The Tokyo 2021 Summer Olympics (Tokyo 2020, postponed to 2021) was expected to be held on one of the hottest days recorded thus far (ambient temperature 27–31 ™ƒ, 60–80%relative humidity in July and August) (Gerrett et al., 2019; Notley et al., 2020). These hot-humid environmental conditions pose a major challenge to the physiological status of athletes (Vanos et al., 2018). As shown previously, exposure to hot climatic conditions could cause a decrease in athletic performance and potentially compromise safety during the competition (Choo et al., 2017; Wendt et al., 2007) perhaps by through elevated: thermoregulatory strain (Havenith and Fiala, 2016), cardiovascular strain (Cheung and Sleivert, 2004), thermal perception (Schlader et al., 2010), and by altering the function of the central nervous system (Nybo, 2011). During exercise, hyperthermia could distribute more blood for peripheral convective cooling and augment sweat loss for evaporative cooling (Reilly et al., 2006), which impaired exercise capacity (Nybo, 2008). Furthermore, the augmented sweat loss could induce a progressive decrease in body fluids and lead to dehydration (Nassis and Geladas, 2003a; Nassis and Geladas, 2003b; Quod et al., 2006). A low degree of dehydration could impair thermoregulatory function and aggravate cardiovascular strain (Kenefick, 2018). Once the water deficit of body mass exceeds ~2%, endurance exercise performance declines under hot conditions (Cheuvront et al., 2003).

Athletes may use practical and effective pre-cooling strategies and devices to alleviate the adverse effects of hot conditions, and improve their exercise performance and capacity (Gibson et al., 2019; Périard et al., 2016). These strategies aim at reducing the body temperature before exercising in a hot environment (Bongers et al., 2014; Cotter et al., 2001; Marino, 2002; Montain and Coyle, 1992; Wohlfert and Miller, 2019). Pre-cooling strategies can decrease thermoregulatory strain, cardiovascular strain, improve thermal perception (Cheuvront et al., 2003; Siegel et al., 2011), and subsequently reduce the level of hyperthermia and dehydration (Montain and Coyle, 1992). Pre-cooling can attenuate the total sweat loss under hot conditions (Faulkner et al., 2019; Wilson et al., 2002). However, was there an unequivocal conclusion that pre-cooling could improve hydration when the total sweat loss decreased. Hence, the effects of pre-cooling on the hydration require further research.

Pre-cooling strategies are classified according to the application of the cooling technique used, that is, whether applied externally (the surface of the body) or internally (into the body through the mouth and/or nose) (Ross et al., 2013). Internal cooling can increase body heat storage capacity and reduce heart rate by decreasing the core temperature (Marino, 2002; Quod et al., 2006; Wegmann et al., 2012). External cooling can reduce blood flow in the skin (James et al., 2015) via superficial blood vessel constriction and increase the heat gradient from the core to the skin, thereby facilitating heat loss (Cheuvront et al., 2010). When compared with non-cooling strategies, the use of internal pre-cooling strategies showed increase in time to exhaustion (19–31.9%) in highly trained athletes (>55 mL/kg/min of VO₂max), while external cooling elicited increase in distance (3.6–13.1%) covered by highly trained athletes (Rodríguez et al., 2020). However, large volumes of fluid consumed before high-intensity exercise could result in a high risk of gastrointestinal upset or discomfort (Ross et al., 2011), which could lead to shivering and increase glycogen utilization (Jacobs et al., 1994). Besides that, the stronger cooling power of pre-cooling protocol (exposure more part of body, longer period, and lower temperature) could induce muscle stiffness and uncomfortable sensations of coldness (Yeargin et al., 2006). Additionally, the mixed-method cooling (combination of internal and external strategies) vs. internal or external strategies did not exhibited any significant benefit, although a mixed-method approach showed a favourable trend to reduce thermal and improve performance in highly trained athletes (Rodríguez et al., 2020). To date, none of the studies on this topic have focussed on the effect of mixed-method cooling on the time to exhaustion under heat stress conditions in highly trained athletes (Aldous et al., 2019; Munoz et al., 2012; Ross et al., 2011).

Using this underlying rationale, the aim of this study was to determine whether a mixed-method cooling would exert potential ergogenic effects on the time to exhaustion (a measure of exercise capacity or endurance) under heat stress conditions in highly trained athletes. The other objective was to investigate whether the modified pre-cooling intervention, which did not cause gastrointestinal discomfort or shivering (Daries et al., 2000), could improve exercise performance while exercising in the heat. We hypothesised that pre-cooling approaches, including internal, external and mixed-method cooling strategies, could prolong the duration of exercise at a speed of 80% of VO₂max under heat stress conditions in highly trained athletes.

Seven male college athletes volunteered to participate in this study. No participant is acclimatised to the heat conditions. The mean age, stature, mass, body fat, and VO₂max were 20.3 ± 1.3 years old, 1.83 ± 0.04 m, 84.3 ± 4.7 kg, 12.7 ± 4.5%, and 60.71 ± 4.07 mL·kg^-1·min^-1 (55-66 mL·kg^-1·min^-1), respectively. All participants were rugby players who regularly trained 5 times per week (20 hours per week). Their training history was 15.1 ± 2.7 years (10–18 years) of training. All procedures complied with the guidelines prescribed by the Declaration of Helsinki, 2013. Permission was obtained from the ethical committee of the Chinese Institute of Sport Science (the Fundamental Research Foundation of the China Institute of Sport Science (20-06) and the National Natural Science Foundation of China (11775059)). All volunteers provided verbal and written informed consent prior to this investigation.

All experimental procedures were conducted in the laboratory during the spring season (March to April) in Beijing, China. Athletes were in a fully hydrated state before arrival to the laboratory and refrained from strenuous exercise, caffeine intake, and alcohol consumption for 24 h prior to the experiments. Every volunteer was advised to replicate food and fluid supplementation for 24 h before the experiments. Trials were performed at 7-day intervals and were conducted at the same time of the day to eliminate the effects of circadian rhythm. The integrated experimental plan is shown in Figure 1.

All volunteers completed a graded exercise test (GXT) on a treadmill (Pulsar, H/P/Cosmos Sports & Medical, Nussdorf Traunstein, Germany) to get the VO₂max, which is the maximal rate of whole-organism oxygen consumption during the GXT (Daries et al., 2000; Millet et al., 2003), at normal temperature (27 ™ƒ, 40% RH) prior to the commencement of the experimental trials. The GXT included a continuous protocol on the treadmill as per previously described methods (Metaxas et al., 2005). Briefly, the participants began running at 8.0 km/h and 1.0% grade for 3 min. The speed was increased by 2.0 km/h every 3 min. When the treadmill speed reached 14.0 km/h, the grade increased to 2.0%. Thereafter, the speed continued to increase by 2.0 km/h every 3 min until a stage with a speed of 20.0 km/h was reached. Once this stage was reached (20.0 km/h and 2.0% grade), the treadmill speed and grade remained unchanged until volitional exhaustion. The criteria for reaching VO₂max were coincided with at least 2 as follows: 1) HR recorded a value 220-age; 2) the respiratory exchange ratio was higher than 1.05; 3) the RPE reached 19–20; 4) the participant could not keep up with the exercise intensity (Katica et al., 2017; Krishnan et al., 2017). Following the GXT, the participants rested in the laboratory. After the resting period, they had a short run at a speed of 80% VO₂max (3 min) in order to familiarise with the speed.

All experimental procedures (control and pre-cooling conditions) were conducted at the Special Environment Laboratory (CNRO Science Technology, Tianjin, China) at the Emphasis Laboratory of the General Administration of Sport of China. The experimental procedures were performed in a hot and humid environment (38.1 ± 0.6 ™ƒ, 55.3 ± 0.3% RH), in a randomised order. At the beginning of each experimental session, in a 27 ™ƒ, and 40% RH environment, a 30-min warm-up protocol at 60% VO₂max intensity was performed by each volunteer. After this warm-up, all physiological, psychological, and biochemical parameters were recorded for 5 min before pre-cooling (before). Thereafter, the 30 min of control procedure and the pre-cooling protocol were performed in a hot and humid environment (38.1 ± 0.6 ™ƒ; 55.3 ± 0.3% RH) under four separate conditions, as follows: 1) volunteers sat with no pre-cooling and ingesting nothing (CON); 2) volunteers wore a vest cooled to a temperature of 4 ™ƒ (Vest) as the external cooling method without ingesting any fluid; 3) volunteers ingested a beverage cooled to a temperature of 4™ƒ at a dose of 2.3 mL/kg body mass (Beverage) as the internal cooling method; and 4) the external and internal cooling methods were performed simultaneously (Mix). The vest (2.4 kg, Raxwell RAX-201, SYSBEL, Shanghai, China) could deposit four sealed cooling packs containing phase change material (0.4 kg, Raxwell RAX-2011, Sysbel, China) in two anterior and posterior pockets and was tested using an infrared thermometer. The cooling beverage (6% carbohydrate, Gatorade, PepsiCo, New York, USA) was ingested at the beginning of pre-cooling, at 10 min and 20 min of pre-cooling period. When the 30-min pre-cooling procedures were completed, the physiological parameters were recorded for a 5-min (after). Thereafter, the exercise protocol was performed at a speed of 80% VO₂max on a treadmill until volitional exhaustion (Figure 1). When the exercise regimen was completed, the physiological parameters were recorded once again (exhaustion).

Height (GMCS-IV stadiometer, shanghai, China, accuracy of 0.01 m) and weight (RCS-2 electronic scales, shanghai, China, accuracy of 0.01 kg) of each participant were measured in the laboratory. Fat mass was determined using dual-energy X-ray absorptiometry scan (DXA, Lunar Prodigy; General Electric, Madison, WI, USA). Expired air samples were collected via a metabolic cart (Cortex Biophysik Metalyzer 3B, Leipzig, Germany) to determine VO₂max, which was calculated as the average of the VO₂ values measured over the final 30 s.

Urine samples were collected before pre-cooling and after exercise to determine the urine specific gravity (USG) by using a hand-held refractometer (MASTER-URC/NM, ATAGO, Japan). After removing sweat with a towel, the body mass was determined using a weighting scale (InBody 370, InBody, Korea). The whole body sweat loss (SL) was calculated using a modified equation corrected for fluid ingestion, urine excretion, and blood removal (Stevens et al., 2016). Thus, the SL (L) can be estimated using Eq.1 mentioned below:

SL=W₀-W+F-U-B      (1)

Where, W₀ is the initial body mass measurement of pre-cooling (W_Before). W is the final body mass measurement of exercise (W_Exhaustion). F indicates the fluid ingested, U is urine volume, and B is blood removed.

Heart rate (HR) was recorded with a chest HR sensor monitor (H10, Polar, Finland) and a sports watch (V800, Polar, Finland) throughout the pre-cooling and exercise protocol. T_core was measured with a thermometer (T12, DEDAKJ, Germany), self-inserted in the volunteer’s rectum approximately 10 cm past the edge of the anal sphincter and securely positioned. T_skin was recorded with thermocouple thermometers (YHT309, ShenZhen YuanHengTong Technology, China) at the following locations: forehead (T_forehead), left upper chest (T_chest), right scapula (T_scapula), right upper arm (T_upper-arm), left lower arm (T_lower-arm), left hand (T_hand), right anterior thigh (T_thigh), and left calf (T_calf). Mean T_skin was estimated as (Faulkner et al., 2019):

The rating of perceived exertion (RPE) and thermal sensations (TS) were recorded every 5 min during the pre-cooling period and exercise protocol with the 6–20 RPE scale (6: least effort, 20: maximum effort) and the 0–8 TS scale (0: unbearably cold, 8: unbearably hot) (Bedny and Seglin, 1997; Gagge et al., 1969). Blood was collected from the fingertip to determine the blood lactic acid ([Bla]) concentration using a Lactate Scout portable lactate test analyser (EKF Diagnostics, Berlin, Germany). Blood sample (5 mL) were collected from the antecubital vein of the arm. A coagulant was added to all blood samples to separate the serum via centrifugation (X-15R, Beckman, American) at 4 ™ƒ for 15 min. The separated serum sample was stored at -80 ™ƒ until determination of sodium (Na⁺) and potassium (K⁺) concentrations. The concentrations of sodium and potassium were tested using an ion selective electrode (ISE, Roche Group).

The data were non-normally distributed. Consequently, the Kruskal-Wallis H test used to test the differences between variables, which served as the primary test for assessment of potential statistical differences. The Kruskal-Wallis H test was used to determine differences in HR, T_core, T_skin, Na⁺, K⁺, RPE, TS, and [Bla] values before and after pre-cooling and at the end of exercise, SL during pre-cooling and exercise, and time to exhaustion and USG at the point of exercise exhaustion, between the four pre-cooling trials. When a difference was detected, the Cohen’s d effect sizes (ES) were then verified to evaluate the level/degree of difference. The following criteria were used: an ES <0.2 was classified as ‘trivial’, ES = 0.2–0.49 as ‘small’, ES = 0.5–0.79 as ‘moderate’, and ES>0.8 as a ‘large’ effect (Hopkins et al., 2009). Data were analysed using Statistics SPSS 22.0 for Windows (Version 22, SPSS Inc., Chicago, Illinois, USA) with statistical significance set at p < 0.05 and high statistical significance set at p < 0.01. All data are presented as mean ± standard deviation (S.D.).

The time to exhaustion was longer in Mix (648.43 ±77.53 s) compared to that in CON (509.14 ± 54.57 s, H = 9.120, p = 0.016, ES = 0.72, Figure 2). There was no difference between other pre-cooling trials and CON (Vest: 582.43 ± 86.81 s, p = 0.81, Beverage: 591.57 ± 99.94 s, p = 0.493).

No significant differences were observed in VO₂ at exhaustion among the four trials (CON: 56.71 ±5 .45 mL·kg^-1·min^-1, Vest: 57.29 ± 3.77 mL·kg^-1·min^-1, Beverage: 57.86 ± 5.96 mL·kg^-1·min^-1, Mix: 58.14 ± 3.53 mL·kg^-1·min^-1, H = 0.879, p = 0.831).

In terms of the HR responses, there were no significant differences (H = 4.680, p = 0.197, Table 1) between Vest and CON, Beverage and CON, Mix and CON and among the pre-cooling trials at the end of the exercise protocol.

T_core did not differ among the conditions before pre-cooling (H = 0.392, p = 0.942, Table 2) There were no significant differences among the four different conditions (H = 5.159, p = 0.161) after pre-cooling. There were no significant differences between the trials (H = 0.046, p = 0.997) at the time of exhaustion.

T_skin was similar in all conditions before pre-cooling (H = 1.033, p = 0.793, Table 2). After pre-cooling, there were no significant differences between each trial with T_skin (H = 9.574, p = 0.691, Table 2). At the time of exhaustion, there were no significant differences between the trials (H = 1.189, p = 0.756).

SL was lower in Mix as compared to that in CON at the end of pre-cooling (H = 11.667, p = 0.009, ES = 0.67, Table 3). At the same time, there were no significant differences between Vest and CON (p = 1.000), Beverage and CON (p = 0.579), Mix and Vest (p = 0.072) and Mix and Beverage (p = 0.706). At the exhaustion of exercise, there was no difference in SL among the four experimental (H = 0.824, p = 0.844, Table 3).

At the time of exhaustion, no significant differences among the trials were observed in USG (H = 1.877, p = 0.202, Figure 3).

Before pre-cooling, the differences in Na⁺ concentrations among the four trials were not significant (H =0.629, p = 0.890, Table 4). Even after pre-cooling the difference among all trials was not significant (H = 0.306, p = 0.959). At the time of exhaustion, no differences were found (H = 3.587, p= 0.310) among the four different conditions as well.

Before pre-cooling, the differences in K⁺ concentrations among the four trials were not significant (H = 0.122, p = 0.989, Table 4). After pre-cooling, and at the time of exhaustion, no significant differences among the trials were observed in K⁺ concentrations (H = 0.448, p = 0.398 and H = 1.514, p = 0.679).

No significant difference was observed in RPE among the trials at the time of exhaustion (H = 1.381, p = 0.710, Table 5).

No significant differences were observed in the TS among the four trials before and after pre-cooling (H = 0.269, p = 0.966 and H =7.013, p=0.071, respectively, Table 5). At the time of exhaustion, there were no significant differences in TS in any condition (H = 2.250, p = 0.522, Table 5).

Before pre-cooling, the differences in [Bla] levels among the four trials were also not significant (H = 3.392, p = 0.862). After pre-cooling, [Bla] level in the mixed trial was significantly lower than that in CON (H = 13.396, p = 0.005, ES = 0.87; Table 6). At the end of exhaustion, [Bla] level in the mixed trial was significantly lower than that in CON (H = 16.932, p = 0.003, ES = 0.89; Table 6).

Our primary findings show that 30 min pre-cooling strategies with a mixed-method improved the high-intensity running capacity in a hot and humid environment. The mixed-method strategy that combines external and internal cooling may be more effective than the others in improving performance.

This finding is consistent with previous studies that used a mixed pre-cooling strategy. Aldous and colleagues (2019) reported that exercise performance increased by simultaneous ingestion of 7.5 g/kg body mass of -1 ™ƒ ice slurry and usage of -14.0 ± 4.6 ™ƒ ice packs. Brade and colleagues (2014) concluded that after 30 min of combined body-cooling techniques (internal cooling: jacket; external cooling: 7.5 g/kg ice slurry), the repeated sprint cycling performance improved compared with a single cooling method. The effects of internal (ingested 7.5 g/kg body mass of -1 ™ƒ ice slurry) and external (immersed in 24 ™ƒ cold water) pre-cooling measures on exercise performance in the study conducted by Siegel et al. (2011) were identical to those in the current study. In the study of Thomas and colleagues (2019) reported that a combination of internal and external cooling techniques did not offer benefits to high-intensity exercise despite the fact that this pre-cooling method reduced HR, T_core, and TS. This contradiction among the studies may be due to differences in exercise protocols. In the study by Thomas and colleagues, a self-paced exercise protocol was adopted, as opposed to our study, where in exercise at a fixed intensity was considered.

Evidence regarding combination of external and internal pre-cooling strategies confirmed that mix-method could augment the reduction in body temperature compared with the application of a single method (Bongers et al., 2014). It is logical that external pre-cooling would lower the core temperature and thus may benefit subsequent exercise performance in the heat (Castle et al., 2006). Internal pre-cooling (ice slurry) could contribute to a reduction in heat storage in the body and an increase in the capacity of heat storage (Jay and Morris, 2018). Therefore, combining external and internal cooling methods provided cooling effect through thermoregulatory factors (Gibson et al., 2019), thereby favourably affecting exercise performance during intense exercise in a hot and humid environment.

Wearing a vest cooled to a temperature of 4 ™ƒ, as utilized in our study, can transfer and dissipate excessive heat by increasing conduction and evaporation to temporarily offset the thermal equilibrium (Ross et al., 2013). A mixed-method approach may ameliorate thermoregulation stress to maintain homoeostasis for enhancement of exercise performance. The high T_core temperature is a major factor to limit to the exercise performance (González-Alonso et al., 1999; Gregson et al., 2002), which supports the experimental result that the T_core was same at the exhaustion state. Even though no difference occurred in T_core at the end of exhaustion, the rate of the T_core rise during exhaustion exercise was lower in this research. The mix pre-cooling could forbid the T_core to rising too fast, which could maintain T_core in a relative lower level and delay the fatigue happened during exercise. Therefore, mix pre-cooling could improve the ability of attenuating the arising of T_core drastically without changing, which maintain the homeostasis in a dynamic stable state. Besides that, whether the mix pre-cooling could prolong the time of exercise through increasing critical T_core during exercise need further research.

Our findings of improved performance in the mix condition were observed despite similar rectal and skin temperatures after pre-cooling as well as at the point of exhaustion. Previous research has shown that external pre-cooling does not always result in a reduction in the core temperature (James et al., 2015). Duffield et al. (2010) reported performance benefits following external cooling techniques that did not generate reduction in T_core. During exercise, increasing of the T_skin prematurely would impede the heat dissipation (Cotter et al., 2001). In this study, eight locations were used for the calculation of T_skin (Faulkner et al., 2019), which was more precise than a 4 site T_skin equation (Aldous et al., 2019). In this research, the same pre-cooling duration and the same temperature of the environment contribute the result of T_skin, which were no difference between each one. The difference in T_skin was similar to the study of Griggs and Havenith (Griggs et al., 2017).

Our study demonstrates improved performance in hot conditions with the mixed-method approach pre-cooling. Attenuating increases in skin temperature may facilitate the transfer of heat from the body’s core to the periphery, although this was not translated into a lower core temperature in our study. A lower skin temperature may also contribute to a better cardiovascular function. Indeed, the HR at exhaustion was lower in the mixed method compared to that observed in the control in the trend (CON: 197.3±5.0 bpm v.s. Mix: 187.3±8.8 bpm) in our study, which is indicative of a possibility of a better cardiovascular function. It appears that T_skin and skin wetness are important mediators of behavioural thermoregulation and may explain the extension of exercise time in our subjects. In a previous study (Schlader et al., 2011), thermal sensation was reported to be associated with skin temperature.

Wohlfert and Miller (2018) also reported the same results that there was no clinically meaningful differences between pre-cooling modalities in RPE and TS. Pre-cooling could create a heat sink to store more heat and blunt the body temperature to rise, which could attenuate the adverse effects, the RPE, and the TS (Rasmussen et al., 2010). During exercise, the heat stress improving lead the beta band cortical oscillation declined which damage the cerebral blood flow and metabolism through the cortical deactivation, finally, all those influence and change were verified to contribute to a higher RPE and TS (Nybo et al., 2014). Researches also suggested that thermoregulatory behavior is regulated by the perceived exertion before pronounced elevation in the thermo-physiological parameter during exercise (Rasmussen et al., 2010). As such, cool water consumed intermittently may alter the sensory feedback and attenuate the inhibitory effect on neural drive, thus improving perceptual measures and exercise performance without an obvious cooling effect (Watkins et al., 2018).

One of the limitations of our study is that only included 7 subjects. There is no doubt that a higher number of participants would strengthen our findings. Nevertheless, our participants were well-trained, and our findings could be used by competitive athletes. Another one of the limitations is that the fixed intensity exercise protocol in laboratory, even exhaustion protocol could measure the exercise capacity, still limits the practice application in real field. Another limitation is that we only recruited male participants. The extension of these research questions to the female population would increase the significance and impact of the results. The strength of our study relies on the fact that we tested our participants in an environment that was more stressful than that expected during the Tokyo Summer Olympic Games. Indeed, previous data on climatic conditions of Tokyo in July and August indicate a WBGT of 27±2.5 ™ƒ, which is lower than the estimated WBGT of 34 ™ƒ recorded in our study. Therefore, our findings may be beneficial to the athletes preparing for the Olympic Games in 2021.

In the current study, 30-min pre-cooling strategies, simultaneous (Mix) could enhance the duration of 80% VO₂max high-intensity aerobic exercise in hot and humid conditions. It could be inferred that mix pre-cooling could supress the increase in temperature during exercise in the hot conditions. Concurrently, mixed pre-cooling could decrease the sweat loss to delay the water loss during the exercise in the heat. Additionally, pre-cooling could ameliorate the cardiovascular strain during exercise. Finally, combination of external and internal pre-cooling provided a cooling effect through thermoregulatory factors (forbid the indexes to rising too fast), thereby enhancing exercise performance favourably in a hot and humid environment.

Furthermore, combination of beverage consumption and vest wearing, which are portable and inexpensive approaches, may be recommended to players and practitioners prior to training sessions and match play events to counter the challenge of heat stress.