ライフサイエンスコーパス: jet lag

1 ep timing and circadian rhythmicity ('social jet-lag').

2 eep and circadian misalignment (i.e., social jet lag).

3 rapid re-entrainment following experimental jet lag.

4 vironmental cues has the potential to reduce jet lag.

5 indicating that these cells are a target for jet lag.

6 peritoneal macrophages in mice after chronic jet lag.

7 logical clocks disrupted in a mouse model of jet lag.

8 and 0.5 mg taken on a shifting schedule) for jet lag.

9 contrasting melatonin regimens to alleviate jet lag.

10 how that NFL teams are adversely affected by jet lag.

11 rstand the basis of circadian disruption and jet lag.

12 imals and whether it indicates resistance to jet lag.

13 circadian rhythm-sleep disorders and social jet-lag.

14 T) to daylight saving time (DST), and during jet-lag.

15 self-reported sleep disturbances and social jet lag (absolute value of the difference in sleep midpo

16 ilitated by longer circadian periods, reduce jet lag after westward travel and make it easier to work

17 schedules; (2) an individual's tolerances to jet lag and alternating shift work are positively correl

18 ounter melatonin is widely used to alleviate jet lag and as a safer alternative to benzodiazepines an

19 rcadian misalignment, as occurs acutely with jet lag and chronically with shift work.

20 s are not easily fooled; the consequences of jet lag and shift work are many and severe, including me

21 er understanding the biological responses to jet lag and shift work, with the hope that this will pav

22 to the development of therapies for treating jet lag and sleep disorders, and add to our understandin

23 a new rating scale for measuring severity of jet lag and to compare the efficacy of contrasting melat

24 sitively correlated, while the tolerances to jet lag and transient shift work are negatively correlat

25 health outcomes associated with shift-work, jet-lag and exposure to artificial light.

26 splayed expected phase shifting responses to jet-lag and nocturnal light pulses.

27 ked shift of the clock effectively inducing "jet lag" and causing impaired time perception.

28 hand, and stress (including stress caused by jet-lag) and depression on the other.

29 ong-haul flights, cosmic-radiation exposure, jet lag, and cabin-air quality are growing health-care i

30 on adapt activity onset to seasonal changes, jet lag, and shift work.

31 verative thinking, midpoint of sleep, social jet lag, and the categorization of and recognition memor

32 cles, disturbed sleep, shift work and social jet lag are factors that might contribute to circadian d

33 Practically, if the effects of jet lag are unclear, then it is also unclear whether int

34 Jet lag arises from a misalignment of circadian biologic

35 Difficulties with jet lag because of sleep loss and decreased performance

36 A new study suggests that this 'social jet lag' can be remedied by a 'personalized schedule', a

37 ed that repeated 6 h phase advances (chronic jet lag; CJL) for 8 weeks alters cerebrovascular archite

38 potential outcomes framework to determine if jet lag, conditional on game time, causes collegiate foo

39 e are subjected to continuous light or to a 'jet lag' (defined as a shift of 12 h).

40 nes, shift work, mistimed eating, and social jet lag-disrupt the circadian clock, affecting GI proces

41 hat identifies prominent daytime symptoms of jet lag distress.

42 team confounding variables, we observed that jet-lag effects were largely evident after eastward trav

43 disrupted by a model of human shift-work and jet-lag, Fischer (344) rats were exposed to either a sta

44 in crew group, who had a history of repeated jet lag, had significantly higher salivary cortisol leve

45 On the other hand, jet lag impacted both home and away defensive performanc

46 It is broadly accepted that jet lag impacts human performance in sport; however, thi

47 Surprisingly, we found that jet lag impaired major parameters of home-team offensive

48 adian timing in shift work or during chronic jet lag in animal models leads to a higher risk of sever

49 also unclear whether interventions to treat jet lag in elite sport are warranted for teams crossing

50 in the SCN because SCN dysfunction underlies jet lag in humans and influences the response to shift w

51 lower than those recommended for overcoming jet lag in humans.

52 se working on night shifts or suffering from jet-lag, in order to realign their SCNCC and PCC's, ther

53 This pathophysiological pathway is driven by jet-lag-induced genome-wide gene deregulation and global

54 increases enterohepatic bile acid levels and jet-lag-induced HCC, while loss of constitutive androsta

55 Chronic jet lag induces spontaneous hepatocellular carcinoma (HC

56 n modern human life (e.g., shiftwork, social jet-lag, irregular eating habits), these results emphasi

57 Jet lag is a consequence of the misalignment of the body

58 Since jet lag is caused mainly by inappropriate timing of the

59 ircadian desynchrony induced by shiftwork or jet lag is detrimental to metabolic health, but how sync

60 The model predicts that ameliorating social jet-lag is more effectively achieved by reducing evening

61 an rhythms, such as occurs in shift work and jet lag, is associated with disruption of rhythmicity in

62 Ratings on a summary jet lag item were highly correlated with total jet lag s

63 of high-fat high fructose (HFHF) diet and/or jet lag (JL)-mediated NAFLD.

64 The use of melatonin for preventing jet lag needs further study.

65 side world, resulting in conditions such as "jet-lag." Numerous aspects of human physiology are great

66 ssessed, presented sleep alterations, social jet lag, obesity and higher metabolic risk.

67 To test the effects of repeated jet lag on mental abilities, airline cabin crew were com

68 d circadian patterns, such as shift work and jet lag, on ghrelin secretion.

69 erences may affect how individuals adjust to jet lag or shift work as well.

70 ions, as well as artificial disruptions like jet lag or shift work, can advance or delay the clock ph

71 It is now believed that frequent jet lag or shifts of daily rhythms caused by rotating sh

72 point of intake and had more frequent social jet lag (P < 0.05).

73 uently, the mice rapidly phase shift under a jet lag paradigm and their behavior rhythms gradually de

74 ed adult, wild-type mice to distinct chronic jet-lag paradigms, which showed that long-term circadian

75 Jet lag ratings were made on the day of travel from New

76 potential approach to address shift work and jet lag related disorders.

77 ot sleep loss or stress, are associated with jet lag-related dysregulation of the innate immune syste

78 as effects experienced due to night work or jet lag, remain to be established in humans.

79 Jet lag's effects were compatible with the null hypothes

80 Jet lag's symptoms, such as depressed cognitive alertnes

81 , syndrome-specific instrument, the Columbia Jet Lag Scale, that identifies prominent daytime symptom

82 adian desynchrony (CCD), mimicking a chronic jet-lag scheme, and assayed a range of cellular function

83 There was a marked increase in total jet lag score in all four treatment groups on the first

84 The internal consistency of the total jet lag score was high on each day of the study.

85 t lag item were highly correlated with total jet lag scores (from a low of r = 0.54 on the day of tra

86 aluable for treating many maladies including jet lag, shift work and related sleep disorders, various

87 e influenced by factors such as seasonality, jet lag, shift work, and childbirth, are hallmarks of mo

88 However, modern lifestyle factors, such as jet lag, shift work, and irregular eating patterns, sign

89 are perturbed or misaligned, as a result of jet lag, shiftwork or other lifestyle factors, adverse h

90 Here, we examined the effects of jet lag, that is, travel that shifts the alignment of 24

91 ights are associated with travel fatigue and jet lag, the symptoms of which are considered here, alon

92 Greater social jet lag was associated with significantly higher SBP (be

93 F mice, but resetting responses to simulated jet-lag were unaffected.

94 ratory oscillations, altered by experimental jet lag, were implemented by perivascular SNS fibers act

95 tributable to sleep loss or so-called social jet lag, whereas physical inactivity was associated with

96 related changes in the response to simulated jet lag will reflect altered circadian function, we exam