Subconcussive Impact-Dependent Increase in Plasma S100β Levels in Collegiate Football Players

Keisuke Kawata; Leah H Rubin; Masahiro Takahagi; Jong Hyun Lee; Thomas Sim; Victor Szwanki; Al Bellamy; Ryan Tierney; Dianne Langford

doi:10.1089/neu.2016.4786

Subconcussive Impact-Dependent Increase in Plasma S100β Levels in Collegiate Football Players

J Neurotrauma. 2017 Jul 15;34(14):2254-2260. doi: 10.1089/neu.2016.4786. Epub 2017 Apr 27.

Authors

Keisuke Kawata^{1

2}, Leah H Rubin³, Masahiro Takahagi⁴, Jong Hyun Lee¹, Thomas Sim⁵, Victor Szwanki⁴, Al Bellamy⁴, Ryan Tierney⁵, Dianne Langford¹

Affiliations

¹ 1 Department of Neuroscience, Lewis Katz School of Medicine at Temple University , Philadelphia, Pennsylvania.
² 2 Department of Kinesiology, Indiana University , Bloomington, Indiana.
³ 3 Department of Psychiatry, University of Illinois at Chicago , Chicago, Illinois.
⁴ 4 Department of Athletics, Temple University , Philadelphia, Pennsylvania.
⁵ 5 Department of Kinesiology, Temple University , Philadelphia, Pennsylvania.

PMID: 28181857
DOI: 10.1089/neu.2016.4786

Abstract

The current study investigates whether repetitive subconcussive impacts cause changes in plasma S100β levels, and also tests the associations between S100β changes and frequency/magnitude of impacts sustained. This prospective study of 22 Division-I collegiate football players included baseline and pre-season practices (one helmet-only and four full-gear). Blood samples were obtained and assessed for S100β levels at baseline and pre- to post-practices; symptom scores were assessed at each time-point. An accelerometer-embedded mouthguard was employed to measure the number of impacts (hits), peak linear acceleration (PLA), and peak rotational acceleration (PRA). Because we observed a distinct gap in impact exposure (hits, PLA, and PRA), players were clustered into lower (n = 7) or higher (n = 15) impact groups based on the sum of impact kinematics from all five practices. S100β levels significantly changed across the study duration. Although S100β levels remained stable from baseline to all pre-practice values, statistically significant acute increases in S100β levels were observed in all post-practice measures compared with the respective pre-practice values (range: 133-246% in the overall sample). Greater number of hits, sum of PLA, and sum of PRA were significantly associated with greater acute increases in S100β levels. There were significant differences in head impact kinematics between lower and higher impact groups (hits, 6 vs. 43 [M_lower - M_higher = 35, p < 0.001]; PLA, 99.4 vs. 1148.5 g [M_lower - M_higher = 1049.1, p < 0.001]; PRA, 7589 vs. 68,259 rad/s² [M_lower - M_higher = 60,670, p < 0.001]). Players in the higher impact group showed consistently greater increases in plasma S100β levels, but not symptom scores, at each post-practice than the lower impact group. Collectively, these data suggest that although players continued to play without noticeable change in symptoms, a brain-enriched serological factor suggests an acute burden from head impacts. Assessing the effects of repetitive subconcussive head impacts on acute changes in S100β levels may be a clinically useful blood biomarker in tracking real-time acute brain damage in collegiate football players.

Keywords: biomarker; concussion; head impact kinematics; subconcussive; traumatic brain injury.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Adult
Athletic Injuries / blood*
Biomarkers / blood
Biomechanical Phenomena
Brain Concussion / blood*
Football*
Humans
Male
S100 Calcium Binding Protein beta Subunit / blood*
Universities
Young Adult

Substances

Biomarkers
S100 Calcium Binding Protein beta Subunit
S100B protein, human