ライフサイエンスコーパス: alertness

1 ish during a reaction-time task that reports alertness.

2 d increase in excitation and inhibition with alertness.

3 crucial role in the stability of arousal and alertness.

4 eased facial expression and increased visual alertness.

5 ty patterns associated with enhanced arousal/alertness.

6 e control processes including maintenance of alertness.

7 There was no effect on alertness.

8 ral tasks that primarily depend on sustained alertness.

9 ted as anxiety like or as signs of increased alertness.

10 n variation of sleep measures and subjective alertness.

11 drenergic neurons are critical in generating alertness.

12 t its severity increases under states of low alertness.

13 of sleep and improves objective measures of alertness.

14 es was mutually correlated during heightened alertness.

15 ulate cognitive functions, consciousness and alertness.

16 amplitude of body temperature, cortisol and alertness.

17 ould treat excessive sleepiness by promoting alertness.

18 on onto independently derived predictions of alertness.

19 ively correlated with sensitized measures of alertness.

20 directly examined during different states of alertness.

21 piates, drugs of abuse that reduce cognitive alertness.

22 y slow (20-30 min later) re-establishment of alertness--a temporal dissociation that facilitates spec

23 ncentration, motivation, effort, arousal, or alertness also affect performance on perceptual tasks an

24 In simple cells, alertness also increases the temporal frequency bandwidt

25 lag's symptoms, such as depressed cognitive alertness, also arise from work and social schedules mis

26 or blind tube placement in 2007 due to their alertness and ability to cooperate and provide feedback

27 ion also consistently improved self-reported alertness and arousal, whereas effects on pleasure or re

28 role in prefrontal or "executive" aspects of alertness and attention than previously anticipated.

29 rainstem provide critical inputs to optimize alertness and attention.

30 Light is a powerful stimulant for human alertness and cognition, presumably acting through a pho

31 ions whose activity decreases with increased alertness and externally focused attention, consistent w

32 nergic, and peptidergic cell types linked to alertness and found that activity in these cell types wa

33 sted sleep) that was associated with reduced alertness and increased sleepiness.

34 g and content, hormone secretion, subjective alertness and neurobehavioral performance.

35 ation are reasonably effective at predicting alertness and neurocognitive performance during total sl

36 ask designed to determine the trial-by-trial alertness and neuronal response to tactile and auditory

37 ness and prevent the deterioration of driver alertness and performance.

38 xplore and answer all ethical questions; (2) alertness and preparedness for emerging ethical question

39 tion, and were associated with the increased alertness and reduced sleepiness when methylphenidate wa

40 C. asiatica could improve alertness and relieve anger.

41 tablish the mode of action of TRH analogs on alertness and REM sleep-related symptoms, our results su

42 n = 55), or when the Observer Assessment of Alertness and Sedation scale (OAAS) was less than 4 (Con

43 tanding of the neurological underpinnings of alertness and sleepiness deepens, improved treatment met

44 shift and suppression, along with changes in alertness and sleepiness, were assessed.

45 Consistent with a role in regulating alertness and switching behaviours, an early system is a

46 al structures underpinning phasic control of alertness and task requirements.

47 highly conserved across different states of alertness and that observed state-related changes in rec

48 gests that they are in a heightened state of alertness and that the reduced response to unpleasant st

49 melatonin release, and modulation of sleep, alertness, and activity.

50 ssion and regulate motor control, vigilance, alertness, and arousal.

51 rature (CBT), salivary melatonin, subjective alertness, and polysomnographically recorded sleep were

52 rt rate, visual and auditory reaction times, alertness, and psychomotor skills have also been repeate

53 Impaired sleep and alertness are some of the most common nonmotor manifesta

54 wakefulness, but their role in the decreased alertness associated with sleep deprivation is unclear.

55 of cortical-subcortical structures-maintains alertness, attention, and awareness.

56 The effect of illumination on alertness can be assessed by comparing the efficacy of a

57 Fluctuating states such as alertness can be governed by neuromodulation, but the un

58 l has extensive effects on sleep and daytime alertness, causing premature disability and death.

59 tual waking period had a different impact on alertness, cognitive performance and hormonal secretion

60 wed blunted amphetamine-induced euphoria and alertness compared with HV.

61 spite a large increase in response gain with alertness, contrast sensitivity remained nearly constant

62 rtia effects (post-awakening performance and alertness deficits) is effected by reactivation of these

63 Increasing alertness did not cause visually unresponsive CG neurons

64 l and modafinil are associated with improved alertness during shift work but are also associated with

65 effects of a drug, modafinil, that increases alertness during wakefulness.

66 en we travel, our sleep wake pattern, mental alertness, eating habits and many other physiological pr

67 tory of NMSC should increase the clinician's alertness for certain noncutaneous cancers as well as me

68 acterized by an impaired ability to maintain alertness for long periods and by sudden losses of muscl

69 he need for increased attentional effort and alertness for visuomotor control and is an ideal candida

70 ically instrumented lambs to study states of alertness, glottal muscle electrical activity, tracheal

71 We show that a neurotransmitter critical for alertness, hypocretin (orexin), directly excites prefron

72 s did not change melatonin concentrations or alertness in an ISI-dependent manner.

73 ) depolarization associated with wakefulness/alertness in cortical networks, called the "desynchroniz

74 ession of activity in nocturnal animals, and alertness in diurnal animals.

75 d blue-enriched light to directly manipulate alertness in healthy volunteers.

76 Brain networks subserving alertness in humans interact with those for spatial atte

77 oting agents reveals an unsuspected role for alertness in setting pain sensitivity.

78 ons associated with better-quality sleep and alertness in shift workers?

79 coding model, we show that these effects of alertness in simple cells--enhanced reliability, higher

80 They boost energy and alertness in some conditions, but may have adverse hemod

81 ssibility that S-SIA is a state of increased alertness in which the animal's location in the environm

82 We show that in both cell classes, alertness increases the strength and greatly enhances th

83 Lower nighttime alertness is also observed, suggesting a physiological b

84 This nonspatial deficit in alertness is often considered to be a different problem

85 , and the task becomes routine, the level of alertness lessens and sensory adaptation becomes robust.

86 ponse, and changes in self-report ratings of alertness levels and affective states (arousal and valen

87 de of the diurnal and circadian variation of alertness, mainly due to a larger decline in the nocturn

88 in the cingulo-opercular network underlying alertness maintenance and higher behavioral alertness pe

89 ntermeasure against sleep-loss decrements in alertness, melatonin and cortisol profile, skin temperat

90 echanism, chest pain, intoxication, abnormal alertness/mental status, distracting painful injury, and

91 tes of arousal, defined by increased sensory alertness, motor activity and emotional reactivity.

92 or visually responsive CG neurons, increased alertness nearly doubled the modulated response amplitud

93 pattern of functional connectivity in basic alertness networks of the brainstem and thalamus.

94 derness, no focal neurologic deficit, normal alertness, no intoxication, and no painful, distracting

95 tivity accompany the paradoxical increase in alertness observed in some patients with severe brain in

96 diurnal and circadian variation of sleep and alertness of 8 women studied during two phases of the me

97 udy obtained less sleep than is required for alertness on the job.

98 Here, we study the effects of alertness on two cell classes in layer 4 of primary visu

99 effectiveness is reduced, but by increasing alertness or providing better sleep.

100 sicians reported less irritability, improved alertness, or both in seven patients.

101 tics, such as zopiclone, and sleep outcomes, alertness, or harms.

102 ulating three distinct attentional networks: alertness, orienting and executive control.

103 d eye (P = 0.0027), reduced patient-reported alertness (P = 0.0177), increasing age (P = 0.0040), cur

104 isease (P = 0.015), reduced patient-reported alertness (P = 0.023), and CIGTS clinical center (P <or=

105 alertness maintenance and higher behavioral alertness performance than both homozygous groups.

106 melatonin, core body temperature, cortisol, alertness, performance and sleep after a perturbation of

107 The alertness-promoting medications armodafinil and modafini

108 notype, CO network activation, and sustained alertness, providing insights into how genetics shapes i

109 ed homologous neuromodulatory cells in mice; alertness-related cell-type dynamics exhibited striking

110 This has been linked to alertness-related modulation of spatial bias in left neg

111 caffeine in the body is well-understood, its alertness-restoring effects are still not well character

112 At 48 hrs, neurologic alertness score was significantly better in animals trea

113 Scale (8.5) and the Observer's Assessment of Alertness/Sedation Scale (3.7) demonstrated "very low" p

114 Finally, alertness selectively suppresses the simple cell respons

115 so, then phasically increasing the patients' alertness should temporarily ameliorate their spatial bi

116 aviors and physiological responses including alertness, social recognition, and hunger, yet, their me

117 eview delineates four attentional functions (alertness, spatial orienting, attention to object featur

118 There have been suggestions that this alertness-spatial awareness link may be detectable in th

119 ir circadian clock, and reduced next-morning alertness than when reading a printed book.

120 Blindness has an impact on sleep and alertness that adds to the primary disability.

121 ase in overnight sleep duration and improved alertness the next morning.

122 e right-hemisphere lesions also impair tonic alertness (the ability to maintain arousal).

123 ng a gradual behavioral transition from full alertness to loss of consciousness (LOC) and on through

124 sal microbiota confers a goldilocks state of alertness to pathogens, yet restrains deleterious inflam

125 ngage attention and maintain a high level of alertness to the task.

126 desynchronized responses, indicative of high alertness, to highly synchronized responses.

127 tion and facilitate attention via increasing alertness, vigilance, and by decreasing attentional thre

128 for hormonal analyses, subjective ratings of alertness, wellbeing, visual comfort and cognitive perfo

129 These effects of alertness were uniform across the broad spectrum of CG a

130 ad a positive impact on employee fatigue and alertness, whilst quick returns between shifts appeared

131 romotion of appetite by combining OX-induced alertness with food seeking.