ライフサイエンスコーパス: index finger

1 ed unimanual typing (moving little finger to index finger).

2 echanoreceptor stimulation of the tip of the index finger.

3 tension and flexion movements of the paretic index finger.

4 motor stimulus, and tapping by the nonstroke index finger.

5 ically stimulating the digital nerves of the index finger.

6 10 sighted control subjects using the right index finger.

7 ing stimulation of the digital nerves of the index finger.

8 d cat, a veterinarian was bitten on the left index finger.

9 stimulation at the randomly alternated cued index finger.

10 evoked during unopposed weak flexion of the index finger.

11 iston as strongly as possible with the right index finger.

12 ol of a precision grip between the thumb and index finger.

13 nervated area of the proximal phalanx of the index finger.

14 k a 1 s interval by tapping with their right index finger.

15 delayed reaction times in the contralateral index finger.

16 angular velocity transducer strapped on the index finger.

17 ometric force for 35 s with abduction of the index finger.

18 (2.5 and 10% MVC) with the fingertip of the index finger.

19 ng a rapid passive extension movement of the index finger.

20 electrical stimulation to the left or right index finger.

21 throughout the theoretical workspace of the index finger.

22 tap a force sensor mounted above their left index finger.

23 d by self-initiated voluntary flexion of the index finger.

24 of the proximal interphalangeal joint of the index finger.

25 like corpuscles in the distal phalanx of the index finger.

26 ing Braille reading with both right and left index fingers.

27 ations were simultaneously presented to both index fingers.

28 l and bimanual movements with right and left index fingers.

29 Cutaneous stimulation of the index finger (80 Hz, 1.5 s duration, twice sensory thres

30 rtex ipsilateral to the 1DIvol during active index finger abduction compared with the 1DIvol relaxed.

31 spinal motor neuron excitability (F-waves), index finger abduction force and electromyographic activ

32 etween the thumb and index finger and during index finger abduction in uninjured humans and in patien

33 reduced during precision grip compared with index finger abduction in uninjured humans, but was unch

34 phic (EEG) oscillations to self-paced simple index finger abduction movements in patients with writer

35 while performing a power grip but not during index finger abduction or precision grip.

36 le cue while performing a power grip but not index finger abduction or precision grip.

37 quiring different degrees of hand dexterity: index finger abduction, a precision grip, and a power gr

38 (F-waves) in an intrinsic hand muscle during index finger abduction, precision grip and power grip.

39 power grip compared with precision grip and index finger abduction, suggesting a cortical origin for

40 ential finger-thumb opposition or repetitive index finger abduction.

41 power grip compared with precision grip and index finger abduction.

42 tude of passive angular displacements of the index finger about the metacarpophalangeal joint and to

43 owing tasks (a) a sustained abduction of the index finger against resistance at 10-20 % maximum volun

44 tercepted these trajectories by moving their index finger along the surface of a display monitor.

45 es by actively feeling objects with a single index finger and by passively feeling objects that moved

46 small (6 mm) cylinder between the thumb and index finger and during index finger abduction in uninju

47 presented with a swollen, erythematous left index finger and elevated serum markers of inflammation.

48 The spontaneous index finger and other referential pointing in 3 adult,

49 G) elicited by air puff stimulation of right index finger and recorded using 306-channel MEG from 21

50 ility to retrieve the object by opposing the index finger and thumb in >80% of trials.

51 Eight subjects used index finger and thumb to grip two levers that were unde

52 Twelve right-handed subjects used index finger and thumb to grip two levers that were unde

53 Three-dimensional positions of the index finger and thumb were recorded while subjects with

54 scles when grasping a 6 mm cylinder with the index finger and thumb while the hand was held in the ne

55 to display force signals to two fingertips (index finger and thumb) as they traveled along collinear

56 g actuators that replicate the motion of the index finger and thumb.

57 y frequently acquire pointing, both with the index finger and with the whole hand, without explicit t

58 ed tactile stimulation to the right and left index fingers and also while they rested (eyes-closed).

59 n and adduction movements was recorded in 12 index fingers and nine little fingers reinnervated subse

60 Movements of the thumb, index finger, and little finger typically were more high

61 tify the reorganized region of D1-D3 (thumb, index finger, and middle finger) representation.

62 ous and proprioceptive input from the thumb, index finger, and middle finger.

63 key presses of the little, ring, middle and index fingers, and the 'complex' sequence of a much less

64 e saposin-like domain and in the base of the index finger are better tolerated and permit residual Wn

65 o terminus, the thumb, and at the tip of the index finger are incompatible with secretion and/or acti

66 ssive vibrotactile stimuli delivered to each index finger arrived first as they were preparing to eit

67 contraction (MVC), and (b) abduction of the index finger as in (a) whilst performing self paced low

68 l interosseus muscle as the subject held the index finger at a constant position while supporting a l

69 the same effect was newly generated for the index finger by the same postural change.

70 ical Gaussian noise (0-15 Hz) applied on the index finger can improve the performance during compensa

71 the longitudinal analysis on a single (right index) finger demonstrates that (i) genuine match scores

72 covery of precision grip using the thumb and index finger depends on the survival of afferents innerv

73 amic parameters and the grip aperture (thumb-index finger distance) were calculated.

74 Wnt engages FZD through protruding thumb and index finger domains, which are each assembled from pair

75 during voluntary self-paced abduction of one indexed finger; EMG activity could also be recorded simu

76 finger longer than the ring finger), type 2 (index finger equal to the ring finger), or type 3 (index

77 folds, resembling a "hand" with "thumb" and "index" fingers extended to grasp the Fz8-CRD at two dist

78 three conditions: rest; self-initiated right index finger extension at a variable rate of once every

79 or was quantified using accelerometry during index finger extension.

80 during self-initiated and predictably paced index finger extensions.

81 med flexion-extension movements of the right index finger (finger tapping) at varying rates before an

82 the performance of unconstrained syncopated index finger flexion movements in patients with PD, olde

83 Two animals performed an index finger flexion-extension task to track a target pr

84 study was to explore motor impairment of the index finger following stroke.

85 nd binding site, the conserved tip of Wnt's "index finger" forms hydrophobic amino acid contacts with

86 analysis, the location of stimulation on the index finger (four distinct sites) could be decoded with

87 action force of each individual finger), the index finger generated larger force than the little fing

88 self paced low amplitude tapping of the (i) index finger, (ii) thumb, (iii) middle finger, (iv) litt

89 t various intervals during a movement of the index finger in 16 patients with FHD and 20 controls.

90 als of the base to tip representation of the index finger in S1.

91 s were imaged while tapping with their right index finger in synchrony with tones that were separated

92 ne-like domains, including the thumb and the index finger in Wnt folding/secretion and FZD binding.

93 urial of Phe30 and Phe34 from the tip of the index finger into a pocket at the top of the thumb and t

94 Pointing with the index finger is a species-typical human gesture, althoug

95 our theory that grasping with the thumb and index finger is based on a combination of two goal-direc

96 o suppress (NOGO) or initiate (GO) ballistic index finger isometric voluntary contractions.

97 e 'simple' sequence consisted of 16 repeated index finger key presses, the 'scale' sequence of four t

98 iographs were visually classified as type 1 (index finger longer than the ring finger), type 2 (index

99 Participants performed an out-and-back index finger movement and were instructed that monetary

100 preceding the onset of unilateral voluntary index finger movements (paretic hand in patients, right

101 ometry beamforming analysis of visually cued index finger movements.

102 tor cortex during observation of little- and index-finger movements [11-13].

103 b muscle, and flexor digitorum profundus, an index-finger muscle) was just as large as that for pairs

104 intramuscular electromyograms from all seven index finger muscles.

105 uced corticospinal excitability in the right index finger of 8/16 participants.

106 brotactile stimulation of sites on the right index finger of a single human subject.

107 etect H. pylori from beneath the nail of the index finger of each subject's dominant hand.

108 ted with forces varying from 1 to 3 N on the index finger of their left hand.

109 ermal stimulators are placed on the ring and index fingers of one hand, and a neutral-temperature sti

110 as mirror movements (moving little finger to index finger on both hands), and the third task compared

111 a target object from a clamp using thumb and index finger opposition.

112 0-25 constant-velocity contractions with the index finger over a 10 deg range of motion by using 6 s

113 dot arrays, applied to the immobilized right index finger pad using a computer-controlled, MRI-compat

114 oxidase was then injected into the thumb and index finger pads bilaterally to label the central termi

115 Index finger pointing was more frequent with the subject

116 hat a rubber right hand pressing on the left index finger produced somatosensory attenuation but only

117 otlets that enervate the macaque's thumb and index finger (segments C6-C8), the cortical representati

118 Index finger sensory function correlated with MEP size d

119 finger equal to the ring finger), or type 3 (index finger shorter than the ring finger).

120 sustained co-extension of the left and right index fingers, simultaneous finger tremor and extensor i

121 ter moved the blindfolded participant's left index finger so that it touched the fake hand, and simul

122 gaged in three tasks: synchronization (right index finger tapping in synchrony with a tone presented

123 lant users, a tactile aid was applied to the index finger that converted voice fundamental frequency

124 Further, a double cysteine mutation at the index finger tip results in a Wnt3a with normal secretio

125 Here, subjects used their right index finger to tap a force sensor mounted above their l

126 ts was recorded in 3D during 15-s repetitive index finger-to-thumb tapping trials.

127 to movement onset, IHI targeting the moving index finger turned into facilitation in controls but re

128 ensory cortex (iS1) to sensory gating during index finger voluntary activity.

129 inhibition) the iS1 at rest and during tonic index finger voluntary activity.

130 a need to suppress but not to execute rapid index finger voluntary contractions in individuals with

131 imulating four sites along the length of the index finger, we were able to identify and locate map re

132 ifically, the kinetics and kinematics of the index finger were analysed throughout its workspace.

133 In addition, scans (both wavelengths) of the index finger were performed prior to and during 2 minute

134 entified axons projecting from the thumb and index finger were then cut in two monkeys (Group 1).

135 ed an irregular "maze" line pattern with the index finger while viewing their hand and the maze in a

136 humb" and a disulfide-stabilized C-terminal "index finger," yet how these binding events trigger rece