Putamen Volume Predicts Real-time FMRI Neurofeedback Learning Success Across Paradigms and Neurofeedback Target Regions

Overview

Journal Hum Brain Mapp

Publisher Wiley

Specialty Neurology

Date 2021 Jan 5

PMID 33400306

Citations 15

Authors

Zhiying Zhao

Shuxia Yao

Jana Zweerings

Xinqi Zhou

Feng Zhou

Keith M Kendrick

Huafu Chen

Klaus Mathiak

Benjamin Becker

Affiliations

Soon will be listed here.

Abstract

Real-time fMRI guided neurofeedback training has gained increasing interest as a noninvasive brain regulation technique with the potential to modulate functional brain alterations in therapeutic contexts. Individual variations in learning success and treatment response have been observed, yet the neural substrates underlying the learning of self-regulation remain unclear. Against this background, we explored potential brain structural predictors for learning success with pooled data from three real-time fMRI data sets. Our analysis revealed that gray matter volume of the right putamen could predict neurofeedback learning success across the three data sets (n = 66 in total). Importantly, the original studies employed different neurofeedback paradigms during which different brain regions were trained pointing to a general association with learning success independent of specific aspects of the experimental design. Given the role of the putamen in associative learning this finding may reflect an important role of instrumental learning processes and brain structural variations in associated brain regions for successful acquisition of fMRI neurofeedback-guided self-regulation.

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