Participants were 16 women aged between 19 and 24 years studying at Gangneung-Wonju National University during the period of the study. The first of two groups was composed of eight athletes (tennis players), whereas the remaining eight were non-athletic women. After data collection, one subject was removed from the non-athlete group due to missing data, bringing the number of subjects to seven in this group and the total number to 15 participants. The following criteria were used for exclusion of subjects from the study: (a) having type 1 diabetes, being on insulin treatment, or being under oral hypoglycemic drug treatment; (b) having a disease affecting energy metabolism or under treatment with a drug affecting energy metabolism (including patients with stomach disease, thyroid disease, or kidney disease); (c) consuming more than 40 g of alcohol/day.

There was a significant difference in measurement period between the two groups. For the athletic group, TEE_DLW was measured over a period of 8 days. For the non-athletic group, TEE_DLW was measured over the period of 2 weeks. The study protocol was approved by the Gangneung-Wonju National University Institutional Review Board (GWNUIRB-2013-2). Before the investigations, written informed consent was obtained from all participants.

Anthropometric measurements and body composition assessment were performed using standard procedures. Weight, height, and body composition were measured using Inbody 720 (Biospace Co., Seoul, Korea). Body mass index (BMI) was calculated as body weight (kg) divided by square of body height (m). All measurements were done with subjects wearing the lightest clothes possible to reduce error.

REE measurement was conducted with indirect calorimetry using a ventilated hood system (TrueOne2400, Parvo Medics, USA). Calibration of the system was performed before every measurement, and automatic calibration was set every 5 minutes during the measurement. Measurement was conducted in a thermo-neutral room where the temperature was maintained as constant, with an average of 20.8℃. Before the REE measurement, subjects were instructed to fast for at least 12 hours and abstain from vigorous activities for the 24 hours preceding the measurement. During the REE measurement, subjects laid on a bed with the head covered by a canopy for at least 15 minutes. After measurement of O₂ consumption and CO₂ production, energy expenditure was calculated using the Weir equation as follows: REE (kcal/day) = 1.44 (3.9 VO₂ + 1.1 VCO₂) [12], where VO₂ is the volume of O₂ consumed and VCO₂ is the volume of CO₂ produced.

On the first day of the measurements (day 0), subjects' baseline urine samples were collected for determination of background isotope levels before the dose administration. Collected samples were kept in well-sealed bottles. Each subject was then given a measured oral dose of DLW containing 0.07 g of ²H₂O (99.9%, Sigma-Aldrich Co., USA) and 1.1 g of H₂ ¹⁸O (10%, Taiyo Nippon Corporation, Japan) per kg body weight. One hour after the dose administration, subjects voided their bladders, but this urine was not collected. The second and third urine samples were collected 3 and 4 hours, respectively, after the dose ingestion. For the athletic group, subsequent urine collection was carried out on day 1, day 2, day 7, and day 8, whereas for the non-athletic group, subsequent urine samples were collected on day 1, day 2, day 13, and day 14. The difference in observation period between the two groups was based on the fact that water turn-over is more rapid in athlete participants compared to non-athletes [13]. This difference in water turnover rate may lead to error, which can be corrected by reducing the length of the measurement period in high activity subjects [13]. To ensure accuracy of the results, all urine samples were collected at the same time of day. On the day of sample collection, subjects were instructed to void their bladders of urine immediately after waking up (this urine was not collected), followed by collection 1 hour later. Subjects were also instructed to abstain from drinking any liquid at least 30 minutes before the sample collection. For each urine sample, the collection date and time of day were recorded. Samples were stored at -30℃ until the time of analysis in the laboratory. For calculation of TEE, a modified Weir's formula was used [6]: TEE (kcal/day) = 1.1 rCO₂ + 3.9 rCO₂ / FQ, where rCO₂ (mol/day) is the rate of CO₂ production and FQ is the food quotient. The principle for calculation of rCO₂ with the DLW method is explained in detail elsewhere [613]. To calculate FQ, food consumption data were collected through a 24-hour dietary recall, which was conducted on 2 weekdays and 1 weekend day for every subject.

In this study, predicted EER were calculated using the DRI predictive equation for EER [7], which has also been used to determine the 2015 DRI for Koreans [8]. This equation considers the age, weight, and height of the subjects. In addition, a PA whose value depends on the activity level of the subjects was applied. Regarding age, this study focused on adults aged 19 years and above. A PA value of 1.45 (very active) was applied to the athlete group while a PA of 1.12 was used for non-athletes (low active). The DRI equation is as follows:

EER for women aged 19 years and older

EER = 354 - (6.91 × age [years]) + PA × (9.36 × weight [kg] + 726 × height [m])

Where PA is the physical activity coefficient:

PA = 1.00 if it is estimated that 1.0 ≤ PAL < 1.4 (sedentary)

PA = 1.12 if it is estimated that 1.4 ≤ PAL < 1.6 (low active)

PA = 1.27 if it is estimated that 1.6 ≤ PAL < 1.9 (active)

PA = 1.45 if it is estimated that 1.9 ≤ PAL < 2.5 (very active)

All data are presented as mean ± standard deviation. Statistical analyses were performed using SPSS version 23 (IBM SPSS Statistics 23). To assess the difference between the two groups with regard to different variables, independent t-test was performed while paired t-test was used for comparison between the EER_DRI and TEE_DLW. Concerning accuracy of the DRI predictive equation by comparison with DLW as the reference method, the mean difference and mean percentage difference between the results of the two methods as well as the root mean squares prediction error (RMSPE) were calculated. The following formula was used to calculate the RMSPE [14]:

Accurate prediction percentage was defined as the percentage of subjects predicted by the DRI predictive equation within 10% of TEE_DLW. Under-prediction percentage was defined as the percentage of subjects predicted by the DRI predictive equation < 10% of TEE_DLW, whereas over-prediction percentage was defined as the percentage of subjects predicted by the DRI predictive equation > 10% of TEE_DLW. Agreement between the two methods was assessed using the Bland-Altman test [15]. In addition, correlation analysis was performed to assess whether or not the two methods have similar tendencies. In all statistical tests, differences were considered as statistically significant if the P value was less than 0.05.

Comparison of anthropometry and body composition characteristics was conducted between the athlete and non-athlete groups, and results are presented in Table 1. Results of the two groups were not significantly different in terms of height (162.7 ± 5.7 cm vs 159.3 ± 3.7 cm, P = 0.196) or BMI (21.7 ± 2.1 vs 21.4 ± 3.3, P = 0.229). On the contrary, skeletal muscle mass was significantly higher in athletes than non-athletes (23.4 ± 2.3 kg and 19.1 ± 1.4 kg respectively, P = 0.001). Average fat-free mass was also higher in athlete subjects compared to non-athletes (42.4 ± 3.7 kg vs 35.7 ± 2.4 kg, P = 0.001).

As shown in Table 2, there was no significant difference between athlete and non-athlete groups with regard to resting energy expenditure and energy expenditure adjusted for body weight. On the contrary, REE adjusted for fat-free mass was significantly lower in the athlete group compared to non-athlete subjects (32.5 ± 1.8 kcal/kg/day vs 35.5 ± 2.8 kcal/kg/day, P = 0.037). In comparison to the non-athlete group, athlete participants had significantly higher values for total body water (30.2 ± 2.4 kg vs 25.2 ± 1.8 kg, P = 0.001), rCO2 (503.5 ± 77.8 L/day vs 361.4 ± 28.8 L/day, P = 0.001), total energy expenditure (2,780.3 ± 429.5 kcal/day vs 2,012.3 ± 160.5 kcal/day, P = 0.001), total energy expenditure adjusted for body weight (48.3 ± 4.0 kcal/kg/day vs 39.1 ± 3.2 kcal/kg/day, P < 0.001), total energy expenditure adjusted for fat-free mass (65.3 ± 5.2 kcal/kg/day vs 56.4 ± 2.0 kcal/kg/day, P = 0.001), and physical activity level (1.97 ± 0.17 vs 1.60 ± 0.15, P = 0.001). The range of PAL was from 1.7 to 2.3 in athletes and from 1.4 to 1.8 in non-athlete subjects.

The EER_DRI and TEE_DLW for both athletes and non-athlete subjects are presented in Table 3. For the athlete group, the mean difference between EER_DRI and TEE_DLW was -74.3 ± 321.6 kcal/day (P = 0.534), the RMSPE was 31.9 ± 23.5 kcal, and the percentage difference mean was -1.1 ± 11.7%. Concerning the non-athlete group, the mean difference was 28.3 ± 125.2 kcal/day (P = 0.572), the RMSPE was 13.5 ± 11.2 kcal/day, and the percent difference mean was 1.8 ± 6.9% ned. The accurate prediction percentage was only 37.5% in the athlete group and 85.7% in the non-athlete group. With regard to agreement between the two methods, which was assessed by the Bland-Altman method (Fig. 1), the range of limits of agreement was -704.6, 556.0 in the athlete group and -217.1, 273.7 in the non-athlete group. In addition to the RMSPE test, results of correlation analysis between TEE_DLW and EER_DRI are shown in Fig. 2. There was a very good correlation in the athletes group (r = 0.938, P = 0.001) as well as a good correlation in non-athlete group (r = 0.679, P = 0.094).