ライフサイエンスコーパス: fingertip

1 r up and down or left and right across their fingertip.

2 pressure and hemodynamic parameters from the fingertip.

3 ss the instantaneous speed of the biomimetic fingertip.

4 tained by scanning the linear array over the fingertip.

5 the spatial and temporal acuity of the human fingertip.

6 activin type I receptor such as ALK4 at the fingertip.

7 humans compare two vibratory stimuli on the fingertip.

8 ometry in skin biopsies from the third digit fingertip.

9 tion frequencies applied sequentially to one fingertip.

10 variable amplitude applied to the skin of a fingertip.

11 vered custom-molded splint was placed on the fingertip.

12 er joints result in the same movement at the fingertip.

13 tterns of tactile stimuli presented to their fingertips.

14 rimination rivals that of humans using their fingertips.

15 On day 24, the patient moved her fingertips.

16 rvices to patients at the order of patient's fingertips.

17 bility for delivering tactile stimuli to the fingertips.

18 orientation of raised edges scanned with the fingertips.

19 ctile information when we touch objects with fingertips.

20 pressure afferents from the thumb and index fingertips.

21 of single tactile afferents innervating the fingertips.

22 ections representative of natural use of the fingertips.

23 it anlagen, growth plates, skull sutures and fingertips.

24 es articles, books, videos, and games at our fingertips.

25 erials and biological tissues, such as human fingertips.

26 , to the middle of the digits, to the distal fingertips.

27 echanoreceptive afferents that innervate the fingertips.

28 zation was detected most frequently on palms/fingertips (76%) and nares (71%).

29 the surface between the thumb domain and the fingertip about 30 A away from the active site of the HC

30 control of finger musculature when the index fingertip abruptly transitions from motion to static for

31 focal cortical activation between the single fingertip activation regions.

32 "scratching" task of rhythmically moving the fingertip along a 5.8 +/- 0.5 cm target line.

33 etric sensor was positioned on the patient's fingertip and connected to a pulse co-oximeter.

34 f interest (BOI), palm, inner elbow, temple, fingertip and forehead, are demonstrated using a wideban

35 h, suggesting that a generalized increase in fingertip and limb forces did not occur.

36 ation of the helix is non-canonical, and the fingertip and the N terminus of the helix project out of

37 ditions of direct moving contact between the fingertip and the surface (direct touch) and contact thr

38 ng standard and test wheels with their index fingertip and were required to adjust the test wheel unt

39 patterning the limb from the shoulder to the fingertips and another that presented the co-discovery o

40 r interactions are shifted toward the ligand fingertips and away from the dimer interface.

41 We transferred molecules from clean fingertips and fingertips covered with plasticine modeli

42 stemming from accidental alignments between fingertips and inferred surface structures.

43 information about the force object exerts on fingertips and the friction of the surfaces to determine

44 , brachydactyly of hands and feet with broad fingertips and toes, and uni- or bilateral renal agenesi

45 tactile acuity, including whisker follicles, fingertips and touch domes.

46 ile moving a single tactile point across the fingertip, and used signal detection theory to quantify

47 le, the high innervation of the fovea or the fingertips, and stimulus statistics, for example, the hi

48 s described in 1991 as an XLID syndrome with fingertip arches and contractures and mapped to proximal

49 Stable precision grips using the fingertips are a cornerstone of human hand dexterity.

50 deliver simultaneous stimuli across multiple fingertip areas.

51 x, high-frequency vibrations elicited in the fingertip as it is scanned across a surface.

52 It does so via a pair of fingertip aspartates that can bind magnesium, placing TF

53 ent inter-burst intervals) to the left index fingertip at frequencies corresponding to established ne

54 nless, leveraging the high sweat rate on the fingertip at rest without any sweat stimulation.

55 xtures were manipulated by a soft biomimetic fingertip at six different speeds.

56 er characteristics, were recorded using NFC; fingertip blood flow (FBF) was measured using LDI at dif

57 The human fingertip can detect small tactile features with a spati

58 he sensory system integrated on a prosthetic fingertip can identify 20 different commercial textiles

59 Fingertip capillary blood samples were collected from 3-

60 d that large ridge-count differences between fingertips (cephalad > caudad) might reflect fetal inhib

61 ctivity allotted to the tactile receptors on fingertips conforms to skilful use of the hand.

62 gauge apparatus designed to mimic ballpoint fingertip contact with a bottle.

63 Roughness perception through fingertip contact with a textured surface can involve sp

64 ipheral cutaneous vascular beds, such as the fingertips, contain a high concentration of arteriovenou

65 ample, the higher contact frequencies on the fingertips, contribute?

66 augmentation by skin stretch feedback at the fingertip could modulate the standing balance of the peo

67 nsferred molecules from clean fingertips and fingertips covered with plasticine modeling clay onto ou

68 ICMS pulses generated whenever the avatar's fingertip crossed a ridge.

69 ated noise sequence delivered to whiskers or fingertips, defined by its temporal patterning over hund

70 measured by a pulse oximeter attached to the fingertip), describe this erroneously as the PTT.

71 irectional tactile motion stimulation on the fingertip during slow wave sleep selectively enhanced su

72 repetitive tactile motion stimulation on the fingertip during slow wave sleep selectively enhanced su

73 ce that measured the forces generated at all fingertips during individual finger presses.

74 ecule self-limiting gap size control between fingertips ensures ultimate SERS enhancement for sensiti

75 When multiple fingertips experience force sensations, how does the bra

76 dorsal interosseous during the generation of fingertip flexion forces.

77 onic system is used to apply pressure on the fingertip for (i) measuring oscillometric blood pressure

78 n blood flow using skin laser Doppler on the fingertip for 3 minutes at basal temperature (SBFBT) and

79 isuomotor task, just as the fovea guides the fingertip for visually normal subjects.

80 downward tapping motion followed by vertical fingertip force against a rigid surface.

81 Subjects were instructed to generate fingertip force in six orthogonal directions at five dif

82 Specifically, initial fingertip force profiles and resulting action kinematics

83 Fingertip force scaling for lifting objects frequently o

84 switch in underlying neural control polluted fingertip force vector direction beyond what is explaine

85 We simultaneously recorded three-dimensional fingertip force, plus the complete muscle coordination p

86 raction, thus freeing up muscle capacity for fingertip force.

87 Quantifying the ability to produce steady fingertip forces against low-friction surfaces may be a

88 t weighed either 150 g or 1000 g while their fingertip forces and movements were measured.

89 rties [e.g., weight or center of mass (CM)], fingertip forces are appropriately scaled before the obj

90 s case, the pinch force was unrelated to the fingertip forces necessary to grip the object efficientl

91 low-friction surfaces require well-directed fingertip forces of sufficient and precise magnitudes fo

92 randomly varying mechanical properties, the fingertip forces reflect the previous lift.

93 ed changes across the adult life span of the fingertip forces used to grip and lift objects and their

94 ndings included that anticipatory control of fingertip forces using memory of object weight was unimp

95 inally, old and young adults modulated their fingertip forces with equal smoothness and with similar

96 s, IMA participants learned to differentiate fingertip forces with repeated lifts of both familiar an

97 g 150 or 1000 g while the breathing pattern, fingertip forces, and movements were measured.

98 internal model for predictively controlling fingertip forces.

99 ules, while at the same time the gold-coated fingertips form a reliable Raman hot spot for molecule d

100 m the 19th week of pregnancy, are related to fingertip growth during early gestation.

101 d the duration of a vibration applied to the fingertip (human) or whiskers (rat), increasing stimulus

102 nt in which subjects viewed a moving virtual fingertip in place of their own finger.

103 entation is magnified cortically, as are the fingertips in touch.

104 Here, we fabricated a soft biomimetic fingertip including an 8 x 8 array tactile sensor and a

105 dback device to display force signals to two fingertips (index finger and thumb) as they traveled alo

106 activity in response to touch on the little fingertip is larger than that in control subjects.

107 surfaces that are actively touched with the fingertips is perceived using both vision and touch [3].

108 ctile stimulus was presented to a nonvisible fingertip, located either to the left or right of gaze.

109 terminal repeat-retroelement RTs and the RT fingertips loop, with the 3' nucleotide of the acceptor

110 routine motion-to-force transitions with the fingertip may explain the existence of specialized neura

111 velocity-based skin stretch feedback at the fingertip may increase the signal-to-noise ratio of the

112 Fingertip mechanoreceptors comprise sensory neuron endin

113 Second, the TFIIB fingertip mediates the timing of the release of TFIIB th

114 our study on the simultaneous production of fingertip motion and force disagrees with this commonly

115 , such as capillary refill time on the index fingertip, mottling, and Pv-aCO(2) (the difference betwe

116 We found that synchrony of both fingertip movement and neural activity between the two p

117 (normal) and load (tangential) forces at the fingertip-object interface were measured and the grip fo

118 f visually identical screen objects with the fingertip of a hand avatar-controlled first via a joysti

119 diverse set of everyday textures across the fingertip of awake macaques while recording the response

120 ects discriminated gratings delivered to the fingertip of either the right or left hand.

121 submaximal forces (2.5 and 10% MVC) with the fingertip of the index finger.

122 Each subject was instructed to use the fingertip of their dominant hand's index finger to rub o

123 ing the power of atlas-level analysis at the fingertips of a broad community of users.

124 tion revealed small areas of necrosis on the fingertips of her right hand.

125 NCs), the tactile end-organs enriched in the fingertips of humans and the whisker hair follicles of n

126 resenting tactile gratings and plaids to the fingertips of monkeys, using the tactile analogue of a v

127 a wide range of natural textures across the fingertips of rhesus macaques and recorded the responses

128 distance information at teleoperation to the fingertips of teleoperators, i.e., proximity sensation.

129 electrical stimulation was applied onto the fingertips of teleoperators, with the pulsing frequency

130 ecificity is derived from differences in the fingertips of the ligands that interact with an extended

131 anical touch on the thumb, index, and middle fingertips of touchscreen phone users and nonusers (owni

132 ifference between the right fourth and fifth fingertips only (dR45; r = 0.36, p = 0.003).

133 tracking an individual's BGL by placing his fingertip onto the sensor.

134 Arterial oxygen saturation (fingertip oximeter) was lowered (P<0.05) from 96+/-0.7%

135 3rd digit of the right hand (DeltaT(forearm-fingertip)), oxygen uptake and heart rate were recorded.

136 In the 102 patients (29%) with poor fingertip perfusion-defined as a capillary refill time g

137 Using a fingertip peripheral arterial tonometry (PAT) device, we

138 e music or speech or scan a texture with our fingertip, physical features in the stimulus are concate

139 nalysis revealed significant improvements in fingertip pinch force, hand prehension and strength, upp

140 oint angles (mean error: 4.16 degrees ), and fingertip positions (mean 3D error: 4.02 mm), and on ove

141 Maximum pinch strength and fingertips pressure sensation threshold were also examin

142 ex (SI) that simultaneous stimulation of two fingertips produces a single focal cortical activation b

143 eremia produced a time-dependent increase in fingertip pulse amplitude.

144 detecting weak physiological signals such as fingertip pulse under different skin humidity.

145 velocity-based skin stretch feedback at the fingertip reduced the entropy of the standing postural s

146 r example, tactile acuity is greatest on the fingertips, reflecting the high innervation density and

147 rphic response in mammals that is similar to fingertip regeneration in humans.

148 l forms showed conformational changes in the fingertip region and in the thumb domain that may help t

149 For GDF11, additional contacts at the fingertip region substitute for the interreceptor intera

150 2:ActA reveals that binding relies on ActA's fingertip region, mirroring the interaction of ActA with

151 sis DUs, particularly those occurring on the fingertips, represent a vascular ischemic complication,

152 otion sickness procedure, the DeltaT(forearm-fingertip) response was significantly attenuated, indica

153 Fingertip retinal bivariate area was positively correlat

154 Concentric overlap of fPRL and fingertip retinal ellipses indicates that it is the fPRL

155 Fingertip retinal ellipses surrounded and were approxima

156 e scotoma and bivariate ellipses of fPRL and fingertip retinal positions.

157 riod similar to the dimensions of individual fingertip ridges.

158 evel signal continuous information about the fingertip's viscoelastic deformation state, which is sha

159 loadings signaled information related to the fingertip's viscoelastic deformation state.

160 lass mobilize intricate interactions between fingertip sensory inputs and motor commands to account f

161 Such plasticity of the fingertip sensory representation is not limited to extra

162 both the genome and proteome worlds at their fingertips simultaneously.

163 Alterations in fingertip skin blood flow can be evaluated using a laser

164 the resulting strain gradients and that the fingertip skin may possess a higher mechanical spatial r

165 me, tissue oxygen saturation, and forearm-to-fingertip skin temperature gradient.

166 ducts and Meissner's corpuscle in the human fingertip skin-features that are otherwise obscured by s

167 to the use of sweat deposits (in the form of fingertip smears or fingerprints) for non-invasive scree

168 or the early detection of breast cancer from fingertip smears.

169 Fingertips smears were taken from each patient and from

170 uch", a sensorimotor strategy based on light fingertip support, significantly enhanced their balance

171 sized that a simple physical characteristic, fingertip surface area, might constrain tactile learning

172 ttern type is related to the geometry of the fingertip surface when fingerprint patterns are formed.

173 c correlation between the finger touch-based fingertip sweat and capillary blood samples.

174 method relies on instantaneous collection of fingertip sweat on a highly permeable hydrogel that tran

175 f-testing approach utilizing a touch-enabled fingertip sweat UA electrochemical biosensor based on a

176 the drug concentration in naturally secreted fingertip sweat.

177 Touch-sensitive neurons in the fingertips take previous physical contacts into account

178 e, when more information is available at our fingertips than ever, the information we choose to colle

179 pidermal nerve fiber density is lower in the fingertips than in the hand dorsum.

180 the spatial acuity for pain is higher on the fingertips than on proximal skin regions such as the han

181 The increased spatial acuity for pain on the fingertips therefore cannot be explained simply by perip

182 actual auditory feedback as they moved their fingertip through a virtual soundscape.

183 eys which could be because of differences in fingertip tissue compliance and skin friction.SIGNIFICAN

184 -order tactile neurons innervating the human fingertip to loadings applied in different directions re

185 onsenting adults to use their dominant index fingertip to maximize voluntary downward force against a

186 tronic device that stretches the skin of the fingertips to address this issue in the intact sensorimo

187 s five elastomeric capacitive sensors on the fingertips to measure touch pressure so as to enable tac

188 ormation about object texture by using one's fingertips to scan a surface.

189 igapixel digitised pathological images using fingertip touch.

190 eta-afferent endings, are highly abundant in fingertips, touch domes, and whisker hair follicles of m

191 face to face with the tester with or without fingertips touching (i.e., IPS).

192 s; range, 0.2-19.2 years; P = .003) and more fingertip ulcers (50.0% vs 9.3%, P < .001).

193 Fingertip ulcers and disease duration were strongly asso

194 ) in multivariate analyses that adjusted for fingertip ulcers and other covariates.

195 erlie the development of both calcinosis and fingertip ulcers in patients with DM.

196 ely associated with longer disease duration, fingertip ulcers, and NXP-2 autoantibodies and negativel

197 ist in multivariate models that adjusted for fingertip ulcers.

198 diverse set of natural textures across their fingertips using a custom-made rotating drum stimulator.

199 asive system for real-time WBC counting from fingertip videos.

200 The fingertip was the area of highest spatial acuity, for bo

201 Meissner's corpuscle (MC) density in the fingertips was assessed using in vivo laser reflectance

202 cortical potentials from the thumb and index fingertips were directly proportional to the intensity o

203 en, the potentials associated with the three fingertips were enhanced in touchscreen users compared t

204 The spatial paths described by their fingertips were more circuitous, being of greater length

205 uted over the entire terminal segment of the fingertip when it was contacted by surfaces with differe

206 k any equivalent to the tactile fovea on the fingertips, where the density of nociceptive fibers is r

207 TS was applied to either the thumb or middle fingertip which had greater contact with the handle, gra

208 On some trials, we perturbed the virtual fingertip while it moved behind an occluder.

209 -afferent nerve endings and are localized in fingertips, whisker hair follicles, and other touch-sens

210 vice solely using "in-flow" imaging of 3 muL fingertip whole blood for improved identification and co

211 evaluated the usefulness of an on site rapid fingertip whole blood point-of-care test (POCT) for such

212 The fingertip whole blood rapid POCT might fulfill the unmet

213 ed participants to pull on their right index fingertip with their left hand while they were presented