The Impact of COVID-19 on National Hockey League Players' Return To Play.

OBJECTIVE Evaluate the on-ice performance and return to play (RTP) rate following COVID-19 for National Hockey League (NHL) players during the 2020-21 season. METHODS Players with COVID-19 during the abbreviated 2020-21 season were identified using publicly accessible online sources. Demographics and on-ice metrics were accessed using the NHL's online statistics website. The length of time, rate of RTP, and games missed due to COVID-19 were analyzed. Primary outcomes included average time on ice (TOI) per game (TOI/G), average TOI per shift (TOI/S), and points per game (PPG) compared at different timepoints including pre- and post-COVID-19. RESULTS A total of 73 players (47 forwards, 18 defencemen, 8 goalies) had a documented COVID-19 diagnosis during the abbreviated 2020-21 season. Players missed an average of 5.6 games (14.7 days) due to COVID-19. The post-COVID-19 RTP rate was 97.3%, including playoffs. No differences were found in TOI/G between the pre- (15.7 ± 3.9 min) and post-COVID-19 (15.8 ± 3.4 min, p = 0.874) or in the first (15.8 ± 4.0 min) and second week (15.9 ± 3.8 min, p = 0.925) returned. TOI/shift did not change from pre- (45.6 ± 5.3 sec) to post-COVID-19 (46.7 ± 4.6 sec, p = 0.035) or in first (46.2 ± 5.4 sec) and second week post-COVID-19 (46.2 ± 4.8 sec, p = .854). No differences were identified for PPG between career, pre-COVID-19, and post-COVID-19 (0.44 vs 0.38 vs 0.41; p = 0.274). CONCLUSION RTP post-COVID was markedly high for NHL players. While the effects of COVID-19 on specific physiological measures remains to be elucidated, this study found NHL players do not have reduced performance following COVID-19.

[1]  J. Hull,et al.  Respiratory complications following COVID‐19 in athletic populations: A narrative review , 2022, Scandinavian journal of medicine & science in sports.

[2]  M. Kabadayı,et al.  Respiratory muscle strength and pulmonary function in unvaccinated athletes before and after COVID-19 infection: A prospective cohort study , 2022, Respiratory Physiology & Neurobiology.

[3]  F. Fedele,et al.  Low prevalence of cardiac abnormalities in competitive athletes at return-to-play after COVID-19 , 2022, Journal of Science and Medicine in Sport.

[4]  E. Achkasov,et al.  The incidence and severity of COVID-19 in adult professional soccer players in Russia , 2022, PloS one.

[5]  N. Köktürk,et al.  Respiratory muscle strength in volleyball players suffered from COVID-19 , 2021, Irish Journal of Medical Science (1971 -).

[6]  B. Merkely,et al.  Cardiopulmonary examinations of athletes returning to high-intensity sport activity following SARS-CoV-2 infection , 2021, Scientific reports.

[7]  M. Davey,et al.  Return to Play Following COVID-19 Infection-A Systematic Review of Current Evidence. , 2021, Journal of sport rehabilitation.

[8]  N. Heron,et al.  Clinical patterns, recovery time and prolonged impact of COVID-19 illness in international athletes: the UK experience , 2021, British Journal of Sports Medicine.

[9]  B. Vopat,et al.  Defining Return to Sport: A Systematic Review , 2021, Orthopaedic journal of sports medicine.

[10]  J. Sallis,et al.  Physical inactivity is associated with a higher risk for severe COVID-19 outcomes: a study in 48 440 adult patients , 2021, British Journal of Sports Medicine.

[11]  David A. Drew,et al.  Attributes and predictors of long COVID , 2021, Nature Medicine.

[12]  S. Lombardo,et al.  Impact of COVID-19 on Recovered Athletes Returning to Competitive Play in the NBA “Bubble” , 2021, Orthopaedic journal of sports medicine.

[13]  R. Bahr,et al.  Resuming professional football (soccer) during the COVID-19 pandemic in a country with high infection rates: a prospective cohort study , 2021, British Journal of Sports Medicine.

[14]  S. Rodeo,et al.  Sports Medicine Considerations During the COVID-19 Pandemic , 2020, The American journal of sports medicine.

[15]  M. J. Broadhurst,et al.  Mitigating a COVID-19 Outbreak Among Major League Baseball Players — United States, 2020 , 2020, MMWR. Morbidity and mortality weekly report.

[16]  S. Keteyian,et al.  Maximal Exercise Capacity is Inversely Related to Hospitalization Secondary to Coronavirus Disease 2019 , 2020, Mayo Clinic Proceedings.

[17]  V. Palmieri,et al.  Is extensive cardiopulmonary screening useful in athletes with previous asymptomatic or mild SARS-CoV-2 infection? , 2020, British Journal of Sports Medicine.

[18]  B. Gärtner,et al.  Successful return to professional men’s football (soccer) competition after the COVID-19 shutdown: a cohort study in the German Bundesliga , 2020, British Journal of Sports Medicine.

[19]  Allen K. Sills,et al.  Return to sport for North American professional sport leagues in the context of COVID-19 , 2020, British Journal of Sports Medicine.

[20]  H. Dores,et al.  TEAM to Defeat COVID-19: A Management Strategy Plan to Address Return to Play in Sports Medicine , 2020, Orthopaedic journal of sports medicine.

[21]  A. Corsini,et al.  Return to football training and competition after lockdown caused by the COVID-19 pandemic: medical recommendations , 2020, Biology of sport.

[22]  A. Corsini,et al.  Medical recommendations for home-confined footballers’ training during the COVID-19 pandemic: from evidence to practical application , 2020, Biology of sport.

[23]  A. Maior,et al.  Inspiratory muscle training improves performance of a repeated sprints ability test in professional soccer players. , 2019, Journal of bodywork and movement therapies.

[24]  I. Juric,et al.  Inspiratory muscle strength affects anaerobic endurance in professional athletes , 2019, Arhiv za higijenu rada i toksikologiju.

[25]  J. Metz Upper respiratory tract infections: Who plays, who sits? , 2003, Current sports medicine reports.

[26]  P. Neufer,et al.  Effect of reduced training on muscular strength and endurance in competitive swimmers. , 1986, Medicine and science in sports and exercise.