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Research Papers/Books

Original papers

  1. Ryan C, Tahara Y, Haraguchi A, Lu Y, Shibata S, Nobiletin stimulates adrenal hormones and modulates the circadian clock in mice, Nutrients, 2024, 16(10), 1491.

  2. Du Y, Kusama K, Hama K, Chen X, Tahara Y, Kajiwara S, Shibata S, Orihara K, Protective Effects of Inulin on Stress-Recurrent Inflammatory Bowel Disease, International Journal of Molecular Sciences, in press.

  3. Khaing IK, Tahara Y, Chimed-Ochir O, Shibata S, Kubo T, Effect of breakfast protein intake on muscle mass and strength in adults: a scoping review, Nutrition Reviews, 2024, nuad167.

  4. Takahashi M, Mineshita Y, Yamagami J, Wang C, Fujihira K, Tahara Y, Kim HK, Nakaoka T, Shibata S: Effects of the timing of acute mulberry leaf extract intake on postprandial glucose metabolism in healthy adults: a randomized, placebo-controlled, double-blind study. European Journal of Clinical Nutrition. 77, 468-473, 2023.

  5. Kim HK, Yamada Y, Tahara Y, Takahashi M, Ono R, Shibata S. Association between disruption of circadian activity rhythms and obesity, Chronobiology International, 2023, 1546-1556.

  6. Takahashi M, Fukazawa M, Tahara Y, Kim HK, Tanisawa K, Ito T, Nakaoka T, Higuchi M, Shibata S. Association between circadian clock gene expressions and meal timing in young and older adults. Chronobiol Int. 2023, 40:1235-1243.

  7. Kuwahara M, Tahara Y, Nitta L, Furutani A, Mochida S, Makino N, Nozawa Y, Shibata S, Association of breakfast styles such as Japanese, Western and Cereals on sleeping habits, eating habits and lifestyle in preschooler and elementary school children, Frontiers in Nutrition, 2023, 10:1131887.

  8. Nitta L, Tahara Y, Shinto T, Makino S, Kuwahara M, Tada A, Abe N, Michie M, Shibata S, Association of Eating Pattern, Chronotype, and Social Jetlag: A Cross-Sectional Study Using Data Accumulated in a Japanese Food-Logging Mobile Health Application, Nutrients, 2023, 15:2165.

  9. Shiga K, Haraguchi A, Sasaki H, Tahara Y, Orihara K, Shibata S, Effect of circadian clock and claudin regulations on inulin-induced calcium absorption in the mouse intestinal tract, Bioscience of Microbiota, Food and Health, 2023, 42:114-123.

  10. Kuwahara M, Tahara Y, Suiko T, Nagamori Y, Shibata S, Effects of differences of breakfast styles, such as Japanese and 
    Western breakfasts, on eating and dietary habits,Nutrients, 2022, 14: 5143.

  11. Shinto T, Tahara Y, Watabe A, Makino N, Tomonaga M, Kimura H, Nozawa Y, Kobayashi K, Takahashi M, Shibata S, Interaction effects of sex on the sleep loss and social jetlag-related negative mood in Japanese children and adolescents : A cross-sectional study,SLEEP Advances, 2022, 3: zpac035.

  12. Imamura M, Tahara Y, Suiko T, Nagamori Y, Shibata S, Association between blood pressure and circadian timing of physical activity of Japanese workers,Frontiers in Physiology, 13:992945.

  13. Roshanmehr F, Tahara Y, Makino S, Tada A, Abe N, Michie M, and Shibata S, Association of Japanese Breakfast Intake with Macro- and Micronutrients and Morning Chronotype,Nutrients, 2022, 14: 3496.

  14. Roshanmehr F, Hayashi K, Tahara Y, Suiko T, Nagamori Y, Iwai T, and Shibata S, Association between Breakfast Meal Categories and Timing of Physical Activity of Japanese Workers,Foods, 2022, 11:2609.

  15. Shinto T, Tahara Y, Makino S, Nitta L, Kuwahara M, Tada A, Abe N, Michie M, Shibata S, Relationship between protein intake in each meal and physical activity level: Cross-sectional Study,_cc781905-5cde-3194- bb3b-136bad5cf58d_JMIR Public Health and Surveillance, 2022, 8: e35898.

  16. Haraguchi A, Saito K, Tahara Y, Shigenobu S, Polygalae Radix shortens the circadian period through the activation of the CaMKII pathway, Pharmaceutical biology, 2022, 60: 689-698.

  17. Imamura M, Sasaki H, Shinto T, Tahara Y, Makino S, Kuwahara M, Tada A, Abe N, Michie M, Shibata S, Association between Na, K, and lipid intake in each meal and blood pressure,Frontiers in Nutrition, 2022, 9: 853118.

  18. Tahara Y*, Makino S, Suiko T, Nagamori Y, Iwai T, Aono M, Shibata S*, Association between Irregular Meal Timing and the Mental Health of Japanese Workers,Nutrients, 13:2775, 2021 (*Corresponding author)

  19. Tahara Y, Shinto T, Inoue K, Roshanmehr F, Ito A, Michie M, and Shibata S, Changes in sleep phase and body weight of mobile health App users during COVID-19 mild lockdown in Japan,International Journal of Obesity, 2021, 45:2277-2280.

  20. Aoyama S, Kim HK, Hirooka R, Tanaka M, Shimoda T, Chijiki H, Kojima S, Sasaki K, Takahashi K, Makino S, Takizawa M, Takahashi M, Tahara Y, Shimba S, Shinohara K, Shibata S, Distribution of dietary protein intake in daily meals influences skeletal muscle hypertrophy via the muscle clock,Cell Reports, 2021, 36:109336.

  21. Miyazaki S, Tahara Y, Colwell CS, Block GD, Nakamura W, Nakamura TJ, Chronic methamphetamine uncovers a circadian rhythm in multiple-unit neural activity in the dorsal striatum which is independent of the suprachiasmatic nucleus,Neurobiology of Sleep and Circadian Rhythms, 2021, 11, 100070.

  22. Fujita H, Yamagishi K, Zhou W, Tahara Y, Huang SY, Hashimoto M, Fujie T, Design and fabrication of a flexible glucose sensing platform toward rapid battery-free detection of hyperglycaemia,Journal of Materials Chemistry C, 2021, DOI: 10.1039/d1tc00667c.

  23. Haraguchi A, Nishimura Y, Fukuzawa M, Kikuchi Y, Tahara Y, Shibata S, Use of a social jetlag-mimicking mouse model to determine the effects of a two-day delayed light- and/or feeding-shift on central and peripheral clock rhythms plus cognitive functioning,Chronobiology Int., 2021, 38: 426-442.

  24. Wang HB, Tahara Y, Luk SHC, Kim YS, Hitchcock ON, Kaswan MZA, Kim YI, Block GD, Ghiani CA, Loh DH, Colwell CS, Melatonin treatment of repetitive behavioral deficits in the Cntnap2 mouse model of autism spectrum disorder,Neurobiology of Disease, 2020, 145: 105064.

  25. Motohashi H*, Tahara Y*, Whittaker DS, Wang HB, Yamaji T, Wakui H, Haraguchi A, Yamazaki M, Miyakawa H, Hama K, Sasaki H, Sakai T, Hirooka R, Takahashi K, Takizawa M, Makino S, Aoyama S, Colwell CS, and Shibata S, The circadian clock is disrupted in mice with adenine-induced tubulointerstitial nephropathy,Kidney International,2020, 97: 728-740 (*Equal contribution).

  26. Aoyama S, Kojima S, Sasaki K, Shimoda T, Takahashi K, Hirooka R, Tahara Y, Shibata S, Effects of day-time feeding on murine skeletal muscle growth and synthesis.Journal of Nutrition & Intermediary Metabolism, 2019, 17: 100099.

  27. Hattammaru M, Tahara Y, Kikuchi T, Okajima K, Konishi K, Nakajima S, Sato K, Otsuka K, Sakura H, Shibata S, Nakaoka T. The effect of night shift work on the expression of clock genes in beard hair follicle cells .Sleep Med.2019, pii: S1389-9457(18)30593-30598.⇒Pubmed

  28. Morinaga K, Sasaki H, Park S, Hokugo A, Okawa H, Tahara Y, Colwell CS, Nishimura I.Neuronal PAS domain 2 (Npas2) facilitated osseointegration of titanium implant with rough surface through a neuroskeletal mechanism.Biomaterials.2019, 192:62-74. ⇒Pubmed

  29. Kuljis D, Kudo T, Tahara Y, Ghiani CA, Colwell CS, Pathophysiology in the suprachiasmatic nucleus in mouse models of Huntington's disease.J Neurosci Res2018, 96:1862-1875. ⇒Pubmed

  30. Whittaker DS, Loh DH, Wang HB, Tahara Y, Kuljis D, Cutler T, Ghiani CA, Shibata S, Block GD, Colwell CS, Circadian-based treatment strategy effective in the BACHD mouse model of Huntington's disease,Journal of Biological rhythms, 2018, 33:535-554. ⇒Pubmed

  31. Takahashi M, Tahara Y, Tsubosaka M, Fukazawa M, Ozaki M, Iwakami T, Nakaoka T, and Shibata S, Chronotype and social jetlag influence human circadian clock gene expression,Scientific Reports, 2018, 8:10152. ⇒Pubmed

  32. Tsurudome Y, Koyanagi S, Kanemitsu T, Katamune C, Oda M, Kanado Y, Kato M, Morita A, Tahara Y, Matsunaga N, Shibata S, Ohdo S. Circadian clock component PERIOD2 regulates diurnal expression of Na+/H+ exchanger regulatory factor -1 and its scaffolding function.Scientific Reports, 2018, 8:9072. ⇒Pubmed

  33. Tahara Y, Yamazaki M, Sukigara H, Motohashi H, Sasaki H, Miyakawa H, Haraguchi A, Ikeda Y, Fukuda S, Shibata S. Gut Microbiota-Derived Short Chain Fatty Acids Induce Circadian Clock Entrainme5t in Mouse Peripheral Tissue.Scientific Reports, 2018, 8:1395. ⇒Pubmed

  34. Haraguchi A, Fukuzawa M, Iwami S, Nishimura Y, Motohashi H, Tahara Y, Shibata S. Night eating model shows time-specific depression-like behavior in the forced swimming test.Scientific Reports, 2018, 8:1081. ⇒Pubmed

  35. Hassan N, McCarville K, Morinaga K, Mengatto CM, Langfelder P, Hokugo A, Tahara Y, Colwell CS, Nishimura I, Titanium biomaterials with complex surfaces induced aberrant peripheral circadian rhythms in bone marrow mesenchymal stromal cells.PLoS ONE, 2017, 12:e0183359.⇒PubMed

  36.  Kamagata M, Ikeda Y, Sasaki H, Hattori Y, Yasuda S, Iwami S, Tsubosaka M, Ishikawa R, Todoh A, Tamura K, Tahara Y, Shibata S, Potent Synchronization of Peripheral Circadian Clocks by Glucocorticoid Injections in PER2::LUC-Clock/Clock mice.Chronobiol Int., 2017, 13:1-16. ⇒PubMed

  37. Motohashi H, Sukigara H, Tahara Y, Saito K, Yamazaki M, Shiraishi T, Kikuchi Y, Haraguchi A, Shibata S, Polyporus and Bupleuri radix effectively alter peripheral circadian clock phase acutely in male mice,Nutrition Research, 2017, 43:16-24.⇒Nutrition Research

  38. Shinozaki A, Misawa K, Ikeda Y, Haraguchi A, Kamagata M, Tahara Y, Shibata S, Potent Effects of Flavonoid Nobiletin on Ampliturde, Period, and Phase of the Circadian Clock Rhythm in PER2::LUC Mouse Embryonic Fibroblasts.PLoS One2017, 12:e0170904.⇒PubMed

  39. Tahara Y, Takatsu Y, Shiraishi T, Kikuchi Y, Yamazaki M, Motohashi H, Muto A, Sasaki H, Haraguchi A, Kuriki D, Nakamura TJ, Shibata S, Age-related circadian disorganization caused by sympathetic dysfunction in peripheral clock regulation,npj Aging and Mechanisms and Disease,2017, 3:16030.⇒npj Aging HP⇒Nature Asia

  40. Takahashi M, Haraguchi A, Tahara Y, Aoki N, Fukuzawa M, Tanisawa K, Ito T, Nakaoka T, Higuchi M, Shibata S, Positive association between physical activity and PER3 expression in older adults. Scientific Reports, 2017, 7:39771 .⇒PubMed

  41. Sasaki H, Hattori Y, Ikeda Y, Kamagata M, Iwami S, Yasuda S, Tahara Y, Shibata S, Forced rather than voluntary exercise entrains peripheral clocks via a corticosterone/noradrenaline increase in PER2::LUC mice.Scientific Reports, 2016, 6:27607.⇒PubMed

  42. Tahara Y, Yokota A, Shiraishi T, Yamada S, Haraguchi A, Shinozaki A, Shibata S, In vitro and in vivo Phase Changes of the Mouse Circadian Clock by Oxidative Stress,Journal of Circadian Rhythms, 2016, 14:1-7. ⇒JCR HP

  43. Li H, Ohta H, Tahara Y, Nakamura S, Taguchi K, Nakagawa M, Oishi Y, Goto Y, Wada K, Saga M, Inagaki M, Otagiri M, Yokota H, Shibata S, Sakai H, Okamura K, Yaegashi N , Artificial oxygen carriers rescue placental  hypoxia and improve fetal development in the rat pre-eclampsiamodel.Scientific Reports,2015, 5:15271.⇒PubMed,press release

  44. Tanabe K, Kitagawa E, Wada M, Haraguchi A, Orihara K, Tahara Y, Nakao A, Shibata S., Antigen exposure in the late light period induces severe symptoms of food allergy in an OVA-allergic mouse model.Scientific Reports, 2015, 5:14424.⇒PubMed

  45. Hamaguchi Y*, Tahara Y*, Kuroda H, Haraguchi A, Shibata S. Entrainment of mouse peripheral circadian clocks to <24 h feeding/fasting cycles under 24 h light/dark conditions.Scientific Reports,2015, 5:14207. (*equal contribution)⇒PubMed

  46. Hamaguchi Y, Tahara Y, Hitosugi M, Shibata S. Impairment of Circadian Rhythms in Peripheral Clocks by Constant Light Is Partially Recovered by Scheduled Feeding or Exercise.J Biological Rhythms, 2015, 30:533-542. ⇒PubMed

  47. Furutani A, Ikeda Y, Itokawa M, Nagahama H, Ohtsu T, Furutani N, Kamagata M, Yang ZH, Hirasawa A, Tahara Y, Shibata S. Fish Oil Accelerates Diet-Induced Entrainment of the Mouse Peripheral Clock via GPR120.PLoS ONE, 2015, 10:e0132472. ⇒PubMed

  48. Tahara Y, Shiraishi T, Kikuchi Y, Haraguchi A, Kuriki D, Sasaki H, Motohashi H, Sakai T & Shibata S. Entrainment of the mouse circadian clock by sub-acute physical and psychological stress.Scientific Reports, 2015, 5:11417. ⇒JournalFeatured paper

  49. Moriya S, Tahara Y, Sasaki H, Ishigooka J, Shibata S. Phase-delay in the light-dark cycle impairs clock gene expression and levels of serotonin, norepinephrine, and their metabolites in the mouse hippocampus and amygdala.Sleep Medicine,2015, 16:1352-1359. ⇒PubMed

  50. Moriya S, Tahara Y, Sasaki H, Ishigooka J, Shibata S. Housing under abnormal light-dark cycles attenuates day/night expression rhythms of the clock genes Per1, Per2, and Bmal1 in the amygdala and hippocampus of mice.Neuroscience Research,2015, 99:16-21. ⇒PubMed

  51. Ikeda Y, Sasaki H, Ohtsu T, Shiraishi T, Tahara Y, Shibata S, Feeding and adrenal entrainment stimuli are both necessary for normal circadian oscillation of peripheral clocks in mice housed under different photoperiods.Chronobiology International, 2015, 32:195-210. ⇒PubMed

  52. Narishige S, Kuwahara M, Shinozaki A, Okada S, Ikeda Y, Kamagata M, Tahara Y, Shibata S. Effects of caffeine on circadian phase, amplitude, and period evaluated in cells in vitro and peripheral organs in vivo in PER2::LUCIFERASE mice.British Journal of Pharmacology,2014, 171:5858-5869. ⇒PubMed

  53. Aoki N, Yoshida D, Ishikawa R, Ando M, Nakamura K, Tahara Y, and Shibata S, A single daily meal at the beginning of the active or inactive period inhibits food deprivation-induced fatty liver in mice.Nutr Res,2014, 34:613-622. ⇒PubMed

  54. Moriya S, Tahara Y, Sasaki H, Hamaguchi Y, Kuriki D, Ishikawa R, Ishigooka J, Shibata S, Effect of Quetiapine on Per1, Per2, and Bmal1 Clock Gene Expression in the Mouse Amygdala and Hippocampus.J Pharmacol Sci, 2014, 125:329-332. ⇒PubMed

  55. Haraguchi A, Aoki N, Ohtsu T, Ikeda Y, Tahara Y, and Shibata S, Controlling access time to a high fat diet during the inactive period protects against obesity in mice,Chronobiology International, 2014, 31:935-944. ⇒PubMed

  56. Ohnishi N*, Tahara Y*, Kuriki D, Haraguchi A, and Shibata S, Warm water bath stimulates phase-shifts of the peripheral circadian clocks in PER2::LUCIFERASE mouse,PLoS ONE, 2014, 9:e100272, (*These authors equally contributed this work.) ⇒PubMed

  57. Nakamura Y*, Ishimaru K*, Tahara Y*, Shibata S, Nakao A, Disruption of the Suprachiasmatic Nucleus Blunts A Time of Day-Dependent Variation in Systemic Anaphylactic Reaction in Mice,J Immunological Research,2014, 2014: ID474217. (*These authors equally contributed this work.) ⇒PubMed

  58. Nakamura Y, Nakano N, Ishimaru K, Hara M, Ikegami T, Tahara Y, Katoh R, Ogawa H, Okumura K, Shibata S, Nishiyama C, Nakao A, Circadian Regulation of Allergic Reaction by the Mast Cell Clock.J Allergy Clin Immunol, 2014, 133:568-575. ⇒PubMed

  59. Kudo T, Loh DH, Tahara Y, Truong D, Hernández-Echeagaray E, Colwell CS, Circadian dysfunction in response to the in vivo treatment with the mitochondrial toxin 3-nitropropionic acid.ASN Neuro,2014, 6:e00133. ⇒PubMed

  60. KudoT, Tahara Y, Gamble KL, McMahon DG, Block GD, Colwell CS, Vasoactive intestinal peptide produces long lasting changes in neural activity in the suprachiasmatic nucleus.J of Neurophysiol,2013, 110: 1097-1106. ⇒PubMed

  61. Kuroda H*, Tahara Y*, Saito K, Ohnishi N, Kubo Y, Seo Y, Otsuka M, Fuse Y, Ohura Y, Hirao A, Shibata S, Meal frequency patterns determine the phase of mouse peripheral circadian clocks.Sci Rep, 2012, 2: 711. (*These authors equally contributed this work.) ⇒PubMed

  62. Takita E, Yokota S, Tahara Y, Hirao A, Aoki N, Nakamura Y, Nakao A, Shibata S, Biological clock dysfunction exacerbates contact hypersensitivity in mice.Br J Dermatol,2012, 168; 39-46. ⇒PubMed

  63. Fuse Y, Hirao A, Kuroda H, Otsuka M, Tahara Y, Shibata S, Differential roles of breakfast only (one meal per day) and a bigger breakfast with a small dinner (two meals per day) in mice fed a high-fat diet with regard to induced obesity and lipid metabolism.J Circadian Rhythms, 2012, 10: 4. ⇒PubMed

  64. Tahara Y, Kuroda H, Saito K, Nakajima Y, Kubo Y, Ohnishi N, Seo Y, Otsuka M, Fuse Y, Ohura Y, Komatsu T, Moriya Y, Okada S, Furutani N, Hirao A, Horikawa K, Kudo T , Shibata S, In Vivo Monitoring of Peripheral Circadian Clocks in the Mouse.Current Biology,2012, 22: 1029-1034. ⇒PubMed

  65. Kubo Y, Tahara Y, Hirao A, Shibata S, 2,2,2-Tribromoethanol phase-shifts the circadian rhythm of the liver clock in Per2::Luciferase knockin mice: lack of dependence on anesthetic activity.J Pharmacol Exp Ther, 2012, 340: 698-705. ⇒PubMed

  66. Okamoto M, Irii H, Tahara Y, Ishii H, Hirao A, Udagawa H, Hiramoto M, Yasuda K, Takanishi A, Shibata S, Shimizu I, Synthesis of a new [6]-gingerol analogue and its protective effect with respect to the development of metabolic syndrome in mice fed a high-fat diet.J Med Chem, 2011, 54: 6295-6304. ⇒PubMed

  67. Tahara Y, Otsuka M, Fuse Y, Hirao A, and Shibata S, Restricted feeding elicits insulin-dependent regulation of Per2 and Rev-erba gene expression as an early step in entrainment of the liver clock,J Biol Rhythms,2011, 26: 230-240. ⇒PubMed

  68. Nakamura Y, Harama D, Shimokawa N, Hara M, Suzuki R, Tahara Y, Ishimaru K, Katoh R, Okumura K, Ogawa H, Shibata S, Nakao A, The circadian clock gene Period2 regulates a time of day-dependent variation in Cutanenous anaphylactic reaction.Allergy Clin Immunol,2011, 127: 1038-1045. ⇒PubMed

  69. Hirao A, Nagahama H, Tsuboi T, Hirao M, Tahara Y, Shibata S. Combination of starvation interval and food volume determines the phase of liver circadian rhythm in Per2::luc knock-in mice under two meals per day feeding.Am J Physiol Gastrointest Liver Physiol,2010, 299: G1045-1053. ⇒PubMed

  70. Tahara Y, Hirao A, Moriya T, Kudo T, Shibata S, Dorsomedial hypothalamus is not necessary for the feeding-induced entrainment of liver circadian rhythm in Per2::luc knock-in mouse.J Biol Rhythms, 2010, 25: 9-18. ⇒PubMed

  71. Hirao A, Tahara Y, Kimura I, Shibata S, A balanced diet is necessary for proper entrainment signals of the mouse liver clock.PLoS One, 2009, 4, e6909. ⇒PubMed

 

Books/Chapters

  1. 田原 優、「概日リズムの同調機構」、「食品・サプリ」、睡眠学の百科事典、丸善出版、2024年6月

  2. 田原 優、「パフォーマンスや精神健康と関連する生活習慣」、臨床スポーツ医学、文光堂、2024, 6月

  3. 田原 優(共編著)、「プレシジョン栄養学」、建帛社、2024年5月

  4. 田原 優、「時間栄養学と飲食料品への応用」、「明日の食品産業」、一般社団法人食品産業センター、2024年3月

  5. 田原 優、「時間栄養学の基礎と臨床」、「精密栄養学」、実験医学、羊土社、2023年6月

  6. 睡眠環境学入門 全日本病院出版会 2023年6月

  7. 臨床栄養 第142巻6号「脳腸相関UPDATE」医歯薬出版 2023年5月

  8. 腎臓 第45巻「腎機能の日内変動と体内時計」 日本腎臓財団 2023年3月

  9. 体育の化学 第73巻3号「コロナ禍での生活リズム変化」 杏林書院 2023年3月

  10. ​ 臨床栄養 第142巻2号「時間栄養学研究の現状と展望」 医歯薬出版 2023年3月

  11. 体内時計の応用方法 杏林書院 2022年5月

  12. 睡眠と栄養ー経時栄養 All Japan Hospital Press

  13. 臨床時間治療学 診断治療社 2021年12月

  14. 「よるヨーグルトで腸内アップデート」 辰巳出版 2021年12月

  15. 体育の化学「体内時計と感染症、免疫 杏林書院 2021年5月

  16. Medical History Topics 「慢性字kん雑兵により体内時計が乱れる」 杏林書院 2020年9月

  17. アグリバイオ臨時粗増刊号「精神医学・神経学と時間栄養学」 北隆館 2020年6月

  18. 時間栄養学:時間遺伝子、体内時計、食生活をつなぐ 「時間栄養学の測定法・方法論(マウス・ヒト)「糖尿病と時間栄養学」 化学同人 2020年7月

  19. 食と医療12号 講談社 2020年1月

  20. アンチ・エイジング医学 メディカルレビュー社 2020年1月

  21. 体育の科学69巻11月号「健康づくりのための時間栄養学 杏林書院 2019年10月

  22. 食品と開発 2019年10月号特集 「進展する時間栄養学研究と利用」 インフォーマーマーケッツジャパン 0219年10月

  23. 「体を整えるすごい時間割:だるさ解消・スッキリ睡眠」 大和書房 2019年

  24. 月刊糖尿病2018年7月号特集「時間」を軸に考えた糖尿病治療の新展開 2018年7月

  25. 医薬ジャーナル54巻6号特集 実臨床へ向けた時間医薬研究の新動向 2018年6月

  26. Q&Aですらすらわかる体内時計健康法:時間栄養学・時間運動学・時間睡眠学から解く健康 杏林書院 2017年12月

  27. 体内時計「時間栄養学、食品機能性成分の吸収、代謝機構」 CMC出版 2018年

  28. 実験科学 日々のゆらぎと生体リズム 羊土社 2016年

  29. 体育の科学 連載「概日時計の研究を健康に活かす」 杏林書院 2015年

  30. Food Style 21「食品に関わる時間栄養とメンタルヘルス」 食品科学新聞社 2013年8月

  31. 食品機能性成分の吸収・代謝機構 CMC出版 2013年5月

  32. 子供の発育発達「概日リズムを作り出す体のメカニズム」 杏林書院 2011年

  33. 子供の体内時計と遺伝 日本乳児医学・心理学会 2010年

  34. 行動薬理学における実験技術 概日リズム評価メソッド 日本薬理学会

Reviews

  1. Tahara Y and Shibata S, Chapter3: Synchronizers of Circadian Rhythms, "Chronobiology and Chronomedicine: From molecular and cellular mechanisms to whole body: interdigitating networks", Royal Society of Chemistry, 2024, p40-70.

  2. Tahara Y, Qian J, Oike H, Escobar C, Editorial: The Present and Future of Chrono-nutrition Studies, Frontiers in Nutrition, 2023, 10: 2023.

  3. Takahashi M, Tahara Y, Timing of Food/Nutrient Intake and Its Health Benefits, J Nutr Sci Vitaminol, 2022, 68:S2-S4.

  4. Tahara Y and Shibata S, Entrainment of the mouse circadian clock: Effects of stress, exercise, and nutrition. Free Radic Biol Med. 2017, 119:129-138.

  5. Tahara Y and Shibata S, Abnormal tuning of the hepatic circadian metabolic rhythms in lung cancer. Hepatology, 2016, 65:1061-1064.

  6. Tahara Y, Aoyama S, Shibata S, The mammalian circadian clock and its entrainment by stress and exercise. J Physiological Science, 2017, 76:1-10. 

  7. Tahara Y & Shibata S, Circadian rhythms of liver physiology and disease: experimental and clinical evidence, Nature Reviews Gastroenterology and Hepatology, 2016, 13:217-226.

  8. Shibata S, Tahara Y, Circadian Rhythm & Exercise, J Phys Fitness Sports Med., Review, 2014, 3:65-72.

  9. Tahara Y, Shibata S, Chrono-biology, chrono-pharmacology, and chrono-nutrition, J Pharm Sci., Review, 2014, 124:320-335.

  10. Tahara Y, Shibata S, Chronobiology and Nutrition. Neuroscience, Review, 2013, 253: 78-88.

  11. Tahara Y, Shibata S, Nutrition and diet as potent regulators of the liver clock. Circadian rhythms: Health and Disease, Wiley, chapter 7, 2015.

  12. Yu Tahara, Hiroyuki Sasaki, Shigenobu Shibata, Chrono-nutrition and Chrono-exercise in Mice, アショフホンマ財団 『Circadian Clocks』, 2015, p53-59.

  13. Tahara Y, Shibata S, Circadian rhythm and food/nutrition. Mechanisms of Circadian Systems in Animals and Their Clinical Relevance, Springer, 2014, 237-260.

  14. Shibata S, Tahara Y, Hirao A, The adjustment and manipulation of biological rhythms by light, nutrition, and abused drugs, Advanced Drug Delivery Reviews, 2010, 62, 918-927.

  15. Shibata S, Hirao A, Tahara Y, Restricted feeding-induced entrainment of activity rhythm and peripheral clock rhythm, Sleep & Biological Rhythms, 2010, 8, 18-27.

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