Evaluation of Brain Alterations and Behavior in Children With Low Levels of Prenatal Alcohol Exposure

Xiangyu Long; Catherine Lebel

doi:10.1001/jamanetworkopen.2022.5972

. 2022 Apr 5;5(4):e225972. doi: 10.1001/jamanetworkopen.2022.5972

Evaluation of Brain Alterations and Behavior in Children With Low Levels of Prenatal Alcohol Exposure

Xiangyu Long ^1,^2,³, Catherine Lebel ^1,^2,^3,^✉

¹Department of Radiology, University of Calgary, Calgary, Alberta, Canada

²Alberta Children’s Hospital Research Institute, Calgary, Alberta, Canada

³Hotchkiss Brain Institute, University of Calgary, Calgary, Alberta, Canada

Accepted for Publication: February 17, 2022.

Published: April 5, 2022. doi:10.1001/jamanetworkopen.2022.5972

^✉

Corresponding Author: Catherine Lebel, PhD, B4-513, Alberta Children’s Hospital Research Institute, 28 Odi Dr NW, Calgary, AB T3B 6A8, Canada (clebel@ucalgary.ca).

Author Contributions: Drs Long and Lebel had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis.

Concept and design: Both authors.

Acquisition, analysis, or interpretation of data: Both authors.

Drafting of the manuscript: Long.

Critical revision of the manuscript for important intellectual content: Both authors.

Statistical analysis: Long.

Obtained funding: Lebel.

Administrative, technical, or material support: Lebel.

Supervision: Lebel.

Conflict of Interest Disclosures: Dr Lebel reported receiving grants from the Canada Research Chair program during the conduct of the study. No other disclosures were reported.

Funding/Support: This study was supported by the University of Calgary I3T program (Dr Long) and the Canada Research Chair program (Dr Lebel).

Role of the Funder/Sponsor: The sponsors had no role in the design and conduct of the study; collection, management, analysis, and interpretation of the data; preparation, review, or approval of the manuscript; and decision to submit the manuscript for publication.

Disclaimer: This article reflects the views of the authors and does not necessarily reflect the opinions or views of the NIH or ABCD study investigators.

Additional Information: Data used in the preparation of this article were obtained from the Adolescent Brain Cognitive Development (ABCD) study (https://abcdstudy.org), held in the National Institute of Mental Health Data Archive (NDA). A full list of supporters is available at https://abcdstudy.org/federal-partners.html. A listing of participating sites and a complete listing of the study investigators can be found at https://abcdstudy.org/consortium_members/. ABCD study investigators designed and implemented the study and/or provided data but did not necessarily participate in the analysis or writing of this report. The ABCD study data repository grows and changes over time. The ABCD study data used in this report came from http://dx.doi.org/10.15154/1503209.

^✉

Corresponding author.

PMCID: PMC8984786 PMID: 35380644

This cross-sectional study examines altered brain structure and function in children with low levels of prenatal alcohol exposure compared with well-matched unexposed children.

Key Points

Question

How do brain structure and behavior of children with low levels of prenatal alcohol exposure (PAE) differ compared with those of a well-matched control group of children?

Findings

In this cross-sectional study of 135 children with low levels of PAE and 135 unexposed controls, children with PAE had worse externalizing behavior scores and lower fractional anisotropy in several white matter areas of the brain compared with children in the control group. Higher fractional anisotropy was associated with less problematic behavior in the control group, but no association was found in the PAE group.

Meaning

These findings suggest that even small amounts of PAE are associated with structural brain alterations, highlighting the importance of evidence-based policy making and underscoring the need to consider prenatal exposures in future studies of pediatric brain development.

Abstract

Importance

High levels of prenatal alcohol exposure (PAE) are associated with widespread behavioral and cognitive problems as well as structural alterations of the brain. However, it remains unclear whether low levels of PAE affect brain structure and function, and prior studies generally have not had well-matched control populations (eg, for sociodemographic variables).

Objective

To compare structural brain alterations and behavioral changes in children with lower levels of PAE with those of well-matched controls with no PAE.

Design, Setting, and Participants

In this cross-sectional study, participants were selected from the Adolescent Brain Cognitive Development study. Children with PAE were compared with controls matched for age, sex, family income, maternal educational level, and caregiver status. Neither group had prenatal exposure to other adverse substances (eg, tobacco, cannabis, illicit drugs). Data were collected from September 1, 2016, to November 15, 2018, and analyzed from October 14, 2020, to February 14, 2022.

Exposures

Diffusion tensor imaging, resting-state functional magnetic resonance imaging (MRI), and Child Behavior Checklist (CBCL) administration.

Main Outcomes and Measures

Fractional anisotropy (FA); mean, axial, and radial diffusivity from diffusion tensor imaging; brain functional signal variations from functional MRI; and several scores, including internalizing and externalizing behavior problems, from the CBCL. Spearman correlation coefficients between diffusion tensor imaging and functional MRI measures and the CBCL scores were calculated.

Results

A total of 270 children were included in the analysis (mean [SD] age, 9.86 [0.46] years; 141 female [52.2%] and 129 male [47.8%]), consisting of 135 children with PAE (mean [SD] age, 9.85 [0.65] years; 73 female [54.1%] and 62 male [45.9%]) (mean exposure, 1 drink/wk) and 135 unexposed controls (mean [SD] age, 9.87 [0.04] years; 68 female [50.4%] and 67 male [49.6%]). Children with PAE had lower mean (SD) FA in white matter of the left postcentral (0.35 [0.05] vs 0.36 [0.04]; mean difference, −0.02 [95% CI, −0.03 to −0.01]), left inferior parietal (0.31 [0.07] vs 0.33 [0.06]; mean difference, −0.03 [95% CI, −0.04 to −0.01]), left planum temporale (0.26 [0.04] vs 0.28 [0.03]; mean difference, −0.02 [95% CI, −0.03 to −0.01]), left inferior occipital (0.30 [0.07] vs 0.32 [0.05]; mean difference, −0.03 [95% CI, −0.04 to −0.01]), and right middle occipital (0.30 [0.04] vs 0.31 [0.04]; mean difference, −0.01 [95% CI, −0.02 to −0.01]) areas compared with controls, and higher FA in the gray matter of the putamen (0.22 [0.03] vs 0.21 [0.02]; mean difference, 0.01 [95% CI, 0.005-0.02]). Externalizing behavior scores were higher (worse) in children with PAE than in controls (mean [SD], 45.2 [9.0] vs 42.8 [9.0]; mean difference, 2.39 [95% CI, 0.30-4.47]). Several of these regions had significant group-behavior interactions, such that the higher FA was associated with less problematic behaviors in controls (ρ range, −0.24 to −0.08) but no associations were present in the PAE group (ρ range, 0.02-0.16).

Conclusions and Relevance

In this cross-sectional study, children with low levels of PAE had lower FA and more behavioral problems compared with a well-matched control group. These results suggest that PAE, even in small amounts, has a measurable effect on brain structure in children.

Introduction

Nearly 10% of pregnant individuals report consuming alcohol,¹ which can adversely affect fetal development and lead to a variety of physical, behavioral, and neurological deficits.² Heavy prenatal alcohol exposure (PAE) is associated with a diagnosis of fetal alcohol spectrum disorder (FASD), a neurodevelopmental disorder that includes lifelong cognitive and behavioral difficulties.^2,3 Prenatal alcohol exposure is also is associated with an increased risk of mental health problems; more than 90% of individuals with FASD have a co-occurring mental illness.⁴

Using magnetic resonance imaging (MRI), disrupted brain structure and function after PAE have been observed. The most common finding is reduced brain volume, which has been observed among individuals ranging from infants to adults.^5,6 Altered white matter microstructure has also been reported across ages using diffusion tensor imaging, although neonates and young children with PAE tend to show lower diffusivity,^7,8 whereas older children, adolescents, and young adults with PAE show higher diffusivity and lower anisotropy^9,10,11 and weaker structural network connectivity¹² than controls. In terms of brain function, increased functional connectivity among motor, brainstem, and thalamic networks have been detected in neonates with PAE.^13,14 In children and adolescents, PAE is associated with disrupted functional connectivity in the default mode network,¹⁵ sensorimotor network,¹⁶ attention and language network,^17,18,19,20 and whole brain network structure.^21,22

Internalizing behaviors (those directed inward such as depression and anxiety) and externalizing behaviors (those directed outward such as aggression and hyperactivity) are more common in children with PAE and can indicate a higher risk of later mental illness.^4,23 In unexposed children and adolescents, these behaviors are related to white matter microstructure,²⁴ cortical thickness,²⁵ and gray matter volumes.^26,27 However, few studies have examined associations between adverse behaviors and brain alterations associated with PAE. One study with a relatively small sample²⁸ showed no association between brain volumes or white matter microstructure and internalizing or externalizing behavior, whereas another study²⁹ found negative correlations between brain volumes and psychopathology and behavioral scores in youths with PAE.

Most previous studies of brain alterations and PAE have focused on individuals with high levels of PAE and/or a diagnosis of FASD (which requires high levels of exposure or the sentinel facial features associated with fetal alcohol syndrome). However, lower levels of PAE can affect cognitive and behavioral function,^30,31 and emerging evidence^29,32 suggests brain volumes and functional connectivity are affected. Dose-dependent associations between the amount of PAE and brain volumes have been reported by several prior studies, providing further evidence that lower levels of exposure may impact brain volumes.^33,34,35 White matter tends to be disproportionately affected by PAE,^5,36 yet it remains unclear how low levels of PAE are associated with white matter microstructure and structural brain connectivity. The lack of evidence of structural changes in the brain associated with low levels of PAE may be part of the reason that many individuals perceive small amounts of PAE as safe during pregnancy. Understanding how low levels of PAE affect brain outcomes is critical for making evidence-based policy recommendations.

Most prior studies of PAE^{28,34,37,38,39,40} have been unable to appropriately control for factors such as family income, educational level, child care situation, and prenatal exposure to other substances owing to small sample sizes. For example, in many studies,^28,34,37 most children with PAE and/or FASD are in adoptive or foster care, whereas the control group primarily resides with biological parents. Many studies^38,39,40 also report lower family income and/or parent educational level in the PAE group compared with controls. Prenatal exposure to other teratogenic substances such as tobacco, cannabis, and illicit drugs often co-occurs with PAE,⁴¹ and these substances are independently associated with brain alterations.^42,43,44 Studies with well-matched controls and alcohol exposure in isolation are critical to better understand the specific effects of PAE.

The aim of the present study was to examine brain structure and function in children with low to average levels of PAE while carefully controlling for potentially confounding factors. We hypothesized that children with PAE would have lower total brain volume, lower fractional anisotropy (FA), and higher functional MRI signal variations compared with unexposed matched controls. Furthermore, we expected correlations between brain metrics and internalizing and externalizing behavioral scores, such that lower FA would be associated with worse behavior.

Methods

Participants

All neuroimaging and cognitive and behavioral data were obtained from the Adolescent Brain Cognitive Development (ABCD) study, release 2.0.1.⁴⁵ This cohort study recruited more than 10 000 children approximately 10 years of age across the US from September 1, 2016, to November 15, 2018. Neuroimaging data include structural MRI, resting-state functional MRI, and diffusion tensor imaging. The ABCD study was approved by a central institutional review board at the University of California, San Diego, with local institutional review board approval for a few sites.⁴⁶ Parents provided written informed consent and children provided informed assent. The present study followed the Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) reporting guideline.

The ABCD Developmental History Questionnaire asked about PAE and prenatal exposure to other substances (tobacco, cannabis, heroin, cocaine, and oxycodone [Oxycontin]).⁴⁷ Using these data, we identified participants whose biological mothers (adoptive parents were excluded owing to potential lack of knowledge of prenatal exposures) answered yes to using alcohol and no to using other substances (tobacco, cannabis, heroin, cocaine, and oxycodone) after awareness of their pregnancy (n = 135). Children whose biological mothers answered no to using alcohol and other substances both before and after awareness of their pregnancy were selected as control participants. Controls were matched to the exposure group on sex, age, maternal educational level, family income, biological parents, and no prenatal exposure to other substances (Table 1). Family income for the past 12 months was measured on a 10-point scale from less than $5000 to greater than $200 000. Maternal educational level was reported on a 21-point scale ranging from never attended school to a doctoral degree.

Table 1. Demographics of the Participants in the Present Study.

Characteristic	PAE group (n = 135)	Matched unexposed controls (n = 135)^a	P value, difference between groups	Cohen d
Age, mean (SD), y	9.85 (0.65)	9.87 (0.04)	.73	0.04
Sex, No. female/male	73/62	68/67	.94	0.07
No. of study sites	22	21	.42	0.01
No. of scanner types	3	3	.94	0.39
Total family income, mean (SD)^b	9 (2)	9 (0)	.18	0.16
Maternal educational level, mean (SD)^c	18 (2)	18 (0)	.50	0.08
Maximum No. of drinks in 1 sitting, mean (SD)	1 (1)	NA	NA	NA
No. of drinks per week, mean (SD)	1 (1)	NA	NA	NA

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Abbreviations: NA, not applicable; PAE, prenatal alcohol exposure.

^{^a}

The unexposed controls were selected to match the PAE group for age, sex, family income, and maternal educational level. Neither group had prenatal exposure to any other adverse substances (eg, tobacco, cannabis, illicit drugs).

^{^b}

Measured on a 10-point scale from less than $5000 to greater than $200 000, with higher scores indicating higher income.

^{^c}

Measured on a 21-point scale ranging from never attended school to a doctoral degree, with higher scores indicating higher educational level.

To assess the quantity of prenatal exposure, we used the answers to: “average drinks per week?” and “maximum drinks in 1 sitting?” after knowing of pregnancy (Table 1). One hundred fourteen of the 135 participants with PAE had information available on drinking quantities.

Behavior Measures

The Child Behavior Checklist (CBCL) was used to assess internalizing and externalizing behaviors.⁴⁷ The summary internalizing, externalizing, and total problem scores, as well as scores of 8 individual scales (Anxious/Depressed, Withdrawn/Depressed, Somatic Complaints, Social Problems, Thought Problems, Attention Problems, Rule-Breaking Behavior, and Aggressive Behavior) were compared between groups. For all participants, behavior measures were collected on the same day as the neuroimaging session.⁴⁷

Neuroimaging

In brief, diffusion tensor imaging preprocessing included corrections for eddy current distortions and head motion. The functional MRI images were preprocessed with head motion correction, normalization, nuisance signal removal (ie, from white matter, ventricles, and the global signal), and band-pass filtering of 0.009 to 0.08 Hz. We corrected T1-weighted images for gradient nonlinearity distortions and intensity inhomogeneity. Cortical surface reconstruction on the T1-weighted images was performed by FreeSurfer brain imaging software, version 5.3 (Harvard University); this was used to calculate total brain volume and create cortical surface-based regions of interest.^45,48 The ASEG atlas from FreeSurfer was used to segment deep gray matter regions.⁴⁹ A more detailed description of ABCD study data processing methods is available elsewhere.⁴⁸

Our analysis used the tabulated MRI measurements of the first time point released from the ABCD study for each participant. Mean FA, mean diffusivity, axial diffusivity, and radial diffusivity were calculated across each of the subadjacent white matter areas of cortical regions from FreeSurfer,⁵⁰ as well as the subcortical gray matter regions. The mean temporal variance of functional MRI blood oxygenation level–dependent signal was calculated within each cortical gray matter Destrieux region.^50,51 We also extracted total brain volume.

Statistical Analysis

Data were analyzed from October 14, 2020, to February 14, 2022. The present study used 2-sample t tests, linear mixed models, and Spearman correlation analysis. Results that were both corrected and uncorrected for false discovery rate at a significance level of 2-sided P < .05 are reported along with mean differences and 95% CIs. Group comparisons between the participants with PAE and unexposed controls were performed on the CBCL scores and MRI measurements of each brain region using a series of 2-sample t tests. Site was included as a random effect for MRI measurements.⁵²

Brain regions with significant group differences in MRI metrics were then examined for associations with CBCL behavior scores. Spearman correlation analysis was performed between MRI metrics and CBCL scores when controlling site as a random effect, then the correlation coefficients were transformed to z scores and compared between groups.

Results

Alcohol Consumption

A total of 270 children (mean [SD] age, 9.86 [0.46] years; 141 female [52.2%] and 129 male [47.8%]) were included in the analysis; 135 children (mean [SD] age, 9.85 [0.65] years; 73 female [54.1%] and 62 male [45.9%]) with PAE were compared with 135 controls (mean [SD] age, 9.87 [0.04] years; 68 female [50.4%] and 67 male [49.6%]). Mean (SD) PAE in the sample was 1 (1) drink/wk. The mean (SD) number of drinks in a single sitting was 1 (1). Most participants’ biological mothers (112 [98.3%]) reported no binge episodes (defined as ≥4 drinks in 1 sitting) during pregnancy. Controls reported no alcohol exposure at any time during pregnancy (before or after pregnancy recognition).

CBCL Scores Related to Prenatal Exposure

Most participants in both the PAE and unexposed control groups scored in the normal range of behaviors (ie, scores <65). The PAE group had significantly elevated (ie, worse) externalizing behavior scores than controls (mean [SD], 45.2 [9.0] vs 42.8 [9.0] ]; mean difference, 2.39 [95% CI, 0.30-4.47]); 2 participants with PAE (1.5%) had clinically elevated externalizing scores (≥65), whereas no controls had clinically elevated scores (eTable 1 in the Supplement). There were no other significant differences in internalizing scores or CBCL subscale scores between groups.

Neuroimaging Metrics Associated With PAE

The PAE group had significantly higher mean (SD) total cortical brain volume than unexposed controls (624 [64] vs 605 [55] cm³; mean difference, 18.77 [95% CI, 4.55-33.00] cm³; P = .01), but no difference in mean (SD) total intracranial volume (1557 [174] vs 1544 [134] cm³; mean difference, 14.15 [95% CI, −23.24 to 51.55] cm³; P = .46).

The mean (SD) FA in the following 5 white matter regions was significantly lower in the PAE group compared with matched controls after false discovery rate correction (Table 2 and Figure 1): the left postcentral (0.35 [0.05] vs 0.36 [0.04]; mean difference, −0.02 [95% CI, −0.03 to −0.01]), left inferior parietal (0.31 [0.07] vs 0.33 [0.06]; mean difference, −0.03 [95% CI, −0.04 to −0.01]), left planum temporale (0.26 [0.04] vs 0.28 [0.03]; mean difference, −0.02 [95% CI, −0.03 to −0.01]), left inferior occipital (0.30 [0.07] vs 0.32 [0.05]; mean difference, −0.03 [95% CI, −0.04 to −0.01]), and right middle occipital (0.30 [0.04] vs 0.31 [0.04]; mean difference, −0.012 [95% CI, −0.02 to −0.01]) areas. Higher FA in the gray matter of the left putamen was also found in children with PAE (0.22 [0.03] vs 0.21 [0.02]; mean difference, 0.01 [95% CI, 0.005-0.02]). These white matter regions also had higher radial diffusivity, higher mean diffusivity, and/or lower axial diffusivity in the PAE group, although these findings did not survive multiple comparison correction (Figure 1B-F).

Table 2. Brain Areas With Significant FA Differences Between Groups After Correction for False Discovery Rate^a.

Brain hemisphere	Brain region	FA, mean (SD)		Mean difference (95% CI)	P value	Cohen d
Brain hemisphere	Brain region	PAE group	Matched unexposed controls	Mean difference (95% CI)	P value	Cohen d
Left	Planum temporale (white matter)	0.26 (0.04)	0.28 (0.03)	−0.02 (−0.03 to −0.01)	<.001	0.43
Left	Inferior occipital area (white matter)	0.30 (0.07)	0.32 (0.05)	−0.03 (−0.04 to −0.01)	<.001	0.46
Left	Inferior parietal area (white matter)	0.31 (0.07)	0.33 (0.06)	−0.03 (−0.04 to −0.01)	.001	0.39
Left	Postcentral area (white matter)	0.35 (0.05)	0.36 (0.04)	−0.02 (−0.03 to −0.01)	.001	0.39
Right	Middle occipital area (white matter)	0.30 (0.04)	0.31 (0.04)	−0.02 (−0.02 to −0.01)	.002	0.42
Left	Putamen (gray matter)	0.22 (0.03)	0.21 (0.02)	0.01 (0.005 to 0.02)	.001	0.39

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Abbreviations: FA, fractional anisotropy; PAE, prenatal alcohol exposure.

^{^a}

No brain areas showed significant differences in other metrics (mean diffusivity, axial diffusivity, radial diffusivity, and blood oxygenation level–dependent signal temporal variance) after false discovery rate correction.

Figure 1. — A, White matter areas with lower FA in the PAE group compared with unexposed controls. B-F, Magnetic resonance imaging metrics (rescaled) of selected white matter (WM) regions by group. AD indicates axial diffusivity; BOLDTV, blood oxygenation level–dependent signal temporal variance; MD, mean diffusivity; and RD, radial diffusivity.

^aGroup differences corrected for false discovery rate at P < .05.

^bGroup differences uncorrected for false discovery rate at P < .05.

When analyses controlled for total intracranial volume, 20 brain areas, including those with differences found to be significant above, had group differences in FA. Nineteen subcortical white matter regions had significantly lower FA in the PAE group, while the putamen had higher FA in the PAE group (eTable 2 and eFigure in the Supplement).

Associations Between CBCL Scores and MRI Metrics

Among the brain regions with significant group differences on MRI metrics, FA in 2 white matter areas had significant group-behavior interactions uncorrected at P < .05 (Figure 2 and Table 3). In these regions, controls showed negative correlations (ρ range, −0.24 to −0.08) between FA and behavior, whereas the PAE group had no significant (ρ range, 0.02-0.16) brain-behavior associations. However, none of these findings survived multiple comparison corrections.

Figure 2. — Scatter plots for 2 selected white matter regions show different associations between FA and CBCL scores in the control group compared with the prenatal alcohol exposed (PAE) group. Trend lines are shown for both the control group (blue) and the PAE group (orange). Additional details are found in Table 3.

Table 3. White Matter Areas With Significant Group Differences in Correlations Between FA and CBCL Scores Uncorrected at P < .05.

CBCL behavioral item	White matter area	PAE group		Matched unexposed controls		Mean difference in correlation coefficient (95% CI)	P value for mean difference	Effect size (diff rho)
CBCL behavioral item	White matter area	Correlation, ρ	P value	Correlation, ρ	P value	Mean difference in correlation coefficient (95% CI)	P value for mean difference	Effect size (diff rho)
Withdrawn/depressed	Left inferior occipital area	0.02	.79	−0.24	.004	0.27 (0.23-0.29)	.03	0.27
Rule break	Left inferior occipital area	0.16	.06	−0.08	.35	0.24 (0.23-0.24)	.05	0.24
Attention	Left inferior parietal area	0.14	.11	−0.11	.22	0.25 (0.24-0.25)	.05	0.25
Thought	Right middle occipital area	0.08	.35	−0.17	.04	0.26 (0.24-0.27)	.04	0.26
Withdrawn/depressed	Right middle occipital area	0.06	.47	−0.23	.009	0.29 (0.27-0.29)	.02	0.29

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Abbreviations: CBCL, Child Behavior Checklist; FA, fractional anisotropy; PAE, prenatal alcohol exposure.

Discussion

To our knowledge, this cross-sectional study is the first to show that small amounts (mean, 1 drink/wk) of PAE are associated with structural brain alterations in children. We found lower FA in white matter compared with unexposed control children matched for age, sex, family income, maternal educational level, caregiver status, and other prenatal substance exposures. Importantly, this finding helps provide clearer evidence of brain alterations likely resulting from PAE compared with previous studies^{34,37,38,39,40} that have sociodemographic mismatches between exposed and control groups. We also found more externalizing behavior problems in children with PAE. This is the first convincing evidence that lower levels of PAE are associated with changes in white matter and a potentially long-lasting impact on child behavior.

Brain Alterations in Children With PAE

Our findings of lower FA are consistent with a growing literature of studies investigating children with PAE,^11,53 although our sample had considerably lower levels of PAE than participants in prior studies. Previous studies^33,35,54 have reported mean exposure levels of 4 to 16 drinks/wk and/or multiple binge episodes (≥4 drinks in 1 sitting), whereas our sample consumed a mean of 1 drink/wk, and most participants’ biological mothers (98.3%) reported no binge episodes during pregnancy. In fact, the mean maximum number of drinks in 1 sitting was only 1.

The subadjacent white matter of the left postcentral, parietal, and temporal regions and bilateral occipital areas showed lower FA in the PAE group compared with controls, largely in agreement with prior studies^10,11,55,56 of children and youths with higher levels of PAE. For example, many previous studies report lower FA within the corpus callosum^10,11,55 and left temporal lobe⁵⁶ in children and youths with PAE. Interestingly, we observed more group differences in the left hemisphere than the right hemisphere in the present study. Cortical lateralization in white matter has not been widely studied yet in the PAE population, although a previous review found atypical asymmetry in the left temporal-parietal region associated with PAE.⁵⁷

One prior study²⁹ examined PAE in the full ABCD cohort and reported larger total brain volume and regional cortical volumes in the PAE group compared with unexposed controls. That study included participants who had been exposed to alcohol before awareness of pregnancy only, those with PAE reported by nonbiological parents, and children with other prenatal exposures (eg, cannabis, tobacco). Our study focused on a smaller but better characterized subsample of the ABCD study cohort, including only children with biological parental reports of alcohol consumption after recognition of pregnancy. Regardless, our cortical volume results are consistent, showing higher volumes in the PAE group, although we report no differences in intracranial volume in our well-matched samples. Prior studies of children with PAE consistently report lower brain volumes.^10,58 The discrepancies may be due to different levels of PAE; prior studies have generally focused on individuals with much higher PAE than the present study. Other factors such as early-life stress, which is higher in most prior studies of PAE than in the present study, may also affect brain volumes.²⁹ It is important to note that the higher cortical volume observed herein does not appear to be adaptive, because these children also had higher externalizing scores, indicating more problematic behavior.

Associations With Behavior

The PAE group had significantly higher externalizing but not internalizing behavior scores compared with the unexposed controls. Previous studies of children, adolescents, and adults with PAE^{4,23,28,29,59,60} consistently report both more externalizing and internalizing problems, including the prior study of the full ABCD cohort.²⁹ The lack of internalizing differences found herein may suggest that externalizing behaviors are more affected by smaller amounts of PAE or may be due to the fact that internalizing behaviors, because they are directed inward, can be difficult to accurately capture via parent report, especially in older children.^61,62,63

In addition to white matter alterations in the brain, the PAE group had disrupted associations between brain structure and behavior and did not show the negative correlations found in controls. Previous studies generally show that lower FA is associated with more problematic behavior (higher internalizing and/or externalizing behavior scores) in typically developing children,^24,64 consistent with our results herein. Prior studies of PAE^28,56 have reported mixed findings with regard to brain-behavior associations. Sowell et al⁵⁶ found the FA in the lateral splenium of the corpus callosum was positively correlated with visuomotor integration, whereas another study²⁸ found no significant correlations between diffusion tensor imaging measures and internalizing or externalizing behavior in the group with PAE. Together, these results suggest that brain alterations induced by PAE disrupt the typical brain-behavior associations and ultimately may contribute to the behavioral difficulties widely observed in individuals with PAE.

Structural vs Functional Alterations

No significant differences in the regional temporal variance of the functional MRI signals were found, although previous studies^13,17,19,29 report widespread changes in functional connectivity between brain regions or networks in children with PAE. Temporal variance measures regional brain activity and thus may be less affected than connectivity between regions⁶⁵; discrepancies between results may also reflect the lower levels of PAE reported herein compared with prior studies. More studies with combined functional and structural brain measures in individuals with PAE population will help clarify these associations.

Implications for Policy and Research

Participants in the present study had low levels of PAE and were not clinically diagnosed with FASD. Indeed, most participants would not meet the exposure criteria for an FASD diagnosis (ie, ≥7 drinks/wk or ≥2 binge episodes during pregnancy).⁶⁶ This highlights the importance of considering any amount of PAE, both in clinical practice and in research studies. From a policy perspective, our findings support the recommendations of the Centers for Disease Control and Prevention and the Society of Obstetricians and Gynaecologists of Canada,⁶⁷ both of which recommend against any amount of alcohol consumption during pregnancy. Despite these recommendations, many individuals assume that small amounts of PAE are fine, and an estimated 10% of women in North America consume alcohol during pregnancy. Our results suggest that PAE status should be considered in future studies of brain alterations and behavior in any number of developmental disorders, diseases, or brain injuries, because PAE may have a substantial confounding effect on results.

Limitations

This study has some limitations. The PAE status was obtained from a retrospective parent-report questionnaire. Retrospective self-reports of PAE can be biased and sometimes underreport alcohol consumption.⁶⁸ To mitigate this, we limited our analysis to participants whose biological mothers reported drinking after awareness of pregnancy and compared them with participants whose biological mothers reported no alcohol consumption before or after pregnancy awareness. Another limitation was that the MRI measures were collected across multiple sites and 3 scanner types. Although the imaging protocol of the ABCD study is harmonized across scanners,⁴⁵ MRI metrics can still vary; to mitigate this, we used a nested design in our statistical analysis.⁵²

Conclusions

In this cross-sectional study, we found structural brain alterations and worse behavior problems in children with low levels of PAE compared with a well-matched group of unexposed controls. Specifically, children with PAE had alterations in diffusion imaging metrics in left postcentral, parietal, temporal, and bilateral occipital white matter and in the gray matter of the putamen. These results suggest that even small amounts of prenatal exposure may lead to structural alterations of the brain, underscoring the importance of evidence-based policy recommendations and considering prenatal exposures in future studies of pediatric brain development.

Supplement.

eTable 1. Group Comparisons on the CBCL Measurements

eTable 2. Brain Areas With Significant FA Differences Between Groups After FDR Correction When Controlling for Total Intracranial Volume

eFigure. Brain Areas With Significant FA Differences Between Groups After FDR Correction When Controlling for Total Intracranial Volume

Click here for additional data file.^{(222.7KB, pdf)}

References

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplement.

eTable 1. Group Comparisons on the CBCL Measurements

eTable 2. Brain Areas With Significant FA Differences Between Groups After FDR Correction When Controlling for Total Intracranial Volume

eFigure. Brain Areas With Significant FA Differences Between Groups After FDR Correction When Controlling for Total Intracranial Volume

Click here for additional data file.^{(222.7KB, pdf)}

[zoi220188r1] 1.Popova S, Lange S, Probst C, Gmel G, Rehm J. Estimation of national, regional, and global prevalence of alcohol use during pregnancy and fetal alcohol syndrome: a systematic review and meta-analysis. Lancet Glob Health. 2017;5(3):e290-e299. doi: 10.1016/S2214-109X(17)30021-9 [DOI] [PubMed] [Google Scholar]

[zoi220188r2] 2.Riley EP, Infante MA, Warren KR. Fetal alcohol spectrum disorders: an overview. Neuropsychol Rev. 2011;21(2):73-80. doi: 10.1007/s11065-011-9166-x [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r3] 3.Lynch ME, Kable JA, Coles CD. Effects of prenatal alcohol exposure in a prospective sample of young adults: mental health, substance use, and difficulties with the legal system. Neurotoxicol Teratol. 2017;64:50-62. doi: 10.1016/j.ntt.2017.10.001 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r4] 4.Pei J, Denys K, Hughes J, Rasmussen C. Mental health issues in fetal alcohol spectrum disorder. J Ment Health. 2011;20(5):438-448. doi: 10.3109/09638237.2011.577113 [DOI] [PubMed] [Google Scholar]

[zoi220188r5] 5.Lebel C, Roussotte F, Sowell ER. Imaging the impact of prenatal alcohol exposure on the structure of the developing human brain. Neuropsychol Rev. 2011;21(2):102-118. doi: 10.1007/s11065-011-9163-0 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r6] 6.Donald KA, Fouche JP, Roos A, et al. Alcohol exposure in utero is associated with decreased gray matter volume in neonates. Metab Brain Dis. 2016;31(1):81-91. doi: 10.1007/s11011-015-9771-0 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r7] 7.Donald KA, Roos A, Fouche JP, et al. A study of the effects of prenatal alcohol exposure on white matter microstructural integrity at birth. Acta Neuropsychiatr. 2015;27(4):197-205. doi: 10.1017/neu.2015.35 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r8] 8.Kar P, Reynolds JE, Grohs MN, et al. White matter alterations in young children with prenatal alcohol exposure. Dev Neurobiol. 2021;81(4):400-410. doi: 10.1002/dneu.22821 [DOI] [PubMed] [Google Scholar]

[zoi220188r9] 9.Moore EM, Migliorini R, Infante MA, Riley EP. Fetal alcohol spectrum disorders: recent neuroimaging findings. Curr Dev Disord Rep. 2014;1(3):161-172. doi: 10.1007/s40474-014-0020-8 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r10] 10.Nguyen VT, Chong S, Tieng QM, Mardon K, Galloway GJ, Kurniawan ND. Radiological studies of fetal alcohol spectrum disorders in humans and animal models: an updated comprehensive review. Magn Reson Imaging. 2017;43:10-26. doi: 10.1016/j.mri.2017.06.012 [DOI] [PubMed] [Google Scholar]

[zoi220188r11] 11.Wozniak JR, Muetzel RL. What does diffusion tensor imaging reveal about the brain and cognition in fetal alcohol spectrum disorders? Neuropsychol Rev. 2011;21(2):133-147. doi: 10.1007/s11065-011-9162-1 [DOI] [PubMed] [Google Scholar]

[zoi220188r12] 12.Long X, Little G, Treit S, Beaulieu C, Gong G, Lebel C. Altered brain white matter connectome in children and adolescents with prenatal alcohol exposure. Brain Struct Funct. 2020;225(3):1123-1133. doi: 10.1007/s00429-020-02064-z [DOI] [PubMed] [Google Scholar]

[zoi220188r13] 13.Donald KA, Ipser JC, Howells FM, et al. Interhemispheric functional brain connectivity in neonates with prenatal alcohol exposure: preliminary findings. Alcohol Clin Exp Res. 2016;40(1):113-121. doi: 10.1111/acer.12930 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r14] 14.Roos A, Fouche JP, Ipser JC, et al. Structural and functional brain network alterations in prenatal alcohol exposed neonates. Brain Imaging Behav. 2021;15(2):689-699. doi: 10.1007/s11682-020-00277-8 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r15] 15.Santhanam P, Coles CD, Li Z, Li L, Lynch ME, Hu X. Default mode network dysfunction in adults with prenatal alcohol exposure. Psychiatry Res. 2011;194(3):354-362. doi: 10.1016/j.pscychresns.2011.05.004 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r16] 16.Long X, Little G, Beaulieu C, Lebel C. Sensorimotor network alterations in children and youth with prenatal alcohol exposure. Hum Brain Mapp. 2018;39(5):2258-2268. doi: 10.1002/hbm.24004 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r17] 17.Fan J, Taylor PA, Jacobson SW, et al. Localized reductions in resting-state functional connectivity in children with prenatal alcohol exposure. Hum Brain Mapp. 2017;38(10):5217-5233. doi: 10.1002/hbm.23726 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r18] 18.Infante MA, Moore EM, Bischoff-Grethe A, Tapert SF, Mattson SN, Riley EP. Altered functional connectivity during spatial working memory in children with heavy prenatal alcohol exposure. Alcohol. 2017;64:11-21. doi: 10.1016/j.alcohol.2017.05.002 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r19] 19.Little G, Reynolds J, Beaulieu C. Altered functional connectivity observed at rest in children and adolescents prenatally exposed to alcohol. Brain Connect. 2018;8(8):503-515. doi: 10.1089/brain.2017.0572 [DOI] [PubMed] [Google Scholar]

[zoi220188r20] 20.Ware AL, Long X, Lebel C. Functional connectivity of the attention networks is altered and relates to neuropsychological outcomes in children with prenatal alcohol exposure. Dev Cogn Neurosci. 2021;48:100951. doi: 10.1016/j.dcn.2021.100951 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r21] 21.Wozniak JR, Mueller BA, Bell CJ, et al. Global functional connectivity abnormalities in children with fetal alcohol spectrum disorders. Alcohol Clin Exp Res. 2013;37(5):748-756. doi: 10.1111/acer.12024 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r22] 22.Wozniak JR, Mueller BA, Mattson SN, et al. ; CIFASD . Functional connectivity abnormalities and associated cognitive deficits in fetal alcohol spectrum disorders (FASD). Brain Imaging Behav. 2017;11(5):1432-1445. doi: 10.1007/s11682-016-9624-4 [DOI] [PMC free article] [PubMed] [Google Scholar]

[zoi220188r23] 23.Khoury JE, Jamieson B, Milligan K. Risk for childhood internalizing and externalizing behavior problems in the context of prenatal alcohol exposure: a meta-analysis and comprehensive examination of moderators. Alcohol Clin Exp Res. 2018;42(8):1358-1377. doi: 10.1111/acer.13805 [DOI] [PubMed] [Google Scholar]

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PERMALINK

Evaluation of Brain Alterations and Behavior in Children With Low Levels of Prenatal Alcohol Exposure

Xiangyu Long, PhD

Catherine Lebel, PhD

Key Points

Question

Findings

Meaning

Abstract

Importance

Objective

Design, Setting, and Participants

Exposures

Main Outcomes and Measures

Results

Conclusions and Relevance

Introduction

Methods

Participants

Table 1. Demographics of the Participants in the Present Study.

Behavior Measures

Neuroimaging

Statistical Analysis

Results

Alcohol Consumption

CBCL Scores Related to Prenatal Exposure

Neuroimaging Metrics Associated With PAE

Table 2. Brain Areas With Significant FA Differences Between Groups After Correction for False Discovery Ratea.

Figure 1. White Matter Areas With Lower Fractional Anisotropy (FA) in the Prenatal Alcohol Exposure (PAE) Group Compared With Unexposed Controls.

Associations Between CBCL Scores and MRI Metrics

Figure 2. White Matter Areas With Significant Group Differences in Correlations Between Fractional Anisotropy (FA) and Child Behavior Checklist (CBCL) Scores.

Table 3. White Matter Areas With Significant Group Differences in Correlations Between FA and CBCL Scores Uncorrected at P < .05.

Discussion

Brain Alterations in Children With PAE

Associations With Behavior

Structural vs Functional Alterations

Implications for Policy and Research

Limitations

Conclusions

References

Associated Data

Supplementary Materials

ACTIONS

PERMALINK

RESOURCES

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Links to NCBI Databases

Table 2. Brain Areas With Significant FA Differences Between Groups After Correction for False Discovery Rate^a.