ライフサイエンスコーパス: alertness

1 ynamics of cognitive control with decreasing alertness.

2 drenergic neurons are critical in generating alertness.

3 t its severity increases under states of low alertness.

4 of sleep and improves objective measures of alertness.

5 ulate cognitive functions, consciousness and alertness.

6 amplitude of body temperature, cortisol and alertness.

7 ould treat excessive sleepiness by promoting alertness.

8 on onto independently derived predictions of alertness.

9 ively correlated with sensitized measures of alertness.

10 directly examined during different states of alertness.

11 piates, drugs of abuse that reduce cognitive alertness.

12 d increase in excitation and inhibition with alertness.

13 irway physiology and next-day sleepiness and alertness.

14 crucial role in the stability of arousal and alertness.

15 eased facial expression and increased visual alertness.

16 ty patterns associated with enhanced arousal/alertness.

17 he phase of circadian rhythms and supporting alertness.

18 r on the condition that the driver maintains alertness.

19 ical network activity can vary widely during alertness.

20 in awake, to right frontoparietal during low alertness.

21 apy according to local practices and patient alertness.

22 sal and vigilance facilitating environmental alertness.

23 e of evidence accumulation in periods of low alertness.

24 g response times (lapses) indicating reduced alertness.

25 hours slept on-call correlated to objective alertness.

26 e visual analog scales to subjectively score alertness.

27 s the most used chemical compound for mental alertness.

28 easonality in the relation between sleep and alertness.

29 any will be exposed to in a state of reduced alertness.

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

31 es was mutually correlated during heightened alertness.

32 aturation, next-day perceived sleepiness and alertness.

33 e control processes including maintenance of alertness.

34 There was no effect on alertness.

35 ral tasks that primarily depend on sustained alertness.

36 t processing are affected by fluctuations in alertness.

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

38 n variation of sleep measures and subjective alertness.

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

40 Noninferiority was not established for alertness according to the PVT-B (between-group differen

41 region implicated in salience processing and alertness, activations that are either spontaneous or ta

42 se signals became positive during periods of alertness, active whisking, and REM.

43 e there is little research on how decreasing alertness affects such cognitive processes, this study h

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

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

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

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

48 , the patient exhibited a decreased level of alertness and appeared tired.

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

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

51 rainstem provide critical inputs to optimize alertness and attention.

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

53 s on physiology including the stimulation of alertness and cognition.

54 Caffeine is widely used to promote alertness and cognitive performance under challenging co

55 st physiological processes, including sleep, alertness and cognitive performance.

56 ghest heart rate probably indicating highest alertness and cortical excitability.

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

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

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

60 fy wakefulness (increased activity, enhanced alertness and motivation), qualities useful for acute su

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

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

63 al task designed to determine trial-by-trial alertness and neuronal response to tactile and auditory

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

65 Shift work is associated with impaired alertness and performance due to sleep loss and circadia

66 tween shift types (day, evening, night), and alertness and performance during day and night shifts in

67 Alertness and performance remain most impaired during ni

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

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

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

71 C. asiatica could improve alertness and relieve anger.

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

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

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

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

76 These findings demonstrate that both alertness and spatial attention modulate neural variabil

77 different components of attention, including alertness and spatial attention, reduces neural variabil

78 ty was reduced by visual cues that modulated alertness and spatial attention.

79 ubdivided into several components, including alertness and spatial attention.

80 ssing, even in otherwise identical states of alertness and stillness.

81 em when affected by internal fluctuations of alertness and suggest that there are neural compensatory

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

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

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

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

86 to thirty-minute test widely used to measure alertness and vigilance.

87 ychological traits (e.g., trustworthiness or alertness) and other attributes (e.g., age or adiposity)

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

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

90 Dopamine (DA) plays a vital role in mood, alertness, and behavior, with dysregulation linked to di

91 Individual sleep dimensions of satisfaction, alertness, and efficiency (from the self-report composit

92 The interplay between attention, alertness, and motor planning is crucial for our manual

93 These factors can negatively impact sleep, alertness, and neurobehavioral performance, all of which

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

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

96 ncluding sleep duration, continuity, timing, alertness, and satisfaction.

97 Cognitive function, mood, alertness, and sleep quality were assessed as secondary

98 Furthermore, we observe that accounting for alertness appears to increase the statistical detection

99 Levels of alertness are closely linked with human behavior and cog

100 but their effects on sleep, sleepiness, and alertness are largely unknown.

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

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

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

104 rmance Assessment System (COMPASS); however, alertness (Bond-Lader Visual Analogue Scales) was better

105 an essential state of decreased activity and alertness but molecular factors regulating sleep duratio

106 n reproduce the behavioral effects of phasic alertness but only when the evidence accumulators compet

107 e each led to seizure cessation and improved alertness by 60 minutes in approximately half the patien

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

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

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

111 main study, data from those completing mood, alertness, cognition, and sleep assessments are presente

112 Nine patients showed improved gait, ataxia, alertness, cognition, or speech.

113 a close interplay between dynamic changes in alertness, cognitive control, and evidence accumulation.

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

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

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

117 sponds to highest heart rate (and presumably alertness/cortical excitability) and correlates with det

118 Subjective alertness decreased in residents after night shifts (-13

119 ull alertness were no longer noticeable when alertness decreased.

120 characterize the compensatory mechanisms as alertness decreases.

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

122 Increasing alertness did not cause visually unresponsive CG neurons

123 e evident for cognitive function, subjective alertness during cognitive testing was improved in the h

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

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

126 ncy bands, reflecting greater fluctuation in alertness, during the hours before cessation of MV were

127 that were largely independent of the actual alertness dynamics achieved.

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

129 irritability (33 of 43 [77%] participants); alertness, energy, and sleep (23 of 43 [53%]); and cogni

130 For neurologic symptoms (decreased alertness, falling asleep during the day, forgetfulness,

131 ubserving cognitive control when affected by alertness fluctuations.

132 as decrements in performance and lowering of alertness following waking, lasts for durations ranging

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

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

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

136 ol is thought to be affected by the state of alertness; for example, when drowsy, we feel less capabl

137 xtract a continuous, time-resolved marker of alertness from fMRI data alone.

138 Although phasic alertness generally benefits cognitive performance, it o

139 informed account, according to which phasic alertness generates a transient, evidence-independent in

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

141 However, it is unclear why phasic alertness has these negative effects.

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

143 known that neuromodulation and the state of alertness impact resting-state activity, neural mechanis

144 terns - with focus on daytime sleeping - and alertness in a Latin American crew overwintering in Arge

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

146 ctive alertness only correlated to objective alertness in consultants.

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

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

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

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

151 sitive developmental period show exacerbated alertness in nonstressful conditions while failing to re

152 ng the intrinsic regulation of goal-directed alertness in patients with chronic hemispatial neglect.

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

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

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

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

157 How people wake up and regain alertness in the hours after sleep is related to how the

158 nown about how natural daily fluctuations in alertness in the regular awake state affect cognitive co

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

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

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

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

163 thermore, an individual's set-point of daily alertness is related to the quality of their sleep, thei

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

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

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

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

168 We demonstrate that this fMRI alertness marker, calculated in a short pre-stimulus int

169 Moreover, we have found that alertness, measured by pupil size, is a good predictor o

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

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

172 ry tone-localization task, we reveal how low alertness modulates evidence accumulation-related proces

173 drowsy, allowing for the characterization of alertness modulating cognitive control.

174 The light environment greatly impacts human alertness, mood, and cognition by both acute regulation

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

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

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

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

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

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

181 showed a ~280 ms delayed onset driven by low alertness of the neural signatures differentiating betwe

182 hanisms/models, understanding the effects of alertness on neural and cognitive processes remain limit

183 sessment of clinical progress and to provide alertness on severity or critical trends of infection.

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

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

186 Postcall subjective alertness only correlated to objective alertness in cons

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

188 ed and does not cause next-day impairment in alertness or sleepiness, or overnight hypoxaemia in OSA.

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

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

191 data did not support strong cognitive, mood, alertness, or sleep quality improvements in MetS partici

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

193 nalysis revealed no effects of ecotourism on alertness, our central measure of tolerance, we observed

194 t illuminance), sleep timing, and subjective alertness over seven days in a convenience sample of 59

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

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

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

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

199 s, changing between full-wakefulness and low alertness, performed an auditory tone-localization task,

200 s of perceptual decision-making in awake/low alertness periods in humans (14 male, 18 female) and cha

201 rons of the master clock to favor subsequent alertness prior to dawn (a circadian "wake maintenance z

202 The alertness-promoting medications armodafinil and modafini

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

204 tracker that is able to objectively measure alertness, reaction time, concentration, and eye-hand co

205 skills and decision making are influenced by alertness, reaction time, eye-hand coordination, and con

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

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

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

209 Fatigue, and Task Effectiveness (SAFTE(tm)) Alertness Score model, a biomathematical model that pred

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

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

212 Finally, alertness selectively suppresses the simple cell respons

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

214 ce of cognition when challenged by decreased alertness.SIGNIFICANCE STATEMENT Most living organisms m

215 to physiological pressure during diminished alertness.SIGNIFICANCE STATEMENT The normal variability

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

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

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

219 young phenotype that reflects the permanent alertness state and important role of this organ in phys

220 and task engagement, concurrent measures of alertness (such as EEG or pupillometry) are often unavai

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

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

223 e., not fixed) factors associated with daily alertness that are modifiable.

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

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

226 -adherent); poor sleep health (Satisfaction, Alertness, Timing, Efficiency and Duration scale (SATED)

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

228 functions of VDRs in maintaining Paneth cell alertness to pathogens in intestinal disorders.

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

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

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

232 t that detects visuomotor reaction time (RT, alertness), variability of reaction time (VRT, sustained

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

234 Noninferiority of the flexible group for alertness was not established.

235 IFICANCE STATEMENT The normal variability in alertness we experience in daily tasks is rarely taken i

236 ural compensatory mechanisms with decreasing alertness, we connected the evidence-accumulation behavi

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

238 Next-morning sleepiness and alertness were also assessed.

239 Sleep duration and morning sleepiness and alertness were compared between the two groups by means

240 well-being including physical exhaustion and alertness were improved in faculty and fellows in the in

241 r changes-that participants show during full alertness were no longer noticeable when alertness decre

242 Next-morning sleepiness and alertness were not different between nights.

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

244 dicators of fearfulness (e.g. heart rate and alertness) were unrelated to learning performance, where

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

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

247 of seasonality in the association of evening alertness with sleep onset.

248 calls significantly correlated to objective alertness, with the third subsequent call related to per