibling pairs, this
does not ensure that the day-to-day level of PAE
was identical between each sibling pair.
14. Advances in Pediatric Research 14 Hemingway et al. 2019 | 5 : 23
Specific aim 4: Heritability
Comparing pairwise discordance in FASD
outcomes for monozygotic versus dizygotic twins
allows an indirect estimate of the importance of
genetic factors in modifying the teratogenic effects
of PAE in this study sample. Percent heritability
(((dizygotic discordance minus monozygotic
discordance) / dizygotic discordance) *100) for
different FASD outcomes in the current study were
as follows:
FASD Diagnosis (FAS, PFAS, SE/AE, ND/AE, Not
FASD/AE):
((0.436 – 0.00) / 0.436)*100 = 100%
FAS Facial Rank:
((0.256 - 0.0) / 0.256)*100 = 100%
Growth Rank:
((0.436 – 0.111)/0.436)*100 = 74.5%
CNS 1-4 Rank:
((0.436 – 0.111)/0.436)*100 = 74.5%
Monozygotic twin pairs in this study had virtually
identical genomes and virtually identical PAE.
Under those genetic-environmental conditions, their
FASD diagnoses and FAS facial phenotype Ranks
were identical (0% discordant). In contrast, the
dizygotic twin pairs in this study had virtually
identical PAE, but shared only 50% of their
genomes. Under those genetic-environmental
conditions, 43.6% of the twin pairs had discordant
FASD diagnoses and 25.6% had discordant FAS
Facial phenotype Ranks. Based on these
discordance rates for the monozygotic and
dizygotic twin pairs, heritability estimates for the
FASD diagnosis and the FAS Facial Rank were
both 100%. In other words, essentially all of the
discordance observed between twin pairs for these
two outcomes appears to be due to differences in
their genotypes, not differences in their
environmental risk factors.
Heritability estimates for the Growth Rank and the
CNS 1-4 Rank were both 74.5%, signifying that the
Growth and CNS Ranks were determined by a
combination of genetic and environmental factors.
Although the prenatal environmental factor PAE
was virtually identical between the twin pairs, PAE
was not the only environmental risk factor in this
study that could adversely impact growth and CNS
development. Other prenatal risk factors like
prenatal exposure to tobacco and other illicit drugs
can impact growth and CNS development, but they,
like PAE were virtually identical between the twin
pairs. Thus, it is unlikely that these other prenatal
risk factors explain the discordance in growth and
CNS development observed between the twin pairs.
On the other hand, postnatal environmental risk
factors like neglect, abuse, and multiple home
placements can adversely impact a child’s growth
and CNS development and did vary slightly
between the dizygotic twin pairs—5 of the 39
dizygotic pairs had discordant Postnatal Risk Ranks
(Table 3). But a much higher number of dizygotic
pairs had discordant Growth Ranks (n = 17) and
discordant CNS 1-4 Ranks (N = 17) (Table 4).
More specifically, not all 5 dizygotic pairs with
discordant Postnatal Risk Ranks had discordant
Growth or CNS 1-4 Ranks. Only 2 of the 5 pairs
had discordant Growth Ranks and only 3 of the 5
pairs had discordant CNS 1-4 Ranks. Stated another
way, only 2 (12%) of the 17 dizygotic pairs with
discordant Growth Ranks had discordant Postnatal
Ranks, and only 3 (18%) of the 17 dizygotic pairs
with discordant CNS1-4 Ranks had discordant
Postnatal Ranks. Thus, as the heritability estimates
suggest, variations in the Growth and CNS 1-4
Ranks appeared to be influenced by both genetic
and environmental factors. Overall, the heritability
estimates generated for the growth (74.5%), FAS
face (100%) and CNS (74.5%) components of
FASD are reflective of the fact that growth and
CNS development are susceptible to a multitude of
prenatal and postnatal environmental risk factors,
whereas the FAS facial phenotype is highly specific
to early prenatal exposure to alcohol.
If fetal genotype is modifying the teratogenic
impact of PAE, the prevalence of pairwise
concordance across FASD outcomes would more
closely reflect the percent of genome shared
between sibling pairs than the pairwise concordance
of PAE and other prenatal and postnatal risk factors.
This is illustrated graphically In Figure 2 and Table
4. Monozygotic twins, dizygotic twins, full siblings
and half siblings share on average 100%, 50%, 50%
and 25% of their genome respectively as depicted
by the first set of bars. The pattern of pairwise
concordance reflected in the bars for each FASD
outcome more closely resemble the pattern of bars
for Genome Shared than the patterns of bars
reflecting pairwise concordance in Alcohol Rank,
other Prenatal Risks, or Postnatal Risks. Since the
FAS facial phenotype, as defined by the 4-Digit
Code, is so highly specific to (caused only by) PAE,
the most compelling evidence supporting the role
15. Advances in Pediatric Research 15 Hemingway et al. 2019 | 5 : 23
genetics plays in modifying the teratogenic impact
of PAE is illustrated in how highly correlated the
bar patterns are between Genome Shared and Face
Rank and how poorly correlated the bar patterns are
between Face Rank and Alcohol Rank (especially
between monozygotic and dizygotic twin pairs with
virtually identical PAE).
Discussion
Fetal genotype modifies the teratogenic effects of
PAE
The outcomes of this study provide conclusive
evidence that fetal genotype can modify the
teratogenic effects of PAE. When twin pairs with
virtually identical PAE were genetically identical,
their FASD diagnoses were identical. When twin
pairs with virtually identical PAE were genetically
different, their FASD diagnoses were often different
(44% presented with discordant FASD diagnoses).
And when their diagnoses were discordant, the
magnitude of discordance was extreme 10% of the
time. For example, four of the 39 pairs of dizygotic
twins were born at opposite ends of the fetal
alcohol spectrum (PFAS and ND/AE), despite
virtually identical PAE. Finally, as the proportion of
genome shared between siblings decreased from
100% to 50% to 50% to 25% across the four study
groups (monozygotic, dizygotic, full-sibling and
half-sibling pairs respectively), the prevalence of
pairwise discordance in FASD diagnoses increased
linearly from 0% to 44% to 59% to 78%.
The prevalence of pairwise concordance in FASD
diagnoses observed in our 48 twin pairs
(monozygotic 100%, dizygotic 56%) was
comparable to the prevalence of concordance
observed in 16 twin pairs (monozygotic 100%,
dizygotic 64%) reported by Streissguth and
DeHaene [6] back in 1993—the only other FASD
twin group study published to date. The 16 twin
pairs (5 monozygotic and 11 dizygotic) were born
to alcohol-abusing mothers from two countries (the
United States and France). The study population
included 11 Caucasian and 5 Native American twin
pairs ranging in age from 1.5 to 30 years. The study
was conducted prior to the creation of rigorous,
case-defined FASD diagnostic systems. Patients
were diagnosed as FAS or Fetal Alcohol Effects
(FAE) in accordance with gestalt approach to
diagnosis published by Clarren and Smith in 1978
[12]. Thirty-nine percent had FAS, 19% had FAE
and 42% were alcohol exposed but unaffected. The
higher concordance observed in their dizygotic twin
pairs will be due in part to the fact that concordance
in a study using only two FASD diagnoses (FAS
and FAE) will always be higher than concordance
in a FASD diagnoses (FAS, PFAS, SE/AE, and
ND/AE). Over the years, the outcomes of ten
additional twin pairs with PAE have been
published as single-case studies [13-20]. Formal
FASD diagnostic evaluations were rarely
conducted, but the clinical descriptions of the twin
pairs were consistent with monozygotic twin pairs
having more concordant outcomes than dizygotic
twin pairs.
Similar to humans, evidence of genetic
modification of FASD outcomes also come from
animal studies. For example, a study by Debelak
and Smith [21] examined 11 genetic strains of chick
embryos following ethanol exposure during early
neurulation and found that the strains could be
classified into very sensitive, moderately sensitive,
or insensitive to ethanol-induced apoptosis of
cranial neural crest cells, which give rise to facial
structures. Comprehensive reviews on the genetics
of FASD are presented by Mead and Sarkar [4] and
Eberhart and Parnell [5].
Discordance in the FAS facial phenotype
It is interesting to note the rather high prevalence of
pairwise discordance (43.6%) in FASD diagnoses
among dizygotic twins in this study, despite
virtually identical PAE. It is clear that discordance
in PAE does not explain their discordant FASD
diagnoses, but are there factors other than PAE that
may explain the discordance? FASD is
characterized by growth deficiency, a specific
cluster of minor facial anomalies, and abnormal
CNS structure and/or function. Only the Rank 4
FAS facial phenotype, as defined by the 4-Digit
Code, is confirmed to be specific to (caused only
by) PAE [7]. The FAS facial phenotype is not
caused by other prenatal and postnatal risk factors.
In contrast, growth deficiency and CNS structural/
functional abnormalities can be caused by a
multitude of other prenatal and postnatal risk
factors. Despite efforts to minimize postnatal
contrasts between the twin pairs in this study (Table
3 and Figure 1), some of the pairwise discordance
in growth and CNS outcomes used to generate the
FASD diagnoses is likely explained, in part, by
discordant postnatal risk factors.
16. Advances in Pediatric Research 16 Hemingway et al. 2019 | 5 : 23
Documenting the prevalence of discordance (if any)
for the Rank 4 FAS facial phenotype is of particular
interest because the Rank 4 FAS facial phenotype is
so highly specific to PAE [7]. If identical PAE can
result in discordant Rank 4 facial phenotypes
between twin pairs, this would further strengthen
the evidence that genes are modifying the
teratogenic impact of PAE. Since the FAS facial
phenotype requires PAE in a very narrow window
of time (during the gastrulation period of fetal
development) [22,23], the only pairwise
discordance in Rank 4 facial phenotypes that would
be meaningful (that could be validly interpreted)
would be among monozygotic and dizygotic twin
pairs—the only two groups where the timing of
PAE can be confirmed to be virtually identical on a
day-to-day basis between twin pairs.
Two of the nine monozygotic twin pairs presented
with Rank 4 FAS facial phenotypes. Both twins in
each pair presented with concordant Rank 4 faces.
Three of the 39 dizygotic twin pairs presented with
Rank 4 FAS facial phenotypes; two pairs presented
with concordant Rank 4 faces and one pair
presented with discordant Face Ranks (Rank 4 vs
Rank 2). The twin pair with discordant Face Ranks
presented as follows: Twin 1: PFAS, Face Rank 4,
all three of the FAS facial features (mean PFL z-
score -3.5, philtrum smoothness Rank 5, upper lip
thinness Rank 4). Twin 2: ND/AE, Face Rank 2,
only 1 of the 3 FAS facial features—a thin upper lip
(mean PFL z-score -1.8, philtrum smoothness Rank
3, upper lip thinness Rank 4). The work by Das et
al., [24], presented below, provides a compelling
genetic explanation for why Face Ranks were
always concordant among monozygotic twins, but
occasionally discordant among dizygotic twins.
Das et al., [24] reported a significant gene-
environment interaction explaining variation in
facial morphology associated with ethanol use in
pregnancy. Genetic diversity in ethanol
metabolizing enzymes occurs in the general
population. Ethanol is metabolized to acetaldehyde
by two enzyme systems: the microsomal ethanol
oxidizing system and alcohol dehydrogenase
(ADH) [25,26]. The presence of the ADH1B*3
allele has been found to be protective for offspring
neurodevelopmental and growth outcome after
maternal ethanol consumption in pregnancy [27]. In
2004, Das et al. [24] demonstrated that among
African American women and their offspring, the
presence of an ADH1B*3 allele was protective for
the effects of maternal ethanol ingestion during
pregnancy on infant facial formation. The
protective effect demonstrated was present with the
allele present in only the mother, only the infant, or
both the mother and the infant. Exposure to ethanol
and absence of the ADH1B*3 allele in both the
mother and infant resulted in significant reductions
in three facial measurements obtained from infant
facial photographs-palpebral fissure length, inner
canthal distance and the distance from the bridge of
the nose to the bottom of the upper lip. Based on
the findings of Das et al., [24] one could speculate
that discordant FAS Face Ranks could occur in
dizygotic twins (as observed in our study) if the
ADH1B*3 allele was absent in the mother and one
twin, but present in the other twin. Based on the
same line of reasoning, one would expect
monozygotic twins to always present with
concordant Face Ranks (as was observed in our
study). Replication of the Das et al., study using a
study population of monozygotic and dizygotic
twins with PAE would greatly advance our
understanding how the ADH1B*3 allele modifies
the teratogenic impact of PAE.
Implications for public health messaging and
setting FASD diagnostic exposure thresholds
Despite virtually identical PAE, 4/39 (10%)
dizygotic twin pairs had FASD diagnostic contrasts
as large as PFAS vs ND/AE. The four twin pairs
had virtually identical PAE, were raised together,
and had reportedly identical prenatal and postnatal
experiences (e.g., prenatal tobacco, illicit drug
exposure, home placements, physical/sexual abuse).
In other words, their contrasts in FASD outcomes
would appear to better-explained by their
discordant genetic vulnerability to PAE, than their
discordant environmental influences. These 4 twin
pairs provide powerful evidence that what may be
construed in public health messaging (and some
FASD diagnostic guidelines [28-30] as a safe level
of exposure for one fetus, may very well place
another fetus at significant risk. Not only can the
same level of PAE cause strikingly different
outcomes in two fetuses, but PAE reportedly below
the threshold of exposure required by some FASD
diagnostic guidelines can result in full FAS (See
Figure 2 in Astley, et al., [31]). Thus, as stated by
the U.S. Centers for Disease Control and Prevention
[32] “There is no guaranteed safe level of alcohol
use at any time during pregnancy. Fetal alcohol
spectrum disorders are completely preventable if a
woman does not drink during pregnancy.”
17. Advances in Pediatric Research 17 Hemingway et al. 2019 | 5 : 23
Potential limitations
Zygosity classification: Twins were classified as
monozygotic or dizygotic for this study based on
clinical and social service records shared with the
FASDPN clinic at the time of their FASD
evaluation. It is unknown how many twin pairs had
zygosity confirmed through DNA genotyping.
While there remains a small chance that one or
more twin pairs in this study have their zygosity
misclassified, a study of 578 twin pairs conducted
by the National Academy of Sciences found parent
report of zygosity was confirmed accurate by DNA
genotyping over 95% of the time [33]. When
misclassification occurred, it was most likely to
occur among monozygotic twins who were not
strikingly similar in appearance and thus incorrectly
classified as dizygotic. This direction of error
would lead to more conservative estimates of
heritability. In the current study, all monozygotic
twins looked identical and all dizygotic twins were
easily distinguished from one another.
Do twins share identical prenatal environments?
Not necessarily. It is for that reason the prenatal
environments and PAE shared between our 48 twin
pairs is described throughout this study as virtually
identical. How twins experience the prenatal
environment depends, in part, on chorionicity, i.e.,
whether twins share a single chorion
(monochorionic) or have separate chorions
(dichorionic). Monozygotic twins can be mono- or
dichorionic, whereas dizygotic twins are dichorionic
[34]. The chorionicity of the 9 monozygotic twin
pairs in the current study was unknown. The chorion
is the outer-most fetal membrane that contains the
amnion/amniotic sac. The amnion is the thin inner-
most fetal membrane that protects the
embryo/fetus and contains amniotic fluid. The
chorion connects the amnion, amniotic sac, and the
fetus to the placenta and contributes to placental
development. Thus, if twins share a chorion (e.g.,
are monochorionic) they will share a single placenta,
whereas twins with separate chorions (e.g.,
dichorionic) develop individual placentas. Dizygotic
twins are dichorionic, since they form from two
separately fertilized eggs. Among Caucasian
populations, total twinning rates were estimated at
15–16 per 1,000 in 2003 [35]. In Caucasian
populations, monozygotic twins comprise ~26% of
all twins. For Caucasian populations about 17% of all
twin pairs are monozygotic-monochorionic, ~9%
are monozygotic-dichorionic and ~74% are
dizygotic- dichorionic. All twins can be expected
to have many kinds of in-utero differences,
such as placental flow in monozygotic twins
and the amount of microchimerism in dizygotic
twins [36]. The greatest risk associated with
monochorionic placentation is related to the structure
of blood vessels. One twin typically has better
placement and therefore receives more of the
nutrients [34]. The placenta also functions as a
barrier, allowing small molecules (e.g., gases,
nutrients, waste material, antibodies) to pass
between mother and child through passive transport
[37,38]. Other small molecules that can impact fetal
development (e.g., some maternal hormones like
cortisol; bacteria; teratogens such as alcohol) can also
be diffused through the placenta [37,39]. Unequal
placental sharing is a major cause of fetal growth
discordance in monozygotic twins [40]. It is
interesting to note that one of the few occurrences of
discordant outcomes between monozygotic twins in
the current study was discordant growth in one
twin pair (Growth Rank 3 versus Growth Rank
1). Both twins had concordant weight percentiles
(ranging from the 20th to 40th percentiles) at
birth and 2 years of age. Height percentiles,
however, were significantly discordant. One twin
was significantly shorter (1st and 10th percentiles at
birth and 2 years of age) than the other (20th and
60th percentiles at birth and 2 years of age). All in
all, while prenatal environments, including level of
PAE, are not necessarily 100% identical between twin
pairs, the near perfect match between percent of
genome shared and FASD diagnostic concordance
(monozygotic twins: 100% genome shared and
100% FASD concordance; dizygotic twins: 50%
genome shared, 56% FASD concordance) suggests
the prenatal environments and PAE levels in our
48 twin pairs were virtually identical.
Conclusion
Not all fetuses are equally vulnerable to the adverse
effects of prenatal alcohol exposure. Risk is not just
dependent on timing and level of exposure. Fetal
genetics plays an important role. As demonstrated
in this study, despite virtually identical prenatal
alcohol exposures, two fetuses can experience
vastly different FASD outcomes. So which fetus is
genetically vulnerable? We currently have no way
of knowing. Thus, to protect all fetuses, especially
the most genetically vulnerable, the only safe
amount to drink is none at all.
18. Advances in Pediatric Research 18 Hemingway et al. 2019 | 5 : 23
Ethical Approval
This study was approved by the University of
Washington Human Subjects Division.
Author Contribution
All authors are members of the interdisciplinary
FASD diagnostic team and participated in the
interpretation and reporting of the study’s
outcomes. SJAH conducted the statistical analyses.
Acknowledgements
The Washington State FASDPN has been supported
over the past 27 years by the following institutions:
Centers for Disease Control and Prevention
(1992-1997); Western Washington Chapter of the
National March of Dimes Birth Defects Foundation
(1995); Washington State Department of Social and
Health Services, Division of Alcohol and Substance
Abuse (1997-present); the Chavez Memorial Fund
(2002-present) and the Center on Human
Development and Disability, University of
Washington (1993 to present).
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