Sleep plays a critical role in the regulation of both physical and cognitive functions and is essential for optimal  performance in athletes. Maximizing the performance of elite athletes as well as optimizing their physical and mental  health has become an increasingly prominent area of interest particularly in the study of fundamental lifestyle factors  such as sleep and nutrition (Halson 2014). Adequate and quality sleep is crucial for muscle repair immune function and  overall recovery processes. Sleep deprivation in athletes has been shown to lead to performance declines increased injury  risk and impairments in cognitive functions (Milewski et al. 2014). 

Nutrition also plays a significant role in athlete health and performance. Proper nutrient intake is necessary to  maintain energy balance muscle protein synthesis and recovery processes (Kerksick et al. 2018). The literature contains  studies that investigate the associations between nutrient intake and sleep quality. For example some research suggests  that protein and carbohydrate intake can positively influence sleep latency and sleep efficiency (Lund et al. 2010).  Specifically amino acids like tryptophan have been noted to improve sleep quality by enhancing melatonin synthesis  (Peuhkuri et al. 2012). Further while fat intake among male Australian footballers was not associated with sleep  (Falkenberg et al. 2021) high fat intakes in non-athletes have been associated with reduced sleep efficiency and duration  (Crispim et al. 2011; Grandner Kripke et al. 2010). A recent review focusing on the practical applications of sleep related nutrition in athletes underscores the significance of micronutrients particularly magnesium. (Doherty et al. 2023). 

The influence of magnesium on athletes' sleep merits thorough investigation as it is postulated to enhance melatonin  secretion and function as a GABA agonist the primary inhibitory neurotransmitter within the central nervous system  (Peuhkuri et al. 2012). However data are needed on the potential relationship between macro and micro nutrient intake  and sleep in elite athletes. 

Studies directly examining the relationship between nutrient intake and sleep quality in elite athletes are limited  (Condo et al. 2022; Falkenberg et al. 2021; Hoshino et al. 2022; Moss et al. 2022) with notable gaps in the literature.  Existing researches predominantly focus on the general population or amateur athletes while studies on elite athletes are  fewer and often methodologically flawed (Simpson et al. 2017). Consequently more in-depth studies on the relationship  between nutrient intake and sleep quality in elite athletes are necessary. This study aims to address this gap by evaluating  the relationship between nutrient intake and sleep quality in elite athletes using a cross-sectional approach based on the  hypothesis that poor sleep quality in elite athletes is associated with low nutrient intake. 

METHODS 

Participants: A power analysis was performed using G*Power to determine the statistical power of the study. The  sample size included in the study was calculated to reach 80% statistical power taking into account the predetermined  effect size (Cohen's d: 0.8) and the accepted alpha level (α = 0.05)(Lakens 2013). According to this analysis at least 107  participants were required. A total of 124 athletes from five sports (swimming canoeing archery volleyball and  taekwondo) were included in the cross-sectional study. Following Swann et al. elite athletes were defined as individuals  who (a) are presently benefiting from support or funding via the international carding scheme and/or (b) are part of a  national or professional team or are included in a recruitment/academy squad and/or (c) hold a national ranking in their  respective sport (Swann et al. 2015). All athletes competed at the national level. Individuals younger than 18 years old  and those diagnosed with sleep disorders were excluded from the study. A self- administered questionnaire was  administered.

This study was approved by Baskent University Institutional Review Board and Ethics Committee (Date: June   15 2022 Protocol no: E-94603339-604.01.02-138333). The study complies with the Helsinki Declaration. A  comprehensive explanation of the study details was provided to all participants and written informed consent was  acquired from each of them. 

Data Collection: The study period was between May 2023 and June 2023 and was conducted during the regular  training season. Questionnaire data were obtained on weekday training days. Body weight (kg) and body fat (%) were  measured using a body composition monitor (MC780 TANITA Tokyo Japan). The body mass index (BMI) was  determined by dividing the body weight (in kilograms) by the square of the height (in meters).  

Data collection tools included a demographic information form a 24-hour food consumption record and the  Richard-Campbell Sleep Scale (RCSQ). Data were collected in the morning and the previous day's night sleep and  nutrition were recorded. 

The Turkish validity and reliability study of the RCSQ developed by Richards in 1987 was conducted by Karaman  Özlü and Özer in 2015. The Cronbach's α values of the scales were found to be 0.82 and 0.91 (respectively Ozlu & Ozer   2015; Richards 1987). Each item on the six-item scale which assesses the depth of night sleep time to fall asleep   frequency of awakenings duration of wakefulness upon awakening sleep quality and environmental noise level is rated  on a visual analog scale from 0 mm to 100 mm. The total score is derived from five items excluding the sixth item that  measures environmental noise level. A total RCSQ score of ≥50 was used to define good sleep. Participants with total  RCSQ score <50 were considered to have poor sleep (Richards 1987). As the score of the scale increases the sleep  quality of the participants also increases. 

Participants' daily energy and food intakes were assessed using a 24-hour recall dietary record. In order to  accurately determine the amount of food consumed measuring cups such as water glasses tea glasses teaspoons dessert  spoons tablespoons serving spoons ladles and bowls are used and cooking methods (baked grilled boiled fried with  meat etc.) are used to accurately identify the consumed foods. Daily energy macronutrients and micronutrients were  calculated using the Nutritional Information System 8.1 software (BeBIS 2006). Glycemic index values of participants'  last meals were sourced from University of Sydney’s database (Sydney University Glycemic Index Research Service   2007: www.glycemicindex.com). 

Data Analysis: Upon analyzing the item analysis results of the sleep quality scale it was found that the corrected  item-total correlation values ranged from 0.475 to 0.627 and the factor loadings ranged from 0.639 to 0.798. The  independent samples t-test conducted to evaluate the differences between the top and bottom 27% groups revealed  statistically significant differences between these groups. Consequently the Cronbach's alpha internal consistency  coefficient was calculated as 0.770. 

Based on the RCSQ scores participants were categorized into two groups: good sleepers and poor sleepers. The  nutrient intakes and subject characteristics of these two groups were then compared. Additionally athletes were divided  according to type of sports and their sleep scores were compared. Shapiro–Wilk test confirmed the data normality.  Comparisons were made using one-way ANOVA analysis. Data are presented as mean ± standard deviation. For all  analyses p < 0.05 was considered statistically significant. Data were analyzed using IBM SPSS version 27 (Armonk NY   USA).

A total of 124 participants were initially recruited for the study. However incomplete responses were excluded   resulting in a final sample size of 115 participants. Of the sample 37 (24.7%) were female and 78 (75.3%) were male.  The primary attributes of the participants are shown in Table 1. The participant’s age was 19.7 ± 3.6 years height was  175.3 ± 8.8 cm weight was 68.7 ± 10.9 kg BMI was 22.3 ± 2.3 (kg/m2) and body fat percentage was 16.8% ± 5.4%.  The duration of sleep was 7.5 ± 0.9 h.  

There were 104 participants (90.4%) who were in the competition season. None of the participants had any chronic  diseases. Only seven participants consumed alcohol and they reported consuming it once a week. 

RCSQ 

Total (n=115) Poor sleeper (n=29) Good sleeper (n=86) p 

Age (years) 19.7 ± 3.6 19.4 ± 3.3 19.8 ± 3.7 0.59 Height (cm) 175.3 ± 8.8 174.1 ± 10.0 175.6 ±8.3 0.42 Weight (kg) 68.7 ± 10.9 67.6 ± 10.6 69.0 ± 11.0 0.54 BMI (kg / m2) 22.3 ± 2.7 22.2 ± 2.2 22.3 ± 2.9 0.83 Body Fat (%) 16.8 ± 5.4 18.0 ± 6.7 16.4 ± 4.8 0.17 Sleep duration (hours) 7.50 ± 0.9 7.4 ± 6.9 7.5 ± 0.8 0.79 Training (hours/week) 20.3 ± 6.4 20.7 ± 6.9 20.1 ± 6.2 0.65 BMI: Body mass index *p<0 05 

The RCSQ scores of the participants are shown in Table 2. The overall RCSQ score was 62.55 ± 22.49. 29  participants (25.2%) had poor sleep quality while 86 participants (74.8%) had good sleep quality. A comparison of sleep  scores according to sport type revealed no significant differences in total RCSQ scores (p > 0.05). However the canoeing  group exhibited a lower score than all other groups in the sleep quality score (p < 0.05). 

Table 2 

The RCSQ Scores of the Subjects 

Swimming (n = 58) 

Canoeing (n = 11) 

Archery (n = 17) 

Taekwondo (n=18) 

Volleybal (n = 11) 

Total 

(n =115) p 

Sleep duration 7.59 ± 0.80 7.54 ± 1.03 7.58 ± 1.06 7.11 ± 1.02 7.36 ± 1.02 7.50 ± 0.92 0.34 RCSQ measures 

Sleep depth 62.06 ± 18.33 50.90 ± 35.34 65.29 ± 24.26 66.11 ± 21.99 70.90 ± 23.00 62.95 ± 22.39 0.26 Sleep latency 62.41 ± 25.97 43.63 ± 35.85 65.29 ± 29.39 62.77 ± 32.50 71.81 ± 29.93 62.00 ± 29.17 0.22 Awakenings 65.34 ± 33.67 53.63 ± 42.01 72.35 ± 38.00 58.33 ± 35.18 73.63 ± 38.80 64.95 ± 35.72 0.54 

Returning to  sleep  

63.79 ± 36.60 61.81 ± 33.11 69.41 ± 36.30 52.77 ± 33.39 64.54 ± 42.51 62.78 ± 36.04 0.73 

Sleep quality 69.13 ± 28.05 47.27 ± 39.51* 82.94 ± 17.94 71.11 ± 22.46 72.72 ± 31.33 69.73 ± 28.51 0.02 

Total RCSQ  score  

63.65 ± 20.68 53.09 ± 25.38 66.70 ± 25.22 63.44 ± 25.24 58.36 ± 20.68 62.55 ± 22.49 0.55 

Noise 70.34 ± 36.60 75.45 ± 33.87 84.11 ± 23.46 70.00 ± 34.64 65.45 ± 36.70 72.34 ± 34.26 0.59 * p <0.05 Compared to swimming archery taekwondo and volleybal

The balance of energy-producing nutrients was 20% protein 41% fat and 39% carbohydrate. Nutrient intake is  shown in Table 3. Energy intake was 2063 ± 1003 kcal. The RCSQ scores were used to compare the intake of nutrients  in the poor sleeper and good sleeper groups. Good sleeper group had higher energy (kcal) protein (g/kg and g) and  tryptophan (g/kg and g) intakes (p < 0.05). Also glycemic index values of last meal was similar (p > 0.05). 

RCSQ 

Total (n=115) Poor sleeper (n=29) Good sleeper (n=86) p 

Energy (kcal / kg BM) 30.59 ± 15.05 26.74±13.20 31.89±15.48 0.11 Energy (kcal) 2063.56 ± 1003.70 1746.35±722.20 2170.52 ± 1064±62 0.04 Protein (g / kg BM) 1.54 ± 0.83 1.27±0.65 1.63 ± 0.87 0.04 Protein (g) 105.39 ± 57.12 84.36±39.63 112.49 ± 60.47 0.02 Carbohydrate (g / kg BM) 2.90 ± 1.65 2.66±1.58 2.99±1.67 0.35 Carbohydrate (g) 195.19 ± 109.95 173.45 ± 94.26 202.52 ± 114.33 0.22 Fat (g/kg BM) 1.41 ± 0.82 1.22 ±0.75 1.48 ± 0.84 0.06 Fat (g) 95.68 ± 54.07 79.45 ± 41.70 101.16 ± 56.82 0.14 Tryptophan (mg/kg BM) 18.67 ± 9.96 15.57 ±7.43 19.72 ± 10.52 0.05 Tryptophan (mg) 1275.23 ± 688.38 1032.75 ±447.12 1356.99 ±736.79 0.02 Magnesium (mg / kg BM) 5.26 ± 3.62 4.33 ±3.06 5.57 ±3.76 0.11 Magnesium (mg) 355.69 ± 243.86 284.23 ± 187.50 379.78 ± 256.61 0.68 Caffeine (mg) 88.72 ± 48.69 76.41 ± 44.00 92.88 ±49.72 0.11 Water (ml) 3533.47 ± 4557.73 4403.2 ± 1831.80 3240.20 ± 1349.36 0.23 Glycemic index of last meal (score) 63.17±18.24 62.49 ± 18.17 63.39 ± 18.36 0.81 BM: Body Mass *p<0.05 

DISCUSSION 

This study aimed to assess sleep quality and dietary intake among elite athletes. To the best of our knowledge it  is the first study in Turkey to examine the relationship between sleep quality and nutrient intake across different sports  among elite athletes. The primary findings indicated that the energy protein and trytophan intakes of good sleepers were  higher than those of poor sleepers.  

Several studies have examined the subjective sleep quality scores of elite athletes and have found evidence of sleep  disturbance and poor sleep quality in this population. One systematic review (Gupta et al. 2016) reported that  approximately one-third to one-half of elite athletes are classified as 'poor sleepers'. In our study approximately 25% of  all athletes were classified as ‘poor’ sleepers. When the athletes were categorised according to branches the total sleep  scale scores were similar. However the sleep quality score of the canoeing branch was lower than that of the other  branches. This difference may be due to the early training hours and high weekly training hours specific to this branch.  Sargent et al. (2014) examined the effects of training programmes on sleep and highlighted the effects of the timing of  training sessions on sleep. In our study there were participants from the canoeing branch who trained very early in the  morning. This difference may have affected the sleep quality perceived by the athletes. Consequently these effects warrant  further investigation in future studies. 

Participants in this study had an average sleep duration of 7.5 hours. Teece et al. (2023) reported similar results   while other studies with elite athletes (Lastella et al. 2015; Sargent et al. 2014) reported sleep duration <7 hours. The  adult population is advised to get a minimum of 7 hours of sleep a night to maintain good health (Chen et al. 2022). Vitale 

et al. reviewed the literature on sleep hygiene to optimise recovery in athletes and suggested that increasing sleep duration  by 2 hours with a target of up to 9 hours in elite athletes may be beneficial to optimise recovery. However it's important  to recognize that a universal sleep recommendation (7-9 hours) may not be suitable for optimizing an athlete's  performance and well-being (Vitale et al. 2019). An individualized approach which considers perceived sleep  requirements should be implemented. 

The relationship between daily energy intake and sleep in elite athletes has been the subject of limited research  (Falkenberg et al. 2021; Saidi et al. 2024). Insufficient energy intake diminishes sleep quality which is suggested to  have impacted the findings of the study (Halson 2014). The caloric needs of athletes performing moderate intensity  training or high volume intensive training are reported to be 40-70 kcal/kg/day (Kerksick et al. 2018). In our study the  energy intake of the athletes was 2063 calories and 30.59 ± 15.05 kcal/kg (lower of recommended) and poor sleepers had  a lower energy intake. These findings support a similar study that was previously carried out on elite athletes (Halson   2014). 

Protein and tryptophan consumption have been linked to sleep quality in various studies. (Ferguson et al. 2022;  Kautz et al. 2021; Moss et al. 2022; Santos et al. 2022). It has been demonstrated that improvements in sleep parameters   including increased sleep time and efficiency and decreased sleep latency can be achieved following the consumption of  tryptophan; an aminoacid present in foods such as milk (Ferguson et al. 2022). Conversely sleep quality has been shown  to decrease with tryptophan depletion. The mechanism underlying this process involves tryptophan competing with other  large neutral amino acids- such as valine leucine isoleucine tyrosine and phenylalanine- for transport across the blood brain barrier. Once across the barrier tryptophan is converted into serotonin which then serves as a precursor for  melatonin a hormone that promotes sleep (Duan et al. 2018). The current recommended protein intake for athletes is  1.2-2.0 g/kg BM per day (Kerksick et al. 2018). In terms of the necessary dose of tryptophan it has been revealed that  1 g is sufficient to improve both the quantity and the quality of sleep (Silber & Schmitt 2010). In our study the protein  intake of athletes was approximately 1.5 g/kg BM and good sleepers had a higher protein intake (~1.6 g/kg BM) and  tryptophan intake (~1350 mg). The results of this study showed that good sleepers had high protein and tryptophan intakes.  This finding is consistent with the existing results in the literature. However further experimental and longitudinal studies  are needed to confirm the causality of these relationships. In future studies a more detailed examination of the effects of  different sources and intake times of protein and tryptophan on sleep quality may deepen the knowledge on this subject. 

This study found no difference between good and poor sleepers in carbohydrate intake. Similarly a study involving  Australian male football players found no effect of daily carbohydrate intake on sleep outcomes (Falkenberg et al. 2021).  Conversely in non-athletes high carbohydrate diets were linked to improved sleep quality (Lindseth & Murray 2016).  The disparities in findings among studies may suggest that the timing of carbohydrate consumption influences sleep or  that the effects on sleep are contingent upon the type or glycemic index of carbohydrates consumed. The proposed  mechanism for enhancing sleep following a high glycemic index meal involves elevating the plasma tryptophan to large  neutral amino acid (TRP/LNAA) ratio. One study found that a high- glycemic index meal consumed 4 hours before  bedtime significantly reduced sleep onset latency by 48.6% compared to a low- glycemic index meal consumed 4 hours  before bedtime or 38.3% compared to the same meal consumed 1 hour before bedtime (Afaghi et al. 2007). In this study   the average glycemic index of the athletes' last meal was moderate and not associated with sleep quality. Further research  into the optimal timing amount and source of carbohydrate intake and its interaction with other macro- and micronutrients  in an athletic population is needed to determine the effectiveness of carbohydrate on sleep.

The primary limitation of this study is that it was based on participants' self-reports of both their sleep patterns and  dietary intake. As previously acknowledged self-reported methods like questionnaires and journals are susceptible to  inaccuracies in measurement and biases in recall (Lastella et al. 2021). Athletes may tend to overestimate their sleep  durations (Caia et al. 2018). Nonetheless self-report techniques are commonly utilized in athletic contexts due to their  simplicity and cost-effectiveness in monitoring athletes providing a reasonably comprehensive overview of the target  population. Moreover subjective sleep assessments often align with complaints and the pursuit of assistance (Dunican   et al. 2017). Future investigations exploring the potential impact of nutrition on enhancing athlete sleep should integrate both subjective and objective sleep measurement approaches. Another limitation is that stress and psychological factors  were not evaluated in the study. The current limitations were identified during the pilot study of the research. These  findings provide important findings that will shed light on future studies. 

CONCLUSION 

This research investigated the relationships between dietary intake and sleep quality among elite athletes from  various sports disciplines. Data were gathered in-season thus offering a real example of the interaction between nutrition  and sleep during a crucial training period for these athletes. The results indicated a relationship between sleep quality and nutritional intake in elite athletes. However further research is needed to investigate causality in this relationship. Future  studies should aim to identify the effects of specific nutrient deficiencies on sleep quality and delve deeper into the  interactions between sleep regulation and dietary strategies.