key: cord-0815167-ox7hq7m2
authors: Rico-González, Markel; Pino-Ortega, José; Ardigò, Luca Paolo
title: Playing Non-Professional Football in COVID-19 Time: A Narrative Review of Recommendations, Considerations, and Best Practices
date: 2021-01-12
journal: Int J Environ Res Public Health
DOI: 10.3390/ijerph18020568
sha: 6de04ee55182d7ee1b24b21d77505bc7ffd7a032
doc_id: 815167
cord_uid: ox7hq7m2

The coronavirus disease (COVID-19) pandemic in 2020 resulted in widespread interruption of team sports training and competitions. Our aim was to review the recommendations and best practices in return to play in non-professional football after activity lockdown. The authors searched two electronic databases (PubMed, Web of Science) to extract studies published before September 15 2020. Twenty studies explained recommendations, considerations, or best practices in return to play in football, and all of them were clustered into three groups: (1) training load management (n = 10), (2) medical recommendations (n = 9), and (3) recovery related issues (n = 5). The way to establish a progression in training process should be based on training load management and managing the number of stimuli per time. Following the studies, this training process should be divided into three phases: phase 1—physical distancing should be maintained; phases 2 and 3—group training should start. Medical considerations were clustered into different groups: general, pre- and post- training, during training, education, planning to return to competition, and suggestions for post confinement weeks. In particular, social issues, strict hygiene questions, and continuous PCR testing should be considered in return to play over football season. Finally, since a correlation has been found between high-intensive training loads and immunoglobulin A, nutritional and lifestyle recovery strategies should be performed. Moreover, since immunosuppression has been related to congested schedules (<72 h between matches), football federations should avoid this situation.

In late December 2019, a cluster of atypical pneumonia cases in the Chinese Hubei Province of Wuhan resulted in the identification of a novel coronavirus, severe acute respiratory syndrome-coronavirus 2 (SARS-CoV-2), which quickly disseminated to the rest of the world [1, 2] . With over 3.3 million confirmed cases worldwide and over 230,000 confirmed deaths, the COVID-19 pandemic is, without a doubt, the single most important event of the 21st century thus far [3] . The coronavirus disease pandemic has affected all areas of life, and sports is no exception [3] .

The COVID-19 pandemic in 2020 has resulted in widespread training and competition interruption of team sports. In return to play, in football, one of the primary concerns has been the maintenance of physical qualities, game specific contact skills, and decisionmaking ability, attenuating the injury risk on resumption of training and competition [2, [4] [5] [6] [7] [8] . Hence, sports medicine professionals were called to provide advice on return to training and competitions after the lockdown [1] . Additionally, sports scientists provided training 

The search was performed by two authors to identify articles published before 15 September, 2020, in two electronic databases (PubMed and Web of Science) before 11:00 p.m. The authors of this review were not blinded to journal names or manuscript authors. The search was conducted throughout the full text. The search strategy combined terms covering the topics of sport and pandemic-related words: ("team sports" OR basketball OR futsal OR rugby OR soccer OR football OR handball OR hockey) AND (SARS-CoV-2 OR COVID- 19) . Search strategy focused on any sports, but many of the initially retrieved records referred to football and, therefore, the review finally focused on this sport.

After completion of the search, results were compared between researchers to ensure that the same number of articles was found. Then, one of the authors (M.R.) downloaded the main data from the articles (titles, authors, dates, and databases) to an Excel spreadsheet (Microsoft Excel, Microsoft, Redmond, WA, USA) and removed duplicate records. Subsequently, the same authors screened the remaining records to verify the inclusion/exclusion criteria using a hierarchical approach in two phases. The papers were excluded when they were not original and met the following exclusion criteria: (1) no football or COVID-19 related documents; (2) not about recommendations, considerations or best 

After completion of the search, results were compared between researchers to ensure that the same number of articles was found. Then, one of the authors (M.R.) downloaded the main data from the articles (titles, authors, dates, and databases) to an Excel spreadsheet (Microsoft Excel, Microsoft, Redmond, WA, USA) and removed duplicate records. Subsequently, the same authors screened the remaining records to verify the inclusion/exclusion criteria using a hierarchical approach in two phases. The papers were excluded when they were not original and met the following exclusion criteria: (1) no football or COVID-19 related documents; (2) not about recommendations, considerations or best practices; and (3) not about recommendations or best practices concerning returning to play.

The considerations, recommendations, or best practices were summarized in Tables 1-3 and Figure 2 . Specifications were provided when the data of several studies were provided in the discussion and conclusions. 

Recommendations about?

Training Sessions (See Table 2 ) Medical Issues (See Table 3 

Recommendations about?

Training Sessions (See Table 2 ) Medical Issues (See Table 3 

Educate player in:

1. Principles of infection.

Principles of social issues 3.

Principles to report symptoms (e.g., consultation using telehealth or one by one). practices; and (3) not about recommendations or best practices concerning returning to play.

The considerations, recommendations, or best practices were summarized in Tables 1-3 and Figure 2 . Specifications were provided when the data of several studies were provided in the discussion and conclusions. 

A total of 73 documents were initially retrieved from the aforementioned databases, of which 17 were duplicated. Thus, a total of 56 articles were downloaded. After screening the titles and abstract against criterion 1 where applicable, and the full text of the remaining papers against criterion 1:14 studies did not meet the inclusion criteria. From the 42 articles, which aim to explain any point of COVID-19 and the team sport, 26 were ruled out because the articles were not about recommendations, considerations, or best practices (criterion 2). Finally, 16 articles were analyzed, and five of them did not fulfil the inclusion criterion 3. Due to the high number of published documents, based on the article per month ratio, documents published after the research date were included (n = 1). So, finally, 12 studies were included for the qualitative analysis ( Figure 1 ).

No quality assessment was done due to the descriptive nature of the studies included. All 13 articles outlined in Tables 1-3 and Figure 2 were assessed for suitability and evaluated by authors prior to inclusion. All studies had to meet all items on the criteria list to be included in the analysis.

Training recommendations, considerations, and best practices were: training process, medical considerations, and recovery-related recommendations (lifestyle, nutritional, and federation issues).

Recommendations regarding the training process are presented in Table 1 and summarized the Table 2 . Table 2 was composed by summarizing the ideas from 10 articles [1, 2, 8, 18, 19, [21] [22] [23] [24] [25] .

Medical considerations are presented in Table 1 and summarized in Table 3 . It was made from nine articles [1] [2] [3] 8, 18, 19, 21, 25, 26] . They were divided into general comments, before training recommendations, during training recommendations, after training recommendations, education issues for the players, recommendations to return to official matches, and post confinement (pre-first training) recommendations (see Table 3 ).

Recovery related recommendations were clustered into lifestyle, nutritional, and some issues related to federation decisions (Table 1 and Figure 2 ). Lifestyle and nutritional issues were summarized from three articles [2, 19, 24] and federation issues from another three [18, 19, 21] 

The main aim of this narrative review was to summarize the recommendations and best practices in return to playing football after the COVID-19 lockdown. Although this article may be useful for football in general, since professional and semi-professional leagues have already started, it will be more suitable for young and amateur teams, which continue without activity restarts. Since the COVID-19 pandemic has led players to perform in a pre-season period under an uncommon, congested calendar, a training programming should be done with caution. In this sense, a multidisciplinary approach should be performed, considering the medical recommendations as a main basis. In addition, football federations should help players and clubs avoid congested fixture schedules, which could lead to immunosuppression, and, subsequently, player vulnerabilities to virus contagion. Collected recommendations have been clustered into three groups: (1) training load management, (2) medical recommendations, and (3) recovery considerations, narrowly related with immunosuppression.

The novel perspectives have led to understand football, in general, and footballspecific actions, in particular, as those responses are conditioned by a decision (tactical dimension), a motor skill (technical dimension), which require movement (conditional dimension), and, player psychological states (psychological dimension) [27] . These dimensions may be more accurately extended in different structures identifiable in football performance: bioenergetic, cognitive, coordinative, conditional, creative, socio-affective, emotional-volitional, and mental structures [28] . Since the COVID-19 pandemic has induced competition delays, and pre-season periods are expected to be reduced, the challenge lies in achieving an interdisciplinary approach to reduce the impact of the aforementioned worldwide pandemic [2] . This approach means to develop a training process that adapts to the specific requirements of football, based on specificity, and respecting the different structures that comprise human athletes (being the ones who do sports) and their expressions in motor actions [28] . Based on this approach, the specific competitive environment of football will be facilitated to establish a relationship among the different structures and their organization [28, 29] .

The first steps are conditioned by the contradictory fact between physical distancing suggestion and football's social-nature condition. In the first weeks, bioenergetic and conditional dimensions should be separated from the others due to the mandatory situation in which the training task should be decontextualized. Based on different authors, these dimensions should be programmed from greater training volumes to greater intensity training sessions through progressive training processes [1, 2, 8, 21] . Despite the fact that this dynamic is habitually considered in pre-season periods [30] , a more congested COVID-19 pre-season could lead the team staff to program an excessive week-to-week training load progression. Following the articles, the weekly training load progressions should not be greater than 10-20%, mainly, to avoid the injury risk [21] , which has become a main challenge in the post-COVID-19 season [1, 8, 18, 19, 22, 23] .

So, as a practical viewpoint, the development of aerobic capacity and its subsequent adaptations (i.e., circulatory system, endurance performance, nerve and muscle adaptations) have become the first aim of strength and conditioning coaches. Although, this fact should be performed through decontextualized football-specific actions, due to it belong to the first phase of return to training (see Table 2 ). In addition to each player's physical fitness and conditioning assessment, the reference value could be a suitable strategy to program training loads. For example, if professional players run 9-14 km (100-150 m/min) [31] at a higher intensity than 70% of HR max [32, 33] , running most minutes at 80-90% HR max [32] , the first training programs could enroll players in 90-min training sessions with continued training efforts near 70% of HR max . Taking into account the progressive dynamic of training loads during this pre-season periods, some protocols, such as the football-specific drill proposed by Drust et al. [34] could be programmed in a second step. Nonetheless, together with bioenergetic and conditional dimensions, individually trained coordinative tasks, such as exercises with balls aimed to improve technical actions, and other tasks aimed to develop coordinative, creative, socio-affective, emotional-volitional, and mental dimensions, should also be considered in additional training drills.

Immediately after confinement, players should receive medical assessments, with body temperature assessment, respiratory/cardiovascular screening, blood analysis, and PCR, which, due to approximately five days of median incubation period for COVID-19 [3, 35] , the PCR should be repeated some days after. However, independently of the reason of the isolation training period, once the team training is started, players should be continuously enrolled in those training scenarios, demanding decision-making, cognitive, and physical skills (coordinative), and dynamic ever-changing space-time interactions between teammates and opponents in relation to the ball [36] . In this training process, creative, socio-affective, emotional-volitional, and mental structures should be the main basis, under the principle of progression, which, in this case, is related to the idea of the amount and the stimulus per time [27] . In other words, the intensity will be related to the idea of principles and sub-principles of play, and, subsequently, the greater amount of stimulus and the higher intensity demands a certain situation [27] . In this sense, the "different learning" named methodology was proposed based on non-linear pedagogy. Different authors have shown that greater complexity (i.e., more stimuli) and, subsequently, greater levels of concentration, may induce greater improvements in player performances [37] [38] [39] [40] [41] . During these tasks, the idea of concentration should always be maximum, while the bioenergetic and conditional dimensions should be progressively programmed. Therefore, in this period, training tasks should achieve through the viewpoint of all professionals involved in a team staff (e.g., head coach, strength and conditioning coach, psychological coach), the management of all dimensions using different constraints: (1) psychologic-related constraints (i.e., principles of complexity or emotional load modifications), (2) technical-tactical constraints (i.e., tactical-technical predominant actions), (3) physical constraints (i.e., preference of muscular concentrations), and (4) task constraints (i.e., number of players, space size, length of time, or level of intermittency) [27] .

In summary, the delay of return to play after confinement could aggravate those consequences resulted from other short periods of inactivity, such as summer holidays [5] . On the contrary, what was expected, pre-season periods have been congested, suggesting an excessively rapid training load progression. However, the training process should be related with the idea of progression in both senses: tactical/decision making, using the idea of stimulus, and physical/physiological, based on the idea of progressive training loads. All of these progression perspectives should confluence under a multidisciplinary viewpoint, where the teams have an indissoluble set of structures in which a certain modification in one of them will affect the others. In order to ensure that the physical/physiological objectives programmed to each session are achieved, and considering that tracking technologies are uncommon in non-professional football, real-time feedback monitoring may be an interesting strategy to be considered [23] . In this way, the training session may be stopped before finishing the programmed tasks, or to add some drills to complete each player's physical and physiological aims.

Human-to-human close contact has been highlighted as the main mode of SARS-CoV-2 transmission [25] . In fact, when a player is exposed to another infected player s droplets or aerosols, there is a risk it will enter the lungs through contact with mucosal membranes (i.e., eyes, mouth, and nose) [25] . So, despite the fact that football is an outdoor team sport played in great spaces by players, the nature of the game makes it so that the contact between teammates and opponents remains unavoidable. Such is so that some authors have assessed the number of infection risk episodes during matches [25, 42] . For example, Wong et al. [25] showed that, in a 90-min match, the players were, for a long time (i.e., 19-min) under close contact, maintaining an average of 52 episodes of infectious risky behavior [25] . These findings, together with the fact that the virus can remain on surfaces for days [43] , makes it mandatory for all medical suggestions to ensure that only safe individuals should enter into sports facilities. Therefore, Carmody et al. [26] suggested that engaging various departments within the club is essential to coordinate a safe and effective environment for athletes to train and play, together with player education, in regards to SARS-CoV-2 principles (regarding infections, social issues, and principles of transmission) [26] .

The compendium of ideas reported in the included articles (Table 2) , following different governments and football federations (e.g., Croatian [3] , Australian [44] , UK [45] , Italian [46] , or German [47] ), reveal that social issues, strict hygiene questions and continuous PCR testing should be the main basis. Therefore, triage questions (e.g., body temperature and Fever, Travel, Occupation, Contact, and Clustering (FTOCC) status) and hygiene issues (e.g., face mask (N95, FFP2, FFP3), cleaning, and disinfection) are mandatory steps before entering into training places. During training sessions, to the interdisciplinary confluence between the head coach and strength and conditioning experts, the work of the remaining workers has become crucial. Hence, team staff members should program training programs, avoiding closed spaces in clubs, and other workers should ensure clean sports equipment.

In summary, based on the wide ways of recommendations, we summarized: (1) the club personnel should warrant that training spaces and club facilities are well prepared before players return to training; (2) players should learn the main issues regarding medical recommendations; (3) coaches, strength and conditioning coaches (designing training tasks), and players (respecting medical recommendations during training) should be connected during training processes to ensure optimal environments.

Since the essential principle of training under health condition is mandatory in a return to play season, different authors have highlighted different recommendations, mainly focusing on recovery strategies, which could be the main basis to ensure an optimal immune system against upper respiratory tract infections (URTI) from virus or pathogens. To date, the most popular URTI is COVID-19, and immunoglobulin A (IgA) is the main effector against URTI [48] . Such is so that some studies have shown the relationship between IgA and URTI [49] [50] [51] .

In sport settings, different studies have shown the narrow relationship between IgA and intensive efforts [2, 19, 21, 25] , especially during congested fixtures [52] [53] [54] . Based on this scientific evidence, some studies included in this review have warned about this fact [2, 21, 25] . These suggestions have been clustered into three groups: (1) recovery strategies (nutritional and lifestyle), (2) federation decisions (i.e., schedule-related decisions), and (3) training load management (see Section 3.1). Mainly, different authors highlighted that residual fatigue should be between 24-48 h, suggesting up to 72 h of rest time between intensive and prolonged physical exertions [18, 25] . This idea is consistent with different studies that have shown decrements in IgA levels until 72 h after intense efforts [48, 50, [55] [56] [57] . Moreover, since Putlur et al. [58] found that 82% of illnesses could be explained by preceding decrease in salivary immunoglobulin A, and following Nakamura et al. [59] , who found a decrement in IgA three days before URTI, caution is needed in the distribution of high intensity sessions.

Finally, since the stress resulting from poor sleep quality, low mood, and ineffective recovery strategies may all negatively impact an individual's immune function [2, 60] , the administration of appropriate interventions based on objective evidence is a mandatory strategy [53] . In this sense, the idea of recovery strategies between matches is highly suitable, even though they are separated by more than 72 h. Specifically, since different authors have related nutritional and lifestyle recovery strategies with immunosuppression [2, 11, 19] , carbohydrate/protein enrichment diets-this, together with compression garments, soft tissue therapies, and sleep hygiene strategies, seem to be suitable strategies to ensure match-to-match and training-to-training efforts.

In summary, although these suggestions are made with caution, football federations should avoid competition programs where matches are separated for less than 72 h. Nonetheless, despite sufficient recovery time between intensity efforts, lifestyle and nutritional strategies should be followed.

It is a certainty that objective data (i.e., quantification of training load) may be helpful to conduct a cautious, pre-season after activity lockdown. However, unlike other activity lockdown situations, such as summer periods, it is speculated that several negative effects caused on athletes may suppose a novel training load management period, in which the number of injuries increase. Hence, further studies should assess training load periodization and share information to the remaining clubs. Beyond each non-professional football club's economic situation, the rating of perceived exertion (RPE) may be a suitable way to collect and share information.

Since infected human droplets or aerosols are ways to virus transmission [25] , and avoiding physical distancing seems to be the best practice to avoid it, collision sports have been empirically assessed and considered as risk environments [25] . Hence, at initial stages, training should be further to football-specific social structures, which influence collective performance. However, no study has assessed the suitability of tasks with space restrictions, where the pitch is divided into different areas and each player is assigned to one of them, according to specific playing positions, not allowing players to move out during training game [61] . These training tasks could limit social contact, while the players improve their bioenergetic, cognitive, coordinative, conditional, creative, socio-affective, emotional-volitional, and mental structures, even during the first steps of the pre-season.

It is a certainty that training load management and enough recovery periods are related with the immune system, especially, with IgA. In fact, different studies have shown the effects of very high training loads with IgA [49, 53, 62, 63] , and lower levels of IgA with URTI [49] [50] [51] 59] . However a relationship between IgA levels and SARS-CoV-19 is not clear. Further studies should assess if salivary samples may be enough to detect an infected athlete before symptoms appear. However, saliva analysis in non-professional football is not common. For this reason, further studies should corroborate the idea of relationships between IgA and other assessment methods, such as global positioning systems [52, 63] , or even with RPE [49, 62, 63] , and wellness questionnaires [54] .

Finally, it is a certainty that different game durations lead to different player performances [64] . Since some studies speculate about the modification on game duration, and others on the number of substitutions after an activity lockdown season, further studies should assess the impact of these modifications in competition demands.

Due to the immediate necessity to publish articles that guide sports practices in this critical situation, the number of articles published in a short period of time is very large. Hence, there is the possibility that publications after the search date exist that have not been included in the analysis. Furthermore, literature on different aspects of COVID-19 is accumulating fast and its quality is sometimes dubious. Therefore, this leaves some uncertainty concerning the assumptions made on this matter.

Due to the fact that, at least sometimes recommendation-based studies lack empirical data, supporting current considerations and best practices with further research studies could reduce, at least practically, the gap between the theoretical framework and daily practice.

Training sessions should start with warm-up time, when players perform ball drills, and other games improving socio-affective and emotional-volitional, even during first steps, when physical distancing should be maintained. In the main part of the session, coaches should be aware that any actions are unconditionally influenced by a context and, subsequently, the tactical dimension should be mainly considered. In this regard, training task within this part of the training should maintain the highest level of stimulus in order to warrant player concentration. However, tactical dimensions do not exist by themselves; therefore, it makes sense to take them into account only when they occur in interaction with other dimensions. Practically, coaches could consider training tasks within changing environments. Therefore, the players would train, self-adapting to these new circumstances and, simultaneously, face different game constraints (space, time, and number of players) to establish a weekly training load progression. For example, players could perform training tasks, in which boundaries are continuously changing (demand greater concentration) within greater spaces, per player, during the first steps of returning to play football, in order to perform more aerobic efforts. Moreover, players could play within smaller spaces and with greater intensity, demanding tasks as the competition period approaches.

Simultaneously during COVID-19, some strategies should be planned to warrant player predisposition for intensive training sessions or matches, over return to play during football season. In this sense, team staff members should organize theoretical sessions about nutritional and sleep hygiene strategies. On the one hand, coaches should teach players that they should follow a carbohydrate-rich diet with high protein ingestion (0.4 g kg −1 per meal), and additional probiotics, viz., vitamin C and D3 supplementation. On the other hand, players should learn the main sleep hygiene strategies: (1) post-training shower, (2) quiet, cool, and dark bed room environment, (3) avoid bedroom clocks, (4) no technology devices 1 h before sleep, (5) avoid caffeine, alcohol, and other stimulants prior to sleep, (6) high-electrolyte fluid after exercise and prior to sleep, and, (7) light, high glycemic index meals with little protein [65, 66] ). These steps should be followed prior to sleep, especially after late night sessions [67] . In addition, these educational sessions should highlight maintaining physical distancing and strict-hygiene topics, which players should become aware of since they start training and playing for their clubs.

Non-common, congested pre-season periods have given coaches and technical staff members a supreme challenge, to program training sessions and behavioral prescription, where the main aim is to achieve optimal performance for competition periods, considering the high risk of players' health. In this sense, a multidisciplinary training approach seems to be the main basis to perform it, where medical recommendations should be the key point, and federations should conduct the best schedule-related decisions to help clubs in this critical situation. 

Return to Football Training and Competition after Lockdown Caused by the COVID-19 Pandemic: Medical Recommendations

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Pre-Season Football Preparation in the Era of COVID-19: Croatian Football Association Model

Medical Recommendations for Home-Confined Footballers' Training during the COVID-19 Pandemic: From Evidence to Practical Application

The Effect of Short-Term and Long-Term Coronavirus Quarantine on Physical Performance and Injury Incidence in High

Strategies and Solutions for Team Sports Athletes in Isolation Due to COVID-19

How Has COVID-19 Modified Training and Mood in Professional and Non-Professional Football Players?

Returning to Play after Prolonged Training Restrictions in Professional Collision Sports

Methodology in Conducting a Systematic Review of Systematic Reviews of Healthcare Interventions

Sharing Information Is Probably More Helpful than Providing Generic Training Recommendations on Return to Play after COVID-19 Home Confinement

COVID-19: The Inflammation Link and the Role of Nutrition in Potential Mitigation

Functional Role of Dietary Intervention to Improve the Outcome of COVID-19: A Hypothesis of Work

Fracture Management during COVID-19 Pandemic: A Systematic Review

Resistance Training Safety during and after the SARS-Cov-2 Outbreak: Practical Recommendations

Cardiorespiratory Considerations for Return-to-play in Elite Athletes after COVID-19 Infection: A Practical Guide for Sport and Exercise Medicine Physicians

Practical Recommendations for Maintaining Active Lifestyle during the COVID-19 Pandemic: A Systematic Literature Review

COVID-19 and Review of Current Recommendations for Return to Athletic Play

Position Statement of the Royal Spanish Football Federation for the Resumption of Football Activities after the COVID-19 Pandemic

Return to Elite Football after the COVID-19 Lockdown

Preferred Reporting Items for Systematic Review and Meta-Analysis Protocols (PRISMA-P)

Considerations and Best Practices for Elite Football Officials Return to Play after COVID-19 Confinement

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

Elite Football of 2030 Will Not Be the Same as That of 2020: Preparing Players, Coaches, and Support Staff for the Evolution. Scand

Season Suspension and Summer Extension: Unique Opportunity for Professional Team-Sport Athletes and Support Staff During and Following the COVID-19

Impact of the COVID-19 Pandemic on Sports and Exercise. Asia-Pac

Football-Specific Strategies to Reduce COVID-19 Transmission

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Quantifying the Physical Loading of Five Weeks of Pre-Season Training in Professional Soccer Teams from Dutch and Portuguese Leagues

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The Effects of an Enrichment Training Program for Youth Football Attackers

Individual and Collective Creativity in Young Footballers

Effects of the Skills4Genius Sports-Based Training Program in Creative Behavior

Differential Learning as a Key Training Approach to Improve Creative and Tactical Behavior in Soccer

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Immune Function and Exercise

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The Sleep-Immune Crosstalk in Health and Disease

Effects of Pitch Area-Restrictions on Tactical Behavior, Physical, and Physiological Performances in Soccer Large-Sided Games

Salivary Immunoglobulin A Response to a Match in Top-Level Brazilian Soccer Players

High-Intensity Training and Salivary Immunoglobulin A Responses in Professional Top-Level Soccer Players: Effect of Training Intensity

A Match-Derived Relative Pitch Area Facilitates the Tactical Representativeness of Small-Sided Games for the Official Soccer Match

Acute Sleep Hygiene Strategy Improves Objective Sleep Latency Following a Late-Evening Soccer-Specific Training Session: A Randomized Controlled Trial

Sleep Hygiene and Recovery Strategies in Elite Soccer Players

Effect of Acute Sleep Hygiene on Salivary Cortisol Level Following A Late Night Soccer-Specific Training Session

Funding: This research received no external funding.

Informed Consent Statement: Not applicable.

The authors declare no conflict of interest.