睡眠至關重要：前瞻性研究探討多面向睡眠表現型對不同心血管疾病類型之影響

李育霖; Yu-Lin Lee

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102057

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	郭柏秀	zh_TW
dc.contributor.advisor	Po-Hsiu Kuo	en
dc.contributor.author	李育霖	zh_TW
dc.contributor.author	Yu-Lin Lee	en
dc.date.accessioned	2026-03-12T16:16:28Z	-
dc.date.available	2026-03-13	-
dc.date.copyright	2026-03-12	-
dc.date.issued	2026	-
dc.date.submitted	2026-02-02	-
dc.identifier.citation	1. Lindstrom, M., et al., Global Burden of Cardiovascular Diseases and Risks Collaboration, 1990-2021. J Am Coll Cardiol, 2022. 80(25): p. 2372-2425. 2. Luengo-Fernandez, R., et al., Economic burden of cardiovascular diseases in the European Union: a population-based cost study. Eur Heart J, 2023. 44(45): p. 4752-4767. 3. Kapuku, G.K. and W.J. Kop, Classification of Cardiovascular Diseases: Epidemiology, Diagnosis, and Treatment, in Handbook of Cardiovascular Behavioral Medicine, S.R. Waldstein, et al., Editors. 2022, Springer New York: New York, NY. p. 45-80. 4. Hilkens, N.A., et al., Stroke. Lancet, 2024. 403(10446): p. 2820-2836. 5. Netala, V.R., et al., A Comprehensive Review of Cardiovascular Disease Management: Cardiac Biomarkers, Imaging Modalities, Pharmacotherapy, Surgical Interventions, and Herbal Remedies. Cells, 2024. 13(17). 6. Morin, C.M. and D.C. Jarrin, Epidemiology of Insomnia: Prevalence, Course, Risk Factors, and Public Health Burden. Sleep Med Clin, 2022. 17(2): p. 173-191. 7. Canever, J.B., et al., Worldwide prevalence of sleep problems in community-dwelling older adults: A systematic review and meta-analysis. Sleep Med, 2024. 119: p. 118-134. 8. Lim, D.C., et al., The need to promote sleep health in public health agendas across the globe. Lancet Public Health, 2023. 8(10): p. e820-e826. 9. Hillman, D., et al., The economic cost of inadequate sleep. Sleep, 2018. 41(8). 10. Bays, H.E., et al., Ten things to know about ten cardiovascular disease risk factors - 2022. Am J Prev Cardiol, 2022. 10: p. 100342. 11. Schultz, W.M., et al., Socioeconomic Status and Cardiovascular Outcomes: Challenges and Interventions. Circulation, 2018. 137(20): p. 2166-2178. 12. Magnussen, C., et al., Global Effect of Modifiable Risk Factors on Cardiovascular Disease and Mortality. N Engl J Med, 2023. 389(14): p. 1273-1285. 13. Truthmann, J., et al., Modifiable cardiovascular risk factors in adults aged 40-79 years in Germany with and without prior coronary heart disease or stroke. BMC Public Health, 2015. 15: p. 701. 14. Cappuccio, F.P., et al., Sleep duration predicts cardiovascular outcomes: a systematic review and meta-analysis of prospective studies. Eur Heart J, 2011. 32(12): p. 1484-92. 15. Ferrie, J.E., et al., Associations between change in sleep duration and inflammation: findings on C-reactive protein and interleukin 6 in the Whitehall II Study. Am J Epidemiol, 2013. 178(6): p. 956-61. 16. Shah, R., et al., Mild sleep restriction increases endothelial oxidative stress in female persons. Sci Rep, 2023. 13(1): p. 15360. 17. Sondrup, N., et al., Effects of sleep manipulation on markers of insulin sensitivity: A systematic review and meta-analysis of randomized controlled trials. Sleep Med Rev, 2022. 62: p. 101594. 18. Liu, H. and A. Chen, Roles of sleep deprivation in cardiovascular dysfunctions. Life Sci, 2019. 219: p. 231-237. 19. Lloyd-Jones, D.M., et al., Life's Essential 8: Updating and Enhancing the American Heart Association's Construct of Cardiovascular Health: A Presidential Advisory From the American Heart Association. Circulation, 2022. 146(5): p. e18-e43. 20. López-Bueno, R., et al., Global prevalence of cardiovascular risk factors based on the Life's Essential 8 score: an overview of systematic reviews and meta-analysis. Cardiovasc Res, 2024. 120(1): p. 13-33. 21. Buysse, D.J., Sleep health: can we define it? Does it matter? Sleep, 2014. 37(1): p. 9-17. 22. St-Onge, M.P., et al., Multidimensional Sleep Health: Definitions and Implications for Cardiometabolic Health: A Scientific Statement From the American Heart Association. Circ Cardiovasc Qual Outcomes, 2025. 18(5): p. e000139. 23. Yin, J., 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). 24. Cui, H., et al., Relationship of sleep duration with incident cardiovascular outcomes: a prospective study of 33,883 adults in a general population. BMC Public Health, 2023. 23(1): p. 124. 25. Guo, C., E.L. Harshfield, and H.S. Markus, Sleep Characteristics and Risk of Stroke and Dementia: An Observational and Mendelian Randomization Study. Neurology, 2024. 102(5): p. e209141. 26. Lotti, S., et al., Chronotype Differences in Energy Intake, Cardiometabolic Risk Parameters, Cancer, and Depression: A Systematic Review with Meta-Analysis of Observational Studies. Adv Nutr, 2022. 13(1): p. 269-281. 27. Wang, L., et al., Association between Excessive Daytime Sleepiness and Risk of Cardiovascular Disease and All-Cause Mortality: A Systematic Review and Meta-Analysis of Longitudinal Cohort Studies. J Am Med Dir Assoc, 2020. 21(12): p. 1979-1985. 28. Chen, S., et al., Relationship between daytime napping and cardiovascular disease: A two-sample mendelian randomization study. Hellenic J Cardiol, 2024. 75: p. 26-31. 29. Yamada, T., et al., Daytime Napping and the Risk of Cardiovascular Disease and All-Cause Mortality: A Prospective Study and Dose-Response Meta-Analysis. Sleep, 2015. 38(12): p. 1945-53. 30. Zhao, B., et al., Association of Objective and Self-Reported Sleep Duration With All-Cause and Cardiovascular Disease Mortality: A Community-Based Study. J Am Heart Assoc, 2023. 12(6): p. e027832. 31. Huang, T., S. Mariani, and S. Redline, Sleep Irregularity and Risk of Cardiovascular Events: The Multi-Ethnic Study of Atherosclerosis. J Am Coll Cardiol, 2020. 75(9): p. 991-999. 32. Zheng, N.S., et al., Sleep patterns and risk of chronic disease as measured by long-term monitoring with commercial wearable devices in the All of Us Research Program. Nat Med, 2024. 30(9): p. 2648-2656. 33. Fischer, D., E.B. Klerman, and A.J.K. Phillips, Measuring sleep regularity: theoretical properties and practical usage of existing metrics. Sleep, 2021. 44(10). 34. Leening, M.J., et al., Sex differences in lifetime risk and first manifestation of cardiovascular disease: prospective population based cohort study. Bmj, 2014. 349: p. g5992. 35. Lok, R., J. Qian, and S.L. Chellappa, Sex differences in sleep, circadian rhythms, and metabolism: Implications for precision medicine. Sleep Med Rev, 2024. 75: p. 101926. 36. Khoja, A., et al., Risk Factors for Early-Onset Versus Late-Onset Coronary Heart Disease (CHD): Systematic Review and Meta-Analysis. Heart, Lung and Circulation, 2023. 32(11): p. 1277-1311. 37. Sudlow, C., et al., UK biobank: an open access resource for identifying the causes of a wide range of complex diseases of middle and old age. PLoS Med, 2015. 12(3): p. e1001779. 38. Hirshkowitz, M., et al., National Sleep Foundation's updated sleep duration recommendations: final report. Sleep Health, 2015. 1(4): p. 233-243. 39. Fan, M., 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): p. 1182-1189. 40. Doherty, A., et al., Large Scale Population Assessment of Physical Activity Using Wrist Worn Accelerometers: The UK Biobank Study. PLoS One, 2017. 12(2): p. e0169649. 41. Migueles, J.H., et al., GGIR: A Research Community–Driven Open Source R Package for Generating Physical Activity and Sleep Outcomes From Multi-Day Raw Accelerometer Data. Journal for the Measurement of Physical Behaviour, 2019. 2(3): p. 188-196. 42. 梁雅婷, 利用快速傅立葉轉換進行穿戴式裝置資料特徵變數之選取, in 國立臺灣大學公共衛生學院流行病學與預防醫學研究所. 2022, 國立臺灣大學: 臺北市. 43. van Hees, V.T., et al., Estimating sleep parameters using an accelerometer without sleep diary. Sci Rep, 2018. 8(1): p. 12975. 44. Cespedes, E.M., et al., Comparison of Self-Reported Sleep Duration With Actigraphy: Results From the Hispanic Community Health Study/Study of Latinos Sueño Ancillary Study. Am J Epidemiol, 2016. 183(6): p. 561-73. 45. Alsayid, M., et al., Behavioral circadian phenotypes are associated with the risk of elevated body mass index. Eat Weight Disord, 2022. 27(4): p. 1395-1403. 46. Ohayon, M., et al., National Sleep Foundation's sleep quality recommendations: first report. Sleep Health, 2017. 3(1): p. 6-19. 47. Windred, D.P., et al., Objective assessment of sleep regularity in 60 000 UK Biobank participants using an open-source package. Sleep, 2021. 44(12). 48. UK Biobank. Primary Care Linked Data Version 2.0. 2024; Available from: https://biobank.ndph.ox.ac.uk/showcase/showcase/docs/primary_care_data.pdf. 49. Wu, P., et al., Mapping ICD-10 and ICD-10-CM Codes to Phecodes: Workflow Development and Initial Evaluation. JMIR Med Inform, 2019. 7(4): p. e14325. 50. Wang, M., et al., Joint exposure to various ambient air pollutants and incident heart failure: a prospective analysis in UK Biobank. Eur Heart J, 2021. 42(16): p. 1582-1591. 51. Larsson, S.C., et al., Body mass index and body composition in relation to 14 cardiovascular conditions in UK Biobank: a Mendelian randomization study. Eur Heart J, 2020. 41(2): p. 221-226. 52. Peter Townsend, P.P., Alastair Beattie, Health and deprivation. Inequality and the North. 1997: Revista cubana de higiene y epidemiología 35. 53. Lloyd-Jones, D.M., et al., Defining and setting national goals for cardiovascular health promotion and disease reduction: the American Heart Association's strategic Impact Goal through 2020 and beyond. Circulation, 2010. 121(4): p. 586-613. 54. Mozaffarian, D., Dietary and Policy Priorities for Cardiovascular Disease, Diabetes, and Obesity: A Comprehensive Review. Circulation, 2016. 133(2): p. 187-225. 55. Lourida, I., et al., Association of Lifestyle and Genetic Risk With Incidence of Dementia. Jama, 2019. 322(5): p. 430-437. 56. Chen, L., D.Y. Lin, and D. Zeng, Attributable fraction functions for censored event times. Biometrika, 2010. 97(3): p. 713-726. 57. British Heart Foundation, Heart & Circulatory Disease Statistics, 2024 Compendium. 2024. 58. British Heart Foundation, Analysis of UK GP patient register data [CVD = BHF 2024 estimates]. 2024. 59. Fry, A., et al., Comparison of Sociodemographic and Health-Related Characteristics of UK Biobank Participants With Those of the General Population. Am J Epidemiol, 2017. 186(9): p. 1026-1034. 60. OHID/NHS. Analysis of England GP prevalence data. 2024; Available from: https://www.cvdprevent.nhs.uk/data-explorer. 61. StatsWales. Welsh disease prevalence data. 2024; Available from: https://statswales.gov.wales/Catalogue/Health-and-Social-Care/NHS-Primary-and-Community-Activity/GMS-Contract. 62. Ou, C., et al., Healthy sleep durations appear to vary across cultures. Proceedings of the National Academy of Sciences, 2025. 122(19): p. e2419269122. 63. Bin, Y.S., N.S. Marshall, and N. Glozier, Sleeping at the Limits: The Changing Prevalence of Short and Long Sleep Durations in 10 Countries. American Journal of Epidemiology, 2013. 177(8): p. 826-833. 64. Fischer, D., et al., Chronotypes in the US - Influence of age and sex. PLoS One, 2017. 12(6): p. e0178782. 65. Wang, Z., et al., Association of Sleep Duration, Napping, and Sleep Patterns With Risk of Cardiovascular Diseases: A Nationwide Twin Study. J Am Heart Assoc, 2022. 11(15): p. e025969. 66. Lechner, M., et al., Snoring and breathing pauses during sleep: interview survey of a United Kingdom population sample reveals a significant increase in the rates of sleep apnoea and obesity over the last 20 years - data from the UK sleep survey. Sleep Med, 2019. 54: p. 250-256. 67. Pallesen, S., et al., Prevalence and risk factors of subjective sleepiness in the general adult population. Sleep, 2007. 30(5): p. 619-24. 68. Ohayon, M.M., et al., How sleep and mental disorders are related to complaints of daytime sleepiness. Arch Intern Med, 1997. 157(22): p. 2645-52. 69. Wang, Z., et al., Association of Sleep Duration, Napping, and Sleep Patterns With Risk of Cardiovascular Diseases: A Nationwide Twin Study. Journal of the American Heart Association, 2022. 11(15): p. e025969. 70. Noh, W. and H. Moon, Short Sleep Duration as a Risk Factor of Cardiovascular Disease in Korean Adults: Secondary Analysis of the Fifth Korean National Health and Nutrition Examination Survey. Iran J Public Health, 2019. 48(7): p. 1239-1247. 71. Hou, X.Z., et al., Association of sleep characteristics with cardiovascular disease risk in adults over 40 years of age: a cross-sectional survey. Front Cardiovasc Med, 2024. 11: p. 1308592. 72. Ogilvie, R.P., et al., Joint effects of OSA and self-reported sleepiness on incident CHD and stroke. Sleep Med, 2018. 44: p. 32-37. 73. Zheng, B., et al., Insomnia symptoms and risk of cardiovascular diseases among 0.5 million adults. Neurology, 2019. 93(23): p. e2110-e2120. 74. Krittanawong, C., et al., Association between short and long sleep durations and cardiovascular outcomes: a systematic review and meta-analysis. European Heart Journal. Acute Cardiovascular Care, 2019. 8(8): p. 762-770. 75. Trotti, L.M., Waking up is the hardest thing I do all day: Sleep inertia and sleep drunkenness. Sleep Med Rev, 2017. 35: p. 76-84. 76. Kobayashi Frisk, M., et al., Eveningness is associated with sedentary behavior and increased 10-year risk of cardiovascular disease: the SCAPIS pilot cohort. Scientific Reports, 2022. 12(1): p. 8203. 77. Baldanzi, G., et al., Evening chronotype is associated with elevated biomarkers of cardiometabolic risk in the EpiHealth cohort: a cross-sectional study. Sleep, 2021. 45(2). 78. Nilsson, P.M., et al., Sleep disturbance in association with elevated pulse rate for prediction of mortality--consequences of mental strain? J Intern Med, 2001. 250(6): p. 521-9. 79. Javaheri, S. and S. Redline, Insomnia and Risk of Cardiovascular Disease. Chest, 2017. 152(2): p. 435-444. 80. McAlpine, C.S., et al., Sleep modulates haematopoiesis and protects against atherosclerosis. Nature, 2019. 566(7744): p. 383-387. 81. Stang, A., et al., Midday naps and the risk of coronary artery disease: results of the Heinz Nixdorf Recall Study. Sleep, 2012. 35(12): p. 1705-12. 82. Yan, B., et al., Association of daytime napping with incident stroke in middle-aged and older adults: a large community-based study. Eur J Neurol, 2020. 27(6): p. 1028-1034. 83. Wen, Y., et al., Sleep duration, daytime napping, markers of obstructive sleep apnea and stroke in a population of southern China. Scientific Reports, 2016. 6(1): p. 34689. 84. Tanabe, N., et al., Daytime napping and mortality, with a special reference to cardiovascular disease: the JACC study. International Journal of Epidemiology, 2009. 39(1): p. 233-243. 85. Yang, Y.-B., et al., To nap or not? Evidence from a meta-analysis of cohort studies of habitual daytime napping and health outcomes. Sleep Medicine Reviews, 2024. 78: p. 101989. 86. Wang, H., et al., Relationship of sleep duration with the risk of stroke incidence and stroke mortality: an updated systematic review and dose–response meta-analysis of prospective cohort studies. Sleep Medicine, 2022. 90: p. 267-278. 87. Maida, C.D., et al., Molecular Pathogenesis of Ischemic and Hemorrhagic Strokes: Background and Therapeutic Approaches. Int J Mol Sci, 2024. 25(12). 88. Niu, Y., et al., Association between self-reported snoring and hypertension: a systematic review and meta-analysis. Sleep Medicine, 2021. 88: p. 140-148. 89. Khazaie, H., et al., Among middle-aged adults, snoring predicted hypertension independently of sleep apnoea. Journal of International Medical Research, 2018. 46(3): p. 1187-1196. 90. Yuan, S., et al., Sleep duration, daytime napping, and risk of peripheral artery disease: multinational cohort and Mendelian randomization studies. Eur Heart J Open, 2023. 3(2): p. oead008. 91. Zeng, L., et al., Sleep duration and heart failure risk: Insights from a Mendelian Randomization Study. Medicine (Baltimore), 2024. 103(37): p. e39741. 92. Scholten, M., et al., Comorbidities in heart failure patients that predict cardiovascular readmissions within 100 days-An observational study. PLoS One, 2024. 19(1): p. e0296527. 93. Zhou, T., et al., Adherence to a healthy sleep pattern is associated with lower risks of all-cause, cardiovascular and cancer-specific mortality. J Intern Med, 2022. 291(1): p. 64-71. 94. Zhong, Q., et al., Healthy sleep pattern reduce the risk of cardiovascular disease: A 10-year prospective cohort study. Sleep Medicine, 2023. 105: p. 53-60. 95. Saint-Maurice, P.F., et al., Associations between actigraphy-measured sleep duration, continuity, and timing with mortality in the UK Biobank. Sleep, 2023. 47(3). 96. Yan, B., et al., Objective Sleep Efficiency Predicts Cardiovascular Disease in a Community Population: The Sleep Heart Health Study. Journal of the American Heart Association, 2021. 10(7): p. e016201. 97. Zhao, B., et al., Objectively Measured Sleep Characteristics and Incidence of Ischemic Stroke: The Sleep Heart Health Study. Nat Sci Sleep, 2021. 13: p. 1485-1494. 98. Lunsford-Avery, J.R., et al., Validation of the Sleep Regularity Index in Older Adults and Associations with Cardiometabolic Risk. Scientific Reports, 2018. 8(1): p. 14158. 99. Hoopes, E.K., et al., Sleep duration regularity, but not sleep duration, is associated with microvascular function in college students. Sleep, 2021. 44(2). 100. Pan, Z., et al., Association of napping and all-cause mortality and incident cardiovascular diseases: a dose–response meta analysis of cohort studies. Sleep Medicine, 2020. 74: p. 165-172. 101. Laugsand, L.E., et al., Insomnia and the Risk of Acute Myocardial Infarction. Circulation, 2011. 124(19): p. 2073-2081. 102. Bertisch, S.M., et al., Gender differences in the association of insomnia symptoms and coronary artery calcification in the multi-ethnic study of atherosclerosis. Sleep, 2021. 44(10). 103. Prather, A.A., et al., Gender differences in the prospective associations of self-reported sleep quality with biomarkers of systemic inflammation and coagulation: findings from the Heart and Soul Study. J Psychiatr Res, 2013. 47(9): p. 1228-35. 104. Canivet, C., et al., Insomnia increases risk for cardiovascular events in women and in men with low socioeconomic status: A longitudinal, register-based study. Journal of Psychosomatic Research, 2014. 76(4): p. 292-299. 105. Vitiello, M.V., L.H. Larsen, and K.E. Moe, Age-related sleep change: Gender and estrogen effects on the subjective–objective sleep quality relationships of healthy, noncomplaining older men and women. Journal of Psychosomatic Research, 2004. 56(5): p. 503-510.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102057	-
dc.description.abstract	引言：心血管疾病長期位居全球主要死因之首，許多研究致力於識別其風險因子，並將相關發現納入臨床介入指引。而美國心臟協會近年將睡眠納入維護心血管健康的主要因子之一，並依照年齡層提出建議的睡眠時長。然而，健康的睡眠型態本質上是多面向的，涵蓋多種睡眠表現型。現今大部分研究聚焦於單一睡眠表現型對整體心血管疾病風險的影響，且多數依賴問卷調查來獲取主觀的睡眠資訊。因此，本研究旨在全面性的探討主觀及客觀睡眠表現型與各種心血管疾病亞型的關聯，藉此識別與心血管疾病相關性最強的關鍵睡眠表現型，並了解哪些心血管疾病亞型廣泛受到睡眠型態的影響，亦探討需重點介入的易感性族群。方法：本研究透過英國人體生物資料庫，以問卷調查取得了447,183名參與者的主觀睡眠資料，並進行長期追蹤。部分參與者則進一步配戴腕動計，有5天以上客觀睡眠資料的參與者，使用R套件GGIR取得有意義的睡眠參數。心血管疾病亞型則根據住院之ICD-10診斷碼及初級照護的病歷紀錄，使用PheCODE系統進行亞型分類。統計分析則利用Cox比例風險模型評估睡眠表現型與心血管疾病風險的相關性，並進一步計算族群可歸因分率，以量化特定睡眠表現型對疾病風險的貢獻。最後，針對性別及發病年齡進行分層分析，以識別易感性族群。結果：在主觀睡眠表現型中，午睡、失眠及晨起困難被發現為顯著的風險因子，且在共11種心血管疾病亞型之多重假設檢定經 Bonferroni 校正後（p < 0.0045），廣泛影響近半數的亞型。其中，失眠（HR = 1.14-1.30，PAF = 3.35-8.39）及午睡（HR = 1.05-1.20，PAF = 2.1-10.36）展現了相對較強的風險效應。客觀睡眠指標與心血管疾病的相關性則較弱，僅睡眠規律指數對週邊血管疾病呈現顯著的保護作用（HR = 0.71，p = 0.0029）。我們也觀察到缺血性心臟病與缺血性中風為最廣泛受到不良睡眠表現型影響的兩大心血管疾病亞型。除此之外，結合五項主觀睡眠表現型計算的健康睡眠分數對整體心血管疾病、缺血性心臟病及缺血性中風均呈現顯著的保護效果。以健康睡眠分數3分以下定義為整體睡眠狀況差的參與者增加了13%整體心血管疾病的風險、22%缺血性心臟病風險以及12%缺血性中風風險。觀察到較高的族群可歸因分率則進一步表明，同時考量多面向的睡眠型態相較於單一睡眠表現型能更全面的反映睡眠對心血管的影響。而分層分析結果則發現失眠與午睡的風險效應在女性及早發性心血管疾病的參與者中影響更為顯著。結論：本研究結果突顯了睡眠在心血管健康中的多面向影響及其重要性。關鍵的睡眠表現型，特別是失眠與日間午睡，在調整其他共變項後，依然廣泛且顯著地提升心血管疾病的發生，尤其是在女性及早發性的群體中更為明顯。而客觀量測的睡眠規律也與週邊血管疾病存在顯著關聯。強調了整合主觀及客觀睡眠特徵以加強我們對睡眠健康理解的重要性，並凸顯在心血管疾病預防中實施更精準的睡眠介入策略的必要性。	zh_TW
dc.description.abstract	Background Cardiovascular disease (CVD) continues to be the leading global cause of mortality. Although sufficient sleep duration has been recognized as essential for cardiovascular health, sleep health is inherently multidimensional, encompassing a range of sleep phenotypes. To date, most research has examined single sleep traits in relation to total CVD risk, often relying on subjective self-reports. This study aimed to (1) comprehensively assess both subjective and objective sleep phenotypes in relation to various CVD subtypes, (2) identify the key sleep traits most strongly associated with CVD onset and determine the subtypes most influenced by sleep health, also (3) explore population subgroups that may be more susceptible to sleep-related cardiovascular risk. Materials and Methods A prospective cohort study of 447,183 UK Biobank participants was conducted with extensive person-years of follow-up. Subjective sleep phenotypes were derived from self-reported questionnaires, while objective measures were extracted from a subset with over 5 days of actigraphy data using the R package GGIR. CVD subtypes were classified using the PheCODE system, based on inpatient ICD-10 and primary care records. Cox proportional hazards models were used to evaluate the associations between sleep phenotypes and CVD risk. Additionally, population attributable fraction (PAF) quantified the contribution of specific sleep phenotypes to disease burden. Finally, stratified analyses by age and gender were conducted to identify vulnerable populations. Results Among subjective phenotypes, napping, insomnia, and difficulty waking in the morning emerged as significant predictors, broadly influencing nearly half of all CVD subtypes after Bonferroni correction for multiple testing across 11 subtypes (p < 0.0045), with insomnia (HR = 1.14-1.30, PAF = 3.35-8.39) and napping (HR = 1.05-1.20, PAF = 2.10-10.36) exhibited relatively stronger risk effects. Objectively measured sleep features demonstrated weaker associations, with a significant protective effect only observed for sleep regularity index in relation to peripheral vascular disease (HR = 0.71, p = 0.0029). Additionally, ischemic heart disease and ischemic stroke were identified as the two CVD subtypes most widely affected by adverse sleep profiles. Notably, a healthy sleep score combining 5 subjective sleep phenotypes showed significant protective effects against total CVD, ischemic heart disease, and ischemic stroke. Participants with poor overall sleep health defined as a healthy sleep score of 3 or lower exhibited a 13% increase in total CVD risk, 22% in ischemic heart disease risk, and 12% in ischemic stroke risk. The higher PAF further suggested that a multidimensional assessment of sleep health better captured the overall impact of sleep on CVD risk. The stratified analyses revealed that the effects of insomnia and napping on CVD subtypes were more pronounced in females and in participants with earlier disease onset age. Conclusion Sleep plays a substantial and multidimensional role in cardiovascular health. Key sleep phenotypes, particularly insomnia and daytime napping, contribute broadly and significantly to CVD onset after adjusting for other covariates, especially among women and participants with early disease onset age. Additionally, objectively measured sleep regularity showed a significant association with peripheral vascular disease. These insights show the importance of integrating both subjective and objective sleep characteristics to deepen our understanding of sleep health, and emphasize the need for more targeted sleep interventions in CVD prevention strategies.	en
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dc.description.tableofcontents	口試委員會審定書 I 誌謝 II 中文摘要 III ABSTRACT V List of Tables IX List of Figures X List of Supplementary Materials XI Chapter 1: Introduction 1 1.1 Epidemiology of cardiovascular disease and sleep problem 1 1.2 Sleep as a potential risk factor for cardiovascular diseases 2 1.3 Relationship between sleep phenotypes and cardiovascular disease 3 1.4 The impact of sleep on cardiovascular diseases in subpopulation 4 1.5 Study gaps 5 1.6 Specific aims 5 Chapter 2: Materials and Methods 7 2.1 Data source and study participants 7 2.2 Measurements of subjective sleep phenotypes 7 2.2.1 Assessment and definition of each subjective sleep phenotype 7 2.2.2 Measurement of multidimension healthy sleep score 8 2.3 Measurements of objective sleep phenotypes in subgroup cohort 9 2.3.1 Assessment and processing of actigraphy data 9 2.3.2 Definition and classification of each objective sleep phenotype 10 2.4 Definition and classification of cardiovascular disease subtypes 11 2.5 The design of follow-up cohort 12 2.6 Assessment of covariates 13 2.7 Statistical analysis 14 Chapter 3: Results 16 3.1 Follow-up cohort and sample characteristics 16 3.2 Differential impacts of sleep phenotypes on CVD subtypes 18 3.2.1 Main effects of subjective sleep phenotypes 18 3.2.2 Effects of objective sleep phenotypes in the subgroup 20 3.3 Subjective sleep and healthy sleep score effects on total CVD, ischemic heart disease, and ischemic stroke 20 3.4 Insomnia, napping, and getting up in the morning effects on CVD subtypes 22 3.5 Exploring gender and disease onset age differences 22 Chapter 4: Discussion 24 4.1 Prevalence of CVD in the main cohort and the distribution of subjective sleep phenotypes 25 4.2 Effects of subjective sleep phenotypes on CVD 26 4.2.1 The impact of subjective sleep phenotypes on total CVD 26 4.2.2 The greater impact of sleep on ischemic heart disease and ischemic stroke 27 4.2.3 The impact of sleep on other CVD subtypes 29 4.2.4 The impact of multidimensional healthy sleep on CVD 31 4.3 Effects of objective sleep phenotypes on CVD 32 4.4 Stratification analysis results 33 4.4.1 The impact of insomnia and nap on CVD subtypes by gender 33 4.4.2 The impact of insomnia and nap on CVD subtypes by disease onset age 35 4.5 Strengths and limitations 35 Chapter 5: Conclusion 37 Reference 38 Tables 46 Figures 55 Supplementary Materials 60	-
dc.language.iso	en	-
dc.subject	睡眠	-
dc.subject	失眠	-
dc.subject	午睡	-
dc.subject	心血管疾病	-
dc.subject	世代追蹤研究	-
dc.subject	sleep	-
dc.subject	insomnia	-
dc.subject	napping	-
dc.subject	cardiovascular disease	-
dc.subject	cohort study	-
dc.title	睡眠至關重要：前瞻性研究探討多面向睡眠表現型對不同心血管疾病類型之影響	zh_TW
dc.title	Sleep Matters: A Prospective Study of Multidimensional Sleep Phenotypes and Their Differential Impact on Cardiovascular Diseases	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	李文宗;蕭朱杏;張書森	zh_TW
dc.contributor.oralexamcommittee	Wen-Chung Lee;Chu-Hsing Kate Hsiao;Shu-Sen Chang	en
dc.subject.keyword	睡眠,失眠午睡心血管疾病世代追蹤研究	zh_TW
dc.subject.keyword	sleep,insomnianappingcardiovascular diseasecohort study	en
dc.relation.page	85	-
dc.identifier.doi	10.6342/NTU202600551	-
dc.rights.note	同意授權(全球公開)	-
dc.date.accepted	2026-02-03	-
dc.contributor.author-college	公共衛生學院	-
dc.contributor.author-dept	流行病學與預防醫學研究所	-
dc.date.embargo-lift	2026-03-13	-
顯示於系所單位：	流行病學與預防醫學研究所

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