Protein intake in inhabitants with regular exercise is associated with sleep quality: Results of the Shika study

Fumihiko Suzuki, Emi Morita, Sakae Miyagi, Hiromasa Tsujiguchi, Akinori Hara, Thao Thi Thu Nguyen, Yukari Shimizu, Koichiro Hayashi, Keita Suzuki, Takayuki Kannon, Atsushi Tajima, Sumire Matsumoto, Asuka Ishihara, Daisuke Hori, Shotaro Doki,

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Competing Interests: The authors have declared that no competing interests exist.

https://doi.org/10.1371/journal.pone.0247926, Volume: 16, Issue: 2, Pages: 1-16

Article Type: research-article Article History

Publisher: Public Library of Science

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Table of Contents

Study objectives
Methods
Results
Introduction
Methods
Results
Discussion
Conclusions
Supporting information

Abstract

Study objectives

Although associations between sleep quality and environmental factors and nutrient intake have been reported, interactions between these factors have not been elucidated in detail. Therefore, this cross-sectional study examined the effects of regular exercise and nutrient intake on sleep quality using the Pittsburgh Sleep Quality Index (PSQI), which is the most frequently used index for sleep evaluation.

Methods

The participants included 378 individuals aged 40 years or older living in Shika Town, Ishikawa Prefecture. Of these individuals, 185 met the inclusion criteria. The participants completed a self-administered questionnaire assessing lifestyle habits and frequency and duration of exercise, the PSQI, and the brief-type self-administered diet history questionnaire (BDHQ) on nutrient intake.

Results

A two-way analysis of covariance on regular exercise and PSQI scores indicated that protein intake (17.13% of energy) was significantly higher in the regular exercise and PSQI ≤10 groups than in the non-regular exercise or PSQI ≥11 groups (p = 0.002). In a multiple logistic regression analysis with PSQI scores (≤10 and ≥11), protein intake was a significant independent variable in any of the models adjusted for confounding factors such as age, sex, body mass index, current smoker, and current drinker (OR: 1.357, 95% CI: 1.081, 1.704, p = 0.009) in the regular exercise group but not in the non-regular exercise group.Conclusions

We identified a positive relationship between sleep quality and protein intake in the regular exercise group. These findings suggest that regular exercise at least twice a week for 30 minutes or longer combined with high protein intake contributes to good sleep quality.

Suzuki,Morita,Miyagi,Tsujiguchi,Hara,Nguyen,Shimizu,Hayashi,Suzuki,Kannon,Tajima,Matsumoto,Ishihara,Hori,Doki,Oi,Sasahara,Satoh,Matsuzaki,Yanagisawa,Ikaga,Nakamura,and Moran: Protein intake in inhabitants with regular exercise is associated with sleep quality: Results of the Shika study

Introduction

Sleep plays an important role in maintaining health. Sleep disorders have been shown to negatively affect lifestyle-related diseases, such as metabolic syndrome [1], hypertension [2, 3], diabetes [4, 5], and cardiovascular disease [6, 7]. The following underlying mechanisms have been suggested for this association: neurobiological and physiological stressors [2]; the inhibition of glycemic control, which increases dietary intake through the secretion of ghrelin [5]; and the promotion of insulin resistance by increasing cortisol, IL-6, and TNFα levels [5]. Therefore, preventing sleep disorders is important for maintaining health.

Exercise has been noted to have a positive impact on sleep disorders. Epidemiological studies on sleep disorders and exercise/physical activity have examined non-restorative sleep in middle-aged and elderly individuals [8] and sleep quality in nursing homes [9]. Intervention studies have reported improvements in sleep quality in adults [10] and elderly individuals with depression [11]. Exercise affects sleep via the following mechanisms: its thermoregulatory effects reduce wake times during the night [10], it facilitates sleep onset by activating a heat dissipation mechanism controlled by the hypothalamus to increase central body temperature [12], and it improves mood due to its antidepressant/anxiety effects [13]. In animal studies, exercise was shown to increase the levels of adenosine, which activates the sleep center in the hypothalamus [14], and serotonin, which synthesizes the sleep hormone melatonin [12].

Nutrition has been investigated as another factor related to sleep disorders. Epidemiological studies have reported a relationship between sleep quality and micronutrients such as carotenoids [15], vitamin B₁₂ [15, 16], calcium [17], and selenium [18]. However, the relationships between sleep and macronutrients remain unclear. A previous study indicated the presence of a relationship between sleep and protein intake [16], but another study reported that no such relationship existed [19]. The latter study demonstrated that sleep was associated with lipid and carbohydrate intake [19]. Thus, the findings obtained from previous epidemiological studies are inconsistent. These discrepancies may exist because of the lack of a uniform method for evaluations using questionnaires [15, 16, 18, 20, 21]. Therefore, we conducted an epidemiological study to investigate the factors affecting sleep using the Pittsburgh Sleep Quality Index (PSQI), which is one of the most frequently used indices for evaluating self-rated sleep quality in sleep medicine.

The role of environmental factors must be considering when examining the association between nutrient intake and sleep. However, previous studies have not yet investigated this triangular relationship in detail. Two previous studies that reported different findings on the relationship between protein intake and sleep [16, 19] did not perform an analysis adjusted for environmental factors such as exercise. Therefore, the effects of interactions between environmental factors and nutrient intake on sleep remain unclear. The present cross-sectional study examined the effects of regular exercise and nutrient intake on sleep quality.

Methods

Data collection

In this cross-sectional study, comprehensive health survey data were collected from the residents of Shika Town, Ishikawa Prefecture, Japan, between November 2017 and February 2018. As of November 2017, there were 21,007 residents in Shika Town, and 15,012 were older than 40 years [22]. The Shika study epidemiologically investigates the causes of lifestyle-related diseases through interviews, self-administered questionnaires, and comprehensive medical examinations. Previous studies have also examined the relationship between nutrition and health [23–25].

Participants

This study was conducted on participants recruited from those who underwent a medical examination in Shika Town. For details, a total of 378 people aged 40 years and older who live in four model districts (Horimatsu, Tsuchida, Higashimatsudo, and Togi) provided their consent to participate in this sleep study. Of these individuals, 193 were excluded because they did not meet the survey criteria [169 participants did not complete the brief-type self-administered diet history questionnaire (BDHQ), 1 participant did not have energy records within 600 – 4000Kcal/day, and 23 participants did not complete the smoking, drinking, or exercise questionnaire]. Fig 1 shows the inclusion criteria. In total, 185 participants (95 males and 90 females; mean age ± standard deviation: 60.5 ± 9.7 years, range 41–83 years) who answered all relevant questions in the questionnaires and did not withdraw their consent were included in the analysis.

Fig 1

Participant recruitment chart.

* This reference value was chosen for the following reasons: less than 600 kcal/day is equivalent to half the energy intake required for the lowest physical activity category; more than 4000 kcal/day is equivalent to 1.5 times the energy intake required for the medium physical activity category.

Questionnaire and measurements

The participants completed a self-administered questionnaire on lifestyle and underlying diseases. Lifestyle items included the number of exercise days per week and the mean exercise time during each session, whether they were current smokers (1. yes, 2. no) and/or current drinkers (1. yes, 2. no), and education (1. junior high school, 2. high school 3. junior college, 4. university or higher). Underlying disease items included metabolic syndrome (1. yes, 2. no), hypertension (1. yes, 2. no), diabetes (1. yes, 2. no), angina (1. yes, 2. no), myocardial infarction (1. yes, 2. no), and depression (1. yes, 2. no). Body mass index (BMI) was measured using health survey data from the Shika study.

Nutrient intake was assessed using the BDHQ [26, 27]. The BDHQ is a four-page structured questionnaire that assesses the consumption frequency of 58 foods and beverages that are commonly consumed by the general Japanese population. The BDHQ estimates dietary intake in the last month using an ad hoc computer algorithm. The validity of the BDHQ has been demonstrated in previous studies in Japanese populations [26, 27]. To analyze nutrient data, the density method was used to estimate intake per 1000 Kcal. The following formula was used to calculate the energy intake ratio (% energy) of energy-producing nutrients (proteins, lipids, carbohydrates, and alcohol): energy intake from each nutrient/energy intake (EN) × 100, adjusted intake of non-energy-producing nutrients: crude intake of various nutrients/EN × 1000 Kcal.

Sleep status was assessed using the PSQI [28, 29]. The PSQI assesses sleep quality and disturbances over a one-month period and consists of the following components: subjective sleep quality, sleep latency, sleep duration, habitual sleep efficiency, sleep disturbance, the use of sleeping medication, and daytime dysfunction. Each component of the PSQI is scored from 0 to 3. The PSQI global score is a sum of these components that ranges between 0 and 21, with higher scores indicating poorer sleep quality. The validity of the PSQI has been demonstrated in previous studies in Japanese populations [29].

Statistical analysis

Regular exercise was defined as exercise for at least 30 minutes at a time and twice a week [30]. Buysse et al. [28] defined a PSQI score >5 as poor sleep quality; however, their study population included adolescents and differed from that in our Shika study, which included those aged 40 years and older. In the present study, the median PSQI of the participants was 10; thus, they were classified into PSQI ≤10 and ≥11 groups. The age distribution of the participants in the present study did not differ from that of the Shika Town inhabitants.

The distribution of variables was checked by the Kolmogorov–Smirnov, and Shapiro–Wilk normality tests, or the normal distribution curve in the histogram was confirmed before using other statistical tests. The Student’s t-test was used to compare the means of continuous variables and the Chi-square test was performed to compare the proportions of categorical variables. All participants were stratified into two groups based on their PSQI scores (PSQI ≤10 and ≥11) and whether they participated in regular exercise (regular exercise group and non-regular exercise group). A two-way analysis of covariance (ANCOVA) was used to examine the effects of the interaction between regular exercise and PSQI on nutrient intake. The following confounding factors were adjusted for: age, sex, BMI, current smoker, current drinker, education, hypertension, and diabetes. A multiple logistic regression analysis was conducted to examine the effects of regular exercise and nutrient intake on sleep quality. The dependent variable was the PSQI (≤10 and ≥11). We used three models in the logistic regression analysis. Model 1 included the individual factors of age, gender, and BMI. Model 2 included the environmental factors of current smoker and current drinker together with individual factors. Model 3 included the disease factors of hypertension and diabetes together with individual factors. Additionally, the analyses were stratified by whether the participants performed regular exercise. Pearson’s correlation coefficient was used to confirm multicollinearity. Specifically, there was no value of | r | >0.9 in the correlation matrix table between independent variables. The forced input method was used for variable selection. The significance level was set at 5%. IBM SPSS Statistics version 25 for Windows (IBM, Armonk, NY, USA) was used for the statistical analysis.

Ethics statement

The present study was conducted with the approval of the Ethics Committee of Kanazawa University (No. 1491). Written informed consent was obtained from all participants.

Results

Participant characteristics

The participants’ sleep quality and nutrient intakes are shown in Table 1. Among the 185 participants, there were 95 males with a mean age of 60.9 years (SD = 9.6) and 90 females with a mean age of 60.3 years (SD = 10.1); there was no significant difference between genders. BMI (p < 0.001) was significantly higher in males than in females. Significantly more males were current smokers (p < 0.000), current drinkers (p < 0.001), and had metabolic syndrome (p < 0.001), diabetes (p = 0.049), and angina (p = 0.019) than females. The mean PSQI was 10.7 (SD = 2.7) in males and 10.7 (SD = 2.8) in females, with no significant difference between genders. When comparing nutrients, the total energy (p < 0.001) was significantly higher in males. Conversely, the intakes of other nutrients, excluding carbohydrates, sodium, vitamin D, and vitamin B₁₂, were significantly higher in females.

Table 1

Participant characteristics.

	Total (N = 185)		Male (N = 95)		Female (N = 90)		p Value *
	Mean (n)	SD (%)	Mean (n)	SD (%)	Mean (n)	SD (%)	p Value *
Age, years	60.5	9.7	60.9	9.6	60.3	10.1	0.791
BMI, kg/m²	23.1	3.1	23.8	3.3	22.2	2.6	<0.001
Exercise / week, days	1.5	2.3	1.4	2.4	1.5	2.2	0.700
Exercise time / each session, minutes	27.2	52.2	24.4	53.4	30.2	51.0	0.452
Current smoker, n (%)	31	16.8	25	26.3	6	6.7	<0.001
Current drinker, n (%)	107	57.8	75	78.9	32	35.6	<0.001
Education							0.142
Junior high school, n (%)	38	20.5	19	20.0	19	21.1
High school, n (%)	79	42.7	39	41.1	40	44.4
Junior college, n (%)	39	21.1	15	15.8	24	26.7
University or higher, n (%)	29	15.7	22	23.2	7	7.8
PSQI	10.7	2.7	10.7	2.7	10.7	2.8	0.988
Underlying diseases
metabolic syndrome, n (%)	46	24.9	36	37.9	10	11.1	<0.001
Hypertension, n (%)	61	32.8	37	38.5	24	26.5	0.086
Diabetes, n (%)	14	8.0	11	12.1	3	3.6	0.049
Angina, n (%)	10	5.4	9	9.9	1	1.2	0.019
Myocardial infarction, n (%)	3	1.6	2	2.2	1	1.2	1.000
Depression, n (%)	1	0.6	1	1.1	0	0.0	1.000
Nutrients
Total energy, Kcal	1968.21	632.39	2214.45	648.63	1708.29	499.40	<0.001
Protein, %energy	15.11	3.08	14.33	3.12	15.93	2.84	<0.001
Fat, % energy	25.36	5.76	23.65	5.91	27.17	5.04	<0.001
Carbohydrate, % energy	53.66	7.58	53.08	7.97	54.27	7.15	0.287
minerals, % energy	10.32	1.98	9.72	1.89	10.94	1.88	<0.001
Sodium, mg/1000 Kcal	2397.76	486.77	2338.00	493.78	2460.84	473.82	0.086
Potassium, mg/1000 Kcal	1413.49	412.08	1252.45	331.72	1583.49	421.83	<0.001
Calcium, mg/1000 Kcal	291.66	109.87	260.60	109.61	324.45	100.74	<0.001
Magnesium, mg/1000 Kcal	141.30	32.01	130.51	28.43	152.68	31.76	<0.001
Phosphorus, mg/1000 Kcal	573.06	129.32	537.85	132.97	610.22	114.81	<0.001
Iron, mg/1000 Kcal	4.23	1.05	3.86	0.88	4.61	1.08	<0.001
Zinc, mg/1000 Kcal	4.47	0.64	4.28	0.68	4.67	0.53	<0.001
β-carotene equivalent, μg/1000 Kcal	2044.46	1278.57	1630.35	975.87	2481.58	1413.37	<0.001
Retinol equivalent, μg/1000 Kcal	359.43	175.78	325.33	177.92	395.43	167.03	0.006
Vitamin D, μg/1000 Kcal	8.17	5.23	7.83	5.33	8.53	5.12	0.363
α-Tocopherol, mg/1000 Kcal	3.96	1.06	3.58	0.91	4.37	1.07	<0.001
Vitamin K, μg/1000 Kcal	168.40	87.03	142.38	67.30	195.85	96.90	<0.001
Vitamin B1, mg/1000 Kcal	0.41	0.09	0.38	0.08	0.45	0.09	<0.001
Vitamin B2, mg/1000 Kcal	0.66	0.17	0.61	0.16	0.72	0.16	<0.001
Niacin, mg/1000 Kcal	9.47	2.49	8.90	2.36	10.08	2.49	0.001
Vitamin B6, mg/1000 Kcal	0.70	0.17	0.65	0.15	0.75	0.18	<0.001
Vitamin B12, μg/1000 Kcal	5.53	2.75	5.31	2.77	5.77	2.72	0.258
Folic acid, μg/1000 Kcal	178.61	63.21	158.26	50.75	200.09	68.06	<0.001
Pantothenic acid, mg/1000 Kcal	3.40	0.72	3.13	0.66	3.69	0.67	<0.001
Vitamin C, mg/1000 Kcal	63.04	31.90	53.24	25.05	73.39	35.07	<0.001

* p-values were calculated from the Student’s t-tests for continuous variables and from the Chi-square test for categorical variables (p-values less than 0.05 are highlighted in bold). Abbreviations: SD, standard deviation; BMI, body mass index; PSQI, Pittsburgh Sleep Quality Index.

Comparison with the PSQI

The mean age of the 106 participants in the PSQI ≤10 group was 59.2 years, which was significantly younger than that of the 79 participants in the PSQI ≥11group (62.4 years, p = 0.026) (Table 2). The PSQI ≤10 group reported significantly more exercise days per week (p = 0.004) and a significantly longer mean exercise time per session (p = 0.008). Furthermore, these factors were significantly greater in the PSQI ≤10 group even after adjusting for age, sex, BMI, current smoker, current drinker, education, hypertension, and diabetes (exercise days and exercise time: p < 0.001 and p = 0.004, respectively). Therefore, regular exercise was beneficial for sleep quality. The proportion of participants with metabolic syndrome (p = 0.026) was significantly higher in the PSQI ≤10 group. When comparing each nutrient, the intakes of retinol equivalent (p = 0.044) and vitamin B₂ (p = 0.024) were significantly higher in the PSQI ≤10 group than in the PSQI ≥11 group.

Table 2

Differences in characteristics and daily nutrient intake between the PSQI ≤10 and ≥11 groups.

	Total (N = 185)
	PSQI ≤ 10 (n = 106)		PSQI ≥ 11 (n = 79)		p Value *
	Mean (n)	SD (%)	Mean (n)	SD (%)	p Value *
Age, years	59.2	9.9	62.4	9.3	0.026
Sex: male, n (%)	50	47.2	45	57.0	0.234
BMI, kg/m²	23.4	3.1	22.6	3.0	0.064
Exercise / week, days	1.9	2.5	1.0	1.8	0.004
Exercise time / each session, minutes	35.3	61.9	16.3	32.5	0.008
Current smoker, n (%)	19	17.9	12	15.2	0.693
Current drinker, n (%)	58	54.7	49	62.0	0.367
Education					0.427
Junior high school, n (%)	18	17.0	20	25.3
High school, n (%)	48	45.3	31	39.2
Junior college, n (%)	23	21.7	16	20.3
University or higher, n (%)	17	16.0	12	15.2
PSQI	8.9	1.2	13.2	2.2	<0.001
Underlying diseases
metabolic syndrome, n (%)	33	31.1	13	16.5	0.026
Hypertension, n (%)	33	31.1	28	35.6	0.636
Diabetes, n (%)	6	5.9	8	10.1	0.275
Angina, n (%)	5	5.0	5	6.8	0.746
Myocardial infarction, n (%)	2	2.0	1	1.4	1.000
Depression, n (%)	0	0.0	1	1.4	0.427
Nutrients
Total energy, Kcal	1993.88	673.94	1933.77	574.35	0.524
Protein, %energy	15.48	3.07	14.61	3.05	0.056
Fat, % energy	25.80	5.54	24.77	6.04	0.229
Carbohydrate, % energy	53.58	7.35	53.76	7.94	0.873
minerals, % energy	10.46	1.95	10.13	2.01	0.270
Sodium, mg/1000 Kcal	2407.42	471.59	2384.80	509.17	0.755
Potassium, mg/1000 Kcal	1449.58	418.96	1365.07	400.18	0.168
Calcium, mg/1000 Kcal	300.81	115.94	279.39	100.56	0.190
Magnesium, mg/1000 Kcal	143.67	32.37	138.12	31.44	0.244
Phosphorus, mg/1000 Kcal	587.05	133.72	554.28	121.50	0.088
Iron, mg/1000 Kcal	4.34	1.06	4.08	1.02	0.097
Zinc, mg/1000 Kcal	4.55	0.61	4.37	0.66	0.058
β-carotene equivalent, μg/1000 Kcal	2151.41	1347.64	1900.95	1172.67	0.179
Retinol equivalent, μg/1000 Kcal	381.22	189.21	330.20	152.28	0.044
Vitamin D, μg/1000 Kcal	8.56	5.74	7.65	4.43	0.226
α-Tocopherol, mg/1000 Kcal	4.02	1.05	3.89	1.07	0.398
Vitamin K, μg/1000 Kcal	175.54	93.46	158.81	77.11	0.185
Vitamin B1, mg/1000 Kcal	0.42	0.09	0.40	0.10	0.183
Vitamin B2, mg/1000 Kcal	0.69	0.18	0.63	0.16	0.024
Niacin, mg/1000 Kcal	9.77	2.37	9.06	2.61	0.054
Vitamin B6, mg/1000 Kcal	0.70	0.18	0.69	0.17	0.541
Vitamin B12, μg/1000 Kcal	5.72	2.83	5.28	2.63	0.290
Folic acid, μg/1000 Kcal	181.94	65.37	174.14	60.32	0.408
Pantothenic acid, mg/1000 Kcal	3.49	0.74	3.29	0.67	0.058
Vitamin C, mg/1000 Kcal	62.66	31.54	63.56	32.57	0.850

* p-values were calculated from the Student’s t-tests for continuous variables and from the Chi-square test for categorical variables (p-values less than 0.05 are highlighted in bold). Abbreviations: PSQI, Pittsburgh Sleep Quality Index; SD, standard deviation; BMI, body mass index.

Comparisons with regular exercise

The mean age of the 59 participants in the regular exercise group (64.2 years) was significantly older than that of the 126 participants in the non-regular exercise group (58.8 years, p < 0.001) (Table 3). The mean PSQI (p = 0.003) was significantly higher in the non-regular exercise group. When comparing each nutrient, the intakes of protein (p <0.001), minerals (p < 0.001), and 12 kinds of vitamins were significantly higher in the regular exercise group than that in the non-regular exercise group.

Table 3

Differences in characteristics and daily nutrient intake between regular and non-regular exercise groups.

	Total (N = 185)
	Regular exercise (n = 59)		Non-regular exercise (n = 126)		p Value *
	Mean (n)	SD (%)	Mean (n)	SD (%)
Age, years	64.2	7.8	58.8	10.1	<0.001
Sex: male, n (%)	26	44.1	69	54.8	0.208
BMI, kg/m²	22.8	3.0	23.2	3.1	0.378
Exercise / week, days	4.3	1.7	0.2	0.8	<0.001
Exercise time / each session, minutes	80.3	64.2	2.3	11.7	<0.001
Current smoker, n (%)	5	8.5	26	20.6	0.056
Current drinker, n (%)	30	50.8	77	61.1	0.204
Education					0.536
Junior high school, n (%)	13	22.0	25	19.8
High school, n (%)	27	45.8	52	41.3
Junior college, n (%)	10	16.9	29	23.0
University or higher, n (%)	9	15.3	20	15.9
PSQI	9.9	2.2	11.1	2.9	0.003
Underlying diseases
metabolic syndrome, n (%)	15	25.4	31	24.6	1.000
Hypertension, n (%)	21	35.6	40	31.7	0.618
Diabetes, n (%)	7	11.9	7	5.6	0.144
Angina, n (%)	2	3.4	8	6.3	0.506
Myocardial infarction, n (%)	1	1.7	2	1.6	1.000
Depression, n (%)	0	0.0	1	0.8	1.000
Nutrients
Total energy, Kcal	1961.70	554.63	1971.26	667.77	0.924
Protein, %energy	16.33	3.42	14.54	2.74	<0.001
Fat, % energy	25.79	6.04	25.16	5.64	0.488
Carbohydrate, % energy	52.63	6.80	54.14	7.90	0.206
minerals, % energy	11.10	1.99	9.95	1.87	<0.001
Sodium, mg/1000 Kcal	2460.96	473.81	2368.17	491.78	0.228
Potassium, mg/1000 Kcal	1624.20	432.14	1314.83	364.07	<0.001
Calcium, mg/1000 Kcal	349.42	124.82	264.62	90.70	<0.001
Magnesium, mg/1000 Kcal	156.34	32.86	134.25	29.15	<0.001
Phosphorus, mg/1000 Kcal	635.65	146.91	543.75	109.04	<0.001
Iron, mg/1000 Kcal	4.71	1.10	4.00	0.95	<0.001
Zinc, mg/1000 Kcal	4.72	0.72	4.36	0.57	<0.001
β-carotene equivalent, µg/1000 Kcal	2629.14	1537.63	1770.68	1035.57	<0.001
Retinol equivalent, µg/1000 Kcal	436.79	206.07	323.21	147.08	<0.001
Vitamin D, µg/1000 Kcal	9.95	6.46	7.34	4.32	0.001
α-Tocopherol, mg/1000 Kcal	4.34	1.16	3.79	0.97	0.001
Vitamin K, µg/1000 Kcal	199.24	92.18	153.95	80.91	0.001
Vitamin B1, mg/1000 Kcal	0.46	0.10	0.39	0.08	<0.001
Vitamin B2, mg/1000 Kcal	0.75	0.16	0.63	0.16	<0.001
Niacin, mg/1000 Kcal	10.21	2.54	9.12	2.40	0.005
Vitamin B6, mg/1000 Kcal	0.77	0.17	0.66	0.16	<0.001
Vitamin B12, µg/1000 Kcal	6.18	2.92	5.23	2.62	0.027
Folic acid, µg/1000 Kcal	207.76	66.76	164.96	56.79	<0.001
Pantothenic acid, mg/1000 Kcal	3.74	0.73	3.25	0.66	<0.001
Vitamin C, mg/1000 Kcal	76.62	34.64	56.68	28.52	<0.001

* p-values were calculated from the Student’s t-tests for continuous variables and from the Chi-square test for categorical variables (p-values less than 0.05 are highlighted in bold). Abbreviations: PSQI, Pittsburgh Sleep Quality Index; SD, standard deviation; BMI, body mass index.

Effects of the interaction between regular exercise and the PSQI on nutrient intake

The regular exercise group was divided into two groups based on PSQI scores; there were 43 participants in the PSQI ≤10 group and 16 in the PSQI ≥11 group. The non-regular exercise group was similarly divided into two groups based on the PSQI scores; there were 63 participants in the PSQI ≤10 group and 63 in the PSQI ≥11 group (Table 4). A two-way ANCOVA adjusting for age, sex, BMI, current smoker, current drinker, education, hypertension, and diabetes was used to examine the effects of interactions between regular exercise and the PSQI on nutrient intake. Interactions were observed for age (p = 0.006), education (p = 0.002), protein (p = 0.002), carbohydrate (p = 0.045), phosphorus (p = 0.008), zinc (p = 0.031), vitamin D (p = 0.015), vitamin B₁₂ (p = 0.007), and pantothenic acid (p = 0.008). A post hoc Bonferroni analysis indicated that there was significantly higher protein intake in the PSQI ≤10 group than in the PSQI ≥11 group with regular exercise (p = 0.001); however, there was no difference between the two PSQI groups without regular exercise (S1 Fig).

Table 4

Interactions between exercise groups and PSQI groups.

	Total (N = 185)
	Regular exercise (n = 59)						Non-regular exercise (n = 126)						p Value *
	PSQI ≤ 10 (n = 43)			PSQI ≥ 11 (n = 16)			PSQI ≤ 10 (n = 63)			PSQI ≥ 11 (n = 63)			RE	PSQI	RE * PSQI
	Mean	95% CI		Mean	95% CI		Mean	95% CI		Mean	95% CI
	Mean	Lower	Upper	Mean	Lower	Upper	Mean	Lower	Upper	Mean	Lower	Upper
Age, years	64.2	61.9	66.6	64.2	59.8	68.6	55.7	53.3	58.2	61.9	59.5	64.3	0.003	0.180	0.006
Sex ^†	1.4	1.2	1.6	1.6	1.3	1.8	1.5	1.4	1.7	1.6	1.5	1.7	0.532	0.276	0.469
BMI, kg/m²	23.0	22.1	23.8	22.2	20.1	24.2	23.7	22.9	24.6	22.7	22.0	23.4	0.217	0.037	0.721
Current smoker ^‡	1.9	1.8	2.0	1.9	1.8	2.1	1.8	1.7	1.9	1.8	1.7	1.9	0.111	0.2	0.702
Current drinker ^‡	1.5	1.4	1.7	1.4	1.1	1.6	1.4	1.3	1.5	1.4	1.3	1.5	0.525	0.279	0.751
Education ^§	2.4	2.1	2.7	1.9	1.4	2.4	2.4	2.1	2.6	2.4	2.1	2.6	0.712	0.414	0.002
Underlying diseases ^¶
Metabolic syndrome, %	1.7	1.6	1.86	1.81	1.6	2.0	1.7	1.6	1.8	1.8	1.8	1.9	0.565	0.133	0.922
Hypertension, %	1.6	1.5	1.78	1.69	1.4	1.9	1.7	1.6	1.8	1.6	1.5	1.8	0.566	0.601	0.332
Diabetes, %	1.9	1.9	2.01	1.75	1.5	2.0	2.0	1.9	2.0	1.9	1.9	2.0	0.013	0.023	0.064
Angina, %	2.0	1.9	2.02	1.94	1.8	2.1	1.9	1.9	2.0	1.9	1.9	2.0	0.429	0.89	0.334
Myocardial infarction, %	2.0	1.9	2.02	2.00	2.0	2.0	2.0	2.0	2.0	2.0	2.0	2.0	0.488	0.375	0.441
Depression, %	2.0	2.0	2.0	2.00	2.0	2.0	2.0	2.0	2.0	2.0	2.0	2.0	0.263	0.964	0.263
Nutrients
Total energy, Kcal	2012.22	1850.69	2173.76	1825.92	1492.71	2159.12	1981.37	1789.21	2173.52	1961.16	1819.44	2102.88	0.369	0.043	0.348
Protein, %energy	17.13	16.11	18.14	14.19	12.65	15.73	14.36	13.77	14.95	14.71	13.93	15.49	0.321	0.005	0.002
Fat, % energy	26.67	24.77	28.57	23.45	20.71	26.20	25.22	23.95	26.48	25.11	23.54	26.68	0.817	0.358	0.218
Carbohydrate, % energy	51.59	49.34	53.84	55.42	53.16	57.67	54.94	53.15	56.73	53.34	51.17	55.51	0.610	0.317	0.045
minerals, % energy	11.42	10.84	11.99	10.24	9.10	11.38	9.80	9.36	10.24	10.10	9.60	10.61	0.112	0.197	0.108
Sodium, mg/1000 Kcal	2523.05	2384.08	2662.02	2294.09	2024.30	2563.89	2328.50	2209.59	2447.41	2407.83	2279.05	2536.62	0.926	0.334	0.102
Potassium, mg/1000 Kcal	1671.49	1550.93	1792.05	1497.12	1220.88	1773.37	1298.12	1205.30	1390.94	1331.53	1240.45	1422.62	0.002	0.478	0.591
Calcium, mg/1000 Kcal	368.18	329.05	407.30	298.99	242.42	355.56	254.83	234.49	275.17	274.41	249.38	299.43	0.019	0.068	0.096
Magnesium, mg/1000 Kcal	161.14	151.71	170.57	143.46	124.24	162.68	131.74	124.70	138.78	136.76	129.12	144.40	0.028	0.206	0.150
Phosphorus, mg/1000 Kcal	665.26	620.65	709.87	556.08	490.07	622.09	533.67	509.90	557.44	553.83	523.13	584.53	0.058	0.018	0.008
Iron, mg/1000 Kcal	4.90	4.58	5.23	4.18	3.61	4.75	3.95	3.73	4.17	4.05	3.80	4.31	0.088	0.032	0.105
Zinc, mg/1000 Kcal	4.85	4.65	5.06	4.35	3.94	4.76	4.34	4.22	4.46	4.37	4.21	4.53	0.235	0.021	0.031
β-carotene equivalent, μg/1000 Kcal	2739.29	2267.63	3210.94	2333.12	1501.24	3165.01	1750.17	1488.28	2012.05	1791.19	1529.47	2052.91	0.014	0.353	0.949
Retinol equivalent, μg/1000 Kcal	466.74	398.27	535.20	356.31	288.61	424.01	322.85	288.53	357.17	323.57	283.71	363.43	0.028	0.047	0.208
Vitamin D, μg/1000 Kcal	10.97	8.85	13.10	7.19	5.00	9.38	6.92	5.89	7.95	7.77	6.63	8.91	0.414	0.029	0.015
α-Tocopherol, mg/1000 Kcal	4.51	4.16	4.85	3.87	3.25	4.49	3.69	3.47	3.91	3.89	3.63	4.16	0.181	0.402	0.13
Vitamin K, μg/1000 Kcal	214.78	185.43	244.14	157.46	120.42	194.50	148.75	127.93	169.57	159.16	139.15	179.16	0.33	0.058	0.072
Vitamin B1, mg/1000 Kcal	0.47	0.44	0.50	0.42	0.36	0.49	0.39	0.37	0.41	0.40	0.38	0.42	0.012	0.387	0.302
Vitamin B2, mg/1000 Kcal	0.78	0.73	0.83	0.65	0.58	0.72	0.62	0.58	0.67	0.63	0.59	0.67	0.031	0.021	0.094
Niacin, mg/1000 Kcal	10.60	9.84	11.35	9.17	7.82	10.52	9.21	8.67	9.75	9.03	8.37	9.70	0.146	0.14	0.179
Vitamin B6, mg/1000 Kcal	0.80	0.75	0.85	0.71	0.62	0.80	0.64	0.60	0.68	0.68	0.64	0.72	0.025	0.501	0.109
Vitamin B12, μg/1000 Kcal	6.79	5.85	7.72	4.57	3.61	5.52	4.99	4.37	5.60	5.46	4.76	6.17	0.965	0.034	0.007
Folic acid, μg/1000 Kcal	214.72	194.79	234.65	189.06	151.45	226.67	159.57	145.45	173.69	170.35	155.88	184.82	0.02	0.425	0.449
Pantothenic acid, mg/1000 Kcal	3.91	3.70	4.12	3.28	2.94	3.62	3.20	3.04	3.36	3.29	3.12	3.46	0.046	0.026	0.008
Vitamin C, mg/1000 Kcal	76.90	67.10	86.70	75.86	53.24	98.47	52.93	45.99	59.88	60.43	53.09	67.78	0.008	0.382	0.731

* Analysis of covariance (p-values less than 0.05 are highlighted in bold). Adjusted for age, sex, BMI, current smoker, current drinker, education, hypertension, and diabetes.

† sex (1. female, 2. male)

‡ current smoker or drinker (1. yes, 2. no)

§ education (1. junior high school, 2. high school, 3. junior college, 4. university and higher)

¶ underlying diseases (1. yes, 2. no). Abbreviations: PSQI, Pittsburgh Sleep Quality Index; RE, regular exercise; CI, confidence interval; BMI, body mass index.

Effects of regular exercise and protein intake on sleep quality

Table 5 shows the results of a multiple logistic regression analysis with PSQI (≤ 10 and ≥11) stratified by regular exercise. Protein intake was a significant independent variable in any models that were adjusted for individual factors (age, sex, and BMI; OR: 1.260; 95% CI: 1.037, 1.531; p = 0.020), individual and environmental factors (current smoker and current drinker; OR: 1.357; 95% CI: 1.081, 1.704; p = 0.009), and individual and disease factors (hypertension and diabetes; OR: 1.675; 95% CI: 1.206, 2.326; p = 0.002) in the regular exercise group but not in the non-regular exercise group. This result implies that sleep quality is better with a high protein intake, even after adjusting for different confounding factors only in the regular exercise group.

Table 5

Relationship between protein intake and good sleep quality stratified by regular exercise.

		β	p—Value	OR	95% CI
		β	p—Value	OR	Lower	Upper
Regular exercise	Model 1	0.231	0.020	1.260	1.037	1.531
	Model 2	0.305	0.009	1.357	1.081	1.704
	Model3	0.516	0.002	1.675	1.206	2.326
Non-regular exercise	Model 1	-0.010	0.880	0.990	0.870	1.127
	Model 2	-0.006	0.925	0.994	0.868	1.137
	Model 3	-0.035	0.624	0.966	0.840	1.110

Significant estimates are in bold. Model 1: adjusted for age, sex, and BMI; Model 2: adjusted for age, sex, BMI, current smoker, and current drinker; Model 3: adjusted for age, sex, BMI, hypertension, and diabetes. Abbreviations: β, coefficient; OR, odds ratio; CI, confidence interval; BMI, body mass index.

Discussion

In the present study, the PSQI was selected as the most frequently used index for sleep evaluation. Epidemiological studies on sleep have been performed using sleep times [17, 19] and questionnaires [15, 16, 18, 20, 21]. However, evaluating sleep by time alone lacks objectivity because sleep times and measurement items differ among studies. For example, one study considered the appropriate sleep time to be 7–8 hours [17], but another considered it to be 7–9 hours [19]; other studies have evaluated sleep-related time based on sleep latency (difficulty falling asleep) or sleep efficiency (maintaining sleep) [31]. Therefore, comprehensively evaluating sleep quality using a questionnaire may provide more objective findings. A previous study that compared the diagnostic screening characteristics of the Insomnia Severity Index, the Athens Insomnia Scale, and the PSQI reported similar sensitivities and specificities [32]. Therefore, the PSQI in the present study was confirmed to be a valid and comparable questionnaire to those used in other studies. Buysse et al. [28] defined a PSQI score >5 as poor sleep quality. Conversely, Das et al. [33] demonstrated that the mean PSQI was 8.59 ± 5.35 in a community-based study among a geriatric population, and they described that the difference in the PSQI may be due to the different cultures and lifestyles of people in different countries. The mean PSQI of all the participants in the present study was 10.7 ± 2.7, which seemed to reflect the current average Japanese lifestyle.

Comparisons between the PSQI ≤10 and ≥11 groups in the present study revealed that regular exercise was beneficial for sleep quality, which is consistent with previous findings [8–12, 34]. However, other studies did not observe a relationship between exercise and sleep [35, 36]. Briefly, the lowest or highest levels of exercise were not associated with sleep disorders [35], and the effects of short-term resistance exercise on sleep were inconsistent [36]. By contrast, previous studies reported a positive relationship between exercise intensity and sleep with 30 minutes or more of exercise each time [8], moderate to intense physical activity of 150 minutes or more per week [10], or 500 to 1500 metabolic equivalents of task minutes/week of physical activity [34]. Exercise intensity in the regular exercise group in the present study was considered intermediate because the mean days of exercise per week was 4.3 (SD = 1.7) and the mean exercise time per session was 80.3 minutes (SD = 64.2). Accordingly, the relationship observed between exercise intensity and sleep in the present study appears to support previous findings showing that intermediate exercise intensity has a positive effect on sleep quality.

The multiple logistic regression analysis in the present study revealed a positive correlation between good sleep quality and protein intake only in the regular exercise group. These results seem to indicate that there is a mechanism by which regular exercise promotes protein absorption. In addition to exercise, the ingestion of protein just before sleep has been reported to improve nighttime protein synthesis by enhancing its digestion and absorption [37]. Tryptophan is a constituent amino acid of protein that competes with the other larger neutral amino acids to gain access to the transport system to cross the blood-brain barrier. Dietary carbohydrates pull larger amino acids into the muscle tissue, allowing tryptophan to access the transport system, cross the blood-brain barrier, and contribute to the synthesis of serotonin and melatonin [38]. Tryptophan has been shown to affect the serotonin-melatonin pathway because an intraperitoneal injection in rats increased serotonin levels [39]; likewise, its administration to patients with moderate insomnia significantly reduced sleep latency [40]. The reason for good sleep quality among participants who reported high protein intake in their daily diet and regular exercise was thought to be a result of the pathogenesis in which the tryptophan-serotonin-melatonin pathway was activated due to the enhanced protein absorption.

In the present study, the following micronutrients were associated with sleep quality after adjusting for confounding factors (age, sex, BMI, current smoker, current drinker, education, hypertension, and diabetes): phosphorus, zinc, vitamin D, vitamin B₁₂, and pantothenic acid. Many of these micronutrients showed similar results as previous studies [16, 17, 31]. Frank et al. reported that lower intakes of phosphorus and zinc were associated with a shorter sleep duration [31]. Komada et al. [16] reported that vitamin D and vitamin B₁₂ in adult males were associated with sleep duration. Grandner et al. [17] reported that vitamin D was associated with sleep maintenance difficulties. Since the results for many of the micronutrients examined in the present study agreed with those of previous studies, the relationships observed between micronutrient intakes and sleep in the present study were considered reliable.

One limitation of the present study is that the number of inputs for the independent variables was restricted in the multivariate analysis because of the small number of participants. This study might include selection bias because the subjects participated voluntarily in this study. Since the PSQI was evaluated only with a questionnaire, using a more objective method such as a polysomnogram to assess sleep quality is necessary. Since we have not examined the effects of obstructive sleep apnea, future studies should be performed that incorporate a design to evaluate obstructive sleep apnea. Moreover, since this was a cross-sectional study, interventions analyzing regular exercise and protein intake could not be conducted. Further multicenter randomized controlled trials with target values for exercise intensity and protein intake are necessary to clarify the effects of regular exercise and nutrient intake on sleep quality.

Conclusions

We conducted this cross-sectional study on Japanese participants to investigate the relationship between regular exercise and nutrient intake as factors affecting sleep quality. Protein intake was higher among the participants with a PSQI ≤10 in the regular exercise group (mean, 17.13% of energy consumption) than in those in the non-regular exercise or PSQI ≥11 groups. Furthermore, the results of the multiple logistic regression analysis showed that sleep quality was better in the regular exercise group when protein intake was high; this relationship was not observed in the non-regular exercise group.

Acknowledgements

We would like to thank the officials of Shika Town, Ishikawa prefecture and the staff of the Department of Environmental and Preventive Medicine, Kanazawa University Graduate School of Medical Sciences, Kanazawa University Graduate School of Advanced Preventive Medical Sciences, Department of Bioinformatics and Genomics, University of Tsukuba and Keio University.

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