Citation

Espana L, Lee R, Ling J, Jeromin A, Mayer A, Meier T. J. Neurotrauma 2017; 34(22): 3143-3152.

Affiliation

Medical College of Wisconsin, Neurosurgery , 8701 Watertown Plank Road , Milwaukee, Wisconsin, United States , 53226 ; tmeier@mcw.edu.

Copyright

(Copyright © 2017, Mary Ann Liebert Publishers)

DOI

10.1089/neu.2017.5002

PMID

28665173

Abstract

There is an urgent need to characterize the acute physiological effects of sport-related concussion (SRC). We investigated the effects of SRC on gray matter structure and diffusion metrics in collegiate athletes at 1.64 days (T1; n=33), 8.33 days (T2; n=30), and 32.15 days (T3; n=36) post-concussion, with healthy collegiate contact-sport athletes serving as controls (HA; n=46). Plasma levels of GFAP were assessed in a subset of athletes. We hypothesized that acute SRC would be associated with increased fractional anisotropy (FA), decreased mean diffusivity (MD), and increased GFAP relative to non-injured HA, without acute differences in gray matter volume or cortical thickness. Furthermore, we hypothesized that neither diffusion nor structure would show longitudinal changes across the first month following SRC. Finally, we hypothesized that gray matter diffusion metrics would correlate with plasma GFAP levels, as indicated by preclinical literature. Consistent with our hypothesis, acute SRC was associated with decreased MD in the left pallidum, increased FA in the right amygdala, and a significantly greater number and volume of subject-specific clusters with increased FA compared to HA. No differences in gray matter volume, cortical thickness, or GFAP were observed between groups. There were no longitudinal changes in any measure across the first month following SRC. Finally, FA in the right amygdala was inversely correlated with GFAP at T2. These results suggest that gray matter diffusion metrics may be useful in determining the physiological effects of SRC.

Language: en

Keywords

Diffusion Tensor Imaging; HUMAN STUDIES; TRAUMATIC BRAIN INJURY