Opportunities for Prevention of Concussion and Repetitive Head Impact Exposure in College Football Players: A Concussion Assessment, Research, and Education (CARE) Consortium Study

Michael A McCrea; Alok Shah; Stefan Duma; Steven Rowson; Jaroslaw Harezlak; Thomas W McAllister; Steven P Broglio; Christopher C Giza; Joshua Goldman; Kenneth L Cameron; Megan N Houston; Gerald McGinty; Jonathan C Jackson; Kevin Guskiewicz; Jason P Mihalik; M Alison Brooks; Paul Pasquina; Brian D Stemper

doi:10.1001/jamaneurol.2020.5193

. 2021 Feb 1;78(3):1–5. doi: 10.1001/jamaneurol.2020.5193

Opportunities for Prevention of Concussion and Repetitive Head Impact Exposure in College Football Players

A Concussion Assessment, Research, and Education (CARE) Consortium Study

Michael A McCrea ^1,^✉, Alok Shah ¹, Stefan Duma ², Steven Rowson ², Jaroslaw Harezlak ³, Thomas W McAllister ⁴, Steven P Broglio ⁵, Christopher C Giza ^6,⁷, Joshua Goldman ⁸, Kenneth L Cameron ^9,¹⁰, Megan N Houston ⁹, Gerald McGinty ¹¹, Jonathan C Jackson ¹¹, Kevin Guskiewicz ¹², Jason P Mihalik ¹², M Alison Brooks ¹³, Paul Pasquina ¹⁰, Brian D Stemper ^1,¹⁴

¹Department of Neurosurgery, Medical College of Wisconsin, Milwaukee

²Department of Biomedical Engineering, Virginia Tech, Blacksburg

³School of Public Health-Bloomington, Department of Epidemiology and Biostatistics, Indiana University, Bloomington

⁴Department of Psychiatry, Indiana University School of Medicine, Indianapolis

⁵Michigan Concussion Center, University of Michigan, Ann Arbor

⁶UCLA Steve Tisch BrainSPORT Program, Department of Neurosurgery, University of California at Los Angeles

⁷UCLA Steve Tisch BrainSPORT Program, Department of Pediatrics, University of California at Los Angeles

⁸Department of Family Medicine and Orthopedic Surgery, University of California at Los Angeles

⁹John A. Feagin Jr Sports Medicine Fellowship, Keller Army Hospital Military Academy, West Point, New York

¹⁰Department of Physical Medicine and Rehabilitation, Uniformed Services University, Bethesda, Maryland

¹¹Air Force Academy, Colorado

¹²Matthew Gfeller Sport-Related Traumatic Brain Injury Research Center, Department of Exercise and Sport Science, University of North Carolina at Chapel Hill

¹³Department of Orthopedics and Rehabilitation, School of Medicine and Public Health, University of Wisconsin, Madison

¹⁴Department of Biomedical Engineering, Medical College of Wisconsin, Milwaukee

^✉

Corresponding Author: Michael McCrea, PhD, Center for Neurotrauma Research, Department of Neurosurgery, Medical College of Wisconsin, 8701 W Watertown Plank Rd, Milwaukee, WI 53226 (mmccrea@mcw.edu).

Accepted for Publication: November 28, 2020.

Published Online: February 1, 2021. doi:10.1001/jamaneurol.2020.5193

Author Contributions: Dr McCrea had full access to all the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis.

Concept and design: McCrea, McAllister, Broglio, Giza, Cameron, Guskiewicz, Pasquina, Stemper.

Acquisition, analysis, or interpretation of data: McCrea, Shah, Duma, Rowson, Harezlak, Broglio, Giza, Goldman, Cameron, Houston, McGinty, Jackson, Guskiewicz, Mihalik, Brooks, Pasquina, Stemper.

Drafting of the manuscript: McCrea, Shah, Harezlak, McAllister, McGinty, Stemper.

Critical revision of the manuscript for important intellectual content: McCrea, Shah, Duma, Rowson, Harezlak, McAllister, Broglio, Giza, Goldman, Cameron, Houston, Jackson, Guskiewicz, Mihalik, Brooks, Pasquina, Stemper.

Statistical analysis: McCrea, Harezlak, Stemper.

Obtained funding: McCrea, McAllister, Broglio, Pasquina.

Administrative, technical, or material support: McCrea, Shah, Duma, McAllister, Broglio, Giza, Cameron, Houston, McGinty, Jackson, Mihalik, Brooks, Pasquina, Stemper.

Supervision: McCrea, McAllister, Broglio, Giza, Cameron, Guskiewicz, Brooks, Pasquina, Stemper.

Conflict of Interest Disclosures: Dr McCrea reported grants from the National Institutes of Health (NIH), US Centers for Disease Control and Prevention, Abbott Laboratories, and the National Football League outside the submitted work. Dr Duma reported grants from the NIH outside the submitted work. Dr Rowson reported grants from National Collegiate Athletic Association and grants from Department of Defense during the conduct of the study. Dr Broglio had current or past research funding from the NIH; US Centers for Disease Control and Prevention; Department of Defense–USA Medical Research Acquisition Activity; National Collegiate Athletic Association; National Athletic Trainers' Association Foundation; National Football League/Under Armour/GE; Simbex; and ElmindA. He has consulted for the National Collegiate Athletic Association (travel expenses only), US Soccer, US Cycling (unpaid), medico-legal litigation, and received speaker honorarium and travel reimbursements for talks given. He is on the University of Calgary SHRed Concussions external advisory board (unpaid) and is/was on the editorial boards (all unpaid) for Journal of Athletic Training (2015 to present), Concussion (2014 to present), Athletic Training & Sports Health Care (2008 to present), and the British Journal of Sports Medicine (2008 to 2019). Dr Giza grants from University of California, Los Angeles (UCLA) Steve Tisch BrainSPORT Program, UCLA Brain Injury Research Center, UCLA Easton Clinic for Brain Health, and National Institute of Neurological Disorders and Stroke NS110757; other support from the Highmark Interactive Advisory Board, Stock Options, National Basketball Association, National Football League, National Hockey League Players’ Association, Los Angeles Lakers Clinical consultant, and Blackwell/Wiley Publishing Book royalties outside the submitted work; and serving on Concussion Committees for Major League Soccer, National Basketball Association, and the US Soccer Federation. Dr Cameron reported grants from the NATA Foundation Board of Directors. Dr Guskiewicz reports having served on the National Collegiate Athletic Association Concussion Safety Protocol Review Committee from 2014 to 2020. Dr Mihalik reported grants from the NIH, the National Football League, and the US Centers for Disease Control and Prevention outside the submitted work; in addition, Dr Mihalik serves as Chief Science Officer and Co-founder (equity) for Senaptec Inc. Dr Brooks reported other support from American Medical Society for Sports Medicine Board of Directors (reimbursement for travel to board meetings) and American Academy of Pediatricians’ Council on Sports Medicine and Fitness (reimbursement for travel to Executive Committee meetings) outside the submitted work. Dr Stemper reported grants from Prevent Biometrics and Advanced Medical Electronics outside the submitted work. No other disclosures were reported.

Funding/Support: This publication was made possible in part with support from the Grand Alliance Concussion Assessment, Research, and Education (CARE) Consortium, funded in part by the National Collegiate Athletic Association (NCAA) and the US Department of Defense (DOD). The US Army Medical Research Acquisition Activity, 820 Chandler St, Fort Detrick, Maryland, is the awarding and administering acquisition office. This work was supported by the Office of the Assistant Secretary of Defense for Health Affairs, through the Combat Casualty Care Research Program, endorsed by the Department of Defense, through the Joint Program Committee 6/ Combat Casualty Care Research Program–Psychological Health and Traumatic Brain Injury Program under award W81XWH1420151.

Role of the Funder/Sponsor: The funding organizations approved the original design and conduct of the study but had no involvement in the collection, management, analysis, and interpretation of data; the preparation, review or approval of the manuscript; or the decision to submit the manuscript for publication.

Disclaimer: Opinions, interpretations, conclusions and recommendations are those of the authors and are not necessarily endorsed by the US Department of Defense.

Additional Contributions: We thank Jody Harland, MS, Janetta Matesan, BA, Michael Menser, Larry Riggen, MS (Indiana University School of Medicine); Ashley Rettmann, BS, Nicole L’Heureux, MBA (University of Michigan); Melissa Koschnitzke, MA (Medical College of Wisconsin); Michael Jarrett, MBA, Vibeke Brinck, MS and Bianca Byrne, BA (Quesgen); Melissa Baker, BS (Datalys Center for Sports Injury Research and Prevention); and the research and medical staff at each of the CARE participation sites. We also thank the HIT System operators that participated in this study: Julia Ford, MA, ATC, Philippe Gagnon-Joseph, MA, ATC, CSCS, Miranda Kruse, MA, ATC, Corey Rodrigo, BA, ATC, Parker Traugot, PT, DPT, and Erin Campbell, MSc (University of North Carolina); Gus Hendricks, BS, Max Zeiger, BS, Briana Meyer, BS, Jacob Shalkevic, BS, Michael Amick, BS, Alex Kashou, BS, Hunter Harralson, BS, Philip Rosenbaum, BS (University of California, Los Angeles); Quinn Lukens, MA (University of Wisconsin); Brett Griesemer, BS, ATC, Alex Black, BS, ATC, Lewis Young, BS, ATC (Virginia Tech); Dom Calhoun, BS (US Air Force Academy); and Mike Aderman, MS, Sean Roach, BSN, Jeremy Ross, MS (West Point). All HIT System operators were supported by the study funding.

^✉

Corresponding author.

PMCID: PMC7851752 PMID: 33523101

Key Points

Question

Where might there be opportunities to do the greatest good toward reducing overall concussion incidence and head impact exposure (HIE) in collegiate football?

Findings

In this cohort study, concussion incidence and HIE were disproportionately higher in the preseason than the regular season, and most concussions and HIE occurred during football practices.

Meaning

These findings point to specific areas where public policy, education, and other prevention strategies could be targeted to make the greatest overall reduction in concussion incidence and HIE in college football, which has important implications for protecting the safety and health of collegiate football players.

Abstract

Importance

Concussion ranks among the most common injuries in football. Beyond the risks of concussion are growing concerns that repetitive head impact exposure (HIE) may increase risk for long-term neurologic health problems in football players.

Objective

To investigate the pattern of concussion incidence and HIE across the football season in collegiate football players.

Design, Setting, and Participants

In this observational cohort study conducted from 2015 to 2019 across 6 Division I National Collegiate Athletic Association (NCAA) football programs participating in the Concussion Assessment, Research, and Education (CARE) Consortium, a total of 658 collegiate football players were instrumented with the Head Impact Telemetry (HIT) System (46.5% of 1416 eligible football players enrolled in the CARE Advanced Research Core). Players were prioritized for instrumentation with the HIT System based on their level of participation (ie, starters prioritized over reserves).

Exposure

Participation in collegiate football games and practices from 2015 to 2019.

Main Outcomes and Measures

Incidence of diagnosed concussion and HIE from the HIT System.

Results

Across 5 seasons, 528 684 head impacts recorded from 658 players (all male, mean age [SD], 19.02 [1.25] years) instrumented with the HIT System during football practices or games met quality standards for analysis. Players sustained a median of 415 (interquartile range [IQR], 190-727) recorded head impacts (ie, impacts) per season. Sixty-eight players sustained a diagnosed concussion. In total, 48.5% of concussions (n = 33) occurred during preseason training, despite preseason representing only 20.8% of the football season (0.059 preseason vs 0.016 regular-season concussions per team per day; mean difference, 0.042; 95% CI, 0.020-0.060; P = .001). Total HIE in the preseason occurred at twice the proportion of the regular season (324.9 vs 162.4 impacts per team per day; mean difference, 162.6; 95% CI, 110.9-214.3; P < .001). Every season, HIE per athlete was highest in August (preseason) (median, 146.0 impacts; IQR, 63.0-247.8) and lowest in November (median, 80.0 impacts; IQR, 35.0-148.0). Over 5 seasons, 72% of concussions (n = 49) (game proportion, 0.28; 95% CI, 0.18-0.40; P < .001) and 66.9% of HIE (262.4 practices vs 137.2 games impacts per player; mean difference, 125.3; 95% CI, 110.0-140.6; P < .001) occurred in practice. Even within the regular season, total HIE in practices (median, 175.0 impacts per player per season; IQR, 76.0-340.5) was 84.2% higher than in games (median, 95.0 impacts per player per season; IQR, 32.0-206.0).

Conclusions and Relevance

Concussion incidence and HIE among college football players are disproportionately higher in the preseason than regular season, and most concussions and HIE occur during football practices, not games. These data point to a powerful opportunity for policy, education, and other prevention strategies to make the greatest overall reduction in concussion incidence and HIE in college football, particularly during preseason training and football practices throughout the season, without major modification to game play. Strategies to prevent concussion and HIE have important implications to protecting the safety and health of football players at all competitive levels.

This study investigates the pattern of concussion incidence and head impact exposure across the football season in collegiate football players.

Introduction

Concussion ranks among the most common injuries in US football.¹ Over the past 2 decades, large-scale studies have informed the epidemiology, acute effects, and recovery associated with concussion in collegiate football players.^2,3 Research has driven a major shift in contemporary approaches to injury management and return to play after concussion, which have improved player safety.⁴ However, concerns remain about the short-term and long-term effects of concussion on brain structure and function, particularly in athletes who experience multiple concussions during their athletic career.

Beyond the risks associated with concussion itself are growing concerns about the effects of repetitive head impact exposure (HIE) from football. Data suggest that HIE may mediate concussion risk in football, wherein higher HIE is associated with increased concussion incidence within a football season.^5,6 Repetitive HIE has also been implicated as a possible risk factor for long-range neurologic health problems, including chronic traumatic encephalopathy (CTE) in former football players.^7,8

In response to these concerns, sport governing bodies have implemented rule and policy changes to lower concussion risk and reduce HIE in football.⁹ The National Collegiate Athletic Association (NCAA) and collegiate conferences have modified game aspects with the highest risk of concussion (eg, kickoff) and implemented preseason practice restrictions to reduce concussion and HIE. Prior studies indicate that policy changes have had a variable effect on reducing HIE and concussion incidence in college football.^9,10,11

The Concussion Assessment, Research, and Education (CARE) Consortium is a national study of concussion in collegiate student-athletes and military cadets, including the biomechanics of concussion and HIE in football.¹² In this Brief Report, we summarize key findings from a CARE Consortium study investigating the incidence of concussion and HIE over the course of the season (ie, preseason vs regular season) and by the nature of football activity (ie, practices vs games) in NCAA college football players.

Methods

The CARE Consortium methods have been detailed elsewhere.¹² This study was approved by the Medical College of Wisconsin institutional review board and human research protection office. Written informed consent was obtained from all participants. For this study, collegiate football players were instrumented with in-helmet sensor arrays to measure head impact frequency, location, and magnitude during practices and games (Head Impact Telemetry System; Riddell).^5,6 Players were prioritized for instrumentation with HITS based on their level of participation (ie, starters prioritized over reserves). Data on HIE and concussion incidence that met the CARE operational definition¹² for this report were collected during the 2015 to 2019 football seasons. For inclusion in our analysis, HIE data required confirmation that head impacts with peak linear acceleration greater than 10G were collected during contact football practices or games. The CARE Consortium does not collect epidemiologic data to allow calculation of injury rates per athlete exposures. Our analysis for this report focused primarily on comparing the concussion incidence and HIE in the college football preseason vs regular season and in football practices vs games. Numerical HIE data for all comparisons were summarized as medians and quartiles. Statistical analyses were performed using linear mixed models to take into account repeated observations on athletes within each season. We report estimated means, standard errors, and P values from the linear mixed models. The P value level of significance was .05, and all P values were 2-sided. Analysis of event proportions were adjusted for the length of the preseason and regular season.

Results

Over 5 seasons, 658 football players (all male, mean age [SD], 19.02 [1.25] years) (46.5% of 1416 eligible football players enrolled in the CARE Advanced Research Core [ARC]) at 6 CARE sites were instrumented throughout 1021 athlete-seasons. In total, 528 684 head impacts were recorded and met quality standards for inclusion in our analysis. Players sustained a median of 415 (interquartile range [IQR], 190-727) head impacts per season (preseason and regular season). There were 68 diagnosed concussions among instrumented athletes during football participation (34% of diagnosed concussions among CARE ARC participants from 2015 to 2019).

Preseason vs Regular Season

Concussion incidence and HIE were disproportionately higher in the preseason than the regular season. In total, 48.5% of concussions (n = 33) occurred during the preseason, despite preseason accounting for only 20.8% of the full football season (0.059 preseason vs 0.016 regular-season concussions per team per day; mean difference, 0.042; 95% CI, 0.020-0.060; P = .001). Adjusting for different lengths of the preseason and regular season, HIE in preseason (66.7% of all recorded head impacts) occurred at twice the proportion of the regular season (33.3%) (324.9 vs 162.4 impacts per team per day; mean difference, 162.6 impacts; 95% CI, 110.9-214.3; P < .001). Players averaged 44% more head impacts per week during preseason than in the regular season (46.9 vs 32.4 impacts; mean difference, 14.5 impacts; 95% CI, 13.5-15.5; P < .001) (Table). Across all seasons, players sustained 82.5% more head impacts in August (composed mostly of preseason activities) than in November (180.5 vs 98.4 impacts; mean difference, 82.1 impacts; 95% CI, 75.3-88.8), 34.6% more than in September (180.5 vs 127.9 impacts; mean difference, 52.6 impacts; 95% CI, 46.0-59.1) and 32.7% more than in October (180.5 vs 134.5 impacts; mean difference, 46.0 impacts; 95% CI, 39.3-52.7; P < .001) (Figure).

Table. Head Impact Exposure per Player in the Preseason vs Regular Season and in Football Practices vs Games.

Exposure type	Median (IQR)	Estimated mean^a (95% CI)	P value
Weekly exposures
Preseason	36.0 (14.0-66.3)	46.9 (45.1-48.6)	<.001
Regular season	25.0 (10.0-48.0)	32.4 (30.7-34.0)	<.001
Season-long exposures (regular season)
Practices	175.0 (76.0-340.5)	243.2 (230.8-255.7)	<.001
Games	95.0 (32.0-206.0)	138.3 (125.3-151.3)	<.001

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Abbreviations: HIE, head impact exposure; IQR, interquartile range; LMM, linear mixed model.

^{^a}

Estimated means and 95% confidence intervals from the LMM estimation. Comparison of exposure was conducted by regressing the average daily HIE per team per season on the preseason vs season binary variable: 66.7% in preseason and 33.3% in regular season (P value for the difference between preseason and season <.001). Preseason was defined as the period from the first day of football training through the last day of the week before the week of first scheduled regular season football game; regular season was defined as the period from the first day of the week leading up to the first scheduled game throughout the last day of the regular season. Using these parameters, preseason and regular season are nonoverlapping. Preseason includes practices and intrasquad scrimmages. Regular season includes practices, intrasquad scrimmages, and games.

Figure. — Data represent impacts per player per month: August (preseason) (mean, 181.1; median, 146.0; interquartile range [IQR], 63.0-247.8), September (mean, 134.1; median, 108.5; IQR, 52.0-188.2), October (mean, 142.2; median, 110.0; IQR, 54.0-192.0), November (mean, 107.1; median, 80.0; IQR, 35.0-148.0; P < .001); P value corresponds to an overall test for the equality across 4 months.

Practice vs Games

Across all 5 seasons, the abundance of concussions and HIE occurred in practices. Including the preseason and regular season, 72% of concussions occurred during football practice and 28% in games (game proportion, 0.28; 95% CI, 0.18-0.40; P < .001). Although head impacts per player per session were higher in games (estimated mean, 19.7 impacts; 95% CI, 18.8-20.6) than in practice (estimated mean, 9.2 impacts; 95% CI, 8.6-9.8) (mean difference, 10.5 impacts; 95% CI, 9.7-11.2; P < .001), 66.9% of all head impacts occurred in practice (262.4 impacts [practices] vs 137.2 impacts [games] per player; mean difference, 125.3 impacts; 95% CI, 110.0-140.6; P < .001). Even within the regular season, median HIE sustained by players during all practices was 84.2% higher than in all games (243.2 vs 138.3 impacts; mean difference, 104.9 impacts; 95% CI, 90.3-119.59; P < .001) (Table).

Discussion

We report analyses from the largest study to our knowledge to date on concussion and HIE in instrumented college football players. These data illustrate several important points critical to understanding the profile of concussion and HIE and to informing strategies to reduce concussion incidence and HIE among college football players. First, concussion incidence and HIE are disproportionately higher in the preseason than the regular season. Although preseason training represents only about 20% of the full football season, it accounts for roughly half of all concussions, and HIE occurs at twice the proportion of the regular season. Second, although per session HIE is higher in games than in practice, the abundance of all concussions (72%) and total HIE (67%) occurs during practices, not games.

There is growing consensus that reducing concussion incidence and HIE has important implications to improving athlete safety in football. To date, NCAA policy changes have had a limited effect in reducing preseason concussion incidence and HIE.¹¹ The most effective prevention strategies will require a multidimensional approach that extends beyond singularly focused policy and will require buy-in from all key stakeholders, including sport governing bodies, institutional athletic administration, coaches, and athletes themselves. Football practice reform to reduce exposure and risk of concussion will undoubtedly require engagement from coaches, who ultimately design and implement drill-specific practice activities.¹³ Our data support the development of robust educational offerings that should be customized to specific audiences, including coaches, athletic administrators, and players.

There is often natural tension between proposed changes to improve athlete safety and fundamental interest in preserving the competitive nature of football. Achieving both may require alternative training paradigms to maximize competitive readiness of players, while minimizing exposure and risk. The current data suggest that targeted prevention strategies to yield the greatest overall effects toward reducing HIE and concussion incidence without major modification to football game play. While rule changes (eg, targeting penalties) are an important component to protecting athletes during competition, our data suggest modifying preseason training activities and football practice throughout the season could lead to a substantial reduction in overall concussion incidence and HIE. To that end, we offer the following for consideration:

Policy and governance: Sport governing bodies, including the NCAA and major collegiate athletic conferences, are encouraged to explore policy and rule changes to further reduce concussion incidence and HIE, with a particular focus on preseason and regular season football practice guidelines. Policy changes reducing contact practices at the high school level have already been shown to decrease HIE by up to 50%.¹⁴
Institutional responsiveness: Data from this study should inform strategic efforts by the NCAA to reduce HIE and concussion in college football. In turn, institutional leaders and coaches should promote educational efforts and modify local training practices to universally reduce concussion incidence and HIE.
Athlete instruction: As we reported previously,¹⁵ the largest percentage of variance in HIE during football practice resides at the level of the individual athlete,¹⁵ indicating the importance of strategies to reduce HIE in those athletes at highest risk. When available, innovative technologies may provide an effective means for individual player instruction to reduce exposure and associated injury risk.
Monitoring efficacy: Sport governing bodies should collect data to systematically evaluate the effectiveness of policy changes and other prevention strategies in reducing HIE and concussion incidence.

Limitations

In addition to the methodologic strengths of this study, certain limitations should be considered in interpretation and generalization of its findings. Although the HIT System is the most widely used and validated device for measurement of HIE in football, there is potential for some degree of measurement error and the occurrence of false-positive or false-negative recording of impacts.¹⁶ Additionally, this study did not involve live or video surveillance to independently verify recorded head impacts. The study sample of 658 players instrumented with the HIT System is, to our knowledge, the largest available, but resource limitations did not allow instrumentation of all rostered players at all ARC sites. Finally, the study included only NCAA Division 1 football players. It is possible that the profile of concussion and HIE in the preseason and in football practice may be different at other competitive levels (eg, youth, high school, and professional).

Conclusions

These findings from the CARE Consortium help inform a powerful opportunity to do the greatest good toward reducing concussion incidence and HIE in college football players through a combination of policy and education while still maintaining the competitive nature of game play. If effective, similar strategies could be implemented to prevent concussion and HIE across all levels of competitive football (youth, high school, and professional) and other sports.

References:

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[nbr200007r1] 1.McCrory P, Meeuwisse WH, Aubry M, et al. Consensus statement on concussion in sport: the 4th International Conference on Concussion in Sport held in Zurich, November 2012. Br J Sports Med. 2013;47(5):250-258. doi: 10.1136/bjsports-2013-092313 [DOI] [PubMed] [Google Scholar]

[nbr200007r2] 2.McCrea M, Guskiewicz KM, Marshall SW, et al. Acute effects and recovery time following concussion in collegiate football players: the NCAA Concussion Study. JAMA. 2003;290(19):2556-2563. doi: 10.1001/jama.290.19.2556 [DOI] [PubMed] [Google Scholar]

[nbr200007r3] 3.Guskiewicz KM, McCrea M, Marshall SW, et al. Cumulative effects associated with recurrent concussion in collegiate football players: the NCAA Concussion Study. JAMA. 2003;290(19):2549-2555. doi: 10.1001/jama.290.19.2549 [DOI] [PubMed] [Google Scholar]

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PERMALINK

Opportunities for Prevention of Concussion and Repetitive Head Impact Exposure in College Football Players

Michael A McCrea, PhD

Alok Shah, MS

Stefan Duma, PhD

Steven Rowson, PhD

Jaroslaw Harezlak, PhD

Thomas W McAllister, MD

Steven P Broglio, PhD

Christopher C Giza, MD

Joshua Goldman, MD

Kenneth L Cameron, PhD

Megan N Houston, PhD

Gerald McGinty, DPT

Jonathan C Jackson, MD

Kevin Guskiewicz, PhD

Jason P Mihalik, PhD

M Alison Brooks, MD, MPH

Paul Pasquina, MD

Brian D Stemper, PhD

Key Points

Question

Findings

Meaning

Abstract

Importance

Objective

Design, Setting, and Participants

Exposure

Main Outcomes and Measures

Results

Conclusions and Relevance

Introduction

Methods

Results

Preseason vs Regular Season

Table. Head Impact Exposure per Player in the Preseason vs Regular Season and in Football Practices vs Games.

Figure. Head Impacts per Player per Month.

Practice vs Games

Discussion

Limitations

Conclusions

References:

ACTIONS

PERMALINK

RESOURCES

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