ライフサイエンスコーパス: field stimulation

1 neurostimulation techniques (e.g., cutaneous field stimulation).

2 release of [3H]acetylcholine in response to field stimulation.

3 ains by employing weak, alternating magnetic field stimulation.

4 to cholecystokinin octapeptide or electrical field stimulation.

5 ulated with a muscarinic agonist or electric field stimulation.

6 rebound responses similar to the response to field stimulation.

7 ory thalamic neurons to peripheral receptive field stimulation.

8 sponses to non-noxious and noxious receptive field stimulation.

9 e potential caused by extracellular electric field stimulation.

10 ted by ipsilateral rostral scratch receptive field stimulation.

11 rical brain responses associated with visual field stimulation.

12 se of [3H]NE was elicited through electrical field stimulation.

13 ncholinergic nerve stimulation by electrical field stimulation.

14 ual-evoked potentials associated with visual field stimulation.

15 enhanced contractile response to electrical field stimulation.

16 ergic neurostimulation initiated by electric field stimulation.

17 ntractile responses to CCh and to electrical field stimulation.

18 rmal spontaneous Ca(2+) release events after field stimulation.

19 es of anesthetized mice in response to local field stimulation.

20 PY overflow increased 0 s and 30 s following field stimulation.

21 nd centralized rotors by optical S1-S2 cross-field stimulation.

22 arterioles was assessed at 0 s and 30 s post-field stimulation.

23 ng bilateral compared with unilateral visual field stimulation.

24 stimulation and phase two started 35 s after field stimulation.

25 and prVEP amplitude evoked by full- and half-field stimulation.

26 e of FM4-64 only during the initial phase of field stimulation.

27 cted to increasingly faster pacing rates via field stimulation.

28 NEP) using alternating current (ac)-magnetic field stimulation.

29 , and their frequency could be elevated with field stimulation.

30 Nerves were stimulated with electrical field stimulation (0.1-20 Hz, 4-60 s) and the associated

31 beta(1)-adrenergic stimulation or electrical field stimulation (0.1-3 Hz) or both.

32 Field stimulation (1 Hz) of cells or exposure of quiesce

33 d 1000 ms) and SNA was initiated using local field stimulation (30-50 V; 1 ms at 2, 8 and 16 Hz).

34 on with elevated KCl or patterned electrical field stimulation (50 biphasic rectangular pulses of 25

35 ntitate the overflow of ADPR upon electrical field stimulation (8 Hz, 0.3 ms, 15 V, 1-2 min) of both

36 Slow waves evoked by electrical field stimulation actively propagated from end to end of

37 ty were evaluated using video microscopy and field stimulation after exposure to osmotic stress at 37

38 ning both a nearly normal twitch response to field stimulation and a robust positive inotropic respon

39 interactive effects of pulsatile electrical field stimulation and substrate topography on cell diffe

40 ion channels using extracellular electrical field stimulation and voltage-sensitive fluorescent prob

41 lar [Ca2+] was monitored using fura-2 during field stimulation and while membrane potential was contr

42 e cell membrane under conditions of electric field stimulation, and a counterbalancing interplay betw

43 Delta) preparations, responses to electrical field stimulation are nearly abolished despite persisten

44 contraction of bladder strips to electrical field stimulation, as well as activation with carbachol,

45 In control experiments, field stimulation at 0.5 Hz evoked about 66 +/- 5% desta

46 ended in an organ bath at 37 degrees C, with field stimulation at 1 Hz.

47 Field stimulation at 10 Hz evoked exocytosis (36 +/- 18%

48 om wild-type (WT) mice, [Na](i) increased on field stimulation at 2 Hz from 11.1+/-1.8 mmol/L to a pl

49 Ad-FKBP12.6 group compared to Ad-LacZ (1 Hz field stimulation at 37 degrees C).

50 We investigated the effects of electrical field stimulation (average frequency 2 Hz) in an irregul

51 In the normal homozygous mice, electrical field stimulation caused a biphasic response, an initial

52 auditory cortex (AC stimulation) under free field stimulation conditions using a two-tone inhibition

53 big brown bat, Eptesicus fuscus, under free-field stimulation conditions.

54 inferior collicular (IC) neurons under free field stimulation conditions.

55 uth than at contralateral azimuth under free-field stimulation conditions.

56 P, overflow of beta-NAD evoked by electrical field stimulation correlated with stimulation frequency

57 ed by myography, and responses to electrical field stimulation determined.

58 cholinergic responses elicited by electrical field stimulation (EFS) (8 Hz, 1 ms, 8 V for 10 s every

59 ergic (NANC) nerve stimulation by electrical field stimulation (EFS) (either short-train or continuou

60 ular transmission was achieved by electrical field stimulation (EFS) (frequency, 10 Hz; pulse voltage

61 es min(-1) using 0.1 ms pulses of electrical field stimulation (EFS) (three pulses delivered at 3-30

62 of the guinea pig vas deferens to electrical field stimulation (EFS) and norepinephrine (NE) exocytos

63 t treatment vs. neurostimulation by electric field stimulation (EFS) in bovine tracheal smooth muscle

64 xation responses were assessed by electrical field stimulation (EFS) in presence of A(2B)AR agonists,

65 S was induced by CO, NO, VIP, and electrical field stimulation (EFS) in the presence and absence of n

66 Electric field stimulation (EFS) increased [Ca2+]i, MLCK activati

67 High-frequency electrical field stimulation (EFS) of distal colon segments produce

68 on evoked by exogenous purines or electrical field stimulation (EFS) of enteric neurons.

69 rgic stimulation by NO donors and electrical field stimulation (EFS) of intrinsic enteric inhibitory

70 ne, guanethidine and propranolol, electrical field stimulation (EFS) of the atrial preparations evoke

71 Electrical field stimulation (EFS) only increased pT38.

72 s in an organ bath in response to electrical field stimulation (EFS) under nonadrenergic, noncholiner

73 of intrinsic excitatory nerves by electrical field stimulation (EFS) were also compared.

74 one, vasoconstrictor responses to electrical field stimulation (EFS) were not attenuated by vitamin E

75 ses, frequency-response curves to electrical field stimulation (EFS) were performed with results expr

76 resides in the combination of the electrical field stimulation (EFS) with data acquisition in spatial

77 measured in the basal state, after electric field stimulation (EFS), ganglionic stimulant dimethyl d

78 Electrical field stimulation (EFS), which releases ACh from nerves,

79 lium acts as a crucial sensor for electrical field stimulation (EFS)-enhanced osteogenic response in

80 icromol/L atropine did not affect electrical field stimulation (EFS)-induced contraction.

81 gs of (i) caffeine-induced-, (ii) electrical field stimulation (EFS)-induced force, (iii) pCa-force,

82 d contractions in cardiomyocytes by electric field stimulation (EFS).

83 onse of tracheal smooth muscle to electrical field stimulation (EFS).

84 After electrical field stimulation (EFS, 10 Hz; 1 min) NK1R-LI was intern

85 n to ATP and norepinephrine (NE), electrical field stimulation (EFS, 4-16 Hz, 0.1-0.3 ms, 15 V, 60-12

86 ons were stimulated for 60 s with electrical field stimulation (EFS; vas deferens), dimethylphenylpip

87 d and pressurized in a microvessel bath with field stimulation electrodes.

88 nd pressurized in a microvessel chamber with field stimulation electrodes.

89 Electrical field stimulation evoked purinergic inhibitory junction

90 e epilepsy were exposed to weak, DC magnetic field stimulation following computer-controlled protocol

91 eased the contractile response to electrical field stimulation for 48 hours after administration.

92 neurotransmitters or evoked by extracellular field stimulation from a cochlear implant.

93 Field stimulation (FS) of single ventricular myocytes el

94 after spontaneous contraction or short-term field stimulation fusion activity increased in cardiomyo

95 Electrical field stimulation gave rise to frequency-dependent relax

96 Diastolic field stimulation has been much less studied than systol

97 tage (V(m)) of cardiac cells during electric field stimulation have a complex spatial- and time-depen

98 tylcholine release in response to electrical field stimulation in both the stomach and small intestin

99 siologically relevant patterns of electrical field stimulation in culture, including tonic stimulatio

100 spatially resolved Ca(2+) transients during field stimulation in left ventricular (LV) myocytes from

101 lateral and unilateral left and right visual field stimulation in normal and compromised systems.

102 Using cross-field stimulation in this model, we obtained a stable se

103 Electric field stimulation increased RLC phosphorylation and forc

104 oth muscle hyperresponsiveness to electrical field stimulation, indicating that IgE/CD23-mediated imm

105 Over only 8 days in vitro, electrical field stimulation induced cell alignment and coupling, i

106 Action potentials elicited by field stimulation induced transient increases of intrace

107 These measurements suggest that field stimulation-induced somatic Ca2+ responses in hipp

108 de of the somatic Ca2+ increase triggered by field stimulation is independent of the extracellular Ca

109 urred spontaneously and could be evoked with field stimulation: large, rapid, global Ca2+ transients

110 The field-stimulation-mediated BDNF secretion depends on the

111 ations related to a specific set of magnetic field stimulations occur.

112 Electrical field stimulation of colonic muscles inhibited slow wave

113 results are consistent with predictions from field stimulation of continuous representations of myoca

114 much has been learned about BDNF function by field stimulation of hippocampal neurons, it is not know

115 ectrical activity or responses to electrical field stimulation of intrinsic nerves in these mice.

116 ansmission have used indiscriminate electric field stimulation of neural elements within the gastric

117 potentiation of the contractile response to field stimulation of perfused rat caudal artery.

118 Using electrical field stimulation of primary cultures of hippocampal neu

119 Superfusion and electrical field stimulation of rat hippocampal brain slices were u

120 the ciliary nerves in the eye, or electrical field stimulation of the cornea, evoked Ca2+ transients

121 In response to field stimulation of the cremaster muscle (0.5, 1, 3 Hz)

122 testinal peptide (VIP) and direct electrical field stimulation of the intrinsic innervation; inhibiti

123 ing, and function was assessed by electrical field stimulation of tracheas in the presence/absence of

124 Field stimulation of ventricular myocytes co-cultured wi

125 inantly observed in the contralateral visual field, stimulation of hMST also affected the ipsilateral

126 , but did contract in response to electrical field stimulation or carbamoylcholine.

127 which do not relax in response to electrical field stimulation or L-arginine.

128 ng fluorescence technologies with electrical field stimulation or the patch-clamp technique in beatin

129 ty to neuropeptide Y (P<0.05) and electrical field stimulation (P<0.05) in mesenteric arteries was al

130 USA) delivers percutaneous electrical nerve field stimulation (PENFS) in the external ear to modulat

131 For cells undergoing field stimulation, phi(i) acts as the cellular physiolog

132 ion of skeletal muscle fibres via electrical field stimulation produced a vasodilatation (19.4 +/- 1.

133 so demonstrate that near-threshold diastolic field stimulation produces activation of deep myocardial

134 After external electric field stimulation pulses were applied, to admit Ca(2+) v

135 Electrical field stimulation releases ACh from nerves to increase R

136 imetic actuation when controlled by electric field stimulation results in movement similar to that of

137 teries subjected to low-frequency electrical field stimulation revealed Ca2+ transients in perivascul

138 OFF-centre RGC responses were evoked by full-field stimulation, significantly fewer converted that re

139 Ca2+ transients were induced by field stimulation, square wave voltage steps, or action

140 ATP, and a reduced contraction to electrical field stimulation, suggesting altered P2X1 receptor func

141 (IJPs) and relaxations evoked in response to field stimulation (supramaximal voltage, 0.1 ms, single

142 mbining fluorescence imaging with electrical field stimulation, the patch-clamp method and knock-out

143 Primary cilia are sensors of electrical field stimulation to induce osteogenesis of human adipos

144 nvestigate the use of low intensity electric field stimulation to perturb the spiral wave.

145 owed similar patterns of surface labeling by field stimulation to those shown previously by high pota

146 emonstrate that transcranial static magnetic field stimulation (tSMS) over the somatosensory parietal

147 Transcranial static magnetic field stimulation (tSMS) was recently introduced as a pr

148 Maximum sarcomere shortening elicited by field stimulation was graded in the order: LVendo > LVep

149 oline (ACh) or noradrenaline (NA) release to field stimulation was measured 4 months after gene trans

150 ction potentials (S-IJPs) evoked by electric field stimulation was significantly higher in CSE-KO mou

151 cy-dependent relaxation evoked by electrical field stimulation was significantly lower in gallbladder

152 Electrical field stimulation was used to contract the cremaster mus

153 Electrical field stimulation was used to excite parasympathetic ner

154 cell activity responses to somatic receptive fields stimulation, was compared between anesthetized ca

155 onophosphate elevations evoked by electrical field stimulation were diminished markedly in both nNOSD

156 C-acetylcholine (ACh) released by electrical field stimulation were measured simultaneously in strips

157 C]acetylcholine (ACh) released by electrical field stimulation were measured simultaneously in strips

158 in perilesional cortex in response to blind field stimulation, whereas the others did not.

159 art cell contractility inducible by electric field stimulation with directionally dependent electrica

160 durable in solution and responds to electric field stimulation with flexible movement.

161 tment spiking neurons responding to electric field stimulation with small incremental polarization.

162 Electrical field stimulation yielded fast excitatory junction poten