Abigail Greene

Recent advances in human neuroimaging techniques have begun to offer insights into brain-behavior relationships; such work is exciting both because it sheds light on the neural underpinnings of complex traits, and because it offers the promise of predicting such traits on the basis of neural data, alone. Relevant patterns of neural activity are widely distributed across the brain, making whole-brain, data-driven, functional connectivity-based analyses well suited for their study.

Such analyses are commonly performed using data acquired at rest, an unconstrained state that may fail to capture the full range of individual differences in patterns of functional connectivity. Our research seeks to leverage such individual differences to predict individual traits, and has demonstrated that predictive models built using task-based functional connectivity (i.e., connectivity calculated using data acquired while subjects perform cognitive tasks [e.g., working memory and emotion identification tasks]) better predict phenotype than predictive models built using rest-based data. Thus, much like a stress test reveals variations in cardiac function not observable at rest, cognitive tasks reveal trait-relevant differences in functional connectivity. Our subsequent work has explored how tasks have this effect, and most recently applied this framework to a novel, clinically and demographically heterogeneous dataset, which includes task-based fMRI and neurocognitive measures, finding that brain-based models of phenotype recapitulate sample stereotypes; that is, one brain-phenotype relationship does not fit all. Together, this body of work seeks to develop and apply robust methods to relate patterns of brain activity to neurocognitive phenotypes with relevance to both health and disease.