Resting-state functional connectivity and nicotine addiction: prospects for biomarker development

Given conceptual frameworks of addiction as a disease of intercommunicating brain networks, examinations of network interactions may provide a holistic characterization of addiction‐related dysfunction. One such methodological approach is the examination of resting‐state functional connectivity, whi...

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Bibliographic Details
Published in:Annals of the New York Academy of Sciences 2015-09, Vol.1349 (1), p.64-82
Main Authors: Fedota, John R., Stein, Elliot A.
Format: Article
Language:English
Subjects:
addiction
Addictions
Biomarkers
Biomarkers - analysis
Biomarkers - metabolism
Brain Mapping
Cognition - drug effects
Cognition - physiology
Humans
Limbic System - drug effects
Limbic System - physiopathology
Neural Pathways - drug effects
Neural Pathways - physiopathology
Nicotine
Nicotine - adverse effects
Rest - psychology
resting-state functional connectivity
Substance Withdrawal Syndrome - physiopathology
Substance Withdrawal Syndrome - psychology
Tobacco Use Disorder - metabolism
Tobacco Use Disorder - physiopathology
Tobacco Use Disorder - psychology
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Summary:Given conceptual frameworks of addiction as a disease of intercommunicating brain networks, examinations of network interactions may provide a holistic characterization of addiction‐related dysfunction. One such methodological approach is the examination of resting‐state functional connectivity, which quantifies correlations in low‐frequency fluctuations of the blood oxygen level–dependent magnetic resonance imaging signal between disparate brain regions in the absence of task performance. Here, evidence of differentiated effects of chronic nicotine exposure, which reduces the efficiency of network communication across the brain, and acute nicotine exposure, which increases connectivity within specific limbic circuits, is discussed. Several large‐scale resting networks, including the salience, default, and executive control networks, have also been implicated in nicotine addiction. The dynamics of connectivity changes among and between these large‐scale networks during nicotine withdrawal and satiety provide a heuristic framework with which to characterize the neurobiological mechanism of addiction. The ability to simultaneously quantify effects of both chronic (trait) and acute (state) nicotine exposure provides a platform to develop a neuroimaging‐based addiction biomarker. While such development remains in its early stages, evidence of coherent modulations in resting‐state functional connectivity at various stages of nicotine addiction suggests potential network interactions on which to focus future addiction biomarker development.
ISSN:0077-8923
1749-6632
DOI:10.1111/nyas.12882