ライフサイエンスコーパス: low-voltage

1 ending on the frequency applied at sustained low voltage.

2 < 10% of left atrial surface area) of atrial low voltage.

3 mely thin electrodes, and can be actuated at low voltage.

4 duce an even-distributed electric field with low voltage.

5 n improve mapping resolution within areas of low voltage.

6 l (LEC), the polymer emits infrared light at low voltage.

7 vice is also capable of providing heat under low voltage.

8 ing the load vanishes to enable switching at low voltage.

9 of basal LV epicardial > endocardial bipolar low voltage.

10 ropy of NiFe can be electrically modified by low voltages.

11 nce the OFET transconductance when driven at low voltages.

12 that leads to inefficient electrophoresis at low voltages.

13 r reverse bias allows for strong adhesion at low voltages.

14 strates and scaled the devices to operate at low voltages.

15 um-ion insertion to produce shape changes at low voltages.

16 nnels, unique CaV1 channels that activate at low voltages.

17 on to achieve gigahertz digital switching at low voltage (0.1 V).

18 /VF; they were found to have unique abnormal low voltage (0.94+/-0.79 mV), prolonged duration (132+/-

19 hieve simultaneous high-speed (25 Gb s(-1)), low-voltage (0.5 VPP) and efficient 0.9 fJ per bit error

20 roducible rectification ratios above 1000 at low voltage (2.7 V).

21 le electrochemical actuators that operate at low voltages (200 microvolts), low power (10 nanowatts)

22 uid chromatography (GLC) in combination with low voltage (30 eV) electron ionization ion trap mass sp

23 and reactivity with the SWNT, as revealed by low-voltage aberration-corrected high-resolution transmi

24 VI only and patients requiring PVI+selective low-voltage ablation (P = 0.42).

25 dual cell trapping and electroporation using low voltage AC fields.

26 We found that the increased activity of low voltage activated T-type calcium channels induced by

27 We also find evidence for high expression of low-voltage activated Ca(2+) channels in the same region

28 ity induces rapid Ca(2+) signals mediated by low-voltage activated Ca(2+) channels under strict inhib

29 These data identify a role of low-voltage activated calcium channels in synaptic plast

30 Mitral cells express low-voltage activated Cav3.3 channels on their distal ap

31 The present study tested the hypothesis that low-voltage activated Kv1 channels affect threshold dyna

32 mall molecule that has been shown to inhibit low-voltage activated T-type Ca(2+) channels (TCCs).

33 After 24 h in NA, additional low-voltage activated transient Ca(2+) current developed

34 alocytes in noradrenaline for 24 h induced a low-voltage activated transient Ca(2+) current whose pha

35 Voltage clamp recordings revealed transient low voltage-activated (LVA) currents with activation bet

36 g Ca(2+) channel subunit Ca(V)3.2 mediates a low voltage-activated (T-type) Ca(2+) current (I(CaT)) t

37 These channels are low voltage-activated calcium channels that play a key r

38 annels coimmunoprecipitate and interact with low voltage-activated Cav3.2 Ca(2+) channels at the nano

39 d Ca(2+) channels (Ca(v)1.3) responsible for low voltage-activated L-type Ca(2+) current.

40 erbalancing the suppression of EPSP peaks by low voltage-activated potassium channels.

41 The M-current is a low voltage-activated potassium current generated by neu

42 action potential firing by suppression of a low voltage-activated potassium current, M-current.

43 and has been considered electrically silent, low voltage-activated T-type Ca(2+) channels are assumed

44 recent evidence that H2 S is a modulator of low voltage-activated T-type Ca(2+) channels, and discri

45 Low voltage-activated T-type Ca(v)3.2 calcium channels a

46 ras between P/Q channels and Gem-insensitive low voltage-activated T-type channels, we identify a reg

47 ure, at 23 A resolution, for a member of the low voltage-activated voltage-gated calcium channel fami

48 ntaining TN cells examined, we recorded both low-voltage-activated (LVA) and high-voltage-activated (

49 Ca(2+) channels, only OFF RGCs also express low-voltage-activated (LVA) Ca(2+) channels.

50 modifier toxins have been reported to target low-voltage-activated (LVA) calcium channels, and the st

51 revealed that MDIMP binds preferentially to low-voltage-activated (LVA) channels.

52 inent high-voltage-activated (HVA) and small low-voltage-activated (LVA) macroscopic (whole-cell) Ca

53 trous oxide's selective inhibition of CaV3.2 low-voltage-activated (T-type) calcium channels in pain

54 ptic hyperpolarization and deinactivation of low-voltage-activated Ca(2+) channels.

55 D3 receptor activation was found to regulate low-voltage-activated CaV3.2 calcium channels localized

56 maturing (P7-P9) type I hair cells acquired low-voltage-activated channels that shortened the rise t

57 inner-ear mechanisms (transducer adaptation, low-voltage-activated channels, nonquantal transmission,

58 lts showing that MDIMP preferentially blocks low-voltage-activated channels.

59 d more simply on the selective expression of low-voltage-activated ion channels by irregular afferent

60 signal with temporal precision depends on a low-voltage-activated K(+) conductance (gKL) and a hyper

61 uctances are relatively small, in particular low-voltage-activated K(+) conductances (K(LVA)).

62 These immature nodal structures lacked low-voltage-activated KV1.1 which was not enriched at ju

63 Thus, potentiation of a low-voltage-activated L-type current by synaptically rel

64 of type I hair cells is the expression of a low-voltage-activated outward rectifying K(+) current, I

65 named the calyx, and by the expression of a low-voltage-activated outward rectifying K(+) current, I

66 A strong, low-voltage-activated potassium conductance (g(KL)) at t

67 A low input resistance and activation of a low-voltage-activated potassium conductance that are cha

68 rolling subthreshold synaptic integration: a low-voltage-activated potassium current (I(K-LVA)) and a

69 r regular firing phenotype, due to different low-voltage-activated potassium currents.

70 nd genetic data indicate a prominent role of low-voltage-activated T-type calcium channels (T-channel

71 e for calcium entry into T cells-through the low-voltage-activated T-type CaV3.1 calcium channel.

72 oes occur, but there is little evidence that low-voltage-activated, Ca(v)3 ("T-type"), channels take

73 , voltage ramps revealed a non-inactivating, low-voltage-activated, nimodipine-sensitive current that

74 v)3.1-Ca(v)3.3 constitute the T-type, or the low-voltage-activated, subfamily, the abnormal activitie

75 itability of these neurons, secondary to the low voltage-activating, noninactivating K(V)7/M channels

76 tivated potassium conductance, G(BK) , and a low-voltage-activating delayed rectifier, G(K(LV)) , tha

77 pression events that are associated with EEG low voltage activity events, which correlate with transi

78 providing scar-related EP characteristics of low voltages, altered SR activation, electrogram fragmen

79 e) use of real-time modeling of conventional low-voltage alternating-current impedance spectroscopy t

80 h these electrodes could be smaller than the low-voltage aluminum electrolyte capacitors that are typ

81 d easily with carbon nanotube (CNT)-assisted low-voltage ambient ionization mass spectrometry.

82 ENODe switches at low voltage and energy (<10 pJ for 10(3) mum(2) devices)

83 The agreement between low voltage and fat on multidetector computed tomography

84 We attribute the low voltage and high rate capability of disordered rock

85 se scar [DS] and low voltage areas, unipolar low voltage and penumbra areas) and morphology character

86 e which enables the separation of ions using low voltages and has a theoretically unlimited mass rang

87 Here, we report low-voltage and high-performance digital and analog CNT

88 egative predictive value for poor outcome of low-voltage and isoelectric electroencephalogram pattern

89 for predicting poor neurological outcome of low-voltage and isoelectric electroencephalogram pattern

90 t have characteristics of reduced amplitude (low voltage) and fractionation.

91 l limit, in both the variable-range-hopping (low-voltage) and sequential-tunnelling (high-voltage) re

92 c arrest, the combined group of isoelectric, low voltage, and "burst-suppression with identical burst

93 imately 500 mJ/m(2) to near zero) using very low voltage, and the change is completely reversible.

94 of the generated high-voltage for practical low-voltage applications is still under investigation.

95 lose to the visible spectrum with remarkably low voltages ( approximately 3 V).

96 These TFTs operate at low voltages (approximately 4.0 V) and exhibit good visi

97 llation (AF), left atrial diameter (LAD) and low voltage area (LVA) are intermediate phenotypes that

98 e, across the spline, HD wave solution); the low voltage area and late potential areas were compared.

99 Mean total low voltage area in patients with ICM was 101 +/- 55 cm(

100 Within the total low voltage area, vLP were observed more frequently in I

101 normal innervation (<50% tracer uptake), and low-voltage area (<1.5 mV), respectively.

102 <5 mm area was smaller than the endocardial low-voltage area (54 cm(2) [Q1-Q3, 46-92] versus 71 cm(2

103 atients with nonischemic cardiomyopathy, the low-voltage area by far exceeded the area accounted for

104 The median low-voltage area drawn by the HD wave configuration was

105 r amplitude <0.5 mV) with a 47% smaller very low-voltage area identified using 1-mm electrode cathete

106 In patients without cardiomyopathy, the low-voltage area matched well with the area of epicardia

107 The extent of bipolar RV endocardial low-voltage area was a powerful predictor of arrhythmic

108 nervation, 47.8 cm(2) [40.5-68.1 cm(2)]; and low-voltage area, 29.5 cm(2) [24.5-102.6 cm(2)]; P > 0.0

109 rget DZ, representing ablation of 18% of the low-voltage area.

110 The presence and extent of LA low voltage areas may influence the long-term outcomes a

111 The presence of LA low voltage areas was a predictor of 12-month AF recurre

112 diofrequency catheter ablation of AF, but LA low voltage areas were more frequently observed in patie

113 LA low voltage areas were observed in 46% of patients with

114 Left atrial (LA) low voltage areas were semiquantitatively estimated and

115 ysis of voltage (bipolar dense scar [DS] and low voltage areas, unipolar low voltage and penumbra are

116 All patients had unipolar low voltage areas, whereas 18% had no identifiable endoc

117 MetS was an independent predictor of LA low voltage areas: odds ratio, 11.64; 95% confidence int

118 Low-voltage areas (<1.5 mV) and local abnormal ventricul

119 Low-voltage areas (<1.5 mV) were commonly identified on

120 rval, 1.4-8.8; P=0.03) and extent of bipolar low-voltage areas (hazard ratio=1.7 per 5%; 95% confiden

121 atrial voltage mapping, PVI, and ablation at low-voltage areas (LVA < 0.5 mV in AF) associated with e

122 All patients showed low-voltage areas (LVA) at electroanatomical map (97% ep

123 blation of atrial fibrillation (AF) based on low-voltage areas (LVAs) in the left atrium (LA).

124 blation procedure, precisely identifying the low-voltage areas and quickly visualizing the diastolic

125 elping to identify propagating activation in low-voltage areas from nonconducting tissue.

126 was 28.9 cm(2), 13% and 15% smaller than the low-voltage areas identified by the along and across con

127 estimated burden of bipolar versus unipolar low-voltage areas of 24.8% (7.2-31.5) and 64.8% (39.8-95

128 With median bipolar and unipolar low-voltage areas of 37 and 116 cm(2), respectively, 22%

129 The bipolar and unipolar low-voltage areas were compared, and direct electrogram

130 , abnormal electrograms disappeared, whereas low-voltage areas were replaced by scar areas (<0.5 mV)

131 ured following periods of calendar ageing at low voltages, at and well below the manufacturer's recom

132 were collected from an area with discordant low-voltage bipolar/normal unipolar EVM and they showed

133 nificant differences in bipolar and unipolar low-voltage characterization of scar were observed with

134 This approach is readily applicable to low-voltage circuit integration, as this work exemplifie

135 nt remaining challenge is the achievement of low-voltage circuit operation.

136 ADVICE 4: Monopolar hemostatic forceps with low-voltage coagulation can be an effective alternative

137 The low voltage combined with a higher density than graphite

138 Low-voltage complementary circuits comprising n-type and

139 Printed low-voltage complementary inverters based on electrolyte

140 Our approach enables low-voltage complementary n-type and p-type transistor o

141 ide 3-kinase blocker wortmannin, whereas the low-voltage component is not.

142 tES) is a neuromodulatory technique in which low voltage constant or alternating currents are applied

143 ic (FM) based heterostructures which exhibit low voltage-controlled magnetic anisotropy (VCMA) effici

144 zing the performance of MeRAM devices is the low voltage-controlled magnetic anisotropy (VCMA) effici

145 Here, the first report of low-voltage-controlled molecular release with a novel or

146 etween the areas of WT <5 mm and endocardial low voltage (correlation-R=0.82; P=0.001), but no such c

147 Importantly, 54.4% of all low voltage data points recorded with 1-mm electrode cat

148 ielectric constant gate insulator layers for low-voltage device operation.

149 efficient conditioning circuit for powering low-voltage devices using triboelectric nanogenerators.

150 Unipolar low-voltage distribution in nonischemic cardiomyopathy a

151 o weakly or highly anisotropic attractive by low-voltage electric fields.

152 Low-voltage electric pulses permeabilize a small area of

153 eates passive contraction of muscles through low-voltage electrical impulses delivered through skin e

154 -micrometer electrodic cavity, which enables low-voltage electrical operation of pi-gels.

155 of the soft elastronic arrays for localized low-voltage electrical stimulation of the sciatic nerve

156 theoretical challenges and possibilities for low-voltage electro-optic devices.

157 indings provide new fundamental insight into low-voltage electroadhesion and broaden its possible app

158 rate the possibility to set up an efficient, low-voltage, electrochemical cell that converts CO2 into

159 Isoelectric or low-voltage electroencephalograms after 24 hrs predicted

160 use of unipolar EVM unmasked >/=1 region of low-voltage electrogram affecting 26.2% (11.6-38.2) of R

161 e only independent predictor was the bipolar low-voltage electrogram burden (hazard ratio=1.6 per 5%;

162 The LP were defined as low voltage electrograms (<1.5 mV) with onset after the

163 ent bipolar (<1.5 mV) and unipolar (<6.0 mV) low-voltage electrograms was estimated using the CARTO-i

164 emonstrate a novel type of high-temperature, low-voltage electromechanical oxide actuator based on th

165 ) nanosheets are poised to be at the core of low-voltage electronic device development.

166 A low voltage electropolishing of metal wires is attractiv

167 Patterns were classified as isoelectric, low voltage, epileptiform, burst-suppression, diffusely

168 To test the safety of the batteries at low voltages, external short-circuit tests were performe

169 sy can be classified as hypersynchronous and low-voltage fast according to their onset patterns.

170 ry cortex that resembles focal seizures with low-voltage fast activity at onset observed in humans.

171 G) bursts of slow waves contrasting with the low-voltage fast desynchronized activity of REM sleep.

172 bral cortex and REM sleep by an "activated," low-voltage fast electroencephalogram (EEG) paradoxicall

173 200 Hz) and fast ripples (250-500 Hz) during low-voltage fast-onset (LVF) and hypersynchronous-onset

174 optogenetically induced seizures had similar low-voltage fast-onset patterns.

175 Experimental evidence suggests that low-voltage fast-onset seizures mainly result from the s

176 interneuronal networks in the initiation of low-voltage fast-onset seizures.

177 ation of 4-aminopyridine), the initiation of low-voltage, fast and of hypersynchronous onset seizures

178 It has been suggested that the low-voltage, fast onset pattern is mainly contributed by

179 genetic activation of interneurons displayed low-voltage, fast onset patterns that were associated wi

180 assified, based on their onset pattern, into low-voltage, fast versus hypersynchronous onset seizures

181 Although demonstrated on silicon, low-voltage field ionization can be detected on any shar

182 Here, we report the fabrication of a low-voltage field-effect transistor with a vertical vacu

183 The low-voltage field-ionization phenomena observed here can

184 e functionality of ion gels by demonstrating low-voltage, flexible electrochemiluminescent (ECL) devi

185 switch on intercalation at an unprecedented low voltage for an oxide?

186 g high concentrations of salt and relatively low voltage for the spray.

187 on threshold" that differentiated functional low voltage from nonconducting areas for each map.

188 getically coupled during the activation of a low voltage-gated T-type CaV3 channel.

189 analyzed the voltage dependence of high- and low-voltage-gated Ca(2+) channels.

190 dies emphasized the importance of the T-type low-voltage-gated calcium channels (VGCC) in different c

191 ecordings and computational modeling, that a low-voltage-gated potassium current, IKLT, underlies the

192 l, likely because maturing VGNs also acquire low-voltage-gated potassium currents (I (KL)), whose inh

193 ng is inversely correlated to the density of low-voltage-gated potassium currents (I (KL)).

194 Low-voltage-guided substrate modification is an emerging

195 tive and improved objective image quality of low-voltage half-dose CT angiograms compared with standa

196 60) light emitting diodes exhibit a distinct low voltage (half-bandgap) threshold for emission.

197 quid gating on a functional thin film with a low voltage has drawn a lot of attention due to rich che

198 capable of overcoming this effect, allowing low-voltage high-mobility operation.

199 showed high wall stress was associated with low voltage (ie, <0.5 mV) and electrical scar (ie, <0.05

200 he patients, whereas EVM identified areas of low voltage in 61%.

201 ultiple molecules into various cell types at low voltage in a dosage-controlled manner.

202 ro pre-treatment of samples and operation at low voltages in a direct electron transfer mode.

203 in Xenopus oocytes and measured the onset of low-voltage inactivation under two-electrode voltage cla

204 emiquantitatively estimated and presented as low voltage index.

205 rence increased with 84.5% for every unit of low voltage Index.

206 ide, mineralocorticoid receptor antagonists, low voltage, ineligibility for chemotherapy, response to

207 ction into the chemisorbed molecular ring at low voltage, injection into the physisorbed molecular ri

208 nt for the future design and optimization of low-voltage intercalation anodes for lithium batteries.

209 his work provides a basis for development of low-voltage ionization sensors.

210 anic complexes further enhances the scope of low-voltage ionization.

211 electric-field-driven magnetic switching at low voltage is achievable by design.

212 Markedly, these devices operated at very low voltages (less than 500mV) and were able to monitor

213 This is compared with low-voltage lithium intercalation for unstrained MoS2.

214 achieve high external quantum efficiency and low voltage loss for OSC.

215 Both devices exhibited a low voltage loss of 0.57 V and high short-circuit curren

216 In particular, the low voltage loss of these cells implies a remarkably low

217 ory requirements of non-volatility and fast, low-voltage (low-energy) switching has proved challengin

218 illators, constructed from high-performance, low-voltage, low-hysteresis CdSe nanocrystal field-effec

219 ufficient to treat patients with left atrial low voltage < 10%.

220 ed in voltage attenuation and best separated low voltage (<1.5 mV) from normal voltage (>/=1.5 mV; se

221 polar switching memory characteristics, with low voltage (<1.5 V) operation, no significant retention

222 -effect mobility of 91 cm(2) V(-1) s(-1), at low voltage (<5 V).

223 ive inorganic semiconductor function well at low voltages (<+/-4.0 V).

224 Our results show that a low-voltage (<0.4 V) LEEFT has no obvious effect on the

225 voltage and LGE CMR signal intensities with low voltage occurring across a large range of signal int

226 Moreover, we achieve 10 mA cm(-2) at a low voltage of 1.44 V for 48 h in basic media for overal

227 erall-water-splitting with 10 mA cm(-2) at a low voltage of 1.64 V is achieved using the ternary elec

228 ensities of 500 and 1000 mA cm(-2) at record low voltages of 1.608 and 1.709 V, respectively, for ove

229 g-time stable and can be induced by applying low voltages of 200 mV.

230 otension and cyanosis, pericardial effusion, low voltage on the electrocardiogram, marked elevation o

231 The impact of low voltages on microbial attachment to electrically con

232 tform enables straightforward integration of low-voltage, on-chip EOPs into portable microfluidic dev

233 ge hole mobilities up to 17.2 cm(2)/(V.s) in low-voltage operating devices.

234 Low-voltage-operating organic electrochemical light-emit

235 ansmission electron microscope optimized for low voltage operation can resolve and identify the chemi

236 ents down to 6 x 10(-9) A cm(-2) that enable low voltage operation of p-type semiconducting single-wa

237 stance than interconnection wire resistance, low voltage operation, low power consumption, long-term

238 lies that exhibit a practical combination of low-voltage operation and efficient electrochromic switc

239 d swing (SS) in transistors is essential for low-voltage operation and lower power consumption, both

240 The combination of low-voltage operation and small capacitance implies intr

241 e application of the doping technique to the low-voltage operation of PBTTT OFETs with high-k gate di

242 o realize a platform technology that enables low-voltage operation of pixels for temporal color mixin

243 ude longitudinal-field reduction demanded by low-voltage operation plays a fundamental role, enabling

244 ole) and shows that the general paradigm for low-voltage operation via an enhanced gate-to-channel ca

245 acid to a target solution, and demonstrates low-voltage operation, high drug-delivery capacity, and

246 cal advances, such as device scalability and low-voltage operation, is achieved in the future.

247 Low-voltage organic field-effect transistors (OFETs) pro

248 ibes and correlates the threshold voltage of low-voltage organic field-effect transistors with the mo

249 Here, we present a means of addressing the low voltage output by introducing novel trimetallic nitr

250 conversion efficiencies (PCEs) has been the low voltage output caused by a molecular orbital mismatc

251 However, low power and low voltage output of MFCs typically do not allow direct

252 nstitute an important milestone in realizing low-voltage polymer transistors for solution-based analo

253 Through manipulation of channel geometry, a low-voltage power source (500 V max) was used to selecti

254 a substrate in a fraction of a second via a low-voltage pulse that drives electroosmotic flow.

255 However, low-voltage QRS complex is not a uniform finding with th

256 Low-voltage QRS complex was the sine qua non of infiltra

257 athode carbon nanotubes (CNTs) are used in a low-voltage quadrupole ion trap mass spectrometer and sh

258 In the low voltage range, a distinct drop in deadtime was obser

259 t receptor potential-like conductance in the low-voltage range, and in the high-voltage range, a Ca(2

260 RM helps to define activation through low-voltage regions and aids ablation of atrial tachycar

261 Regional myocardial WT correlates to low-voltage regions and distribution of LAVA critical fo

262 In patients with a paucity of dense, low-voltage regions identified during substrate mapping,

263 s to its ability in identifying and locating low-voltage regions.

264 The combined attributes of flexible design, low voltage requirements and lossless ion transmission t

265 mbined attributes of the flexible design and low voltage requirements for the TW-SLIM module provide

266 Endocardial voltage mapping (EVM) identifies low-voltage right ventricular (RV) areas, which may repr

267 ity of designer channels, which accounts for low-voltage sensitivity in all known temperature-gated i

268 ow great promise for flexible, low-cost, and low-voltage sensors for aqueous solutions.

269 ion atrial tachycardias are characterized by low-voltage signals that challenge current mapping metho

270 tion (PVI) plus ablation of selective atrial low-voltage sites may be more successful than PVI only.

271 y recorded cells, as well as K-complexes and low-voltage spindles in the local field potential.

272 cortical oscillations including K-complexes, low-voltage spindles, and high-voltage spindles.

273 memory trace reactivation is correlated with low-voltage spindles, it is not correlated with high-vol

274 anopore-embedded water-filter membrane and a low-voltage square-wave generator.

275 in wall stress were associated with areas of low voltage, suggestive of focal remodeling.

276 ulti-level analog states, "write" linearity, low-voltage switching, and low power dissipation.

277 uding potassium (K(ATP), A-type) and calcium low voltage T-type and high voltage L-type currents.

278 on occurring in solution was captured by the low-voltage technique.

279 dence of the differential conductance at the low voltages that operate in biological systems.

280 to produce high-mobility ZnO thin films for low voltage thin-film transistors (TFTs) and digital log

281 : structural adaptations in CaV1.3 mediate a low-voltage threshold for activation, and alterations in

282 hat amyloid-beta causes a shift from high to low voltage-threshold activated L-type Ca(2+) currents i

283 These low voltage-threshold activated L-type Ca(2+) currents w

284 hese neurons, there was a shift from high to low voltage-threshold activated L-type Ca(2+) currents,

285 c dielectric P(VDF-TrFE-CFE), we demonstrate low-voltage transistors with hole mobilities on the orde

286 Low-voltage transmission electron microscopy has shown a

287 Two origins for the low voltage turn-on have been proposed: (i) Auger assist

288 of patients in group I with a low amount of low voltage undergoing PVI only and patients requiring P

289 from an area with discordant normal bipolar/low-voltage unipolar EVM and they were diagnostic or sug

290 The nanoscale depth of the device and the low voltage used limit convection relative to diffusion,

291 It is believed that the plasma generated by low-voltage, vacuum spark, via a pulsed DC in Spark Plas

292 greater release in the hemisphere displaying low-voltage (waking) EEG activity, linking acetylcholine

293 Pacing threshold within the area of low voltage was lower with 1-mm electrode catheters (0.9

294 e of the tachycardia from within the area of low voltage was more frequent with 1-mm electrode cathet

295 an bipolar voltage amplitude in this area of low voltage was significantly higher with 1-mm electrode

296 cal abnormalities (right bundle branch block/low voltages) was developed to predict the presence of A

297 icide transformations, particularly those at low voltages, which are highly relevant to practical cyc

298 annel light-emitting transistor operating at low voltage, with low power dissipation, and high apertu

299 One treatment of 16 or 24 Gy low-voltage x-ray therapy with as-needed ranibizumab app

300 w-temperature conversion method to fabricate low-voltage ZnO transistors with electron mobilities exc