Predicting risk for Alcohol Use Disorder using longitudinal data with multimodal biomarkers and family history: a machine learning study.
paper
Primary
Public
- Authors
- Kinreich, Sivan; Meyers, Jacquelyn L; Maron-Katz, Adi; Kamarajan, Chella; Pandey, Ashwini K; Chorlian, David B; Zhang, Jian; Pandey, Gayathri; Subbie-Saenz de Viteri, Stacey; Pitti, Dan; Anokhin, Andrey P; Bauer, Lance; Hesselbrock, Victor; Schuckit, Marc A; Edenberg, Howard J; Porjesz, Bernice
- Year
- 2021
- Journal
- Molecular psychiatry
- PMID
- 31595034
- DOI
- 10.1038/s41380-019-0534-x
- PMCID
- PMC7138692
Predictive models have succeeded in distinguishing between individuals with Alcohol use Disorder (AUD) and controls. However, predictive models identifying who is prone to develop AUD and the biomarkers indicating a predisposition to AUD are still unclear. Our sample (nβ=β656) included offspring and non-offspring of European American (EA) and African American (AA) ancestry from the Collaborative Study of the Genetics of Alcoholism (COGA) who were recruited as early as age 12 and were unaffected at first assessment and reassessed years later as AUD (DSM-5) (nβ=β328) or unaffected (nβ=β328). Machine learning analysis was performed for 220 EEG measures, 149 alcohol-related single nucleotide polymorphisms (SNPs) from a recent large Genome-wide Association Study (GWAS) of alcohol use/misuse and two family history (mother DSM-5 AUD and father DSM-5 AUD) features using supervised, Linear Support Vector Machine (SVM) classifier to test which features assessed before developing AUD predict those who go on to develop AUD. Age, gender, and ancestry stratified analyses were performed. Results indicate significant and higher accuracy rates for the AA compared with the EA prediction models and a higher model accuracy trend among females compared with males for both ancestries. Combined EEG and SNP features model outperformed models based on only EEG features or only SNP features for both EA and AA samples. This multidimensional superiority was confirmed in a follow-up analysis in the AA age groups (12-15, 16-19, 20-30) and EA age group (16-19). In both ancestry samples, the youngest age group achieved higher accuracy score than the two other older age groups. Maternal AUD increased the model's accuracy in both ancestries' samples. Several discriminative EEG measures and SNPs features were identified, including lower posterior gamma, higher slow wave connectivity (delta, theta, alpha), higher frontal gamma ratio, higher beta correlation in the parietal area, and 5 SNPs: rs4780836, rs2605140, rs11690265, rs692854, and rs13380649. Results highlight the significance of sampling uniformity followed by stratified (e.g., ancestry, gender, developmental period) analysis, and wider selection of features, to generate better prediction scores allowing a more accurate estimation of AUD development.
A data-flow diagram
Model accuracy by ancestry. Classification obtained by the only EEG features, only SNP features and by the combined EEG and SNP features for EA and AA samples. Results indicate that the combined model has higher accuracy than the EEG based model, and the SNP based model. The error bars are standard deviations. *p < 0.05, **p < 0.01
Model accuracy by gender and ancestry. Classification accuracy obtained by the only EEG features, only SNP features and by the combined EEG and SNP features stratified by gender. Results indicate higher accuracy scores for the female compared to male in both EA and AA samples for the three models-based features. The error bars are standard deviations. *p < 0.05, **p < 0.01
Model accuracy by gender, family history and ancestry. Mother AUD and father AUD features were added to the female and male models. Results highlight ancestry and gender differences of the effect of parent AUD over the accuracy of the model. For both AA and EA, male and female samples, mother AUD feature increased model accuracy. Father AUD increased the accuracy of the combined model for the AA female sample. The error bars are standard deviations. *p < 0.05, **p < 0.01
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| Name | Type |
|---|---|
| 64-channel electrode cap local | drug |
| AA | cohort |
| AA-AUD local | cohort |
| AA-AUD female local | cohort |
| AA-AUD females local | cohort |
| AA-AUD male local | cohort |
| AA_AUD_male local | cohort |
| AA female local | cohort |
| AA_female local | cohort |
| AA group | cohort |
| AA male local | cohort |
| AA_male local | cohort |
| adolescents | cohort |
| adults | cohort |
| African American | cohort |
| African ancestry (AA) local | cohort |
| age group | cohort |
| alcohol | phenotype |
| alcohol dependence | phenotype |
| Alcohol_dependence | phenotype |
| Alcohol-related EEG measures local | phenotype |
| Alcohol Use Disorder | phenotype |
| Alcohol-vulnerable individuals local | cohort |
| AUD | phenotype |
| AUD AA female local | cohort |
| AUD AA male local | cohort |
| AUD EA female local | cohort |
| AUD EA male local | cohort |
| binge drinking | phenotype |
| brain functions local | anatomy |
| brain structure | anatomy |
| Collaborative Study on the Genetics of Alcoholism (COGA) | cohort |
| control | cohort |
| controls | cohort |
| depression | phenotype |
| DSM-5 AUD | phenotype |
| DSM-IV alcohol dependence | phenotype |
| EA | cohort |
| EA-AUD local | cohort |
| EA-AUD female local | cohort |
| EA AUD females local | cohort |
| EA-AUD male local | cohort |
| EA_AUD_male local | cohort |
| EA female local | cohort |
| EA_female local | cohort |
| EA genders local | cohort |
| EA group | cohort |
| EA male local | cohort |
| EA_male local | cohort |
| EEG | phenotype |
| EEG+SNP local | drug |
| EEG+SNP features local | drug |
| Electro-Cap International, Inc. local | drug |
| European American females local | cohort |
| European ancestry | cohort |
| extended 10β20 System local | drug |
| family history of alcoholism | phenotype |
| fast beta EEG local | phenotype |
| fathers | cohort |
| first visit cohort local | cohort |
| FLII local | gene |
| follow-up visit cohort local | cohort |
| frontal cortex | anatomy |
| Frontal-Parietal local | anatomy |
| Frontal-parietal gamma connectivity local | phenotype |
| frontal-parietal region local | anatomy |
| Frontal-parietal region local | anatomy |
| FUT2 | gene |
| higher beta correlation local | phenotype |
| higher frontal gamma ratio local | phenotype |
| higher predictive model scores local | phenotype |
| higher sensitivity local | phenotype |
| higher slow wave intrahemispheric connectivity local | phenotype |
| higher slow wave intrahemispheric connectivity (delta, alpha) local | phenotype |
| higher theta local | phenotype |
| higher theta occipital interhemispheric connectivity local | phenotype |
| Increased absolute theta log power local | phenotype |
| Increased connectivity of slower wave bands local | phenotype |
| Increased frontal theta local | phenotype |
| Increased interhemispheric theta coherence local | phenotype |
| Increased intrahemispheric theta coherence local | phenotype |
| Increased introspect inside attention local | phenotype |
| Increased occipital theta local | phenotype |
| Industrial Acoustics, Inc. local | drug |
| Interoceptive network local | anatomy |
| lower beta intrahemispheric correlation local | phenotype |
| lower delta occipital interhemispheric correlation local | phenotype |
| lower frontal-parietal gamma correlation local | phenotype |
| lower gamma parietal amplitude local | phenotype |
| lower gamma parietal interhemispheric coherence local | phenotype |
| lower occipital gamma amplitude local | phenotype |
| lower posterior gamma amplitude local | phenotype |
| maximum number of alcoholic drinks within 24 h local | phenotype |
| more accurate prediction local | phenotype |
| mother AUD | phenotype |
| mothers | cohort |
| occipital cortex | anatomy |
| parental alcoholism | phenotype |
| parietal cortex | anatomy |
| Parietal gamma activity local | phenotype |
| paternal alcohol use disorder | phenotype |
| posterior | anatomy |
| Posterior gamma activity local | phenotype |
| posterior region | anatomy |
| Posterior salience network local | anatomy |
| Pre-AUD cohort local | cohort |
| Reduced outside attention local | phenotype |
| RF-shielded booth local | drug |
| rs11690265 local | variant |
| rs13093097 local | variant |
| rs13380649 local | variant |
| rs167336 local | variant |
| rs2605140 local | variant |
| rs28709965 local | variant |
| rs303754 local | variant |
| rs303757 local | variant |
| rs34467936 local | variant |
| rs4780836 local | variant |
| rs62057756 local | variant |
| rs692854 local | variant |
| rs7430178 local | variant |
| schizophrenia | phenotype |
| sex | phenotype |
| SNP | cohort |
| SNPs (selected set) local | variant |
| teens | cohort |
| temporal | anatomy |
| temporal-iparietal region local | anatomy |
| temporal lobe | anatomy |
| unaffected | phenotype |
| unaffected controls local | phenotype |
| younger age group local | phenotype |
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