ライフサイエンスコーパス: electromyographic

1 carbamazepine did not alter the clinical or electromyographic abnormalities.

2 Surface electromyographic activity (EMG) and force were recorded

3 ographic activity (EEG) over motor areas and electromyographic activity (EMG) from affected neck musc

4 EUS reflex electromyographic activity (EMG), innervation of pelvic

5 , mean skin and mean body temperature (Tb ), electromyographic activity (EMG), metabolic rate (M) and

6 correlated better with transversus abdominis electromyographic activity (r = 0.7 to 0.95) than did th

7 Evoked electromyographic activity and force were recorded in re

8 Electromyographic activity and joint rotation were measu

9 (F-waves), index finger abduction force and electromyographic activity as well as a hand dexterity t

10 these disorders and a more normal pattern of electromyographic activity during rest and movement.

11 Measurements of onset time of electromyographic activity during steady-state hypoxic h

12 sed the elevations in oxygen consumption and electromyographic activity elicited by cooling the POAH.

13 rons (309) were recorded simultaneously with electromyographic activity from arm and shoulder muscles

14 etection sites that can sample intramuscular electromyographic activity from the entire muscle cross-

15 Integrated electromyographic activity from the upper eyelid was rec

16 inal tract, by measuring reaction times from electromyographic activity in an intrinsic finger muscle

17 urethane and respiratory airflow, as well as electromyographic activity in respiratory muscles were r

18 isometric forces acting a hand joint and the electromyographic activity in the first dorsal interosse

19 the time from stimulus onset to the onset of electromyographic activity in the responding muscle.

20 tor, indomethacin, effectively inhibited the electromyographic activity induced by UCD.

21 A head-fixed computer transformed forelimb electromyographic activity into proportional subthreshol

22 the jaw movements and associated masticatory electromyographic activity occurring during gum chewing,

23 be coherent with oscillatory activity in the electromyographic activity of hand and forearm muscles.

24 he response was measured from changes in (i) electromyographic activity of hip and ankle muscles, (ii

25 The electromyographic activity of intercostal muscles couple

26 re was an unusual, overall increase in tonic electromyographic activity of the diaphragm, suggesting

27 re determined from the evoked changes in the electromyographic activity of the orbicularis oculi (OO)

28 ned responses (CRs) were determined from the electromyographic activity of the orbicularis oculi musc

29 Electromyographic activity of the superior, middle, and

30 rved and accompanied by sustained quadriceps electromyographic activity often lasting > 2s after stim

31 ed stimulus-triggered averaging (StTAing) of electromyographic activity to map the cortical represent

32 imum O(2) uptake were reduced whereas muscle electromyographic activity was increased in hypoxia comp

33 ed chewing cycles and associated masticatory electromyographic activity were sampled from each subjec

34 separated sites and between neural and limb electromyographic activity.

35 in POAH temperature, oxygen consumption, and electromyographic activity.

36 Kinematic and electromyographic analyses of reaching movements demonst

37 Electromyographic analysis suggested that this behavior

38 Electrophysiological recordings (electromyographic and direct records form muscle nerves)

39 We recorded facial electromyographic and electrocardiographic activity whil

40 um elevations of muscle enzymes, the classic electromyographic and muscle biopsy findings of inflamma

41 een for constraint-induced movement therapy, electromyographic biofeedback, mental practice with moto

42 e 'Q, R, S and T' waves of the post-stimulus electromyographic complex (PSEC)) occurred in full-wave

43 Here we have found electromyographic correlates of internal model formation

44 First, we recorded electromyographic data from vocal muscles in singing Ben

45 task-set model predicts, and behavioral and electromyographic data support, the hypothesis that unde

46 hat three synergies accounted for 81% of the electromyographic data variation in each monkey.

47 y 100% on the visual analogue scale, and the electromyographic discharges disappeared from the parasp

48 l pattern, (2) magnitude, and (3) latency of electromyographic (EMG) activation associated with HFLD-

49 ctions and external urethral sphincter (EUS) electromyographic (EMG) activation during urodynamic rec

50 he GG of 11 subjects (20-40 years) to record electromyographic (EMG) activities and pulmonary ventila

51 Electromyographic (EMG) activities of external oblique a

52 ine hydrochloride, may increase genioglossal electromyographic (EMG) activity (EMGgg) in a manner res

53 Electromyographic (EMG) activity and fetal and maternal

54 cant increases in plantarflexion torques and electromyographic (EMG) activity from the soleus (SOL) a

55 Stimulus-triggered averaging (StTA) of electromyographic (EMG) activity is a form of intracorti

56 Tongue electromyographic (EMG) activity is increased in patient

57 ume, transpulmonary pressure, compliance and electromyographic (EMG) activity of genioglossus (GG), h

58 iring rates and the percentage of CRs or the electromyographic (EMG) activity of the orbicularis ocul

59 Surface electromyographic (EMG) activity recorded from the left

60 Diaphragm electromyographic (EMG) activity was also recorded, toge

61 Electromyographic (EMG) activity was recorded from selec

62 associated with equivalent resting levels of electromyographic (EMG) activity.

63 and mean absolute plantarflexion errors) and electromyographic (EMG) activity.

64 Electromyographic (EMG) analysis indicating denervation

65 ngle oral dose of 50 and 100 mg of S44819 on electromyographic (EMG) and electroencephalographic (EEG

66 stimulus (US) can greatly enhance the early electromyographic (EMG) component (R1) of the rat eyebli

67 quantified using the latency and duration of electromyographic (EMG) data and the center of pressure

68 The slope of predicted vs. electromyographic (EMG) data for an individual was compa

69 limb, the wiping limb, was implanted with 12 electromyographic (EMG) electrodes and attached to a rob

70 anted with electroencephalographic (EEG) and electromyographic (EMG) electrodes for the recording of

71 s on the left common peroneal nerve and with electromyographic (EMG) electrodes on the left tibialis

72 agonist, into MS alter behavioral, EEG, and electromyographic (EMG) measures of sleep and waking in

73 Electromyographic (EMG) measures were made of the eyebli

74 oth simple RT and self-paced movements after electromyographic (EMG) offset, there was a first period

75 Electromyographic (EMG) recordings during these movement

76 Responses to CRD are measured as electromyographic (EMG) recordings of the abdominal musc

77 ed intracortical microstimulation (ICMS) and electromyographic (EMG) recordings to test whether neuro

78 e placed within the vagina or anal canal, or electromyographic (EMG) sensors in the same locations, t

79 mands to generate motor outputs by analyzing electromyographic (EMG) signals collected from 13 hindli

80 We found that the use of electromyographic (EMG) signals from natively innervated

81 unit potential (MUP) morphology derived from electromyographic (EMG) signals in patients with OSA ver

82 measured along with force, joint angle, and electromyographic (EMG) signals of the performing muscle

83 Electromyographic (EMG) signals were recorded using intr

84 ), handgrip force, and finger flexor surface electromyographic (EMG) signals.

85 sist length change--leads to the result that electromyographic (EMG) synergies will arise without the

86 Using surface electromyographic (EMG) techniques, we compared the VO2

87 is hypothesis, utilizing kinematic, kinetic, electromyographic (EMG), and metabolic data taken from f

88 We measured the electromyographic (EMG), kinematic and kinetic patterns

89 palatini (TP) muscle activity (% of maximum electromyographic [EMG] activity) in 10 OSA patients and

90 A total of 21 of 22 (95%) patients had electromyographic evidence of chronic partial denervatio

91 Incorporation of needle electromyographic evidence of lower motor neuron degener

92 All patients had distinct clinical and electromyographic evidence of MG (MGFA clinical classifi

93 ly in which 2 of 7 siblings had clinical and electromyographic features consistent with AChR deficien

94 ve a combination of clinical, laboratory, or electromyographic features of IIM.

95 ossible to reconcile discrepant anatomic and electromyographic findings in patients with OSA, to expl

96 phenomenon quantitatively, using the phasic electromyographic metric (PEM), in relation to clinical

97 a cava, all patients underwent diaphragmatic electromyographic monitoring using surface electrodes.

98 ot correlate with the burden of clinical and electromyographic motor neuron dysfunction.

99 authors examined the standard deviations of electromyographic onset latencies from the bilateral int

100 central and midline regions before and after electromyographic onset.

101 Electromyographic phrenic nerve monitoring using the sur

102 ratory muscle activity were obtained by wire electromyographic recording of the activity of the trans

103 instrumented for electroencephalographic and electromyographic recording, to locally manipulate neuro

104 viors by performing paired single-neuron and electromyographic recordings in awake rats.

105 Using electromyographic recordings of both abdominal and colon

106 performing electroencephalographic (EEG) and electromyographic recordings of C57BL/6J mice receiving

107 Electromyographic recordings of neck and hand muscles du

108 e response was assessed bilaterally by using electromyographic recordings of orbicularis oculi.

109 d to simulate joint forces in real time from electromyographic recordings of the wrist muscles.

110 Electromyographic recordings revealed altered muscle act

111 We first use electromyographic recordings to extend previous findings

112 Electromyographic recordings were made from the orbicula

113 Electromyographic recordings were made from the SA and T

114 First, using electromyographic recordings, we demonstrate that volunt

115 oustic correlate of the Piper rhythm seen in electromyographic records of muscle activity.

116 ning was specific and showed an anticipatory electromyographic response to the aversive conditioning

117 al magnetic stimulation-evoked kinematic and electromyographic responses in the d-amphetamine and in

118 Visceromotor electromyographic responses increased within 2 minutes a

119 Electromyographic responses recorded from pharynx and ha

120 Electromyographic responses recorded in soleus (standing

121 graphic, spinal (ChR2 evoked potential), and electromyographic responses revealed a mismatch between

122 Electromyographic responses to gastric balloon distentio

123 rawal thresholds and increased flexor muscle electromyographic responses to graded suprathreshold hin

124 Pharyngeal and thenar electromyographic responses to magnetic stimulation of m

125 dysphagia, mylohyoid, pharyngeal, and thenar electromyographic responses to stimulation of affected a

126 Electromyographic responses were recorded after suprathr

127 ICMS) and recording of evoked jaw and tongue electromyographic responses were used to define jaw and

128 l magnetic stimulation of induced pharyngeal electromyographic responses, recorded from a swallowed i

129 rading their abdominal withdrawal reflex and electromyographic responses.

130 in transcranial magnetic stimulation-evoked electromyographic responses.

131 al involvement) on the basis of MR findings, electromyographic results, and clinical data.

132 tion (ie, regarding atrophy, pain, weakness, electromyographic results, neck and spine history, traum

133 rent algorithms for processing and filtering electromyographic signal, many monitors are affected by

134 ed local field potentials (LFPs) and surface electromyographic signals (EMGs) from the extensor and f

135 The amplitude and timing of electromyographic signals from the leg muscles scaled to

136 onal (direct) control methods, which rely on electromyographic signals produced from a limited set of

137 Intramuscular (I.M.) and surface electromyographic signals were recorded from the vastus

138 Polygraphic EEG-electromyographic studies demonstrated a cortical origin

139 The single-fiber electromyographic studies were also consistent with a pr

140 We assessed our patients by clinical and electromyographic studies, by intercostal muscle biopsie