Junior tennis

Sweating rates in excess of 1 L/h have been reported with young adolescent players during tennis practice4 and tournament competition8 in the heat, including during doubles play. This, of course, varies with on-court environmental heat stress (air temperature, humidity and solar radiation) and intensity and duration of play, as the need for evaporative cooling and thus sweating fluctuate proportionately. With older adolescents, the sweating rate during intense practice and competitive play in challenging environmental conditions can often reach 2.5 L/h or more.1 ,2 Across this entire range of sweat loss rates, however, junior tennis players are not always effective at appropriately minimising body water deficits during practice or play or recovering with sufficient fluid intake between matches.

In contrast to earlier findings with non-tennis youth,12 ,13 unflavoured water has recently been shown to be equally effective as a carbohydrate-electrolyte sports drink (CHO-E) in encouraging voluntary fluid intake in physically active young girls during intermittent exercise in the heat,14 adolescent boys during basketball15 and notably with high-level, fit junior tennis players during intense on-court training in very warm conditions outdoors.4 Effective rehydration, however, during and after play, often involves more than simply ample fluid intake. On-court sweat sodium losses can be substantial, even for a young tennis player who is well acclimatised to the heat.1 ,2 Accordingly, sweat electrolyte losses (particularly sodium and chloride) incurred during play must be replaced as well, in order to fully rehydrate and optimise body water retention and distribution in all fluid compartments.16–20

Adult tennis

On-court sweating rates and related sodium losses in adult tennis players are generally comparable to those in older adolescents (though they are often much greater for some adults) during intense practice and competitive play.2 ,3 ,5 ,9 ,21

Hornery et al9 examined 14 male professional tennis players (21.4 (2.6) years) during international tournament competition on hard courts in the heat (32.0 (4.5)°C) and clay courts in somewhat less stressful environmental conditions (25.4 (3.8)°C). Postmatch body mass deficits were significantly greater during hard court competition (1.05 (0.49)%) compared to only 0.32 (0.56)% following the clay court matches. Tippet et al5 assessed seven professional women players during outdoor tournament play on hard courts in similar hot environmental conditions (30.36 (2.36)°C). Although the on-court sweating rate was extensive with 2.0 (0.5) L/h, postplay body weight deficits were only modest (1.2 (1.0)%).

Bergeron et al3 evaluated 20 (12 male and 8 female) tennis players from two Division I university tennis teams during three successive days of competitive round-robin play (ie, 2 singles tennis matches followed by 1 doubles match per day) in a hot environment (32.2 (1.5)°C and 53.9 (2.4)% relative humidity at 1200 h). During singles play, percentage changes in body weight were minimal and similar for all players (men: –1.3 (0.8)%, women: –0.7 (0.8)%), and estimated losses (mmol/day) of sweat sodium (men: 158.7; women: 86.5) were generally met by daily dietary intake. However, as with many older adolescent players, on-court and consequent daily accumulated body water and sodium losses and deficits can be much greater from extensive sweating and often need to be more deliberately replaced to adequately rehydrate and maintain more optimal body water retention and distribution, especially with successive days of training or tournament play.1 ,2 ,16 ,22

Table 1 provides three representative examples of sweat loss (water and sodium) rates (group mean and selecting the lowest and highest sweat rates) from a group of 17 players evaluated on court during hard-court singles tennis in hot environments.2 With the respective rates of observed fluid intake (water only), the table demonstrates how these water and sodium losses from sweating would play out in match-play—contrasting the consequent postplay body water and sodium deficits incurred after 1.5 and 4 h of singles match-play (which could be from a single very long match or cumulatively from two closely scheduled same-day matches, recognising that part of the water and sodium deficits would be recovered in between matches in the latter scenario). Such resultant match-play deficits are often in addition to the already existing preplay deficits incurred from previous matches or practice/warm-up sessions that were never fully restored. This is frequently the case in tournament play when multiple same-day matches are contested on successive days.

Junior tennis

Especially during a hard practice session or an intense competitive match in the heat, a young player's metabolic heat production, heat storage and thus body core temperature can be expected to progressively increase. While visible indications of thermal strain in young players are routinely witnessed during hot-weather competition, the full extent and prevalence of excessive body core temperature and exertional heat illness incurred on court, as well as the consequent contributing role of thermal strain in performance outcome, are largely unknown in junior tennis.

Bergeron et al4 examined differences in ad libitum fluid intake, comparing a 6% CHO-E and water, and thermal strain in highly skilled, fit junior tennis players (15.1 (1.4) years) during intense on-court training in a very warm environment (wet-bulb-globe temperature (WBGT) ∼26.4°C). With a randomised, cross-over design (two 2 h test training sessions on separate days, separated by 1 day), the players experienced the same environment, workload, intensity, drill sequence, break times and activity/rest intervals, to maintain consistency (as much as possible) in the metabolic rate and load between trials. Moreover, players assigned to the CHO-E condition hit with those using water, to further equalise workload and metabolic rate between groups. Accordingly, the average total sweat loss in each group was the same (just over 2.2 L), as was the fluid intake (just over 1.8 L). While a number of players began the monitored training sessions not well-hydrated, prepractice urine-specific gravity (also the same between trials) was not statistically associated with body core temperature responses (which approached or reached 39°C for some players) during the 2 h practice sessions, and no players had any visible indications of excessive thermal strain. However, in examining the main effect for trial (water vs CHO-E), a significantly (p<0.001) lower mean body temperature was observed during the CHO-E trial than during the water trial (37.97 (0.24)°C vs 38.20 (0.31)°C, respectively). Although such a small difference in the observed thermal strain is not likely to be clinically relevant or provide a noticeable performance advantage, it speaks to an apparently measurable effect of drink content (Na⁺) on potentially enhancing body water distribution and thermoregulation.17–19 ,23

Until now, only one study has examined body core temperature in junior tennis players during an actual sanctioned tournament competition. Bergeron et al8 observed eight elite-level young boys (13.9 (0.9) years) during the first round of singles and doubles play in a US Tennis Association national championships event during the first week in August. In contrast to the 2 h practice sessions in somewhat less stressful environmental conditions described above,4 preplay hydration status (urine-specific gravity) in these tournament players was progressively and ultimately strongly associated (r=0.87; p=0.005) with on-court thermal strain (38.7 (0.3)°C at the end of match-play, while exceeding 39°C for some players) during singles competition. While recognising the difference in environmental stress between the two scenarios, these differing relationships between preactivity hydration status and subsequent on-court thermal strain underscore the distinctive characteristics of individual or team practice sessions, where the emphasis is on completion versus winning. That is, players may be able to ‘‘get away with’’ a greater level of dehydration during practice, without that fluid deficit necessarily translating into a significant increase in body core temperature or risk of heat-related complications, because the intensity of activity is typically not sustained at a competitively high level. During elite individual sport competition such as these national championships (or even local and regional contests), however, young athletes will often maintain a strong effort and intensity, despite not feeling 100% or even having the capacity to safely continue. The degree of thermal strain observed in this tournament play study is particularly notable, as the singles matches were relatively short and contested mostly in the morning (WBGT 29.6 (0.4)°C), which also underscores the contrast of metabolic heat production and storage during meaningful competition (vs practice or simulated contests). It is also noteworthy that the preplay to postplay increase in body core temperature from 37.6 (0.2)°C to 38.7 (0.3)°C (p<0.001) during singles remained elevated (38.4 (0.3)°C), even after 10 min following the end of play. As with most dedicated efforts to win, with the later rounds of more competitive play in this event, these elite players characteristically maintained a strong effort and very high intensity, even when facing more challenging environmental heat stress. Unfortunately, the likely greater body core temperature responses were not collected. This study also highlights how even doubles play in junior tournament-level tennis can elicit appreciable thermal strain in hot conditions.

Adult tennis

Hornery et al9 reported moderate thermal strain with similar peak body core temperatures during hard and clay court tournament play (38.9 (0.3)°C vs 38.5 (0.6)°C). With female professional players, Tippet et al5 observed a similar mean body core temperature of 38.65 (0.20)°C throughout match-play and a peak temperature of 39.13 (0.34)°C. The notable aspect of this latter study was a specific examination of the effectiveness of the Women's Tennis Association Extreme Weather Conditions Rule (allowing for a break in play between the second and third sets of a match) in reducing thermal strain. Although body core temperature decreased by 0.25 (0.20)°C after a 10 min break, it remained slightly higher than it was at the start of set two. Subsequently, there was a similar degree of peak thermal strain by the end of play as was observed at the end of the second set. Whether thermal strain at the end of play would have been higher had the players not taken a between-set break is unknown.

Players, parents and coaches

• Progressive acclimatisation—that is, graduated appropriate exposure to a hot and/or humid environment and the intensity and duration of practice/training and competition—is essential to improve performance and minimise the risk of exertional heat illness, especially when travelling to a more stressful (greater heat and/or humidity) environment.37 ,57

• Tennis players often begin competition measurably dehydrated, which can increase on-court cardiovascular and thermal strain. All players have the responsibility to be well hydrated and well nourished prior to playing. Regular appropriate fluid intake during play and a deliberate effort to fully (or as appropriate) rehydrate between on-court sessions should be a priority for all players, especially in the heat.1–5 ,58

• Effective rehydration involves more than simply ample water intake. Sufficient electrolytes (especially sodium) need to be consumed as well to offset often extensive sweat-related electrolyte losses and to better retain and distribute ingested water.1–3 ,16 ,59 ,60

• Incomplete between-match rehydration is often impossible to avoid when multiple same-day singles matches are played and sweating has been extensive, with inappropriately short rest and recovery periods scheduled between contests. In these instances, it is imperative to begin the first match of each day well hydrated and well nourished (especially having sufficiently restored carbohydrate and sodium levels) and immediately begin appropriate postplay rehydration and macronutrient intake (carbohydrate and protein) in order to minimise preplay body water and electrolyte deficits and maximise muscle and energy recovery before the next match. Along with water, a cold carbohydrate–protein replacement drink and small, easily digestible salty snack can be more effective and better tolerated in the heat than a large amount of solid food, especially when there is little time between matches. As between-match time increases, proportionately bigger meals and more optimal fluid intake volume can be considered.58 ,59

• In extreme heat conditions, players should take advantage of opportunities to minimise heat exposure (eg, shorten the prematch warm-up, stay out of the heat prior to play as much as possible and stand in the shade between points, if such areas are available) and maximise cooling opportunities—preplay, on-court and immediately after play. While there has been limited tennis-specific research on popular effective methods for precooling and recovery (eg, ice slurries and cold/ice water baths),55 ,56 ,61 players are increasingly recognising their appeal and apparent effectiveness. Ice slurries can also be convenient during match-play changeovers, although their effectiveness, along with that of applying ice bags/towels or ice/cooling vests during these brief periods, in lowering physiological strain, improving safety or providing a performance advantage on-court has not yet been demonstrated empirically.

• Coaches must be prepared to adjust for changing weather conditions, while recognising that tolerance to physical activity decreases and exertional heat illness risk increases, as the heat and/or humidity rise. Accordingly, it is imperative to modify practice and training duration and intensity, and increase the frequency of breaks, to maintain safety and performance.37 ,48 The same considerations should apply to prematch warm-ups in hot weather tournaments.

• A player's individual level of fitness and medical status also directly affect on-court performance and exertional heat illness risk, especially in the heat. Thus, individualised appropriate modifications to practice and training are essential. Importantly, players should avoid or significantly limit practice, training and competition in the heat if they are currently ill or are recovering from illness, especially those illnesses involving gastrointestinal distress (eg, vomiting, diarrhoea) and/or fever.37 ,48 ,62

• All players should be closely monitored in the heat, and a prompt and appropriate response, including immediately stopping participation and seeking appropriate medical attention and treatment, should be implemented at the earliest signs of developing exertional heat illness.37 ,49 ,62

Tournament administrators and tennis governing bodies

• Multiple competitive matches on the same day can pose a particular performance challenge and exertional heat illness risk due to insufficient recovery time and rehydration between contests, as well as potential carry-over effects from the previous match.24 ,58 Tennis governing bodies and tournament administrators should provide longer rest and recovery periods between same-day matches as environmental heat stress increases, to improve player safety and performance.

• Effective written protocols should be in place and practised and trained personnel with readily available facilities should be on-site for treating all forms of exertional heat illness for tennis tournaments played in warm to hot environmental conditions.