ライフサイエンスコーパス: biological rhythm

1 on of genes involved in photo-entrainment of biological rhythms.

2 ioral effects are associated with endogenous biological rhythms.

3 altered the timing of light used to entrain biological rhythms.

4 al conditions by entraining their endogenous biological rhythms.

5 rtant role in the genesis and maintenance of biological rhythms.

6 unsafe, impairment due to disrupted sleep or biological rhythms.

7 light-dark cycle is a fundamental feature of biological rhythms.

8 ronmental stresses must allow for underlying biological rhythms.

9 rong selective "zeitgeber" that synchronizes biological rhythms.

10 ction as it relates specifically to mood and biological rhythms.

11 s or optimize medication timing according to biological rhythms.

12 vide insights into the mechanisms generating biological rhythms.

13 avoid the CSP when estimating the period of biological rhythms.

14 re integral components for timing endogenous biological rhythms.

15 are described as master pacemaker cells for biological rhythms.

16 f individual women with distinct methods for biological rhythm analysis.

17 ew time cues, the phase relationship between biological rhythms and external time cues are out of syn

18 The circadian system regulates 24-hour biological rhythms and seasonal rhythms, such as floweri

19 Biological rhythms appear to be an elegant solution to t

20 24-hour biological rhythms are essential to maintain physiologic

21 that the genes involved in the generation of biological rhythms are expressed in many brain structure

22 Daily biological rhythms are governed by an innate timekeeping

23 Biological rhythms are known to have a genetic basis for

24 retion of parasite proteins and light-driven biological rhythms are likely involved in the infection

25 Biological rhythms are pervasive in nature, yet our unde

26 cently been suggested that these patterns in biological rhythms are related with each other, reflecti

27 Biological rhythms are ubiquitous.

28 advanced to unravel the genetic machinery of biological rhythms by collecting massive gene-expression

29 Faster biological rhythms, called ultradian rhythms, vary widel

30 Conversely, biological rhythms can influence the effects and toxicit

31 Understanding crop biological rhythms can lead to more ecologically friendl

32 studies show that alterations in the body's biological rhythms can lead to serious pathologies, incl

33 Biological rhythms coordinate organisms' activities with

34 In major depression, biological rhythm disturbances in sleep, appetite, and m

35 atory mechanisms and fitness consequences of biological rhythms exhibited by parasites remain mysteri

36 be used to inform the design of large-scale biological rhythm experiments so that the resulting data

37 Desynchrony of biological rhythms from environmental light cycles has d

38 Biological rhythms have a crucial role in shaping the bi

39 drawing insights from the extensive study of biological rhythms in biomedical and light pollution res

40 onality in incidence; however, the role that biological rhythms in host defences play in defining thi

41 hological processes affect the expression of biological rhythms in the brain.

42 A new mathematical model for biological rhythms in the hypothalamic-pituitary-adrenal

43 sh genome, suggesting compromised control of biological rhythms in the polar light environment.

44 ism, the functional and structural impact of biological rhythms, including mechanisms such as circadi

45 mammalian physiology is under the control of biological rhythms, including the endocrine system with

46 w, we emphasize the potential of integrating biological rhythms into a dimensional framework, leverag

47 vancements now facilitate the integration of biological rhythms into ecotoxicology, offering unpreced

48 tors and sex differences influence sleep and biological rhythms is central to advancing our understan

49 and gonadal steroid modulation of sleep and biological rhythms is in its infancy.

50 An important step in understanding biological rhythms is the control of period.

51 ory have contributed to our understanding of biological rhythms, learning, memory, neurodegenerative

52 ability makes the latter design suitable for biological rhythms like heartbeats and cell cycles that

53 cells are specialized cell types that drive biological rhythms like the heartbeat and intestinal per

54 dian clock to light/dark cycles ensures that biological rhythms maintain optimal phase relationships

55 temperature are powerful inputs driving the biological rhythms of conception and birth in horses, th

56 is increasing evidence showing the impact of biological rhythms on the traffic of hematopoietic stem

57 illumination and temperature, these internal biological rhythms persist with a period close to 1 day

58 nificant heterogeneity, with disturbances in biological rhythms playing a central role.

59 us, efforts must be made to identify patient biological rhythms, preferences, routines, and medical c

60 cues such as photoperiod ensures that daily biological rhythms stay in synchronization with the Eart

61 infections was sinusoidal, consistent with a biological rhythm that modifies vaccine effectiveness by

62 GnRH is released from these terminals with biological rhythms that are critical for the maintenance

63 sts that there is an interdependency between biological rhythms that compose the human neuromuscular

64 abitats in the intertidal zone often display biological rhythms that coordinate with both the tidal a

65 Circadian rhythms are biological rhythms that run with a period close to 24 ho

66 tory for the synchronization of an important biological rhythm, the female estrous cycle.

67 n clock provides robust, approximately 24 hr biological rhythms throughout the eukaryotes.

68 chronotherapy provide insights into linking biological rhythms to disease prevention and treatment.

69 The challenge is how to harness these biological rhythms to improve medical interventions.

70 circannual clock [1], and synchronization of biological rhythms to the sidereal year using day length

71 ntrolling separate functions that range from biological rhythm via circadian photoentrainment, to pro

72 ype) was CYP11B2 (aldosterone synthase), and biological rhythms were the most differentially expresse

73 ICU environment is disruptive to a patient's biological rhythms where sleep-wake cycles are often des

74 Circadian clocks drive biological rhythms which adjust to environmental cues.

75 often exhibit a loss of regulation of their biological rhythms which leads to altered sleep/wake cyc

76 oral structure of the variability of healthy biological rhythms, while pathology and disease lead to

77 Recognizing the importance of biological rhythms will be essential for understanding,

78 We suggest here that a biological rhythm with a period greater than the circadi

79 tonomous oscillator that produces endogenous biological rhythms with a period of about 24 h.

80 Biological rhythms with periods of less than a day are p

81 than half of wild bird species changed their biological rhythms, with many producing a dawn chorus in