Population-based cross-sectional study of sex-specific dose-response associations between night sleep duration and hypertension in Islamic Republic of Iran

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Samaneh Asgari1, Arezu Najafi2, Khosro Sadeghniiat-Haghighi3,2, Farid Najafi4, Roya Safari-Faramani4, Atefeh Behkar2 and Samaneh Akbarpour3,2

1Prevention of Metabolic Disorders Research Center, Research Institute for Endocrine Sciences, Shahid Beheshti University of Medical Sciences, Tehran, Islamic Republic of Iran. 2Occupational Sleep Research Center, Baharloo Hospital, Tehran University of Medical Sciences, Tehran, Islamic Republic of Iran. 3Sleep Breathing Disorders Research Center, Tehran University of Medical Sciences, Tehran, Islamic Republic of Iran. 4Research Center for Environmental Determinants of Health, Kermanshah University of Medical Sciences, Kermanshah, Islamic Republic of Iran (Correspondence to Samaneh Akbarpour: This email address is being protected from spambots. You need JavaScript enabled to view it.).

Abstract

Background: Several studies have suggested that sleep disorders have adverse effects on blood pressure. However, the findings remain controversial and only a few studies have investigated the association between sleep duration and hypertension among all age and sex subgroups.

Aim: To evaluate the dose-response association between sleep duration and blood pressure in the Iranian population using the Ravansar non-communicable disease cohort study.

Methods: This was a cross-sectional study of 9865 participants aged 35–65 years from the 2014–2017 Ravansar non-communicable disease cohort study. Night sleep duration was classified as ≤5 hours, 6 hours, 7 hours, 8 hours, 9 hours, and ≥10 hours. The association between self-reported sleep duration and hypertension was examined using multivariable logistic regression in STATA version 14. Restricted cubic spline analysis showed the dose-response association between sleep duration and hypertension.

Results: The age-adjusted prevalence of hypertension was 16.50% among men, 24.20% among women and 20.50% in the total population. Compared with reference sleep duration (7 hours) in the total population, the multivariable odds ratio [OR (95% CI)] for hypertension was 0.70 (0.55–0.88) for the group with 9 hours sleep duration and 0.90 (0.74–1.09) for the group with ≤5 hours sleep duration. Among pre-menopausal women, we observed an inverse association between 9 hours sleep duration and hypertension [0.62 (0.42–0.90)]. The age-adjusted cubic spline suggested a linear inverse association between sleep duration and prevalence of hypertension among men and the total population and a non-linear association among women.

Conclusion: Longer sleep duration (from 9 hours) had a negative association with hypertension. Further studies are needed to identify the risk factors associated with sleep duration and hypertension among the general population in the Islamic Republic of Iran.

Keywords: sleep, sleep disorder, high blood pressure, hypertension, Ravansar cohort study, Iran

Citation: Asgari S, Najafi A, Sadeghniiat-Haghighi K, Najafi F, Safari-Faramani R, Behkar A and Akbarpour S. Population-based cross-sectional study of sex-specific dose-response associations between night sleep duration and hypertension in Islamic Republic of Iran. East Mediterr Health J. 2023;29(12):954–965. https://doi.org/10.26719/emhj.23.119 Received: 22/12/22; Accepted: 24/07/23

Copyright © Authors 2023; Licensee: World Health Organization. EMHJ is an open access journal. This paper is available under the Creative Commons Attribution Non-Commercial ShareAlike 3.0 IGO licence (CC BY-NC-SA 3.0 IGO; https://creativecommons.org/licenses/by-nc-sa/3.0/igo).


Introduction

In the Islamic Republic of Iran, hypertension is a serious public health concern that significantly increases the risk of cardiovascular and cerebrovascular events (1). Analysis of national data showed that the prevalence of pre-hypertension and hypertension is 25.6% and 39.8%, respectively, among Iranian adults aged 25–70 years (2); the related prevalence among Iranians not taking anti-hypertensive medication is 12.6% (3).

In addition to meta­bolic risk factors, behaviours such as low physical activity, unhealthy diet and smoking (4,5) have been proven to be the main risk factors for incident hypertension (6). Recent studies suggest that sleep disorders have a negative effect on health (7–9). A meta-analysis reported a dose–response association between sleep duration and hypertension; it demonstrated that sleeping fewer than 6 hours increases the risk of hypertension by 10% compared to sleeping 7 hours, and by 20–30% when sleeping fewer than 5 hours a day (10). While the Rotterdam study found no association among the elderly (11), the Whitehall II study indicates an association only among women (12).

A study of the Chinese population found that longer (≥10 hours) or shorter (

Several studies in the Islamic Republic of Iran have assessed the association between sleep disorders and blood pressure (15,16); however, only a few (12,17,18) have investigated this association in terms of the sex differences.

Objective

In this study, we examined the sex-specific dose–response association between sleep duration and blood pressure in a large general population using the Ravansar Non-Communicable Disease (RaNCD) cohort study.

Methodology

Study population and design

This cross-sectional study used data from the RaNCD cohort study, which is part of the national cohort study of the Prospective Epidemiologic Research Studies of Iranian Adults that determines trends in the prevalence, incidence, risk factors and outcomes of non-communicable diseases. The cohort study was designed to be conducted over at least 15 years on a triennial basis.

The RaNCD study included 10 065 rural and urban individuals with the following inclusion criteria: 35–65 years of age; minimum residence of 1 year in Ravansar District, with a minimum stay of 9 months per year; likely to stay in Ravansar for the foreseeable future together with a willingness to participate; provision of written informed consent; capable of communicating with the research team; and having Iranian citizenship (according to national ID card and birth certificate) from November 2014 to February 2017 (19).

For our study of 10 065 individuals from the RaNCD study, we excluded those with missing data for body mass index (BMI), waist circumference (WC), creatinine (Cr), fasting plasma glucose (FPG), education, marital status, alcohol use, systolic blood pressure (SBP), diastolic blood pressure (DBP), smoking status, physical activity, total cholesterol (TC), triglycerides (TG), high-density lipoprotein cholesterol (HDL-C) and night sleep duration (n=200, considering overlaps between missing values). In all, 9865 individuals were eligible for our study (see Figure 1).

We confirm that the original cohort received appropriate ethical approval and informed consent was obtained from all participants. Any further data analysis in our study was in line with the terms of that approval and consent; the study protocol was approved by the Ethics Committee of the Kermanshah University of Medical Sciences. We used the STROBE checklist as a reporting guideline for this study.

Clinical and laboratory measurements

Information on demographic data, educational level, night sleep duration, alcohol use, smoking status and medication history (during the past 12 months) was obtained by a trained interviewer using a standard questionnaire. To address the potential recall bias on medications, participants were requested to provide relevant medical records to the follow-up team.

Anthropometric measurements (height and weight) were recorded with shoes removed and wearing lightweight clothes. Weight was measured to the nearest 100 grams. Height was measured in a standing position using a tape measure while shoulders were in normal alignment. WC was measured with lightweight clothing, at the level of the umbilicus. Questions on physical activity had 3 components: during work time, during leisure time and while doing sports. Metabolic equivalents were measured based on weekly physical activity time.

Based on the RaNCD study design (19), SBP and DBP were measured 2 times in the right arm after a 10-minute rest in a sitting position. Blood pressure was determined by averaging 2 readings. A blood sample was taken from all participants between 07:00 and 09:00 after 8-12 hours of overnight fasting, using standard blood-drawing vacationer techniques. FPG was measured by the enzymatic colorimetric method using glucose oxidase; their inter- and intra-assay coefficients of variation at baseline and follow-up phases were

Total cholesterol was assayed using the enzymatic colorimetric method with cholesterol esterase and cholesterol oxidase; the inter- and intra-assay coefficients of variation at baseline and follow-up phases were both 1.9%. Analyses were conducted using related kits and a Selectra 2 autoanalyser (Vital Scientific). Additional details for laboratory measurements, including FPG, TC, TG, HDL-C and Cr, had been addressed previously (19).

Definition of variables

BMI was calculated as weight (kg) divided by the square of body height (m). The estimated glomerular filtration rate (eGFR; mL/min per 1.73 m2) was estimated using the Chronic Kidney Disease Epidemiology Collaboration (CKD-EPI) (20).

Categorical variables were defined as education (12 years); marital status (single, married and widowed/divorced); smoking status (current, former and never); CKD (eGFR of less than 60 mL/min per 1.73 m2 for longer than 3 months); diabetes (FPG≥7 mmol/L or using anti-diabetic medications); hypertension (SBP≥140 mm Hg or DBP≥90 mm Hg or using anti-hypertensive medications or had been previously diagnosed by a doctor); pre-hypertension (130≤SBP

Menopausal status was defined as the absence of natural menstrual bleeding for more than 12 consecutive months and the exclusion of other pathological or physiological reasons.

Assessment of sleep duration

Total sleep duration was measured by asking the participant when they usually go to bed and wake up. As literature suggests (10, 12), we categorized sleep duration as ≤5 hours, 6 hours (>5 and ≤6 hours), 7 hours (reference, >6 and ≤7 hours), 8 hours (>7 and ≤8 hours), 9 hours (>8 and ≤9 hours) and ≥10 hours. Sleep duration of less than 1 hour is considered zero. We acknowledge that the use of a single question to measure sleep duration may introduce some degree of measurement error. However, this method has been used in previous studies (10,12).

Statistical analysis

Baseline characteristics were described as mean (standard deviation: SD) values for continuous variables, and frequencies (%) for categorical variables. For covariates with a skewed distribution (e.g. TG), the median (interquartile range: IQR) was reported. We compared the baseline characteristics of men and women among those with and without hypertension using the Student’s t-test for normally distributed continuous variables, the chi-squared test for categorical variables, and the Mann–Whitney U statistic for skewed and ordered variables.

Age-adjusted prevalence of hypertension was also presented for different night sleep duration groups. To be able to capture a potential dose–response association between the night sleep duration and hypertension, age-adjusted restricted cubic splines with 4 knots defined at the 5th, 25th, 75th and 95th percentiles were used, a method that enabled us to flexibly model across the groups of night sleep duration while analysing the dose–response association (22).

Potential risk factors suggested by previous studies were included in the univariable and multivariable logistic regression models to evaluate associations between hypertension and night sleep duration.

Confounding variables were adjusted in 5 models: model 1 was a univariable model that included only the night sleep duration variable; model 2 was a multivariable model adjusted for age and sex (only for the total population); model 3 was adjusted for other confounding covariates such as education, marital status, physical activity, current smoking, alcohol use and menopause status for women; model 4 was further adjusted with anthropometric covariates, including BMI and WC; and model 5 was a full model adjusted for the availability of diabetes, dyslipidaemia and CKD.

The multicollinearity of the variables was examined by the variance inflation factor (VIF) (23). We did not find evidence of collinearity (mean VIF=1.44).

The odds ratios (OR) and 95% confidence intervals (95% CI) were reported. However, there was no sex interaction with night sleep duration (P=0.90), and all analyses were done separately for men and women. The sex interaction with alcohol intake and BMI was checked, and since no interaction was observed (P=0.90 and P=0.15, respectively), the adjusted model was reported.

As a sensitivity analysis, we examined the association between night sleep duration and the prevalence of hypertension according to menopausal status. All analyses were conducted using STATA version 14 and a two-tailed P

Results

The study population consisted of 4668 men and 5197 women at baseline with a mean (SD) age of 47.8 (8.0) and 48.3 (8.4) years, respectively (see Table 1). The result using t-test analysis showed that men and women with hypertension had higher BMI, WC, TC and HDL-c and lower levels of TG and eGFR. The chi-square test for both genders revealed a significant statistical difference between smoking status, physical activity and education levels among those with and without hypertension.

The mean age-adjusted SBP of men and women on hypertension medication was 130 mm Hg (95% CI:128.3–132.8) and 124.2 mm Hg (95% CI:122.8–125.6), respectively; the mean SBP was 109.6 (95% CI:109.2–110.1) among men and 105.9 (95% CI:105.5–106.4) among women not taking hypertension medication.

The mean age-adjusted DBP of men and women on hypertension medication was 79.8 mm Hg (95% CI:78.6–80.9) and 77.6 mm Hg (95% CI:76.8–78.5), respectively; the mean DBP was 70.8 (95% CI:70.6–71.1) among men and 68.7 (95% CI:68.4–68.9) among women not taking hypertension medication (see Figure 2).

The age-adjusted hypertension prevalence was 16.5% among men, 24.2% among women (17% pre-menopause and 44.3% post-menopause) and 20.5% among the total population. As shown in Table 2, the age-adjusted prevalence of hypertension was 16.8% among men with ≤5-hour sleep duration and 14.9% in the group with ≥10-hour sleep duration (P for trend=0.39). However, among women, the age-adjusted prevalence of hypertension shows a significant decrease by increasing sleep hours: 23.8% in the group with ≤5-hour sleep duration and 23.5% in the group with ≥10-hour sleep duration (P for trend=0.02).

Table 3 shows the univariable and multivariable logistic regression of different sleep duration hours with the prevalence of hypertension. Among the total population, 9 hours of sleep (7 hours as reference) showed an inverse association with hypertension [OR (95% CI): 0.70 (0.55–0.88%)]. This association was also observed among women [OR (95% CI): 0.65 (0.48–0.86%)] but not men for 9 hours of sleep.

Figure 3 shows multivariable OR (95% CI) of hypertension per additional night sleep hour for men, women and the total population. When night sleep duration was adjusted with age in model 2, each additional night sleep hour was associated with 0.93 (0.87–0.99%) for women and 0.98 (0.972–1.05%) for men; this was significant for women. However, after further adjustment in multivariable model 5, the OR (95% CI) for each additional sleep hour reached 0.96 (0.90–1.01%) for women and 1.0 (0.94–1.07%) for men.

As a sensitivity analysis, we examined the association between night sleep duration and the prevalence of hypertension according to menopausal status. Among premenopausal women, in comparison with the 7-hour night sleep duration in model 5, women with a 9-hour night sleep duration had the age-adjusted OR (95% CI) of 0.62 (0.42–0.90%). Among postmenopausal women, no significant association was observed between night sleep duration and the prevalence of hypertension (see Table 4).

Discussion

This study indicated that a long sleep duration of 9 hours is associated with a lower prevalence of hypertension in the Iranian community-based population. There was a negative association between the prevalence of hypertension and progressively increasing sleep duration among the total population and women, while no significant trend was observed among men.

The association of sleep duration with hypertension persisted after adjustment for potential confounders, including age, education, marital status, physical activity, alcohol use, current smoking, BMI and waist circumference among the total population; the same results were observed only among women.

Analyses showed that the association between sleep duration and hypertension was not confounded by diabetes, dyslipidaemia or CKD. This study demonstrated a dose–response association between sleep duration and hypertension; however, this association was not linear among women.

This study indicates a sex-related difference in the association between sleep duration and hypertension (a U-shaped pattern for women vs a linear pattern for men). Obstructive sleep apnoea is more prevalent among men (24) while women experience more insomnia (25); both are independent risk factors for hypertension (26,27). Accordingly, they can influence the association between sleep duration and hypertension and must be considered in adjusted models.

In their review, Burgard et al. explained that women sleep more than men; we also indicated this in our study (28). This factor can influence the association between hypertension and sleep duration in terms of gender (a U-shaped pattern in women vs a linear decreasing pattern of hypertension odds with sleep duration among men) (see Figure 4).

It has been shown that the association of sleep disorders with hypertension is more prevalent among women (12,29). It is hypothesized that shorter sleep duration makes women more vulnerable to poor cardiovascular outcomes. Gender influence on the association of sleep duration needs more clarification of underlying mechanisms and further population-based studies based on more objective measures of sleep duration (30).

According to a National Sleep Foundation report, the optimal sleep duration for staying healthy is 7–9 hours a day among adults (18–64 years) (31). The principal findings of our study show that sleep duration of ≤5 hours a day is associated with a greater prevalence of hypertension and the negative association was observed with a 9-hour sleep duration. National Health Interview Survey (NHIS) data show that short (

Najafian et al. studied hypertension and self-reported sleep duration in central Iran. Even after adjusting for age, sex, BMI and abdominal obesity, sleeping less than 5 hours a day was associated with hypertension in people over 19 years old. However, the negative association between sleep duration of more than 9 hours and hypertension was statistically insignificant (32). These findings agree with ours; however, after further adjustment with potential confounders among those with sleep duration of ≤5 hours, we did not observe a positive association with hypertension.

A study in China showed a positive association among those with sleep duration of more than 10 hours a day and a negative association among those with sleep duration of 6 hours a day(13). They also found a U-shaped (non-linear) trend between sleep duration and hypertension among men; in our study, only women showed a non-linear trend. A linear negative dose–response relation was detected among the total population. One systematic review of 36 studies (26 cross-sectional and 10 cohorts) reported that short sleep duration was related to higher blood pressure and hypertension (33).

Consistent with our findings, Grandner et al. indicated higher odds for long sleepers (≥10 hours a day) in the non-adjusted model of their study covariates (18). However, in their study, both 9- and ≥10-hour groups were found to have higher odds for hypertension in the adjusted model. This difference in findings may be due to different measures of sleep duration between these 2 studies (sleep duration in the day vs sleep duration at night in our study) and different covariates in adjusted models.

In this study, we evaluated the association among adults aged 35–65 years, while the mechanism of the sleep duration on hypertension may differ among children, adolescents, young adults or the elderly (33). This will be a serious concern if we know that each 10 mm Hg increase in adolescent SBP/DBP increases the risk of early adulthood hypertension by 4% across 10 years of follow-up (11,34).

Limitations

This study’s strength is that it provides an epidemiological profile by assessing the dose–response association in a large sample of men and women in Islamic Republic of Iran, a country in the Middle East and North Africa (MENA) region. However, several limitations must be considered.

First, because it was a cross-sectional study, we were unable to determine causality. Second, it used self-reported sleep duration, smoking habits and alcohol use, and therefore recall bias is possible. Actigraphy and polysomnography could provide objective and detailed data on sleep characteristics.

Quality of sleep, daytime dysfunction, reported difference between weekday and weekend sleep duration and interference of sleep duration with daily activities could also influence the association between high blood pressure and sleep duration. Covariates like insomnia, obstructive sleep apnoea, employment status and shiftwork could affect hypertension and sleep duration, and require consideration in future studies.

The models showed low pseudo-R-squared values, which may suggest that a considerable portion of the variation remains unaccounted for. However, it is crucial to note that pseudo-R-squared was different from R-squared in linear regression models. This is because pseudo-R-squared may be low even when the models fit the data exceptionally, as discussed by Rose and Singh Mann (35).

Conclusion

This study found that longer sleep duration negatively correlates with hypertension. Further longitudinal studies are suggested to find a causal association between hypertension and sleep duration.

Acknowledgment

We acknowledge the staff and participants of the RaNCD cohort study for their cooperation.

Funding: None.

Competing interests: None declared.

Étude transversale en population des associations dose-réponse selon le sexe entre la durée du sommeil nocturne et l'hypertension en République islamique d'Iran

Résumé

Contexte : Plusieurs études ont suggéré que les troubles du sommeil ont des effets indésirables sur l'hypertension artérielle. Cependant, ces résultats restent controversés et seules quelques études se sont penchées sur l'association entre la durée du sommeil et l'hypertension dans tous les sous-groupes d'âge et de sexe.

Objectif : Évaluer la relation dose-réponse entre la durée du sommeil et la tension artérielle dans la population iranienne en utilisant l'étude de cohorte sur les maladies non transmissibles réalisée à Ravansar.

Méthodes : La présente étude transversale a été menée auprès de 9865 personnes âgées de 35 à 65 ans ayant participé à l'étude de cohorte sur les maladies non transmissibles réalisée entre 2014 et 2017 à Ravansar. La durée du sommeil nocturne a été classifiée comme suit : inférieure ou égale à cinq heures, six heures, sept heures, huit heures, neuf heures et supérieure ou égale à dix heures. La relation entre la durée du sommeil auto-déclarée et l'hypertension a été examinée à l'aide de la régression logistique multivariée réalisée avec le logiciel STATA version 14. L'analyse par spline cubique restreinte a mis en évidence l'association dose-réponse entre la durée du sommeil et l'hypertension.

Résultats : La prévalence de l'hypertension ajustée sur l'âge était de 16,50 % chez l'homme de 24,20 % chez la femme et de 20,50 % dans la population totale. Comparativement à la durée du sommeil de référence de sept heures dans la population totale, l'odds ratio multivarié [OR (IC à 95 %)] pour l'hypertension était de 0,70 (0,55-0,88) pour le groupe dont la durée du sommeil était de neuf heures et de 0,90 (0,74-1,09) pour le groupe dont la durée du sommeil était inférieure ou égale à cinq heures. Chez les femmes pré-ménopausées, nous avons observé une association inverse entre la durée du sommeil de neuf heures et l'hypertension [0,62 (0,42-0,90)]. L'analyse par spline cubique ajustée sur l'âge a révélé une association linéaire inverse entre la durée du sommeil et la prévalence de l'hypertension chez l'homme et dans la population totale, et une association non-linéaire chez la femme.

Conclusion : Une durée de sommeil plus longue (supérieure à neuf heures) était négativement associée à l'hypertension. Des études supplémentaires sont nécessaires pour identifier les facteurs de risque associés à la durée du sommeil et à l'hypertension dans la population générale de la République islamique d'Iran.

دراسة سكانية مقطعية لارتباطات الاستجابة لجرعات محددة حسب نوع الجنس بين مدة النوم ليلًا وارتفاع ضغط الدم في جمهورية إيران الإسلامية

سامانة أسجاريا، أريزو نجافيب، خسرو صادغنيات- هاغيغتش، فريد نجافيب، رويا سفاري-فرمانيد، عاطفة بهكارب، سامانة أكباربورك

الخلاصة

الخلفية: أشارت عدة دراسات إلى أن اضطرابات النوم لها آثار سلبية على ارتفاع ضغط الدم. ومع ذلك، لا تزال النتائج مثيرة للجدل، ولم تستقصِ سوى دراسات قليلة العلاقة بين مدة النوم وارتفاع ضغط الدم بين جميع الفئات الفرعية العمرية والجنسية.

الأهداف: هدفت هذه الدراسة الى تقييم علاقة الاستجابة للجرعات بين مدة النوم وضغط الدم لدى السكان الإيرانيين باستخدام الدراسة الأترابية عن الأمراض غير السارية في مدينة رفانسر.

طرق البحث: أُجريت هذه الدراسة المقطعية على 9865 مشاركًا تتراوح أعمارهم بين 35 و65 عامًا في دراسة أترابية عن الأمراض غير السارية في مدينة رفانسر في الفترة بين عامَي 2014 و2017. وصُنِّفت مدة النوم الليلي إلى مدة نوم ≤ 5 ساعات، و6 ساعات، و7 ساعات، و8 ساعات، و9 ساعات، و≥ 10 ساعات. وفُحصت العلاقة بين مدة النوم المُبلغ عنها ذاتيًّا وارتفاع ضغط الدم باستخدام الانحدار اللوجستي المتعدد المتغيرات في الإصدار 14 من برنامج STATA. وأظهر تحليل الشريحة التكعيبية المقيدة ارتباط الاستجابة للجرعات بين مدة النوم وارتفاع ضغط الدم.

النتائج: بلغ معدل انتشار ارتفاع ضغط الدم المُعدَّل حسب العمر 16,50% لدى الرجال، و24,20% لدى النساء، و20,50% لدى عامة السكان. وبالمقارنة مع مدة النوم المرجعية (7 ساعات) لدى عامة السكان، كانت نسبة الأرجحية المتعددة المتغيرات [نسبة الأرجحية (فاصل الثقة 95%)] لارتفاع ضغط الدم [0,70 (0,55-0,88)] للمجموعة التي تنام 9 ساعات و[0,90 (0,74-1,09)] للمجموعة تنام 5 ساعات أو أقل. وفي النساء في مرحلة ما قبل انقطاع الطمث، لاحظنا ارتباطًا عكسيًّا بين مدة النوم البالغة 9 ساعات وارتفاع ضغط الدم [0,62 (0,42-0,90)]. وأشارت الشريحة التكعيبية المُعدَّلة حسب العمر إلى وجود ارتباط عكسي خطي بين مدة النوم ومعدل انتشار ارتفاع ضغط الدم بين الرجال وعامة السكان، وارتباط غير خطي بين النساء.

الاستنتاجات: كانت مدة النوم الأطول (بداية من 9 ساعات) مرتبطة ارتباطًا سلبيًّا بارتفاع ضغط الدم. ويلزم إجراء مزيد من الدراسات لتحديد عوامل الخطر المرتبطة بمدة النوم وارتفاع ضغط الدم بين عامة السكان في جمهورية إيران الإسلامية.

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