ライフサイエンスコーパス: electromechanical

1 LV mechanical discoordination exist from (1) electromechanical activation delay, (2) regional differe

2 feasible and capable of depicting the normal electromechanical activation sequence of both atria and

3 h ultrasound-based mapping of the transmural electromechanical activation sequence reliably at the po

4 Normal electromechanical activation through the His-Purkinje sy

5 oride ionophore, we found alterations in OHC electromechanical activity and cochlear amplification, w

6 thways, (4) whole-heart simulations of human electromechanical activity, and (5) what human data are

7 robust computational models of human cardiac electromechanical activity.

8 toluminescence, water uptake, mechanical and electromechanical actuation properties of the exfoliated

9 force can be generated and used directly for electromechanical actuation without the need for a high-

10 Upon electromechanical actuation, the membrane pushes a massi

11 nd unzipped graphene oxide (GO) as potential electromechanical actuator materials.

12 These electromechanical actuators produce hydrodynamic fluid p

13 ion cast and doped with Li(+) was studied as electromechanical actuators.

14 Electromechanical and CaT alternans are highly correlate

15 aries are responsible for both the anomalous electromechanical and dielectric behaviour.

16 prestin with a unique capability to perform electromechanical and mechanoelectric conversions with e

17 anical discoordination patterns arising from electromechanical and non-electrical substrates and acco

18 First, we will discuss representative electromechanical and resistance-change memory devices b

19 ich makes it a desirable candidate for novel electromechanical and stretchable optoelectronic devices

20 We characterized the electromechanical and thermal performance of the bionic

21 ment was made possible by the integration of electromechanical and thermomechanical components based

22 d, but is related to structural, electrical, electromechanical, and autonomic remodeling.

23 ansfer mechanism, as well as the mechanical, electromechanical, and mechanical resonance properties o

24 processes, suggesting its potential in micro-electromechanical applications.

25 gthscales for diverse sensing, catalytic and electromechanical applications.

26 -controlled electronics and high-performance electromechanical applications.

27 efit transducers and sensors in a variety of electromechanical applications.

28 These alterations in the electromechanical behavior of human cardiomyocytes are c

29 implicate piezoelectricity in the broad-band electromechanical behavior of OHCs underlying mammalian

30 nd eM that result from stretched exponential electromechanical behavior of SLC26a5, also known as pre

31 Furthermore, we consider electromechanical behavior such as pressure-induced chan

32 The resulting nanocomposites display unusual electromechanical behavior, such as postdeformation temp

33 unable to evaluate three-dimensional cardiac electromechanical behavior.

34 have documented the early development of OHC electromechanical behavior.

35 Flexoelectricity explains many interesting electromechanical behaviors in hard crystalline material

36 recent demonstrations of 3D MEAs to monitor electromechanical behaviors of cardiomyocytes and neuron

37 minimally invasive and scalable platform for electromechanical biosensing.

38 elective chemical adsorption, and as movable electromechanical brush contacts and switches.

39 is useful for predicting and optimizing the electromechanical characteristics of highly stretchable

40 nthesis methods, quantitative mechanical and electromechanical characterization of these nanostructur

41 mechanical interactions in a superconducting electromechanical circuit.

42 acts of a developmental nonvolatile bistable electromechanical CNT switch through its fabrication, ex

43 and the engineering of 3D heart tissues with electromechanical conditioning.

44 We sought whether left atrial (LA) electromechanical conduction time (EMT) and myocardial m

45 01), higher LAV (P<0.003), and longer septal electromechanical conduction time (P<0.01).

46 nd computational data on the hemodynamic and electromechanical consequences of left ventricular pacin

47 (channels and reaction chambers) and active electromechanical control structures (sensors and actuat

48 The chip that hosts the electromechanical control structures is called the micro

49 ity to perform direct, rapid, and reciprocal electromechanical conversion depends on membrane potenti

50 As such, the recent discovery of a large electromechanical conversion near room temperature in (1

51 of performing direct, rapid, and reciprocal electromechanical conversion.

52 be 60 pV Hz-1/2 when balanced by choosing an electromechanical cooperativity of ~150 with an optical

53 : i) with high stretchability and negligible electromechanical coupling (>600% strain); ii) with Joul

54 c stimulation with acetylcholine; and intact electromechanical coupling (evidenced by direct response

55 Molecular ferroelectrics combine electromechanical coupling and electric polarizabilities

56 Here we suggest a molecular mechanism for electromechanical coupling and gating polarity in non-do

57 rom the sarcoplasmic reticulum, and impaired electromechanical coupling at the myofibrillar level.

58 am than anticipated; moreover, the predicted electromechanical coupling at the transition is larger t

59 , a mixed junctional complex responsible for electromechanical coupling between cardiomyocytes.

60 K(+) channels (K(v) channels) depends on the electromechanical coupling between the voltage sensor an

61 establish that, in addition to the canonical electromechanical coupling between voltage sensor and in

62 ally switching one to the other yields large electromechanical coupling coefficients.

63 ower lung volume, indicating a diaphragmatic electromechanical coupling during spontaneous expiration

64 Flexoelectricity is a universal electromechanical coupling effect whereby all dielectric

65 igh actuation stresses, directional strains, electromechanical coupling efficiencies, and energy dens

66 formational transition steps having distinct electromechanical coupling efficiencies.

67 2,100 picocoulombs per newton), an excellent electromechanical coupling factor k(33) (about 94 per ce

68 lity-factors at resonance, Q r and effective electromechanical coupling factors, [Formula: see text],

69 pitaxial heterostructures exhibit very large electromechanical coupling for ultrasound medical imagin

70 Electromechanical coupling in OHCs, which enables these

71 Our results show that the high electromechanical coupling in solid solutions with lead

72 n to affect hearing through reduction of the electromechanical coupling in the outer hair cells of th

73 converging on a sliding-helix mechanism for electromechanical coupling in which outward movement of

74 In ferroelectrics, manifestation of a strong electromechanical coupling is attributed to both enginee

75 The fundamental electromechanical coupling itself can be programmed by h

76 Electromechanical coupling may represent a pathophysiolo

77 ike-induced deformations shed light upon the electromechanical coupling mechanism in electrogenic cel

78 For understanding the electromechanical coupling mechanism of prestin, we simu

79 The elasticity, electrostatics, and electromechanical coupling of the composite are investig

80 etween the S4-S5 linker and the S6 domain in electromechanical coupling of voltage-gated K(+) channel

81 ional interstitial cells of Cajal and had an electromechanical coupling that regulated waves of propa

82 sitive biosensor that utilizes the nonlinear electromechanical coupling to overcome the fundamental s

83 alize microwave resonant circuits with large electromechanical coupling to planar acoustic structures

84 tif, which introduces a kink that allows for electromechanical coupling with voltage sensor motions v

85 Electromechanical coupling, a well-described phenomenon

86 rovides key insights into fast inactivation, electromechanical coupling, and pathogenic mutations in

87 es, the structural basis of voltage sensing, electromechanical coupling, and toxin modulation remains

88 This electromechanical coupling, combined with their flexibil

89 after 5 weeks of differentiation show robust electromechanical coupling, consistent H-zones, I-bands,

90 anted in an MI area remains viable, exhibits electromechanical coupling, decreases infarct size, and

91 oltage sensor movement and pore opening, the electromechanical coupling, occurs at the cytosolic face

92 Through the angular dependence of electromechanical coupling, we determined the two-dimens

93 in the piezoelectric coefficient due to the electromechanical coupling.

94 ed to the host electrocardiogram, indicating electromechanical coupling.

95 ce is important for electric propagation and electromechanical coupling.

96 conduction pore, or modifies both aspects of electromechanical coupling.

97 molecular and ion transport, and to explore electromechanical couplings that may have a role in rece

98 a low concentration of tolbutamide prevents electromechanical decline when oxygen availability is re

99 In the intact heart, the distribution of electromechanical delay (EMD), the time interval between

100 The activation level and electromechanical delay of the muscles changed from pre-

101 a Vinci surgical system, a computer-assisted electromechanical device, provides the unique opportunit

102 evading measurements with a superconducting electromechanical device, realizing three long-standing

103 imilar to electrical circuits, which control electromechanical devices, biochemical circuits could be

104 ration of 'on-demand' printed electronic and electromechanical devices.

105 nd guidance for manufacturing graphene-based electromechanical devices.

106 l circuits have played in the engineering of electromechanical devices.

107 Electromechanical discoordination may contribute to long

108 The study sought to investigate a familial electromechanical disorder characterized by SND and NCCM

109 ine in ejection fraction with progression to electromechanical dissociation and electrocardiographic

110 e, a late Na(+) current blocker, reduced the electromechanical dysfunction of human HCM myocardium in

111 These treatments include treatment of electromechanical dyssynchrony and dysrhythmia by cardia

112 it to study right ventricular pacing induced electromechanical dyssynchrony and its reversal (resynch

113 Typical electromechanical dyssynchrony associated with mechanica

114 These pathologic changes may result in electromechanical dyssynchrony.

115 resent the first experimental evidence of an electromechanical effect from torsional strain in single

116 Electromechanical effects are ubiquitous in biological a

117 tanding and ultimately controlling the large electromechanical effects in relaxor ferroelectrics requ

118 DNA molecule during stretching, and thus the electromechanical effects of the pi-pi coupling between

119 were compared to calculations done using the electromechanical (EM) model, which does not require a s

120 he impact of the electrostatic effect on the electromechanical (EM) response in piezoresponse force m

121 scriminate the ferroelectric effect from the electromechanical (EM) response through the use of frequ

122 espond to and integrate with the surrounding electromechanical environment.

123 vity and frequency tuning are underpinned by electromechanical feedback from the outer hair cells.

124 xploration of dielectric responses to strong electromechanical fields.

125 in a magnetic field or a computer-controlled electromechanical flexible robotic system.

126 contribution of prestin to the mechanics and electromechanical force (EMF) generation of the membrane

127 We have measured electromechanical force generation by cell membranes usi

128 s of the chicken auditory papilla possess an electromechanical force generator in addition to active

129 Membrane electromechanical force production can occur at speeds e

130 (OHC) transducer current, which leads to OHC electromechanical force.

131 l traveling wave that is actively boosted by electromechanical forces in sensory outer hair cells (OH

132 C-dnO1 mice displayed normal cardiac electromechanical function and cellular excitation-contr

133 ontains many proteins that are essential for electromechanical function in general, and excitation-co

134 The electromechanical function of the heart involves complex

135 uman animal species for elucidation of human electromechanical function/activity and to identify what

136 Electromechanical instability can be effectively overcom

137 Assay automation on an electromechanical instrument produced an analytical sens

138 Second, the electromechanical integration of hESC-CMs in injured hea

139 rified the presence of proteins important in electromechanical integration of myogenic cells with sur

140 ifferentiation of stem cells, and accelerate electromechanical integration of transplanted stem cells

141 ration and differentiation, as well as their electromechanical integration.

142 oteins with capacity to disrupt intermyocyte electromechanical integrity.

143 This achievement required a large electromechanical interaction, which was obtained by emb

144 Here, we report a microfabricated electromechanical inverter with SiC complementary NEMS s

145 rafts were perfused by host vasculature, and electromechanical junctions between graft and host myocy

146 Here, we present a novel, low-field-enabled electromechanical lysis mechanism of bacterial cells usi

147 Therefore, we believe that the electromechanical lysis will not only facilitate microfl

148 evascularization contractile reserve and (2) electromechanical mapping (EMM) can identify segments th

149 ery of ABMMNCs was performed with the aid of electromechanical mapping to identify viable myocardium.

150 Electromechanical mapping was performed to identify isch

151 imulating factor, underwent an apheresis and electromechanical mapping, and were randomized to receiv

152 ardial injections guided by left ventricular electromechanical mapping.

153 nductors are an extremely important class of electromechanical materials, and this work provides cruc

154 discovery of high-performance, pure-compound electromechanical materials, which could greatly decreas

155 for this phenomenon, we used a comprehensive electromechanical mathematical model of the cochlear res

156 otal scores or subscale scores for the AIMS, electromechanical measures of dyskinesia, or scores from

157 Their electromechanical metrics are among the highest reported

158 t SPM methods, including near field optical, electromechanical, microwave, and thermal probes and com

159 However, their potential to emulate the electromechanical milieu of native tissues or conform we

160 periments, we used a modified version of the electromechanical model frog to present territorial male

161 In prior field studies with an electromechanical model frog, we were able to experiment

162 t high rates, using a biophysically detailed electromechanical model of cardiac tissue.

163 loped a novel biophysically based multiscale electromechanical model of the murine heart.

164 acing (EP) by using a new, to our knowledge, electromechanical model of the rabbit ventricles that in

165 This study used a novel multiscale electromechanical model of the rabbit ventricles to inve

166 Na(v)1.5 (encoded by SCN5A) is expressed in electromechanical organs and is mechanosensitive.

167 letion of NO-GC1 or NO-GC2 did not influence electromechanical outer hair cell (OHC) properties, as m

168 novel type of high-temperature, low-voltage electromechanical oxide actuator based on the model mate

169 length infrared radiation with unprecedented electromechanical performance and thermal capabilities.

170 The electromechanical performance of PVC gels was demonstrat

171 sensors, our main focus in this review is on electromechanical pH sensors due to their significant ad

172 e and a means to dissect basic mechanisms of electromechanical physiology and therapy.

173 hanism is described in terms of the relevant electromechanical principles, and proof-of-principle is

174 We assessed the electromechanical profile of cardiomyocytes from 26 HCM

175 ixed charge in TM constituents suggests that electromechanical properties also may be important.

176 act as nanoscale resonators with remarkable electromechanical properties and the ability to detect a

177 e crystal structure changes abruptly and the electromechanical properties are maximal.

178 Such electromechanical properties are often very complex, so

179 tunable elastic stiffness and corresponding electromechanical properties observed here suggest poten

180 Here, we report how the electromechanical properties of a 1,4'-benzenedithiol mo

181 ed CNTs is developed in order to analyze the electromechanical properties of a highly stretchable fib

182 We determined the electromechanical properties of a suspended graphene lay

183 use model of physiological aging, defects in electromechanical properties of cardiomyocytes are impor

184 This is due to the electromechanical properties of cochlear outer hair cell

185 We have explored the electromechanical properties of DNA by using an electric

186 We have explored the electromechanical properties of DNA on a nanometer-lengt

187 yer number as a powerful tool for tuning the electromechanical properties of graphene for future appl

188 and computational studies of mechanical and electromechanical properties of piezoelectric nanowires

189 e still need to improve our knowledge of the electromechanical properties of the fetal heart as well

190 ein/coupled receptor/IP3R axis modulates the electromechanical properties of the human myocardium and

191 iculum and likely contributes to the altered electromechanical properties of the hypertrophied heart.

192 s demonstrated that optical, electrical, and electromechanical properties of the resulting hybrid fil

193 ten encountered as Silly Putty, changing its electromechanical properties substantially.

194 Fitting these electromechanical properties to a spring model, we show

195 ed that CM+EC+MC ECTs possessed preferential electromechanical properties versus ECTs without vascula

196 Remarkable electromechanical properties, responsive behaviors, and

197 ulate uterine contractions, and tissue level electromechanical properties, which are responsible for

198 on the mechanical, optical, electrical, and electromechanical properties, which delineate them from

199 compositional and thermal prospectus for the electromechanical properties.

200 titative model that completely describes the electromechanical properties.

201 tor with simultaneously tailored optical and electromechanical properties.

202 attention has been given to their impact on electromechanical properties.

203 ave been characterized with respect to their electromechanical properties.

204 number of unique electronic, mechanical and electromechanical properties.

205 "tool-box" for the design of junctions with electromechanical properties.

206 nanoelectromechanical relay that eliminates electromechanical pull-in instability without restrictin

207 Part of the challenge is electromechanical pull-in instability, causing the beam

208 One metric is the OHC electromechanical ratio defined as the amplitude of the

209 The in vivo electromechanical ratio is derived from the recently mea

210 t with the literature values of the in vitro electromechanical ratio measured by others.

211 Thus, ACh triggers electromechanical relaxation of smooth muscle cells alon

212 s do signalling pathways that may complement electromechanical relaxation.

213 onventional "cut-and-sew" cartilage surgery, electromechanical reshaping (EMR) is a molecular-based m

214 nsitivity magnetoelectric sensors with their electromechanical resonance frequencies < 200 kHz have b

215 omechanical systems (NEMS) resonator with an electromechanical resonance frequency of 215 MHz based o

216 very sensitive to DC magnetic fields at its electromechanical resonance, which led to a new detectio

217 filtering that is intrinsic to the mammal's electromechanical resonance.

218 The nanowire is configured as an electromechanical resonator such that its mechanical vib

219 such as optical photons, trapped atoms, and electromechanical resonators.

220 l class of material that exhibit an enormous electromechanical response and are easily polarized with

221 nd-evoked receptor potential that induces an electromechanical response in their lateral wall membran

222 lectricity wherein electric polarization and electromechanical response is induced through strain gra

223 iting/erasure of large-area patterns of this electromechanical response is possible, thus showing a n

224 h there is a beat-to-beat alternation in the electromechanical response of a periodically stimulated

225 Variation of local electromechanical response with dc tip bias is used to d

226 rroelastic domains can significantly enhance electromechanical response.

227 ield, accompanied by a transient rise in the electromechanical response.

228 canning electron microscope show an emergent electromechanical response: a 200 nm mechanical compress

229 Electromechanical responses of a conductive fabric can b

230 hich may include gigantic electrocaloric and electromechanical responses, anomalously reduced thermal

231 sign of other lead-free materials with large electromechanical responses.

232 ell established, how the heart maintains its electromechanical rhythm over a lifetime remains an open

233 ectric materials are critical components for electromechanical sensors and actuators.

234 onal modes, enabling broad applications from electromechanical sensors to quantum bits.

235 These nanocomposites are sensitive electromechanical sensors with gauge factors >500 that c

236 r architecture with emerging concepts of the electromechanical sequence in a beating heart.

237 ple, PCR-free, optics-free approach based on electromechanical signal transduction.

238 We investigated the role of electromechanical stimulation in preventing culture-indu

239 cells, confirming that cells cultured under electromechanical stimulation presented a defined/mature

240 e in vivo environment, particularly constant electromechanical stimulation, is fundamental to the reg

241 r an additional 21 d by increasingly intense electromechanical stimulation.

242 CMW tissue properties could be tuned using electromechanical stimuli and cell composition.

243 which is concomitant with large nonvolatile electromechanical strains ( approximately 1.25%) and tun

244 Researchers have strived to optimize the electromechanical structures and to design necessary ext

245 egional scar and that we could differentiate electromechanical substrates responsive to cardiac resyn

246 s of LV mechanical discoordination caused by electromechanical substrates responsive to CRT from thos

247 ce microscope modality that locally measures electromechanical surface deformation.

248 reversible room-temperature single-molecule electromechanical switch that controllably employs the e

249 control the properties of a single-molecule electromechanical switch, which can be cycled between tw

250 lasmonic signals, either via micro- and nano-electromechanical switches or with electro- and all-opti

251 etwork of fluid-filled conduits that support electromechanical synchronicity within cardiomyocytes.

252 The relative contribution of electromechanical synchronization and ventricular fillin

253 orce while simultaneously developing into an electromechanical syncytium by disassembling focal adhes

254 is essential for the heart to function as an electromechanical syncytium.

255 mmunosensor based on an integrated bio micro-electromechanical system (Bio-MEMS) containing eight gol

256 eams is controlled by a high-precision micro-electromechanical system (MEMS).

257 ic nanowire arrays as a highly accurate nano-electromechanical system based dynamic sensor with a wid

258 tion of ULF radiation, we propose a portable electromechanical system called a Magnetic Pendulum Arra

259 Our nano-electromechanical system consumes negligible tuning powe

260 The electromechanical system Sensei consists of two steerabl

261 allenging to achieve with conventional micro-electromechanical system technologies.

262 Our platform relies on an integrated nano-electromechanical system that enables precise positionin

263 stor, micro/nano-electronic circuit and nano-electromechanical system.

264 ographie Galvanoformung Abformung-like micro-electromechanical systems (LIGA-like MEMS) for real-time

265 technique to efficiently activate micro/nano-electromechanical systems (MEMS/NEMS) resonators at thei

266 we demonstrate a novel magnetoelectric nano-electromechanical systems (NEMS) resonator with an elect

267 Cavity optomechanical or electromechanical systems achieve sideband cooling throu

268 nical energy are useful in a wide variety of electromechanical systems and in robotics, with applicat

269 e opportunities in fields ranging from micro-electromechanical systems and microrobotics, to smart in

270 Nano-electromechanical systems developed using piezoelectric

271 single crystals have triggered revolution in electromechanical systems due to their superior piezoele

272 Miniature electromechanical systems form a class of bioMEMS that c

273 lic nanotubes will enable new types of micro-electromechanical systems such as micro-electric motors,

274 tions such as coating and high stress (e.g., electromechanical systems).

275 arent electronics, optoelectronics, sensors, electromechanical systems, and energy technologies.

276 of triboelectric nanogenerator in micro/nano electromechanical systems, intelligent robots and autono

277 chip will allow solid state devices, such as electromechanical systems, to operate under new physical

278 entional time-of-flight MS (TOF-MS) and nano-electromechanical systems-based MS (NEMS-MS) in situ, we

279 er unique functionalities for electronic and electromechanical systems.

280 graphene has shown great potential for nano-electromechanical systems.

281 ductor PTJs suggest their great potential in electromechanical technology.

282 alow-energy switching of ~50 zJ, from a nano-electromechanical torsion spring at the single molecule

283 The switch is an electromechanical transducer characterized by individual

284 Here we present an electromechanical transducer that integrates a high-freq

285 mplication of this favorable scaling is that electromechanical transducers made of moving droplets, s

286 mena is critical to devising next-generation electromechanical transducers.

287 eported here suggest that passive aspects of electromechanical transduction achieve maturity in Tshrh

288 The electromechanical transduction is achieved without elect

289 e protein prestin (SLC26A5) drives an active electromechanical transduction process in cochlear outer

290 l signaling in biology depends upon a unique electromechanical transduction process mediated by the S

291 ruitment of both hair-bundle- and soma-based electromechanical transduction processes.

292 d the stretchability of the junction enables electromechanical transduction.

293 it hearts stained with ICG and perfused with electromechanical uncouplers.

294 resolution optical mapping in the absence of electromechanical uncoupling agents, the method relieves

295 limited by either low spatial resolution or electromechanical uncoupling of the beating heart.

296 including changes in perfusate temperature, electromechanical uncoupling, and acute ischemia/reperfu

297 xperimental findings for strong but not weak electromechanical (voltage-Ca(2+)) coupling, and offered

298 imulated by generation and propagation of an electromechanical wave along the syncytia.

299 In this paper, electromechanical wave imaging (EWI), a novel ultrasound

300 y sought to validate the association between electromechanical window (EMW) negativity, as derived fr