ライフサイエンスコーパス: sensation

1 fingertips of teleoperators, i.e., proximity sensation.

2 cortex (PCC) was observed during the noxious sensation.

3 tance on the screen), and vision + proximity sensation.

4 ion was incongruent with stimulation-induced sensation.

5 al nerves with pain, feebleness, and loss of sensation.

6 a precise understanding of its role in touch sensation.

7 understanding of piezo2 roles in light-touch sensation.

8 y compromised, leading to loss of peripheral sensation.

9 impact of L2/3 activity on L5 during active sensation.

10 critical for the maintenance of chronic itch sensation.

11 ique for dissecting the neural mechanisms of sensation.

12 little role in either acute or chronic pain sensation.

13 ers tear production and often causes dry eye sensation.

14 hotoreceptor neurons required for our visual sensation.

15 ies; a finding that matches normal cutaneous sensation.

16 oughout the neocortical column during active sensation.

17 al sensitivity is governed by Weber's law of sensation.

18 ormance drop associated with intense fatigue sensation.

19 inated locomotion is regulated by vestibular sensation.

20 hether they also modulate the quality of the sensation.

21 fear behaviors, neurodegeneration, and pain sensation.

22 play important functions in pain and thermal sensation.

23 , heart rate increase, and cardiorespiratory sensation.

24 ota is required for the normal visceral pain sensation.

25 ty is also required for normal cold and heat sensation.

26 s of function as the basis for impaired pain sensation.

27 events, combining sound, sight, and tactile sensation.

28 ious stimuli, is crucial in determining pain sensation.

29 of neuropathic pain and increased pin-prick sensation.

30 hanoreceptor responses that underlie tactile sensation.

31 th the maladaptive coping of the PAG to pain sensation.

32 onal PIEZO2 report deficient bladder-filling sensation.

33 which depends on a rhodopsin (Rh6) for cool sensation.

34 agates toward the CNS, thus shaping the pain sensation.

35 tive brain structures steps removed from raw sensation.

36 will help define their significance in oral sensation.

37 as any such pathway been identified for itch sensation.

38 though with diminished digital dexterity and sensation.

39 e basic mechanisms that underlie this unique sensation.

40 covered circuits also contribute to the itch sensation.

41 e, dairy mouthfeel, and tingling/irritation" sensations.

42 sisted, despite varying vividness of phantom sensations.

43 ., information gain) about the causes of our sensations.

44 model to make inferences about the causes of sensations.

45 l sensory fibers to produce pain and altered sensations.

46 Nav1.8 is crucial for pain sensations.

47 ic target for the treatment of aberrant pain sensations.

48 ry evidence - or beliefs about the causes of sensations.

49 this response is associated with pleasurable sensations.

50 nd pain are closely related but are distinct sensations.

51 ity linearly, without increasing area of the sensations.

52 sterior insula during attention to heartbeat sensations.

53 ecificity of stimulation effects to movement sensations.

54 ions and decreased awareness of non-aversive sensations.

55 c (3/4, 75%) or associated with foreign body sensation (1/4, 25%).

56 visual assistance (20-30%) or the proximity sensation (60-70%), without additional processing time.

57 n (n = 37) reported a "satisfactory" thermal sensation 79% of the time, despite experiencing 29.6 +/-

58 ), dysgeusia (0.3%), dysosmia (0.2%), globus sensation (8.2%), surgical site infection (1.3%), veloph

59 h class with a different name produced color sensations according to the name of the base pitch class

60 dy ownership relies on integrating different sensations according to their temporal and spatial congr

61 The thalamus engages in sensation, action, and cognition, but the structure unde

62 ime scales.SIGNIFICANCE STATEMENT Our recent sensations affect our current expectations and perceptio

63 ny significant influence on appetite-related sensations after breakfast or after meal consumption (al

64 sis for hearing, touch, pain, cold, and heat sensation, among other physiological processes.

65 Symptoms include painful sensations, an urge to move and involuntary leg movement

66 Sensation and action are necessarily coupled during stim

67 model that matches stimulus history to odor sensation and behavioral responses.

68 spite their critical role in both acute pain sensation and chronic pain, little is known of the funda

69 to optimize information transmission during sensation and cognition.

70 they viewed videos depicting body movements/sensation and control videos.

71 provides a hyperdirect link between acoustic sensation and descending control, thus demonstrating a n

72 ent infections, attributed to a lack of pain sensation and failure to seek care for minor injuries.

73 link events separated in time, such as past sensation and future actions.

74 nervation is proposed to facilitate visceral sensation and homeostasis, where sensation and pain are

75 all ganglia types, suggesting that conscious sensation and homeostatic regulation are the result of c

76 tor behaviors, anxiety, depression, and pain sensation and in the rewarding effects of alcohol and co

77 reconfigures the neural activity reflecting sensation and movement.

78 wever, how immune signals participate in gut sensation and neuroendocrine response remains unclear.

79 helial-mesenchymal transition (EMT), loss of sensation and neuropathic pain.

80 te visceral sensation and homeostasis, where sensation and pain are mediated by spinal afferents and

81 ia a parasympathetic spinal circuit, linking sensation and pain to motility.

82 ehaviors.SIGNIFICANCE STATEMENT Motor-guided sensation and perception are intertwined, with motor beh

83 ol thus can be crucial to understand sensory sensation and perception under naturalistic conditions.

84 axonal degeneration causes impaired tactile sensation and persistent pain.

85 somatosensory cortex (S1) could help restore sensation and provide task-relevant feedback in a neurop

86 s are uniquely positioned to be activated by sensation and stress, and in turn, inhibit pain and itch

87 During tactile sensation and the delay epoch, object location was repre

88 nment - both in terms of the afferent arm of sensation and the efferent arm of action - as a generali

89 (S1) can produce percepts that mimic somatic sensation and, thus, has potential as an approach to sen

90 able us to anticipate the timing of upcoming sensations and actions.

91 o obvious correlation was found between blue sensations and array placement or status of visual impai

92 vealing a robust one-to-many mapping between sensations and behaviors that was not apparent from loco

93 ed link between avoidance of unpleasant body sensations and BN symptoms suggests that aversive intero

94 he somatosensory cortex evokes vivid tactile sensations and can be used to convey sensory feedback fr

95 cterized by increased tolerance for aversive sensations and decreased awareness of non-aversive sensa

96 Appetite-related sensations and metabolic hormones were measured at set t

97 y be useful to selectively relief unpleasant sensations and pain associated with mechanical irritatio

98 spatially congruent integration of different sensations and possibly reduces deafference during async

99 arked positive mood, pleasant/unusual bodily sensations and pro-social, empathic feelings.

100 Haptic actuators generate touch sensations and provide realism and depth in human-machin

101 ay a role in evoking C-fibre-mediated airway sensations and reflexes that are associated with airway

102 on of LC was found through 63 early symptoms/sensations and seven background factors.

103 Social laughter increased pleasurable sensations and triggered endogenous opioid release in th

104 events (a composite of new loss of vibratory sensation, ankle reflexes, or light touch).

105 Furthermore, the mice have defects in sensation, another aspect of CMT disease.

106 uency tuning and wide dynamic range of sound sensation are hypothesized to require a mechanotransduct

107 Touch and itch sensations are crucial for evoking defensive and emotion

108 in both homeostatic regulation and conscious sensations are found at all anatomic levels, suggesting

109 Although chemical and mechanical sensations are important for larval aggregation at speci

110 Molecules that initiate painful sensations are intensively sought as therapeutic targets

111 iological approach that considered ambiguous sensation as a fundamental problem of sensory systems th

112 tensity of White individuals' hand ownership sensation as induced by the Rubber Hand Illusion (RHI) w

113 This view treats visual sensations as consequent on action (i.e., saccades) and

114 ts are altered and contribute to the intense sensation associated with allodynia is unclear.

115 h visual and auditory stimuli that replicate sensations associated with the physical world.

116 Increased tension sensation at focal adhesions induced myofibroblast diffe

117 y a combination of early predictive symptoms/sensations attributable to primary lung cancer (LC).

118 gnals for critical processes including touch sensation, balance, and cardiovascular regulation.

119 to trait anxiety and acutely altered bodily sensations-both of which are known to be associated with

120 ependencies specific for auditory and visual sensation but also a broader presence of somatic sensati

121 e generated independent of visual or whisker sensation but are affected by inputs from MEC that conta

122 for decades in the context of direct tactile sensation, but recent work has indicated that rats also

123 S frequency lead to changes in the resulting sensation, but the discriminability of frequency has onl

124 n postural manipulations reinforce perceived sensations, but do not alter them.

125 y assist pain-sensitive human to reduce pain sensation by normalizing hyperexcitable central neural a

126 Menthol in mints elicits coolness sensation by selectively activating TRPM8 channel.

127 molecular/genetic roadmap for internal organ sensation by the vagus nerve.

128 ests that the brain infers the causes of its sensations by combining sensory evidence with internal p

129 rior parietal cortex can give rise to visual sensations called phosphenes.

130 d our understanding of how cutaneous plantar sensation can be used to acquire action-related informat

131 Stimulation of acupoints produces needling sensations caused by the activation of small diameter af

132 Unilateral disruption of plantar sensation causes able-bodied individuals to adopt locomo

133 to diets rich in sugar and fat lowers taste sensation, changes food choices, and promotes feeding.

134 n with cowhage induced a more intensive itch sensation compared with stimulation with other substance

135 at increased tearing rate and ocular dryness sensation derived from deep surgical ablation of corneal

136 lt a device generating cold and vibrotactile sensations down the spine of subjects in temporal conjun

137 hat NK cell function correlates with loss of sensation due to degeneration of injured afferents and r

138 fication of shivering and whole-body thermal sensation during cold stress following the administratio

139 ury and a potential mechanism for regulating sensation during wound healing.

140 tor cortex in generating movement and bodily sensations during REM sleep dreaming.

141 muli evoke a range of acute and long-lasting sensations, emotions, and behaviors.

142 psaicin, which evokes a mix of itch and pain sensations, enhances both excitatory and inhibitory spon

143 nerve, which was sufficient to produce sound sensation even in deafened ears.

144 By systematically characterizing the human sensation evoked by transcranial alternating-current sti

145 with human subjects characterize the visual sensations evoked by stimulating a single cone, includin

146 Studying the intertwined roles of sensation, experience, and directed action in navigation

147 substantiate an explanation for the thermal sensations experienced when one consumes pungent spices

148 situations such as learning and memory, pain sensation, fear and anxiety, substance abuse and cell de

149 touch our hand with the other, the resulting sensation feels less intense than when another person or

150 voke two qualitatively distinctive cutaneous sensations, flutter (frequencies < 60 Hz) and vibratory

151 ICANCE STATEMENT Spinal injuries that remove sensation from the hand, can be debilitating, though fun

152 In this pathway, benign sensations from the gut induce maladaptive cognitive or

153 al differences, reported stimulation-induced sensations from the phantom hand for the whole duration

154 ence satiety through differences in appetite sensations, gastrointestinal peptide release and food in

155 Therefore, the sensation generated by isolated TRPA1 activation in huma

156 e environment and to distinguish between the sensations generated as a consequence of voluntary movem

157 at rats can learn to discriminate artificial sensations generated by DCS and that DCS-induced learnin

158 risingly, this range is where Weber's Law of Sensation governs temporal contrast sensitivity in mouse

159 to differentiate the women for whom genital sensations have a critical role in their subjective arou

160 Touch sensation hinges on force transfer across the skin and a

161 nificant rate of VP insufficiency and globus sensation; however, studies lack details of surgical app

162 that algogens and cooling could inhibit itch sensation; however, the underlying molecular and neural

163 Appetite-related sensations (i.e., hunger and fullness) were recorded by

164 stimulation of one sensory modality produces sensation in a different modality, provides a unique opp

165 serum levels correlate inversely with hunger sensation in challenged subjects.

166 ly filters stimulus noise, allowing reliable sensation in fluctuating environments, and represents a

167 sodium channel, Nav1.7, is critical to pain sensation in mammals, pharmacological inhibitors of Nav1

168 2 (TRPM2) channel plays a key role in redox sensation in many cell types.

169 Trpm8, have been shown to contribute to cold sensation in mice.

170 ptive responses are used as measures of pain sensation in newborn humans, as they are in animals [3,

171 y enthalpic process that enables temperature sensation in plants and possibly other organisms.

172 prosthesis that modulated stimulation-evoked sensation in response to interactions between the prosth

173 of GAD65(+) cells may generate a salt-taste sensation in the brain.

174 These findings suggest that decreased sensation in the foot may be an underrecognized risk fac

175 working memory enables us to hold onto past sensations in anticipation that these may become relevan

176 p and responded to a questionnaire on bodily sensations in dreams.

177 s elegans As capsaicin elicits heat and pain sensations in mammals, transgenic TRPV1 worms exhibit an

178 mised or exaggerated TRPA1-dependent painful sensations in the skin.

179 pectation might cause non-veridical auditory sensations in these individuals, but it might also spont

180 sure with energy intake and appetite-related sensations in young healthy humans.

181 more appropriate to counteract the negative sensations induced by UG phenols.

182 rs to the potential for dehydration via skin sensations initiated by sweat-triggered ejection of ment

183 Somatic sensation is defined by the existence of a diversity of

184 Touch sensation is initiated by mechanosensory neurons that in

185 Pain sensation is powerfully modulated by signal processing i

186 The proximity sensation is two-to-three times more effective than visu

187 anial electric stimulation, its evoked human sensation is understudied and often dismissed as a place

188 Although awareness of bodily sensations is a common mindfulness meditation technique,

189 om responses to 1 s noise bursts at 10-30 dB sensation level (dB above threshold).

190 A sensation level of 30 dB was used.

191 At comparable sensation levels, all measures showed that temporal codi

192 Aside from pain sensation, little is known regarding the role of sensory

193 ude also varied across stimuli to dissociate sensation magnitude from ICMS frequency and ensure that

194 d whether changes in frequency only modulate sensation magnitude-as do changes in amplitude-or whethe

195 t amputees experiencing highly vivid phantom sensations maintain cortical representation of their mis

196 ght tactile touch may induce unpleasant itch sensations (mechanical itch or alloknesis).

197 synchronised neuronal activity is central to sensation, motion and cognition.

198 tinuously process neural activity underlying sensation, movement and cognition, the CNS requires a ho

199 ished evoked responses representing auditory sensation (N100), basic attention (P300), and cognitive

200 racterized by an intense, unpleasant/painful sensation occurring rapidly and reproducibly in 40% of s

201 hreshold levels, and often multiple types of sensation occurring simultaneously in response to the sa

202 old male had blurred vision and foreign body sensation OD for several weeks.

203 and paired with one visual flash induce the sensation of a second illusory flash.

204 hemoreception, in particular, through direct sensation of acidosis induced by CO(2) levels.

205 indicating a compensatory arm response to a sensation of altered body motion.

206 Asthma causes the unpleasant sensation of breathlessness (dyspnea) caused by airway o

207 interaction, adaptation to antibiotics, and sensation of cellular conditions and environments.

208 Upon the sensation of chemical and physical cues specific to the

209 int does not contribute significantly to the sensation of dyspnoea.

210 n-selective channel normally involved in the sensation of gravity in the vestibular system, is essent

211 ural mechanisms underlying interoception-the sensation of internal physiological states-remain largel

212 No subjective sensation of involuntary tetanus was reported, and avers

213 fect and behavior.SIGNIFICANCE STATEMENT The sensation of itch includes an affective component that l

214 nd supraspinal circuitry responsible for the sensation of itch.

215 nd healing is associated with the unpleasant sensation of itching.

216 amental physiological processes that require sensation of mechanical force.

217 tory of normal erections and experienced the sensation of orgasm without ever ejaculating.

218 cation permeation pathway that triggers the sensation of pain.

219 However, sensation of the gut milieu was thought to be mediated o

220 Haptic memory in particular can retain the sensation of the interaction between the human body and

221 e on the body of wines, since it affects the sensation of thickness in the mouth.

222 against external stresses and mediating the sensation of touch and pain(1,2).

223 smart gloves and prosthetics to realise the sensation of touch and pain, and (iii) assistive technol

224 The sensation of touch is mediated by mechanosensory neurons

225 Nausea, the unpleasant sensation of visceral malaise, remains a mysterious proc

226 peace is interrupted, it is often by routine sensations of hunger and urge.

227 gic agonist similar to adrenaline, to induce sensations of palpitation and dyspnea in healthy individ

228 er, studies relating continuous postprandial sensations of satiation to measurable pathology are scar

229 The distinct visual sensations of shape and texture have been studied separa

230 and peripheral motor processes and movement sensations of the dream self.

231 ingly popular biomedical tool for generating sensations of virtual motion in humans, for which the me

232 ), metabolic rate (M) and whole-body thermal sensation on a visual analogue scale (WBTS) ranging from

233 metics did not change focal adhesion tension sensation or enrich for p38-YAP-TEAD interactions, which

234 cruitment of bilateral cortical responses to sensation or movement of the unaffected peripheral area.

235 a significantly higher symptom prevalence in sensation (OR = 4.7, 95% confidence interval [CI], 2.6-8

236 sweetness, fullness/body and alcohol warming sensation (p < 0.05).

237 neous brain states have consequences for our sensation, perception, and behaviour.

238 Interoception, the sensitivity to visceral sensations, plays an important role in homeostasis and g

239 jective abnormalities of either warm or cold sensation prior to the onset of significant symptoms or

240 effects of physical exercise, or vestibular sensation produced via self-motion.

241 ation but also a broader presence of somatic sensation ranging from touch and vibration to pain and p

242 al nerves of trans-tibial amputees to elicit sensations referred to their missing feet.

243 Interestingly, taste sensation related genes and many more differentially exp

244 brain's primary sensory nucleus for visceral sensations relevant to symptoms in medical and psychiatr

245 ionships in vivo, particularly during active sensation, remain poorly understood.

246 us were significantly associated with UPPS-P Sensation Seeking (p = 8.3 x 10(-9), rs139528938) and sh

247 e nucleotide polymorphisms in CADM2 and both sensation seeking and drug experimentation; and between

248 rough human adolescence, a time of increased sensation seeking and vulnerability to the emergence of

249 In fact, for the sensation seeking trait and anxious-depression factor, h

250 sign-tracking'), and subsequently tested for sensation-seeking and novelty-seeking.

251 asures of incentive salience attribution and sensation-seeking behavior that were not previously appa

252 As imaging studies have largely focused on sensation-seeking traits and approach behavior, the neur

253 also increased opportunity for diversion by sensation-seeking users.

254 For example, "sensation-seeking" is predictive of the initial propensi

255 tion induces high-risk personality traits of sensation-seeking/low anxiety associated with enhanced a

256 Individuals at risk often show a high sensation-seeking/low-anxiety behavioural phenotype.

257 s a functional coupling between movement and sensation, since tumbling probability is controlled by t

258 eet and bitter taste types, suggesting taste sensation specificity rather than chemical or receptor s

259 Mimicking human skin sensation such as spontaneous multimodal perception and

260 nisms by which inflammatory pathways promote sensations such as itch remain poorly understood.

261 by physical and chemical stimuli, eliciting sensations such as temperature, touch, pain, and itch.

262 hannels (Navs) can cause alterations in pain sensation, such as chronic pain diseases like inherited

263 avoidance of ingestion of toxins while pain sensations, such as noxious heat, signal adverse conditi

264 a genotype-dependent influence on cold pain sensation suggesting that carriers of the reduced migrai

265 action of concurrent pitches gives rise to a sensation that can be characterized by its degree of con

266 Itch is a distinct aversive sensation that elicits a strong urge to scratch.

267 Pruritus is a sensation that emanates from the skin and is transferred

268 Itch is an aversive sensation that evokes a desire to scratch.

269 Itch is a unique sensation that helps organisms scratch away external thr

270 ion to motor functions, is provided with the sensations that are naturally perceived while grasping a

271 rlying bladder afferent nerves to facilitate sensation, there is also the potential for ATP to act in

272 1.46 vs. 25.1 +/- 1.95, P = 0.005) and cold sensation threshold (21.35 +/- 0.99 vs. 26.08 +/- 0.5, P

273 . 26.08 +/- 0.5, P < 0.0001) and higher warm sensation threshold (43.7 +/- 0.49 vs. 41.37 +/- 0.51, P

274 he dynamic reweighting of synapses that link sensation to action.

275 Itch sensation to histamine injection was lost in most sympto

276 (M1) cortices play a central role in mapping sensation to movement.

277 ices, there is a gradual transformation from sensation to perception and action.

278 This transformation from sensation to perception is thought to be a major functio

279 inflammatory cytokines promote itch and pain sensations to coordinate host-protective behavioral resp

280 Our results suggest that unpleasant dryness sensations, together with augmented tearing rate after c

281 d inversion of the daily rhythmicity of pain sensation under neuropathic pain conditions.

282 iety and acute experiences of altered bodily sensations under MDMA.

283 se of the esophagus is an unpleasant/painful sensation, unrelated to dysphagia, occurring immediately

284 ted the intensity of their cardiorespiratory sensation using a dial.

285 The efficacy of the proximity sensation was evaluated by the initial contact force dur

286 Change from baseline in corneal sensation was significant (P < .001) but did not approac

287 pre-diagnostic descriptors of first symptoms/sensations was administered to patients referred for sus

288 l one-handers, who do not experience phantom sensations, was significantly reduced.

289 s sensory input into decisions during active sensation, we developed a mouse active touch task where

290 Gustatory sensations were evoked in 15 (2.7%) of the 550 stimulati

291 Evoked sensations were occasionally described as naturalistic (

292 voluntary tetanus was reported, and aversive sensations were restricted to the affected limb.

293 ch relate the physical stimuli to subjective sensations, were nonlinear.

294 y experiences, such as tactile or vestibular sensations, were not affected by tDCS, confirming the sp

295 der while blindfolded, which engaged plantar sensation while minimizing visual compensation.

296 In rodent whisker sensation, whisker position signals, including whisking

297 tive blood biomarkers for pain, a subjective sensation with a biological basis, using a stepwise disc

298 rkers for psychological stress, a subjective sensation with biological roots.

299 patterns can enhance the encoding of nose-up sensations without compromising gaze stabilization.

300 This sensation worsened with each subsequent intake.