Microscopic Fractional Anisotropy Detects Cognitive Training-Induced Microstructural Brain Changes

Overview

Journal Tomography

Publisher MDPI

Specialty Radiology

Date 2022 Jan 25

PMID 35076639

Authors

Xinnan Li

Daisuke Sawamura

Hiroyuki Hamaguchi

Yuta Urushibata

Thorsten Feiweier

Keita Ogawa

Khin Khin Tha

Affiliations

Soon will be listed here.

Abstract

Cognitive training-induced neuroplastic brain changes have been reported. This prospective study evaluated whether microscopic fractional anisotropy (μFA) derived from double diffusion encoding (DDE) MRI could detect brain changes following a 4 week cognitive training. Twenty-nine healthy volunteers were recruited and randomly assigned into the training ( = 21) and control ( = 8) groups. Both groups underwent brain MRI including DDE MRI and 3D-T1-weighted imaging twice at an interval of 4-6 weeks, during which the former underwent the training. The training consisted of hour-long dual N-back and attention network tasks conducted five days per week. Training and time-related changes of DDE MRI indices (μFA, fractional anisotropy (FA), and mean diffusivity (MD)) and the gray and white matter volume were evaluated using mixed-design analysis of variance. In addition, any significant imaging indices were tested for correlation with cognitive training-induced task performance changes, using partial correlation analyses. μFA in the left middle frontal gyrus decreased upon the training (53 voxels, uncorrected < 0.001), which correlated moderately with response time changes in the orienting component of attention (r = -0.521, uncorrected = 0.032). No significant training and time-related changes were observed for other imaging indices. Thus, μFA can become a sensitive index to detect cognitive training-induced neuroplastic changes.

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