A global emergency characterized by a respiratory illness called COVID-19 (coronavirus disease) has spread worldwide in early 2020. Preventive measures to reduce the risk of infection include social distancing and the closing of commercial activities to avoid social gatherings. Elite sport is also tremendously affected: ongoing championships have been suspended and the major international events have been postponed (e.g. Summer Olympics, UEFA European Football Championship). This is the first time since the Second World War that all elite athletes are forced to interrupt competitions. Further, most elite athletes are forced to train at home, on their own and mostly unsupervised. Some elite sports clubs have provided players with home-based training programs and/or organized video conferences for online training sessions lead by their fitness trainers. However, logistical constraints and the difficulty to implement sport-specific exercise strategies in the absence of official sports facilities/playgrounds, make it difficult to provide training solutions comparable to those adopted under normal circumstances. During COVID-19 home confinement, athletes are likely exposed to some level of detraining (i.e. the partial or complete loss of training-induced morphological and physiological adaptations), as a consequence of insufficient and/or inappropriate training stimuli [1]. Such changes may result in impaired performance and increased injury risk (e.g. ligament rupture and muscle injuries) if, upon restart, an appropriate sport-specific reconditioning cannot be granted. Moreover, athletes on their return to sports journey may suffer from inappropriate rehabilitation/reconditioning and, therefore, a higher risk of re-injury, when championships would suddenly continue. Cardiorespiratory and neuromuscular adaptations are fundamental in different sports and substantial declines (e.g. 4–14% in maximal oxygen uptake) are known to occur after short-term (< 4 weeks) training cessation [1]. Further, injury occurrence seems to be regulated by a complex mechanical interplay between tissue stress, strain and loading [2]. Therefore, alterations in mechanical structures, such as muscles and tendons, are likely involved in the injury process.
Lessons from physiological studies on muscle and tendon adaptations to unloading (such as bed rest (BR) and unilateral lower limb suspension (ULLS), which can be considered as an extreme form of detraining) taught us that changes in muscle size (e.g. ∼ 5 and ∼ 10% reduction in knee extensors cross-sectional area after 14 and 23 days of ULSS) and architecture (e.g. ∼ 6 and ∼ 14% reduction in vastus lateralis fascicle length and pennation angle, respectively, after 5 weeks of BR) can occur in lower limb muscles even after the exposure to short-term unloading [3, 4]. The rate of muscle disuse atrophy may be even more accelerated in elite athletes since highly trained subjects with greater initial muscle mass exhibit accentuated muscle loss [5]. Besides, morphological changes, reductions in muscle strength (e.g. ∼ 15% of the knee extensors maximum voluntary contraction torque in two weeks of ULLS), power (e.g. ∼ 10% after two weeks of BR) and rate of force development (e.g. ∼ 42% after two weeks of ULLS) have been observed after short-term disuse [3, 6] and training cessation (∼ 7–14% in strength/power performance) [7, 8]. Moreover, significant deterioration in tendon mechanical properties also occurs (e.g. ∼ 10% in tendon stiffness and Young’s modulus after two weeks of ULLS) [3]. Unfortunately, there is limited literature allowing a direct translation of such observations to elite sport, as the available evidence has focused on postinjury conditions [9] or on the detrimental effects of the off-season [10]. Previous work can scarcely mimic the situation that athletes are experiencing now, with a sudden and longer than normal reduction in total training loads and the challenge to provide sport-specific stimuli. Nevertheless, we could rely on disuse-based studies to hypothesize that, in this period of activity reduction, muscles and tendons will undergo alterations of a similar nature. Accordingly, since factors, such as muscle strength and architecture, and tendon structure has been suggested to influence injury risk, after this period of detraining, athletes may be more susceptible to injury throughout an alteration of the tissue-specific mechanical properties after COVID-19 home confinement release [2]. There is a previous similar scenario after the National Football League (NFL) lockout in 2011, where during a period over 3 months players underwent an uncommon off-season without normal access to their facilities and training resources, where a higher rate of Achiles tendon injuries occurred over the first period of the training camp and the subsequent season [11]. Morover, in this scenario, teams must guarantee in the most objective way possible the physical status of the athletes, to bridge the potential gap between the athletes’ perceived (and their urge to compete) versus actual sportreadiness [11].
To date, it is difficult to predict when elite sports will restart. Two different scenarios are possible. In the first one, the COVID-19 pandemic situation will improve relatively quickly and governance would permit to restart sports events behind closed doors. In this scenario, in order to conclude championships once the emergency will end, a lot of matches/events would be probably condensed (e.g. with mini tournaments) in a short time and athletes may be unprepared to cope with the elevated training and match demands. For this reason, a sport-specific reconditioning period would be necessary for the athletes to recover their in-season neuromuscular and cardiorespiratory qualities; thus, potentially reducing the risk of injury, similar to what generally happens during the pre-season after a transition period [12]. In the second scenario, the emergency will continue and championships will not be completed. This situation of insufficient and/or inadequate training would be protracted for several months and the associated physiological decline may be even more accentuated. In this case, a prolonged pre-season would be warranted to allow full resurgence of athletes’ physiological and mental function and performance.
With this perspective, we aim to recommend extreme caution in sports programming after the COVID-19 emergency and we advise to involve all stakeholders in the decisions (e.g. medical staff, head of performance, coaches, fitness trainers and players). We are still unsure when and how to restart championships and events, but we advise to consider the impact that choices could have on injury risk in elite athletes.
References
Mujika I, Padilla S. Detraining: loss of training-induced physiological and performance adaptations. Part I: short term insufficient training stimulus. Sport Med. 2000;30(2):79–877. https://doi.org/10.2165/00007256-200030020-00002.
Kalkhoven JT, Watsford ML, Impellizzeri FM. A conceptual model and detailed framework for stress-related, strain-related, and overuse athletic injury. J Sci Med Sport. 2020. https://doi.org/10.1016/j.jsams.2020.02.002.
de Boer MD, Maganaris CN, Seynnes OR, Rennie MJ, Narici MV. Time course of muscular, neural and tendinous adaptations to 23 day unilateral lower-limb suspension in young men. J Physiol. 2007;583(3):1079–91.
de Boer MD, Seynnes OR, di Prampero PE, Pišot R, Mekjavić IB, Biolo G, et al. Effect of 5 weeks horizontal bed rest on human muscle thickness and architecture of weight bearing and non-weight bearing muscles. Eur J Appl Physiol. 2008;104(2):401–7.
Miles MP, Heil DP, Lason KR, Conant SB, Schneider SM. Prior resistance training and sex influence muscle responses to arm suspension. Med Sci Sports Exerc. 1983;37(11):1983–9.
Rejc E, Floreani M, Taboga P, Botter A, Toniolo L, Cancellara L, et al. Loss of maximal explosive power of lower limbs after 2 weeks of disuse and incomplete recovery after retraining in older adults. J Physiol. 2018;596(4):647–65.
Bosquet L, Berryman N, Dupuy O, Mekary S, Arvisais D, Bherer L, et al. Effect of training cessation on muscular performance: a meta-analysis. Scand J Med Sci Sport. 2013;23(3):140–9.
Mujika I, Padilla S. Muscular characteristics of detraining in humans. Med Sci Sports Exerc. 2001;33(8):1297–303.
Milsom J, Barreira P, Brugess D, Iqbal Z, Morton J. Case study: muscle atrophy and hypertrophy in a premier league soccer player during rehabilitation from ACL injury. Int J Sport Nutr Exerc Metab. 2014;24(5):543–52.
Suarez-Arrones L, Lara-Lopez P, Maldonado R, Torreno N, De Hoyo M, Nakamura FY, et al. The effects of detraining and retraining periods on fat-mass and fat-free mass in elite male soccer players. PeerJ. 2019;2017:7.
Myer GD, Faigenbaum AD, Cherny CE, Heidt RS, Hewett TE. Did the NFL lockout expose the achilles heel of competitive sports? J Orthop Sports Phys Ther. 2011;41(10):702–5.
Silva JR, Brito J, Akenhead R, Nassis GP. The transition period in soccer: a window of opportunity. Sport Med. 2016;46(3):305–13.
Author information
Authors and Affiliations
Contributions
FS, FMI and MVF designed and conceptualised the paper. FS, FMI, JS, SP, IM, NAM and MVF wrote the initial draft. LSA, AA, JB, MB, JC, AC, DN, LTR add AMV revised the draft and endorsed it in its final form. All authors contributed to the manuscript and approved the final version.
Corresponding author
Ethics declarations
Conflict of interests
None of the authors have any conflicts of interest to declare.
Funding
No funding was received for the preparation of this article.
Rights and permissions
About this article
Cite this article
Sarto, F., Impellizzeri, F.M., Spörri, J. et al. Impact of Potential Physiological Changes due to COVID-19 Home Confinement on Athlete Health Protection in Elite Sports: a Call for Awareness in Sports Programming. Sports Med 50, 1417–1419 (2020). https://doi.org/10.1007/s40279-020-01297-6
Published:
Issue Date:
DOI: https://doi.org/10.1007/s40279-020-01297-6