https://orcid.org/0009-0005-8747-1204
Figures
Abstract
Background
Although healthy sleep patterns have been linked to a lower risk of cardiovascular disease in earlier research, it is unclear how beneficial they are for venous thromboembolism (VTE).
Aim
This research aimed to examine the correlation between sleep patterns, genetic susceptibility, and VTE.
Methods
In the UK Biobank cohort, healthy sleep behaviors were defined as early chronotype, 7–8 hours of sleep each day, no snoring, infrequent insomnia, and infrequent daytime sleepiness. Each of the five criteria was given 1 point, creating a healthy sleep score ranging from 0 to 5. Cox proportional hazards regression models were utilized to examine the associations between genetic susceptibility, healthy sleep score and VTE.
Results
The UK Biobank study included 384,758 participants aged 56.6 ± 8.0 years. After a median of 11.9 years of follow-up, 8,885 (2.3%) participants were diagnosed with VTE. A healthy sleep score inversely affected VTE risk. For participants with a score of 5, the hazard ratio of VTE was 0.813 (95% confidence interval: 0.758–0.873, P<0.001) compared to those with a score ≤2. Early chronotype, sleeping 7–8 hours each day, infrequent insomnia, and infrequent daytime sleepiness were significantly associated with a 7.9%, 8.3%, 5.1%, and 20.7% lower risk of VTE, respectively. In addition, the correlation between sleep pattern and the incidence of VTE was consistent, regardless of genetic susceptibility (P for interaction = 0.366).
Citation: Bai J, Yang Z, Jia Y, Yu J, Jiang W, Liu Y, et al. (2024) Sleep patterns, genetic susceptibility, and venous thromboembolism: A prospective study of 384,758 UK Biobank participants. PLoS ONE 19(9): e0309870. https://doi.org/10.1371/journal.pone.0309870
Editor: Ronaldo Go, RWJBH: RWJBarnabas Health, UNITED STATES OF AMERICA
Received: January 20, 2024; Accepted: August 15, 2024; Published: September 6, 2024
Copyright: © 2024 Bai et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: Data and materials can be obtained at https://ukbiobank.dnanexus.com/panx/projects.
Funding: This work was supported financially by grants from Sichuan Science and Technology Program (No. 2023YFS0027, 2023YFS0240, 2023YFS0074, 2023NSFSC1652, 2022YFS0279, 2021YFQ0062, 2022JDRC0148), Sichuan Provincial Health Commission (No. ZH2022-101), Sichuan University West China Nursing Discipline Development Special Fund Project (No. HXHL20017, HXHL20046, HXHL21016) the funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
With more than 10 million cases per year worldwide, venous thromboembolism (VTE), including pulmonary embolism (PE) and deep vein thrombosis (DVT), ranks as the third most prevalent cardiovascular ailment [1]. A large lower extremity vein might develop single or multiple thromboses, which is known as DVT [2]. PE is the most dangerous VTE that occurs when an embolus enters the lungs from a vein and occludes the pulmonary artery [3]. Approximately 20% of individuals with a VTE die within 1 year, and various complications are common among survivors [4]. Therefore, enhancing the prediction and prevention of VTE by identifying its risk factors is critical.
Hospital-based risk factors (e.g., congestive heart failure, recent prior surgery and cancer) for VTE have recently been identified, and effective preventive measures, both primary and secondary, have been given to high-risk patients; however, VTE seems to occur constantly or even increase [1]. The prevention of VTE has expanded beyond targeting primarily hospital-based risk factors to avoid harmful lifestyles, such as smoking and obesity [5]. Adequate evidence has proven that several unhealthy sleep behaviors [6], including long or short sleep duration [7, 8], late chronotype [9, 10], insomnia [11–13], snoring [14], and frequent daytime sleepiness [15], are significant risk factors for cardiovascular disease, primarily coronary heart disease, stroke, and myocardial infarction [16]. However, the etiology of VTE is distinct from that of arterial thrombosis, and there is a paucity of research on the protective effects of healthy sleep habits against VTE.
It is generally accepted that behavioral and genetic factors play a role in cardiovascular disease, including VTE [17]. Numerous studies have demonstrated that lifestyle factors may interact with genetic susceptibility to cardiovascular disease. Furthermore, healthy lifestyle choices such as reducing alcohol consumption [18], quitting smoking [19], engaging in appropriate physical activity [20], and avoiding obesity [21] may significantly reduce the genetically predetermined risk of VTE.
However, whether healthy sleep patterns, which incorporate a variety of sleep behaviors, such as early chronotype, 7–8 hours of sleep each day, infrequent insomnia, no snoring, and infrequent daytime sleeping, could mitigate the impact of genetic susceptibility on VTE remains unknown. Thus, using the UK Biobank cohort project, we prospectively explored the relationships between particular main sleep behaviors, as measured by a healthy sleep score, and VTE risk. Furthermore, our objective was to investigate the possible correlation between genetic susceptibility and healthy sleep patterns, as well as their combined affiliation with VTE (PE and DVT).
Materials and methods
Study population
The data utilized in this study were acquired from the UK Biobank, which is a large-scale prospective cohort study with a sufficiently representative sample of the UK population. A total of 502,655 individuals aged 37 to 73 years were included in the UK Biobank between 2006 and 2010. The participants were recruited from 22 assessment sites situated throughout England, Wales and Scotland. These individuals self-completed a touchscreen questionnaire and participated in verbal interviews to provide information on their sociodemographics and lifestyle. They also completed a number of physiological and anthropometric measurements [22]. Specifics on the acquisition of data may be found at the following website: http://www.ukBiobank.ac.uk. Materials and data are available at https://ukBiobank.dnanexus.com/panx/projects..
A total of 242 people chose to discontinue their participation in the UK Biobank project. In this analysis, we removed individuals who were not white (n = 23,365; addressing the influence of genetic variations among different racial groups on the research outcomes), those who had a history of prevalent VTE at the onset of the study (n = 3,940), and those who had missing data to calculate sleep (n = 84,460) and polygenic risk scores (n = 5,890). A total of 384,758 participants were ultimately included in our final prospective analysis.
Ethics statement
The UK Biobank was ethically approved for this study by the NHS National Research Ethics Service (16/NW/0274). The experimental protocols were carried out in accordance with the ethical guidelines of the Helsinki Declaration. Written informed consent was obtained from the participants or their guardians. All methods were established under guidelines and regulations developed by the UK Biobank. The use of the data was approved by the Human Ethical Committee of the West China Hospital of Sichuan University (2021–601).
Patient and public involvement
The participants in this study were not engaged in the process of designing, implementing, reporting, or disseminating the research.
Assessment of sleep behaviors
During recruitment, a touchscreen questionnaire was utilized to gather all self-reported information on sleep behaviors, including sleep chronotype, sleep duration, snoring, insomnia, and frequent daytime sleeping.
The evaluation of chronotype preference was carried out by asking "How do you perceive yourself?" Participants were asked to categorize themselves as follows: "certainly a ’morning’ person," "morning-oriented more than evening-oriented," "evening-oriented more than morning-oriented," or "certainly an ’evening’ person." Furthermore, each participant’s sleep duration was assessed by the exact number of hours they slept over the course of 24 hours, naps included. The symptoms of insomnia were determined through an inquiry into whether the individual had difficulty initiating sleep or awakening during the night. The response options for the questions were "usually," "sometimes," or "never/rarely." The data pertaining to snoring were acquired through an inquiry into whether the participant’s close relative, companion, or acquaintance lodges complaints regarding their snoring. Participants were given the option to answer either "yes" or "no." Subsequently, "To what extent do you believe it is likely that you will inadvertently fall asleep or doze off during the day?" was utilized to collect information pertaining to participants’ daytime sleepiness. The options for replies were categorized as “Never/rarely,” “Sometimes,” "Often, and “All of the time.” In the event that the sleep habits indicated above underwent significant changes, participants were requested to provide an average response to their behavior in the last month.
Definition of a healthy sleep pattern and healthy sleep score
The criteria for healthy sleep pattern were established as having an early chronotype (being more of a "morning" person than an "evening" person), getting 7–8 hours of sleep each day, experiencing infrequent insomnia ("sometimes" or "never/rarely"), not snoring, and experiencing infrequent daytime sleepiness ("sometimes" or "never/rarely"). The participants received 1 point for each instance of healthy sleep behavior, provided that they matched the specified requirements. Otherwise, they received 0 points. The healthy sleep score, which ranges from 0 to 5, is computed by adding together the individual scores of each of the five components. A higher score indicates a healthier sleep pattern [23].
Assessment of VTE
Participants who had the occurrence of DVT or PE during follow-up were categorized as having developed VTE in this study. The results were chiefly identified by analyzing hospital inpatient records, which included information on admissions and diagnosis. These records were obtained from the Hospital Episode Statistics for the United Kingdom, the Patients Episode Database for Wale, and Scottish Morbidity Record data for Scotland. According to the International Classification of Diseases Edition 10, we identified the following outcomes: I26 for PE and I80, I81, and I82 for DVT.
Following enrollment, the follow-up time was calculated from that date until the earliest of the following occurred: first diagnosis of VTE, death, or termination of the current follow-up in 2023.
Definition of the polygenic risk score
The Polygenic Risk Score (PRS) is a numerical assessment of an individual’s genetic susceptibility to a certain disease. Comprehensive details about quality control, genotyping, and imputation in the UK Biobank research have already been documented [24]. To compute the VTE PRS, a weighted method was implemented. In this investigation, we developed a PRS for VTE by utilizing 35 specific genetic variations called single nucleotide polymorphisms (SNPs), which were derived from a prior genome-wide association study [25]. Afterwards, the individuals’ SNPs were transformed into numerical values of 0, 1, or 2 concerning the count of risk alleles. The impact of SNPs (β) on VTE was utilized as the metric to calculate the aggregated sum of all selected SNPs for the PRS. The VTE PRS equation was: PRS = (β1 *SNP1 + β2 *SNP2 + … + β35 *SNP35). The VTE PRS ranged from −3.98 to 6.23. Based on the PRS tertile, participants were split into three subgroups: low-risk, intermediate-risk, and high-risk.
Assessment of covariates
Drawing on the literature, we identified a number of sociodemographic and behavioral confounders. A variety of health-related data, such as sex, age, education level, income, physical activity, body mass index, drinking and smoking status, cardiovascular disease, hypertension, diabetes, cancer, blood glucose levels, triglyceride levels, total cholesterol, low-density lipoprotein cholesterol, and high-density lipoprotein cholesterol, were collected from the UK Biobank.
Based on height and weight data, the body mass index was computed. A systolic/diastolic blood pressure ≥140/90 mmHg was regarded as hypertension, as was the use of antihypertensive medications. A blood glucose level of 126 mg/dL during fasting, 200 mg/dL during nonfasting, or hypoglycemic medication use was considered to indicate diabetes. Cardiovascular disease markers in this research included self-reported past coronary procedures, anomalies on physiological tests or electrocardiograms, and confirmed incidences of cardiovascular disease.
Statistical analysis
Both parametric and non-parametric continuous variables were presented as means ± standard deviations or medians (25th, 75th), respectively, and were compared utilizing analysis of variance or the Mann‒Whitney U test. Categorical variables were reported as n (%) and compared utilizing the chi-squared test. The missing continuous variables were filled in utilizing multivariate imputation using a chained equation employing predictive mean matching [26].
The minimum sample size was calculated by using the log-rank test [27]. When the type I error and type II error are 0.05 and 0.20, respectively, the calculated minimum sample size required was 35,376.
Individuals were grouped into 4 groups based on their healthy sleep scores: 0–2, 3, 4, or 5. However, individuals who scored 0 and 1 were not suitable for independent analysis due to their low representation in the entire population (0.2% and 2.2%, respectively). We used Cox proportional hazards models to derive hazard ratios (HRs) and 95% confidence intervals (CIs) to evaluate the correlation between healthy sleep patterns and VTE. The reference group consisted of individuals with scores ranging from 0 to 2. Furthermore, to address the possibility of non-vascular disease mortality preventing the incidence of VTE when it occurs first, we used the Gray-fine subdistribution hazard model to evaluate the relationship between healthy sleep score and VTE. For the purpose of investigating the correlation between individual sleep habits and VTE, we included all five components in the model concurrently, treating each one as a binary variable—either meeting or not meeting the healthy criteria. Similar analyses were repeated for participants diagnosed with PE or DVT. All models were fully adjusted for sex, age, income, education, physical activity, body mass index, drinking and smoking status, hypertension status, diabetes status, cancer status, cardiovascular disease status, blood glucose levels, triglyceride levels, low-density lipoprotein cholesterol, high-density lipoprotein cholesterol and total cholesterol. Sensitivity analyses were conducted among individuals without missing values and those who were followed up for more than 2 years. Moreover, cumulative incidence functions were used to estimate the cumulative probability of VTE (PE or DVT) events in four groups with different healthy sleep scores. Referring to previous research, two-sided Gray’s test was utilized to compare the results among the four groups [28].
A fully adjusted Cox proportional hazard model was conducted to examine the correlation between an individual’s healthy sleep score and their risk of developing VTE among different genetic risk subgroups. Additionally, an interaction test was performed to determine whether there was any interaction effect between an individual’s healthy sleep score and their genetic susceptibility to VTE. Furthermore, we evaluated the combined impact of the PRS and healthy sleep score on the risk of VTE utilizing a Cox proportional hazard model.
SPSS version 26.0 (IBM Corp, Armonk, NY, USA) and R statistical software (version 4.1.1) were applied for all the statistical analyses. For all tests, a two-tailed P value less than 0.05 was considered to indicate statistical significance.
Results
Patient characteristics
This study included 384,758 participants aged 56.6 ± 8.0 years, 172598 (44.9%) of whom were male. After an average of 11.9 years of follow-up, 8,885 (2.3%) patients were diagnosed with VTE, with 5,103 (1.3%) and 4,567 (1.2%) patients diagnosed with PE and DVT, respectively. The baseline parameters were compared based on the occurrence of VTE (Table 1). Participants with VTE exhibited characteristics such as older age, lower education level, higher proportion of males, socioeconomically disadvantaged status, higher prevalence of smoking, lower likelihood of engaging in physical activity, and lower prevalence of current alcohol use compared to those without VTE (P<0.05). Furthermore, they exhibited an increased incidence of cardiovascular risk factors, including hypertension, diabetes, cardiovascular disease, and cancer, at the outset of the study (P<0.05).
Healthy sleep score, VTE, and non-vascular disease mortality
After eliminating the competitive risk of non-vascular disease mortality, Fig 1A shows that the cumulative incidence of VTE varied significantly across different healthy sleep score groups (P < 0.001, Fig 1), indicating a progressive increase in VTE incidence as the healthy sleep score decreased. Comparable patterns were also evident in the cumulative incidence of PE and DVT (Fig 1).
A. Cumulative incidence of VTE with different healthy sleep scores; B. Cumulative incidence of PE with different healthy sleep scores; C. Cumulative incidence of DVT with different healthy sleep scores.
The results of the Cox proportional hazards regression analysis are shown in Table 2. According to the fully adjusted Model 3, there was a negative correlation between a healthy sleep score and VTE (HR for 1-point rise: 0.935, 95% CI: 0.917–0.955, P<0.001). Among those with a healthy sleep score of 5, the HR of VTE decreased to 0.813 (95% CI: 0.758–0.873, P<0.001), compared with that of the reference group (scores of 0–2). When assessing the correlation between each binary (healthy vs. unhealthy) factor of the healthy sleep pattern and the risk of VTE, the HRs of VTE were 0.921 (95% CI: 0.881–0.964, P<0.001) for 7–8 hours of sleep each day, 0.917 (95% CI: 0.878–0.957, P<0.001) for early chronotype, 0.949 (95% CI: 0.906–0.994, P = 0.028) for infrequent insomnia, and 0.793 (95% CI: 0.712–0.882, P<0.001) for infrequent daytime sleepiness compared with their counterparts. However, no snoring was not significantly associated with VTE (HR: 0.996, 95% CI: 0.953–1.041, P = 0.853) (Table 2).
When using Gray-fine subdistribution hazard model to eliminate the non-vascular disease mortality in the competing risk analysis (Table 3), the results showed a significant negative correlation between the healthy sleep score and VTE (HR for 1-point rise: 0.939, 95% CI: 0.919–0.960, P<0.001). Moreover, the relationships between sleep-related variables and VTE were largely consistent.
Cox proportional hazards regression analysis of the fully adjusted Model 3 revealed that healthy sleep patterns (5 scores) reduced the risk of PE and DVT by 17.4% and 19.7%, respectively (P < 0.001). Furthermore, healthy sleep behaviors, such as getting 7–8 hours of sleep each day, early chronotype, experiencing infrequent insomnia and daytime sleepiness, were demonstrated to be significantly protective in preventing PE and DVT (P < 0.05) (S1 and S2 Tables).
Sensitivity analyses that omitted participants with missing data on variables (S3 Table) or those with less than 2 years of follow-up (S4 Table) yielded generally robust findings.
Impact of PRS on the association between sleep behaviors and VTE
Participants with a higher genetic risk had a significantly higher incidence of VTE (low vs. intermediate vs. high, 1.5% vs. 2.1% vs. 3.4%, respectively, P<0.001). In the multivariate model (Fig 2), the link between healthy sleep score and VTE proved to be significant (P<0.05) and consistent across individuals in the low, intermediate, and high genetic risk subgroups (P for interaction = 0.431). Comparable correlations were discovered for PE (P for interaction = 0.243) and DVT (P for interaction = 0.627) (S1A and S2A Figs).
We further tested the combined correlation of healthy sleep score and PRS with the incidence of VTE. Participants with a low genetic risk and a good sleep pattern (5 scores) risked least (HR = 0.356, 95% CI: 0.313–0.405, P<0.001) compared to those with a high genetic risk and a poor sleep pattern (0–2 points), who had the greatest risk of VTE (Fig 2B). In a comparable manner, the risk of PE and DVT was decreased by 69.5% and 60.5% (P<0.001), respectively, when low genetic risk and good sleep pattern were combined (S1B and S2B Figs).
Discussion
Our secondary analysis of a large-scale prospectively gathered registry revealed a robust inverse correlation between healthy sleep patterns and the likelihood of developing VTE. This finding aligns with earlier research that explored the connections between various sleep practices and the risk of cardiovascular disease [23, 29–31]. In addition to conventional risk variables such as demographic, genetic, behavioral, and anthropometric factors [5], individuals with a healthy sleep pattern proved to have 20% lower risk of VTE, including PE and DVT, compared to those with a poor sleep pattern (healthy sleep score = 0–2). A healthy sleep patterns may effectively prevent VTE in the overall population.
Alongside conventional risk variables such as demographic, genetic, behavioral, and anthropometric factors, previous studies have demonstrated that five individual sleep behaviors—early chronotype [9, 10], 7–8 h/day of sleep [7, 8], no snoring [14], infrequent insomnia [11–13], and infrequent daytime sleepiness [15]—are independently linked to a diminished risk of cardiovascular disease (stroke and coronary heart disease, for instance). These findings align with our study on VTE. Furthermore, the correlation between snoring and the occurrence of VTE became insignificant when additional adjustments were made for body mass index. This finding implies that obesity, rather than snoring, is one of the independent risk factors for VTE. Similar findings were obtained from the examination of PE and DVT patients.
We conducted a thorough analysis for the first time to uncover the combined impact of sleep behaviors and PRS on the risk of VTE. Our findings indicate that as genetic susceptibility to VTE (PE and DVT) increases, the protective effect of a healthy sleep score on the risk of VTE remains consistent. A healthy sleep pattern might partly mitigate the occurrence of VTE resulting from a high hereditary vulnerability. In contrast, if a person does not have a healthy sleep pattern, they may lose the innate protection that comes with low genetic risk. Hence, maintaining a healthy sleep pattern is crucial for the primary prevention of VTE and other related complications, irrespective of an individual’s genetic predisposition.
Various mechanisms might contribute to the link between a good sleep pattern and lower VTE risk. By means of multiple mechanisms, unhealthy sleep practices may increase the risk of VTE, either individually or in concert. A relatively later chronotype is linked to several factors that may contribute to VTE, such as mood disorders, [32] smoking habits (33), unhealthy diets [34, 35], and low physical activity [36]. Research has shown a clear association between insufficient sleep duration and many risk factors for VTE, such as autonomic nervous system disorders [16], endothelial dysfunction [37], and metabolic disruption [38]. In addition, an extended period of sleep is linked to elevated levels of markers of systemic inflammation, which may contribute to the development of VTE [39]. Similarly, insomnia is thought to be linked to an elevated heart rate [40] and systemic inflammation [41, 42], which are positively associated with the incidence of VTE [43, 44]. These potential mechanisms are worthy of further research.
The importance of taking sleep practices into account in the prevention of VTE is emphasized by our research. This approach is beneficial for identifying persons at high risk and for facilitating health management. Utilizing a simple scoring algorithm offers a more accessible approach to interpreting epidemiological results and implementing them in real-world scenarios, hence increasing their acceptability among the general populace. Nevertheless, more clinical studies targeting sleep practice interventions will be highly necessary to assess the existence of a cause-and-effect link, given that this research is purely observational and that all the results should be regarded cautiously.
Limitations
First, the observed connections between sleep patterns and the occurrence of VTE should not be regarded as causative relationships, given the observational nature of this study. Second, this research used a sample consisting of individuals of Caucasian descent from the UK Biobank, thus potentially limiting the generalizability of the findings to groups outside this specific group. Nevertheless, the study’s internal validity will not be undermined. Third, since the sleep habit data included in our study came from a self-report questionnaire, there may be recall bias and misclassification of exposures, which ultimately leads to an underestimation of the impact of the observed relationships. Fourth, it should be noted that sleep behaviors were only recorded at baseline, therefore failing to account for any changes in sleep patterns that may have occurred throughout the course of the evaluation. Fifth, the UK Biobank’s lack of outpatient VTE records, constituting around 15% of VTE cases, and an intra-hospital diagnostic omission rate of about 10% result in a relatively low VTE incidence rate in this study. This limitation may significantly influence the discussion regarding the association between VTE and sleep. However, contemporary D-dimer tests have up to 98% sensitivity for VTE, greatly improving the diagnosis rate of VTE. Finally, the presence of unmeasured or unexplained residual confounding factors is inevitable.
Conclusions
We identified that healthy sleep patterns, comprising early chronotype, sleeping 7–8 hours each day, infrequent insomnia and daytime sleepiness, are significantly linked with VTE (including PE and DVT) based on data from the UK Biobank study. Our results indicate that a healthy sleep pattern is correlated with a lower risk of developing VTE, irrespective of the individual’s genetic risk. This study highlights the significance of early-stage VTE prevention via the maintenance of a healthy sleep pattern.
Supporting information
S1 Fig. Association of healthy sleep score with PE in subgroups with different genetic risk factors (A), and the joint association of healthy sleep score and PRS with the risk of PE (B).
https://doi.org/10.1371/journal.pone.0309870.s001
(TIF)
S2 Fig. Association of healthy sleep score with DVT in subgroups with different genetic risk factors (A), and the joint association of healthy sleep score and PRS with the risk of DVT (B).
https://doi.org/10.1371/journal.pone.0309870.s002
(TIF)
S1 Table. Association of healthy sleep quality with the risk of PE among 384758 UK Biobank participants.
https://doi.org/10.1371/journal.pone.0309870.s003
(DOCX)
S2 Table. Association of healthy sleep quality with the risk of DVT among 384758 UK Biobank participants.
https://doi.org/10.1371/journal.pone.0309870.s004
(DOCX)
S3 Table. Association of the healthy sleep score with risk of VTE among individuals without missing values.
https://doi.org/10.1371/journal.pone.0309870.s005
(DOCX)
S4 Table. Association of the healthy sleep score with risk of VTE in the individuals with more two years of follow-up.
https://doi.org/10.1371/journal.pone.0309870.s006
(DOCX)
Acknowledgments
The authors appreciate the participants for their involvement and contribution to the UK Biobank study. This study was carried out using the UK Biobank database, with application number 112111.
References
- 1. Heit JA. Epidemiology of venous thromboembolism. Nat Rev Cardiol. 2015;12(8):464–74. pmid:26076949
- 2. Olaf M, Cooney R. Deep Venous Thrombosis. Emerg Med Clin North Am. 2017;35(4):743–70. pmid:28987427
- 3. Huisman MV, Barco S, Cannegieter SC, Le Gal G, Konstantinides SV, Reitsma PH, et al. Pulmonary embolism. Nat Rev Dis Primers. 2018;4:18028. pmid:29770793
- 4. Brill A. Multiple Facets of Venous Thrombosis. Int J Mol Sci. 2021;22(8). pmid:33917767
- 5. Gregson J, Kaptoge S, Bolton T, Pennells L, Willeit P, Burgess S, et al. Cardiovascular Risk Factors Associated With Venous Thromboembolism. JAMA Cardiol. 2019;4(2):163–73. pmid:30649175
- 6. Song Q, Wang M, Zhou T, Sun D, Ma H, Li X, et al. The Lifestyle-Related Cardiovascular Risk Is Modified by Sleep Patterns. Mayo Clin Proc. 2022;97(3):519–30. pmid:35135690
- 7. Itani O, Jike M, Watanabe N, Kaneita Y. Short sleep duration and health outcomes: a systematic review, meta-analysis, and meta-regression. Sleep Med. 2017;32:246–56. pmid:27743803
- 8. Jike M, Itani O, Watanabe N, Buysse DJ, Kaneita Y. Long sleep duration and health outcomes: A systematic review, meta-analysis and meta-regression. Sleep Med Rev. 2018;39:25–36. pmid:28890167
- 9. Merikanto I, Lahti T, Puolijoki H, Vanhala M, Peltonen M, Laatikainen T, et al. Associations of chronotype and sleep with cardiovascular diseases and type 2 diabetes. Chronobiol Int. 2013;30(4):470–7. pmid:23281716
- 10. Makarem N, Paul J, Giardina EV, Liao M, Aggarwal B. Evening chronotype is associated with poor cardiovascular health and adverse health behaviors in a diverse population of women. Chronobiol Int. 2020;37(5):673–85. pmid:32126839
- 11. Canivet C, Nilsson PM, Lindeberg SI, Karasek R, Östergren PO. Insomnia increases risk for cardiovascular events in women and in men with low socioeconomic status: a longitudinal, register-based study. J Psychosom Res. 2014;76(4):292–9. pmid:24630179
- 12. Hsu CY, Chen YT, Chen MH, Huang CC, Chiang CH, Huang PH, et al. The Association Between Insomnia and Increased Future Cardiovascular Events: A Nationwide Population-Based Study. Psychosom Med. 2015;77(7):743–51. pmid:26355726
- 13. Sofi F, Cesari F, Casini A, Macchi C, Abbate R, Gensini GF. Insomnia and risk of cardiovascular disease: a meta-analysis. European journal of preventive cardiology. 2014;21(1):57–64. pmid:22942213
- 14. Li D, Liu D, Wang X, He D. Self-reported habitual snoring and risk of cardiovascular disease and all-cause mortality. Atherosclerosis. 2014;235(1):189–95. pmid:24854629
- 15. Yin J, Jin X, Shan Z, Li S, Huang H, Li P, et al. Relationship of Sleep Duration With All-Cause Mortality and Cardiovascular Events: A Systematic Review and Dose-Response Meta-Analysis of Prospective Cohort Studies. J Am Heart Assoc. 2017;6(9). pmid:28889101
- 16. Tobaldini E, Costantino G, Solbiati M, Cogliati C, Kara T, Nobili L, et al. Sleep, sleep deprivation, autonomic nervous system and cardiovascular diseases. Neurosci Biobehav Rev. 2017;74(Pt B):321–9. pmid:27397854
- 17. Yuan S, Mason AM, Burgess S, Larsson SC. Genetic liability to insomnia in relation to cardiovascular diseases: a Mendelian randomisation study. Eur J Epidemiol. 2021;36(4):393–400. pmid:33712906
- 18. Lippi G, Mattiuzzi C, Franchini M. Alcohol consumption and venous thromboembolism: friend or foe? Intern Emerg Med. 2015;10(8):907–13. pmid:26446524
- 19. Anand SS. Smoking: A Dual Pathogen for Arterial and Venous Thrombosis. Circulation. 2017;135(1):17–20. pmid:28028060
- 20. Evensen LH, Brækkan SK, Hansen JB. Regular Physical Activity and Risk of Venous Thromboembolism. Semin Thromb Hemost. 2018;44(8):765–79. pmid:30286501
- 21. Allman-Farinelli MA. Obesity and venous thrombosis: a review. Semin Thromb Hemost. 2011;37(8):903–7. pmid:22198855
- 22. Collins R. What makes UK Biobank special? Lancet. 2012;379(9822):1173–4. pmid:22463865
- 23. Fan M, Sun D, Zhou T, Heianza Y, Lv J, Li L, et al. Sleep patterns, genetic susceptibility, and incident cardiovascular disease: a prospective study of 385 292 UK biobank participants. Eur Heart J. 2020;41(11):1182–9.
- 24. Bycroft C, Freeman C, Petkova D, Band G, Elliott LT, Sharp K, et al. The UK Biobank resource with deep phenotyping and genomic data. Nature. 2018;562(7726):203–9. pmid:30305743
- 25. Lindström S, Wang L, Smith EN, Gordon W, van Hylckama Vlieg A, de Andrade M, et al. Genomic and transcriptomic association studies identify 16 novel susceptibility loci for venous thromboembolism. Blood. 2019;134(19):1645–57. pmid:31420334
- 26. White IR, Royston P, Wood AM. Multiple imputation using chained equations: Issues and guidance for practice. Statistics in medicine. 2011;30(4):377–99. pmid:21225900
- 27. Zurakowski D, Staffa SJ. Statistical power and sample size calculations for time-to-event analysis. The Journal of thoracic and cardiovascular surgery. 2023;166(6):1542–7.e1. pmid:36266091
- 28. Austin PC, Lee DS, Fine JP. Introduction to the Analysis of Survival Data in the Presence of Competing Risks. Circulation. 2016;133(6):601–9. pmid:26858290
- 29. Wang Z, Yang W, Li X, Qi X, Pan KY, Xu W. Association of Sleep Duration, Napping, and Sleep Patterns With Risk of Cardiovascular Diseases: A Nationwide Twin Study. J Am Heart Assoc. 2022;11(15):e025969. pmid:35881527
- 30. Huang BH, Duncan MJ, Cistulli PA, Nassar N, Hamer M, Stamatakis E. Sleep and physical activity in relation to all-cause, cardiovascular disease and cancer mortality risk. Br J Sports Med. 2022;56(13):718–24. pmid:34187783
- 31. Bertisch SM, Pollock BD, Mittleman MA, Buysse DJ, Bazzano LA, Gottlieb DJ, et al. Insomnia with objective short sleep duration and risk of incident cardiovascular disease and all-cause mortality: Sleep Heart Health Study. Sleep. 2018;41(6). pmid:29522193
- 32. Kowal C, Peyre H, Amad A, Pelissolo A, Leboyer M, Schürhoff F, et al. Psychotic, Mood, and Anxiety Disorders and Venous Thromboembolism: A Systematic Review and Meta-Analysis. Psychosom Med. 2020;82(9):838–49. pmid:32947580
- 33. Broms U, Pennanen M, Patja K, Ollila H, Korhonen T, Kankaanpää A, et al. Diurnal Evening Type is Associated with Current Smoking, Nicotine Dependence and Nicotine Intake in the Population Based National FINRISK 2007 Study. J Addict Res Ther. 2012;S2. pmid:22905332
- 34. Yuan S, Bruzelius M, Håkansson N, Åkesson A, Larsson SC. Lifestyle factors and venous thromboembolism in two cohort studies. Thromb Res. 2021;202:119–24. pmid:33831664
- 35. Zuraikat FM, St-Onge MP, Makarem N, Boege HL, Xi H, Aggarwal B. Evening Chronotype Is Associated with Poorer Habitual Diet in US Women, with Dietary Energy Density Mediating a Relation of Chronotype with Cardiovascular Health. J Nutr. 2021;151(5):1150–8. pmid:33758908
- 36. Johansson M, Johansson L, Wennberg P, Lind M. Physical activity and risk of first-time venous thromboembolism. European journal of preventive cardiology. 2019;26(11):1181–7. pmid:30727768
- 37. Cherubini JM, Cheng JL, Williams JS, MacDonald MJ. Sleep deprivation and endothelial function: reconciling seminal evidence with recent perspectives. Am J Physiol Heart Circ Physiol. 2021;320(1):H29–h35. pmid:33064569
- 38. Sun J, Wang M, Yang L, Zhao M, Bovet P, Xi B. Sleep duration and cardiovascular risk factors in children and adolescents: A systematic review. Sleep Med Rev. 2020;53:101338. pmid:32619932
- 39. Irwin MR, Olmstead R, Carroll JE. Sleep Disturbance, Sleep Duration, and Inflammation: A Systematic Review and Meta-Analysis of Cohort Studies and Experimental Sleep Deprivation. Biol Psychiatry. 2016;80(1):40–52. pmid:26140821
- 40. Cosgrave J, Phillips J, Haines R, Foster RG, Steinsaltz D, Wulff K. Revisiting nocturnal heart rate and heart rate variability in insomnia: A polysomnography-based comparison of young self-reported good and poor sleepers. J Sleep Res. 2021;30(4):e13278. pmid:33622029
- 41. Slavish DC, Graham-Engeland JE, Engeland CG, Taylor DJ, Buxton OM. Insomnia symptoms are associated with elevated C-reactive protein in young adults. Psychol Health. 2018;33(11):1396–415. pmid:30358412
- 42. Javaheri S, Redline S. Insomnia and Risk of Cardiovascular Disease. Chest. 2017;152(2):435–44. pmid:28153671
- 43. Awotoye J, Fashanu OE, Lutsey PL, Zhao D, O’Neal WT, Michos ED. Resting heart rate and incident venous thromboembolism: the Multi-Ethnic Study of Atherosclerosis. Open Heart. 2020;7(1):e001080. pmid:32153786
- 44. Dix C, Zeller J, Stevens H, Eisenhardt SU, Shing K, Nero TL, et al. C-reactive protein, immunothrombosis and venous thromboembolism. Front Immunol. 2022;13:1002652. pmid:36177015