ライフサイエンスコーパス: skin temperature

1 ) and hypervasoconstricted (had a lower tail skin temperature).

2 measurement of glucose and lactate, pH, and skin temperature.

3 onding could not be attributed to changes in skin temperature.

4 n and has not been shown to increase patient skin temperature.

5 ctrodermal activity, blood volume pulse, and skin temperature.

6 underlies the perception of pain, itch, and skin temperature.

7 to similar levels, independently of core and skin temperature.

8 tistically significant difference related to skin temperature.

9 98%) at low temperatures compared to normal skin temperature.

10 tics of a gentle caress delivered at typical skin temperature.

11 t oral doses of 3 mg/kg in reducing the tail skin temperature.

12 duced by cold challenge) in baseline digital skin temperature.

13 eater extent than increases in core and mean skin temperatures.

14 g activity, which may be reflected by facial skin temperatures.

15 s C for 20-50 min) and transient decrease in skin temperature (-0.6 degrees C for 1-3 min).

16 among contributions from increasing surface skin temperature, air temperature, and water vapor.

17 This resulted in an 85% decrease in skin temperature and a predicted 27% reduction in intram

18 ismatch and the difference between the ocean skin temperature and bulk temperature.

19 s independently of differential increases in skin temperature and core temperature.

20 is study observed the effect of OPC-28326 on skin temperature and digital blood flow following an acu

21 NH(3) emissions were mainly associated with skin temperature and EDA.

22 o) mutants show enhanced attraction to human skin temperature and increased heat-evoked neuronal acti

23 ination with low ambient temperature reduced skin temperature and increased survival following 8 Gy C

24 A significant correlation was found between skin temperature and skin blood flow but not with TEWL.

25 s demonstrated through in situ monitoring of skin temperature and sweat electrolytes during exercise

26 Skin temperature and the ability to perceive warm and co

27 Core (Tc)/skin temperature and thermal perception were recorded ev

28 hological body ownership, hypothesising that skin temperature and thermoception differ between right-

29 cies examined exhibit a wide range in torpid skin temperature and torpor bout duration.

30 The ocular skin temperature and water evaporation rate were higher

31 n alertness, melatonin and cortisol profile, skin temperature and wrist motor activity in healthy you

32 Skin temperature and wrist motor activity were continuou

33 ics for the ALT-70 prediction model, surface skin temperature, and both combined were also assessed.

34 e (0.667) and maximum (0.729) blood flow and skin temperature, and for the areas under the rewarming

35 tor activation, rapid and strong decrease in skin temperature, and weak increases in brain and muscle

36 ernal vaginal temperature, respiration rate, skin temperatures, and salivary cortisol concentrations

37 comprised capillary refill time, peripheral skin temperature, arterial lactate concentrations, and M

38 Evaluation of subtle variations in skin temperature associated with mental activity, physic

39 c response depended on neither T(b) nor tail-skin temperature at the time of AMG0347 administration,

40 ) vaginal temperature, respiration rate, and skin temperatures, but salivary cortisol was similar (P

41 .0002), corroborated by increased peri-wound skin temperature by infrared thermography (p=0.0119).

42 lgic gait criterion, skin surface pressures, skin temperature changes, and direct questionnaire feedb

43 glucose uptake, muscle electrical activity, skin temperatures, cold-induced thermogenesis, or self-r

44 , RE: 38.4 +/- 0.5 degrees C; p < 0.01), and skin temperature (CON: 36.3 +/- 0.5, AE: 37.5 +/- 0.6, R

45 physiological parameters (brain, muscle, and skin temperatures), cortical and VTA EEG, neck EMG activ

46 Ambulatory wrist blue light irradiance and skin temperature data were collected in 16 healthy indiv

47 Mean skin temperature did not differ between menstrual phases

48 erative and postoperative imaging, patients' skin temperatures did not exceed 37 degrees C, and no ad

49 Utilising the increase in skin temperature during infection, the truncated bacteri

50 nd on arrayed visual targets warmed to human skin temperature during the nighttime when they are bait

51 Facial skin temperatures during sleep in patients with winter d

52 hemical signals from human bodies, including skin temperatures, electrocardiograms, electromyograms,

53 gical responses were recorded, including the skin temperature, electrodermal activity (EDA), and hear

54 thesis that ultradian oscillations in facial skin temperatures exist in humans and are abnormal in pa

55 Despite no differences in core and skin temperature, fluid ingestion at 52 degrees C rapidl

56 , iontophoresis of acid over a wide range of skin temperatures from 4 to 40 degrees C produced only m

57 ehavior by up-regulating attraction to human skin temperature, further enhancing their status as the

58 oxygen saturation, and forearm-to-fingertip skin temperature gradient.

59 indicated by an increased CBT- proximal back skin temperature -gradient, rather than with changes in

60 ied by measurements of CBT and proximal back skin temperatures, heart rate and sleep (polysomnography

61 esponses were monitored: sublingual and mean skin temperatures, heart rate, beat-by-beat blood pressu

62 Prenalterol also increased skin temperature, however, suggesting that suppression o

63 We hypothesized that skin temperature in a specific limb could be disrupted b

64 efficients and including effect of change of skin temperature in the calibration model, the best pred

65 Skin temperature in the interscapular region of neonates

66 Skin temperature in the lower body was increased from 35

67 measured the sleep EEG, core body and facial skin temperatures in 23 patients with winter depression

68 Skin temperature increased to a median of 37.5 degrees C

69 The decrease in skin temperature is limb-specific: it does not occur in

70 Heat stroke manifests as elevated skin temperature, lack of sweating, and seizures.

71 d Insula, with these regions linked to lower skin temperature located posterior to those associated w

72 At tail-skin temperatures <23 degrees C, the magnitude of the M8

73 s well as a biphasic, down-up fluctuation in skin temperature, matching the response pattern observed

74 eart rate (P = 0.0106 vs. pre-symptoms), and skin temperature measured using skin probe (P = 0.0258 v

75 Nonvessel abdominal skin temperatures measured by thermistors were also lowe

76 s were compared and were related to hind-paw skin temperatures measured during stimulation of awake a

77 achieve beneficial results with cryotherapy, skin temperature (normally 33 degrees C) needs to be red

78 At a skin temperature of 31 degrees C, [ATP](d) averaged 18.9

79 ilst growth was maintained at the uninfected skin temperature of 32 degrees C.

80 tis patients had an average maximum affected skin temperature of 34.1 degrees C, which was 3.7 degree

81 rmia, skin-surface cooling (decrease in mean skin temperature of 4.3 +/- 0.4 degrees C (mean +/- s.e.

82 he rubber hand illusion, we demonstrate that skin temperature of the real hand decreases when we take

83 ermoregulatory responses (deep body and tail skin temperatures) of rats, even though plasma concentra

84 eral lower limb swelling, without changes in skin temperature or color.

85 of esophageal (OR=12.5, 95% CI=1.02-155) and skin temperature (OR=10.3, 95% CI=1.3-80.2).

86 of esophageal (OR=7.3, 95% CI=2.0-26.3) and skin temperature (OR=3.5, 95% CI=1.2-10.4).

87 gear [ps < 0.025], but not core temperature skin temperature, or ventilatory rate [ps > 0.372].

88 We found that facial skin temperatures oscillated significantly across the NR

89 hypothermia trial had serial esophageal and skin temperatures over 72 hours.

90 group, despite both groups having identical skin temperature profiles.

91 h increased in proportion to the increase in skin temperature (r(2) = 0.75, P < 0.05).

92 Skin temperature rapidly dropped after cup presentation,

93 slowly moving stimuli at a neutral (typical skin) temperature, rather than at the cooler or warmer s

94 tonin rhythms accurately from blue light and skin temperature recordings in individuals on a fixed sl

95 The shorter time to skin temperature recovery after 40 mg OPC-28326 suggests

96 During immersion mean skin temperature, rectal temperature, the difference in

97 that are also characterized by disruption of skin temperature regulation, sometimes in a single limb.

98 rain (nucleus accumbens or NAcc), muscle and skin temperature responses to natural arousing stimuli (

99 as similar when using either 1 (wrist) or 11 skin temperature sensor inputs.

100 Skin temperature, sensorimotor function (grooved pegboar

101 rface to sense electrophysiological signals, skin temperature, skin hydration, and respiratory rate.

102 ss, independently of differences in core and skin temperatures, suggesting independent viscerally-med

103 ss, independently of differences in core and skin temperatures, suggesting independent viscerally-med

104 noninvasive skin patch capable of monitoring skin temperature, sweat pH, cortisol levels, and corresp

105 and registered with a nasal thermistor); and skin temperature, sweating, and laser-Doppler skin blood

106 d VC elicited by gradual whole-body cooling (skin temperature (T(sk)) = 30.5 degrees C) and tyramine

107 Mean torpor skin temperature (T(sk)) and torpor bout duration varied

108 Dy neuron ablation consistently reduced tail-skin temperature (T(SKIN)), indicating that KNDy neurons

109 We developed a device to simulate skin temperature that shows temperatures 2.7 degrees and

110 neutral wet and warm wet (5 degrees C above skin temperature) thermal probe (1.32 cm(2) ) to five sk

111 ain and muscle temperatures and decreases in skin temperature; these effects showed a tendency to be

112 ed decrease in T(b) was inversely related to skin temperature, thus suggesting that M8-B blocks therm

113 Cold therapy usually decreased skin temperature to 10 degrees C to 15 degrees C within

114 fficacy endpoint was the ability to increase skin temperature to the desired range.

115 s sodium and potassium ions), as well as the skin temperature (to calibrate the response of the senso

116 ere measured during whole-body cooling (mean skin temperature (Tsk ) 30.5 degrees C; water-perfused s

117 We combined Tb and skin temperature (Tsk) analysis, assessment of prostagla

118 e water-perfused suits to control whole-body skin temperature (Tsk) at 34 degrees C.

119 moeffector, as determined by changes in tail skin temperature (Tsk).

120 st model is based on measurement of the tail-skin temperature (TST) increase following naloxone-induc

121 (10 mg/kg, i.p.) induced an increase in tail-skin temperature (TST) prior to naloxone administration.

122 DHED elicits a significant reduction of tail skin temperature (TST) rise representing hot flushes in

123 ith laser Doppler (LD) flowmetry while local skin temperature was cooled and clamped at 24 degrees C.

124 Proximal skin temperature was increased and subjective responses

125 ing laser Doppler flowmetry (LDF) while mean skin temperature was lowered from 34 to 30.5 degrees C u

126 covery of the change in prechallenge digital skin temperature was shorter after the OPC-28326 40-mg d

127 The area under curve of nasal skin temperature was significantly elevated after peanut

128 ly, infrared thermography-measured abdominal skin temperature was significantly lower in obese subjec

129 ms, heart rate, blood pressure, sweating and skin temperature were compared between NKB and vehicle i

130 red cell flux, capillary blood velocity, and skin temperature were unchanged.

131 Abdominal skin temperatures were also measured via adhesive thermi

132 pared to the young, both proximal and distal skin temperatures were lower in older participants under

133 Mean skin temperatures were recorded from the mouth and nose

134 the application of a cold (5 degrees C below skin temperature) wet (0.8 mL of water), neutral wet and

135 erable to make allowances for differences in skin temperature when testing patients for abnormal exci

136 nvolved in competitive events had lower nose skin temperatures whereas those involved in cooperative

137 ples include non-invasive spatial mapping of skin temperature with milli-Kelvin precision (+/-50 mK)

138 ples include non-invasive spatial mapping of skin temperature with millikelvin precision, and simulta

139 heat-responding neurons encoded the absolute skin temperature without adaptation and received major i