ライフサイエンスコーパス: electromyogram

1 CMD was estimated via quadriceps electromyogram.

2 and whisking was measured via the mystacial electromyogram.

3 the time trials was estimated via quadriceps electromyogram.

4 eck electromyogram, PGO waves, and diaphragm electromyogram.

5 by electroencephalogram, electroculogram and electromyogram.

6 occurred in full-wave rectified and averaged electromyograms.

7 reathing rats while monitoring diaphragmatic electromyogram activity.

8 hough no important physiologic (genioglossal electromyogram, airflow resistance) differences were obs

9 entilation, causing a reduction in diaphragm electromyogram amplitude until apnea/periodic breathing

10 it LFD both in the intact animal as shown by electromyograms and by intracellular recordings at neuro

11 coherent at approximately 20 Hz with surface electromyogram (as already extensively reported) but als

12 All patients underwent electromyogram at baseline, which was repeated in cases

13 herence between the magnetoencephalogram and electromyogram at tremor frequencies suggests that in es

14 s abolished, and afferent stimulation evokes electromyograms at abnormally long latencies.

15 wakefulness by using an electroencephalogram/electromyogram-based screen of randomly mutagenized mice

16 Electroencephalogram, neck electromyogram, blood pressure, respiratory frequency (f

17 n in which both laryngeal nerve activity and electromyograms can be recorded from awake, vocalizing f

18 sed nerve transfers to muscle to develop new electromyogram control signals and nerve transfers to sk

19 ion of these mice using electroencephalogram/electromyogram (EEG/EMG) monitoring and found age-relate

20 nd sustained inhibitory effects on diaphragm electromyogram (EMG(di)).

21 ssive neurodegenerative disease, we measured electromyogram (EMG) activity in hind limb muscles of SO

22 determined by electrocorticogram (ECoG) and electromyogram (EMG) activity over a 7-day sub-chronic a

23 catter enables high-fidelity transmission of electromyogram (EMG) and electroneurogram (ENG) signals

24 At 300 degrees /sec stretch, electromyogram (EMG) and torque reflex responses, which

25 al electrode recordings of the diaphragmatic electromyogram (EMG) as the reference measurement of neu

26 Simultaneous records were made of the electromyogram (EMG) in masseter and anterior digastric

27 igated the modulation of oscillations in the electromyogram (EMG) of human volunteers during tasks re

28 of relaxation as estimated from the surface electromyogram (EMG) of the left FDI.

29 Whole body kinematics and electromyogram (EMG) recordings were made prior to, and

30 reinnervation, these target muscles produce electromyogram (EMG) signals on the surface of the skin

31 Moreover, surface electromyogram (EMG) signals were concurrently detected

32 ed and AP twitch tension (Tw AP) and surface electromyogram (EMG) were measured.

33 Electrocorticogram (ECoG) and myometrial electromyogram (EMG) were recorded continuously in chron

34 nd halothane on the processed EEG and on the electromyogram (EMG) which has not been previously descr

35 encephalogram (EEG), Electrooculogram (EOG), Electromyogram (EMG), Electrocardiogram (ECG) and parame

36 (EEGs), electro-oculograms (EOGs), submental electromyogram (EMG), GG EMG (intramuscular electrodes),

37 rmined from a flow tracing and diaphragmatic electromyogram (EMG), respectively.

38 constraint-induced movement therapy (CIMT), electromyogram (EMG)-triggered neuromuscular stimulation

39 oving-time average (MTA) of the genioglossus electromyogram (EMG-GG) and the esophageal pressure defl

40 The handgrip force and electromyograms (EMG) of the finger flexors declined pro

41 d nerve-evoked whole muscle twitch force and electromyograms (EMG) to a greater extent in older homoz

42 Concurrently, surface electromyograms (EMG) were also recorded from first dors

43 ral respiratory drive, measured as diaphragm electromyogram (EMGdi) activity expressed as a proportio

44 des, and turns and amplitude analyses of the electromyograms (EMGs) during these vocalizations were a

45 To test this hypothesis, we recorded electromyograms (EMGs) from 12-16 upper arm and shoulder

46 POINTS: The present study demonstrates that electromyograms (EMGs) obtained during locomotor activit

47 ower leg flexor and extensor muscles and the electromyograms (EMGs) of the corresponding muscles were

48 Electromyograms (EMGs) were recorded from four hand musc

49 In six patients, genioglossus-muscle electromyograms (EMGs) were recorded.

50 n that of interest may contribute to surface electromyograms (EMGs).

51 the relationship between two dilator muscle electromyograms (EMGs, i.e., genioglossus [GG-an inspira

52 ng stable NREM sleep, measuring genioglossus electromyogram, epiglottic/choanal pressure, and airflow

53 Cortical electroencephalogram, electromyogram, eye movement, hippocampal theta-wave, an

54 t occipital cortex showed: 1) coherence with electromyogram from a right hand muscle; 2) a typical se

55 cle coordination pattern using intramuscular electromyograms from all seven index finger muscles.

56 n, and stimulation of these afferents evokes electromyograms from the first basalar muscle with short

57 Resistive force and electromyograms from triceps surae muscles were measured

58 of airway dilators, we assessed genioglossal electromyogram (GG EMG: rectified with moving time avera

59 We correlated these with the surface electromyograms in the affected muscles.

60 ly implanted to record electroencephalogram, electromyogram, locomotor activity, and body temperature

61 cluded contralateral trials with evidence of electromyogram modulation on the ipsilateral side.

62 and recorded two measures: (i) the mystacial electromyogram ( nabla EMG) as a surrogate of vibrissa p

63 Electromyogram observations indicate that levodopa-induc

64 Electromyograms obtained from three hindlimb extensors o

65 SMC-EEG)] and a motor neuronal pool [surface electromyogram of opponens pollicis (OP-EMG)], and their

66 ple in the nasal cavity and whisking with an electromyogram of the mystacial pad in rats engaged in a

67 Electrocorticogram activity, flow, volume, electromyograms of laryngeal abductor and adductor muscl

68 rable, high-fidelity recording of swallowing electromyograms on the chin.

69 for recording the electroencephalogram, neck electromyogram, PGO waves, and diaphragm electromyogram.

70 recordings were made simultaneously with the electromyogram recorded from contralateral finger muscle

71 the trisynaptic (fast, R1) component of the electromyogram recorded in the rat orbicularis oculi (oo

72 component of the startle reflex measured by electromyogram recording.

73 o coherence between magnetoencephalogram and electromyogram recordings at the tremor frequency, indic

74 were obtained from decomposition of surface electromyogram recordings.

75 ate, skin conductance, and orbicularis oculi electromyogram responses were measured.

76 Spectral analysis of the electromyogram signals showed a significant low-frequenc

77 Using surgical manipulations and electromyograms, the authors show that (a) the head and

78 Effects in ipsilateral electromyogram to trains of stimuli were recorded at 45

79 In 21 healthy adults, we recorded submental electromyograms, videofluoroscopic images of the upper a

80 An electromyogram was categorized as minimal or a minor inc

81 Using EEGs and electromyograms, we show that acute light induces sleep

82 oring respiratory activity through diaphragm electromyogram, which allowed us to estimate nasal airfl

83 Both had myopathic electromyogram with abnormal electrical irritability and

84 l electroencephalogram (EEG) and neck muscle electromyogram with the electrooculogram and pontine EEG