The Impact of Impacts: Repetitive Head Impact Exposure in Canadian University Football Players

Due to the physical nature of the game and repeated head impacts between players each play, the sport of football has one of the highest incidence rates of concussion. With nearly two million participants, this incidence rate translates to a reserved estimate of 100,000 concussions per year due to the contact nature of the sport. Injury thresholds have proven difficult to establish, so American football concussion research has shifted focus to measuring the accumulation of repetitive head impacts. As there are numerous rule differences between Canadian and American football, head impact exposure may present differently for Canadian players. Accordingly, the objective of this thesis was to investigate the effect of cumulative head impacts on Canadian university football players. This was achieved through three research projects using helmet-mounted sensors to monitor head impacts experienced by football players in practices and games, and measuring brain function via saccadic eye movements. Results illustrated that there were no differences in linear and rotational accelerations between striking and struck players during a collision. However, head impacts that occurred during kickoff plays experienced linear head accelerations that were double in magnitude and rotational head accelerations that were triple in magnitude than other special teams, offensive, and defensive plays (Chapter 2). Furthermore, the accumulation of head impacts significantly increased football players’ saccade latencies, which persisted over two successive seasons (Chapter 3). The total number of head impacts experienced during their career was significantly affected by a player’s position, and not their seniority (Chapter 4). In conclusion, this thesis identified football plays that resulted in high magnitude head accelerations, quantified the effect of individual head impacts on brain function using saccade latencies, and characterized career head impact exposure for football players. These results provide evidence that football head impact exposure needs to be reduced for the health of the players. Coaches and league administrators can use evidence-based research to employ strategies to reduce the number of head impacts to the sport of football.

Keywords: Football; concussion; head impacts; saccade; brain injury; linear; rotational acceleration

Year	Entry
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2016	Brooks JS. The Use of P3b as an Indicator of Neurophysiologic Change from Subconcussive Impacts in Football Players [Master's thesis]. University of Western Ontario; 2016.
2012	Rowson S, Duma SM, Beckwith JG, Chu JJ, Greenwald RM, Crisco JJ, Brolinson PG, Duhaime A-C, McAllister TW, Maerlender AC. Rotational head kinematics in football impacts: an injury risk function for concussion. Ann Biomed Eng. January 2012;40(1):1-13.
2008	Greenwald RM, Gwin JT, Chu JJ, Crisco JJ. Head impact severity measures for evaluating mild traumatic brain injury risk exposure. Neurosurgery. April 2008;62(4):789-798.
2011	Rowson S, Beckwith JG, Chu JJ, Leonard DS, Greenwald RM, Duma SM. A six degree of freedom head acceleration measurement device for use in football. J Appl Biomech. February 2011;27(1):8-14.
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Year

Entry

2005

Viano DC, Pellman EJ. Concussion in professional football: biomechanics of the striking player: part 8. Neurosurgery. February 2005;56(2):266-278.

2016

Brooks JS. The Use of P3b as an Indicator of Neurophysiologic Change from Subconcussive Impacts in Football Players [Master's thesis]. University of Western Ontario; 2016.

2012

Rowson S, Duma SM, Beckwith JG, Chu JJ, Greenwald RM, Crisco JJ, Brolinson PG, Duhaime A-C, McAllister TW, Maerlender AC. Rotational head kinematics in football impacts: an injury risk function for concussion. Ann Biomed Eng. January 2012;40(1):1-13.

2008

Greenwald RM, Gwin JT, Chu JJ, Crisco JJ. Head impact severity measures for evaluating mild traumatic brain injury risk exposure. Neurosurgery. April 2008;62(4):789-798.

2011

Rowson S, Beckwith JG, Chu JJ, Leonard DS, Greenwald RM, Duma SM. A six degree of freedom head acceleration measurement device for use in football. J Appl Biomech. February 2011;27(1):8-14.