Tracking Cerebral White Matter Changes Across the Lifespan: Insights from Diffusion Tensor Imaging Studies

Overview

Journal J Neural Transm (Vienna)

Specialties Neurology
Physiology

Date 2013 Jan 19

PMID 23328950

Citations 56

Authors

Qian Jun Yap

Irvin Teh

Paolo Fusar-Poli

Min Yi Sum

Carissa Kuswanto

Kang Sim

Affiliations

Soon will be listed here.

Abstract

Delineating the normal development of brain white matter (WM) over the human lifespan is crucial to improved understanding of underlying WM pathology in neuropsychiatric and neurological conditions. We review the extant literature concerning diffusion tensor imaging studies of brain WM development in healthy individuals available until October 2012, summarise trends of normal development of human brain WM and suggest possible future research directions. Temporally, brain WM maturation follows a curvilinear pattern with an increase in fractional anisotropy (FA) from newborn to adolescence, decelerating in adulthood till a plateau around mid-adulthood, and a more rapid decrease of FA from old age onwards. Spatially, brain WM tracts develop from central to peripheral regions, with evidence of anterior-to-posterior maturation in commissural and projection fibres. The corpus callosum and fornix develop first and decline earlier, whilst fronto-temporal WM tracts like cingulum and uncinate fasciculus have protracted maturation and decline later. Prefrontal WM is most vulnerable with greater age-related FA reduction compared with posterior WM. Future large scale studies adopting longitudinal design will better clarify human brain WM changes over time.

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