ライフサイエンスコーパス: flow velocity

1 and laser Doppler flowmetry (blood flow and flow velocity).

2 flow directionality despite increased actin flow velocity.

3 remic flow velocity but was flat for resting flow velocity.

4 n solute dispersion depending on the average flow velocity.

5 the ratio of hyperemic to resting diastolic flow velocity.

6 n arterial blood pressure and cerebral blood flow velocity.

7 t alpha increased with IS and decreased with flow velocity.

8 ctor was found to reduce with an increase in flow velocity.

9 =6) did not induce a significant increase in flow velocity.

10 ral parameters, including the electroosmotic flow velocity.

11 ciated with high mean middle cerebral artery flow velocity.

12 high, or normal mean middle cerebral artery flow velocity.

13 ildren with high mean middle cerebral artery flow velocity.

14 eference electrode voltage regardless of the flow velocity.

15 other culture apparati and is independent of flow velocity.

16 ignificant changes to the zeta potential and flow velocity.

17 equency that almost linearly scales with the flow velocity.

18 nd CVD events was mediated by hyperemic mean flow velocity.

19 dently of beta-cell expansion or islet blood flow velocity.

20 tivation, aortic valve leaflet separation or flow velocity.

21 r ion conductance and a lower electroosmotic flow velocity.

22 regular RED stack at 1.3 cm/s average linear flow velocity.

23 when these biofilms were subjected to higher flow velocity.

24 a significant increase in transaortic valve flow velocity.

25 with post-PCI increase in hyperemic coronary flow velocity.

26 gh to low permeability regions under various flow velocities.

27 as well as the loss of superfluidity at high flow velocities.

28 nts with IS have increased peak systolic CSF flow velocities.

29 ure of motions over a large dynamic range of flow velocities.

30 increased efficiencies with decreased input flow velocities.

31 umophila adhesion on these biofilm under low flow velocity (0.007 m/s) positively correlated with bio

32 that dechlorination failed at medium or low flow velocity (0.080 or 0.036 m/d).

33 chloroethene to ethene was sustained at high flow velocity (0.51 m/d), but that dechlorination failed

34 with no significant change in microvascular flow velocity (0.8+/-0.1 to 0.7+/-0.1 AU).

35 24 [adenosine]; P = .80) and coronary blood flow velocity (21% +/- 16 [hypercapnia] vs 26% +/- 27 [a

36 cm/s) and significantly less than hyperemic flow velocity (21.2+/-3 cm/s; P<0.01).

37 Hg; p < .05) and middle cerebral artery mean flow velocity (37 +/- 9 cm.sec(-1) vs. 47 +/- 10 cm.sec(

38 low velocity (E), late transmitral diastolic flow velocity (A), and early diastolic mitral annulus ve

39 ely restored for specific, arbitrarily large flow velocities above the critical velocity through quan

40 tion are limited by the fact that the lowest flow velocities accessible by simulations are orders of

41 Two different air flow velocities across the filters were explored: 0.013

42 antified the change in resting and hyperemic flow velocity after PCI in stenoses defined physiologica

43 changes at least 4-fold less than hyperemic flow velocity after PCI.

44 phy to calculate mean middle cerebral artery flow velocity after traumatic brain injury.

45 age correlation spectroscopy to quantify the flow velocities and directionality of filamentous-actin

46 underestimation was observed of intrahepatic flow velocities and flow volumes, except vessel area, wh

47 owed no change in elution times at identical flow velocities and gradient times, while peak elution w

48 LTalpha(-/-) mice exhibited reduced lymph flow velocities and increased interstitial fluid pressur

49 esented nonoverlapping intervals between low flow velocities and medium or high flow velocities (mean

50 When discriminating between low flow velocities and medium or high flow velocities, the

51 te PRO element performance with higher cross-flow velocities and power densities exceeding 8 W/m2 wer

52 electin aptamer also increased microvascular flow velocities and reduced the leukocyte rolling flux.

53 ly reduced shear stress for moderate to high flow velocities and that the maximum stress the adhesin

54 ed how lipid concentration, immiscible phase flow velocities and the device geometrical parameters af

55 In the middle cerebral artery blood flow velocities and vasomotor reactivity were measured w

56 scillatory trajectories are dependent on the flow velocity and cell orientation.

57 ghout exercise, distal coronary pressure and flow velocity and central aortic pressure were recorded

58 relationship between middle cerebral artery flow velocity and cerebral perfusion pressure in pediatr

59 th information regarding blood volume, blood flow velocity and direction, vascular architecture, vess

60 NE evoked similar decreases in femoral blood flow velocity and femoral vascular conductance (FVC) in

61 nts (9%) had low mean middle cerebral artery flow velocity and five children (12%) had high mean midd

62 LAD coronary blood flow velocity and free-breathing myocardial BOLD MR resp

63 the dynamic relation between microstructure, flow velocity and growth rate is shown to be crucial tow

64 tionship between mean middle cerebral artery flow velocity and hematocrit was also found in boys aged

65 Mean cerebral artery flow velocity and jugular vein oxygen saturation were me

66 t precision and resolution, as a function of flow velocity and particle concentration that is provide

67 nsitivity analysis explores the influence of flow velocity and particle size on nAg transport and fat

68 98 mmol/L, Baxter Healthcare) on renal blood flow velocity and perfusion in humans using magnetic res

69 intensity calculated from invasive coronary flow velocity and pressure, with native conduction (LBBB

70 nt of infusion to measure renal artery blood flow velocity and renal cortical perfusion.

71 nt of infusion to measure renal artery blood flow velocity and renal cortical perfusion.

72 re, Thetford, United Kingdom] on renal blood flow velocity and renal cortical tissue perfusion in hum

73 saline results in reductions in renal blood flow velocity and renal cortical tissue perfusion.

74 n coefficient between the CT measurements of flow velocity and the reference measurements was 0.98 (P

75 ational fluid dynamic simulations determined flow, velocity and airway pressure drops.

76 Increasing the flow velocity (and mass transfer rate) increases the pea

77 Phase wrapping was observed at all measured flow velocities, and fringe washout progressively shatte

78 relative capillary-sheath positions, buffer flow velocities, and the cell chamber design were optimi

79 e rigid static structure is larger at higher flow velocities, and this relative increase favors a mor

80 ic hemodynamics, middle cerebral artery mean flow velocity, and dynamic cerebral autoregulation evalu

81 function of cell and aptamer concentration, flow velocity, and incubation time.

82 gNPs) with various input concentration (Co), flow velocity, and ionic strength (IS), and the remobili

83 Muscle MBV, microvascular flow velocity, and microvascular blood flow (MBF) were d

84 ofilm flows like a viscous liquid under high flow velocities applied within milliseconds.

85 ea of the growing crystals, and b) the local flow velocities are above the limit at which growth is t

86 3 independent graders categorized the blood flow velocities as low, medium, or high.

87 systolic (PSV), end-diastolic and mean blood flow velocities as well as pulsatility and resistance (R

88 five stenoses (67 patients) underwent paired flow velocity assessment before and after PCI.

89 peak-systolic, end-diastolic, and mean blood flow velocities at baseline were associated with higher

90 ering results, we concluded that the passage flow velocities at the detector used in this study, 0.2,

91 relies only on already observed or validated flow velocities at the time the prediction is made.

92 arent viscosity significantly, slowing blood flow velocity at arterial oxygen tension even without ad

93 exceeds the electroosmosis-driven bulk fluid flow velocity at only the cathodic edge of the BPE.

94 dings of ascending aortic pressure and blood flow velocity at rest and with supine bicycle exercise i

95 Since the flow velocity at the measurement surface is near zero, d

96 terstitial fluid flow to calculate the fluid flow velocity at the tumor surface (v(0)) based on the r

97 al capillary blood volume (A), microvascular flow velocity (beta), and myocardial perfusion (Axbeta).

98 crepancy was due to the differences in water flow velocities between the lab and the field.

99 d the coupling between BP and cerebral blood flow velocity (BFV) using transfer function analysis.

100 79%) had normal mean middle cerebral artery flow velocity but four patients (9%) had low mean middle

101 near relationship to the change in hyperemic flow velocity but was flat for resting flow velocity.

102 ely, overestimating the corresponding actual flow velocities by 26%, 18%, and 13% and showing precisi

103 ind that near a subduction zone edge, mantle flow velocities can have magnitudes of more than ten tim

104 The observed flow velocity can be decomposed into a constant term of

105 Flow velocity can be measured from row-to-row multidetec

106 icagrelor versus prasugrel on coronary blood flow velocity (CBFV) during increasing doses of intraven

107 es in blood pressure (BP) and cerebral blood flow velocity (CBFV) in 13 healthy subjects (30 +/- 7 ye

108 In contrast, cerebral-blood-flow velocity (CBFv) in arteries and veins fluctuated at

109 ined when considering the raw cerebral blood flow velocity (CBFV) recordings.

110 Coronary blood flow velocity (CBFV) was measured by using transthoracic

111 Coronary blood flow velocity (CBV; Duplex Ultrasound), heart rate (ECG)

112 as investigated varying the parameters cross-flow velocity (CFV) and flux rate.

113 water transport through carbon nanotubes to flow velocities comparable with experimental ones using

114 artery revealed a twofold increase in blood flow velocity compared with tumor-free mice (P < 0.001).

115 echo-Doppler to characterize the transmitral flow velocity curves in various disease states.

116 ty, with no observed response at the highest flow velocity (Darcy velocity = 0.22 mm/s), where chemot

117 fraction, early and atrial peak transmitral flow velocities, deceleration time of early transmitral

118 As the narrower flow paths clog, local flow velocities decrease, which causes the progressive s

119 n (12%) had high mean middle cerebral artery flow velocity despite cerebral perfusion pressure >40 mm

120 r the resting wave-free period and hyperemic flow velocity did not differ statistically.

121 pressure gradient, stenosis resistance, and flow velocity did not reach statistical significance; ho

122 s there was increased carotid arterial blood flow velocity during late systole and diastole.

123 t measurement of early diastolic transmitral flow velocity (E) and mitral annular velocities (e') wit

124 Peak early transmitral diastolic flow velocity (E), late transmitral diastolic flow veloc

125 nd using early to late diastolic transmitral flow velocity (E/A) to assess diastolic function, and E

126 Diagnostic criteria included flow velocity elevation more than or equal to 2 sd above

127 /-50 cm/sec) and the other optimized for CSF flow (velocity encoding range, +/-10 cm/sec), with an im

128 one optimized for arterial and venous blood flow (velocity encoding range, +/-50 cm/sec) and the oth

129 : To evaluate the potential of retinal blood flow velocity estimation by structural OCT.

130 ion pressure and mean middle cerebral artery flow velocity except for hematocrit, which was lower (25

131 Two-dimensional flow velocity fields from color Doppler echocardiographi

132 This procedure yielded 3D pressure and flow velocity fields, and revealed that the migration of

133 n phases, contrast-agent dynamics, and blood flow velocity fields.

134 ologies for simultaneously quantifying blood flow (velocity, flux, hematocrit and shear rate) in exte

135 ions with different concentrations, i.e. the flow velocity for a high-concentration solution displaci

136 ex (PIa) and an estimator based on diastolic flow velocity (FVd).

137 al Doppler (vTCD) of straight sinus systolic flow velocity (FVsv), and methods derived from arterial

138 avigational strategy based on the sensing of flow velocity gradients and provide a comprehensive beha

139 ish (Danio rerio) perform rheotaxis by using flow velocity gradients as navigational cues.

140 h was defined as mean middle cerebral artery flow velocity >2 standard deviation.

141 baseline TCD measurements; 37 with increased flow velocities (> or = 140 cm/s) were then enrolled in

142 ho were aged 4-16 years and had abnormal TCD flow velocities (>/= 200 cm/s) but no severe vasculopath

143 1.07-1.63; P=0.01) and lower hyperemic mean flow velocity (HR, 0.84; 95% CI, 0.71-0.99; P=0.04) were

144 resonance imaging measured in vivo 3D blood flow velocities in 60 AF patients and 15 controls.

145 irst regionally comprehensive map of glacier flow velocities in Central Alaska.

146 H-stat strategy and decreases cerebral blood flow velocities in survivors.

147 xhibited randomized flow direction and equal flow velocities in the anterior and posterior regions.

148 Peak CSF flow velocities in the IS and control groups were calcul

149 Flow velocities in the LV outflow tract on the pre-SAM f

150 tion of pressure-driven separations yielding flow velocities in the separation channel that were near

151 Coronary flow velocity in 18 premenopausal women with SLE (mean +

152 s calculated as the ratio of pulmonary blood flow velocity in response to Ach relative to baseline va

153 A reduction (P < .005) in lymphatic flow velocity in the affected arms of patients and the a

154 oncentrations, while decreased linearly with flow velocity in the column, and effects were related wi

155 mplied progressive decreases in pre-ejection flow velocity in the left ventricular outflow tract, wit

156 Average flow velocity in the main pulmonary artery (PA) was quan

157 Blood flow velocity in the middle cerebral artery (MCAv) and m

158 ciation between blood viscosity and the mean flow velocity in the middle cerebral artery (p = 0.0008)

159 The relatively low mean flow velocity in the middle cerebral artery in combinati

160 ery remained relatively constant with a mean flow velocity in the middle cerebral artery of 71.5 (56.

161 Upon rewarming, the mean flow velocity in the middle cerebral artery remained rel

162 Mean flow velocity in the middle cerebral artery was low (26.

163 Median mean flow velocity in the middle cerebral artery was low (27.

164 Mean flow velocity in the middle cerebral artery was measured

165 There were no differences in mean flow velocity in the middle cerebral artery, pulsatility

166 osity in vivo are associated with changes in flow velocity in the middle cerebral artery.

167 riginated from significantly higher baseline flow velocity in the presence of significantly lower ref

168 ow-concentration solution is faster than the flow velocity in the reverse direction involving the sam

169 At a fixed flow velocity, increase in pre-stress level of the P(VDF

170 In these patients (n=20), hyperemic flow velocity increased significantly from 46.24+/-15.47

171 Hyperemic flow velocity increases 6-fold more when stenoses classe

172 The flow velocity increases outward along the jet in an acce

173 Compared to "stiff" materials, which has a flow velocity-independent flutter frequency, flexible ma

174 d refCFVR, resulting from increased baseline flow velocity indicating impaired coronary autoregulatio

175 Lower blood flow velocity, indicating reduced cerebral metabolism, p

176 r, hyperemic SR, combining both pressure and flow velocity information during hyperemia, was superior

177 ion pressure and mean middle cerebral artery flow velocity (intracranial pressure, PaCO2, hematocrit,

178 Pre-PCI, hyperemic flow velocity is diminished in stenoses classed as physi

179 te bursts closer to the suction source where flow velocity is higher.

180 volume without altering microvascular blood flow velocity, leading to a significantly increased micr

181 locity was defined as middle cerebral artery flow velocity <2 standard deviation and high was defined

182 measurements of middle cerebral artery blood flow velocity (MCAv; transcranial Doppler), heart rate (

183 tween low flow velocities and medium or high flow velocities (mean [SD] I2, 0.3 [5.3], 20.4 [6.4], an

184 nalysis were compared with the retinal blood flow velocities measured by video fluorescein angiograph

185 Peak aortic blood flow velocity measured at 24 hours was a good discrimina

186 Resting flow velocity measured over the wave-free period changes

187 Graft blood flow was calculated from flow velocity, measured by intracoronary Doppler, and lu

188 Combined pressure and flow velocity measurements during baseline conditions ma

189 Live imaging of phloem flow and flow velocity measurements in individual tubes indicate

190 uidewire to obtain simultaneous pressure and flow velocity measurements in the pulmonary artery in co

191 udied; in 24 patients, intracoronary Doppler flow velocity measurements were performed at rest, after

192 crovascular function, as assessed by Doppler flow velocity measurements, for cardiac mortality after

193 accurately assessed by intracoronary Doppler flow velocity measurements.

194 e of detected contrast material was used for flow velocity measurements.

195 ular blood volume (MBV), microvascular blood flow velocity (MFV), and microvascular blood flow (MBF)

196 asurements of OAF parameters, including mean flow velocity (MFV), end diastolic velocity (EDV), peak

197 ties, deceleration time of early transmitral flow velocity, myocardial performance index, peak Emax a

198 low and/or high mean middle cerebral artery flow velocity occur with cerebral perfusion pressure >40

199 cSO2 using near-infrared spectroscopy, blood flow velocities of the middle cerebral artery, and cardi

200 lux annihilation is dictated by the relative flow velocities of the opposing plasmas and is insensiti

201 ons, these observations yielded a meridional flow velocity of +3 +/- 11 km s(-1), that is, one consis

202 At the flow velocity of 0.1 and 0.3 m/s, the ratio of detached

203 ion even when these biofilms were exposed to flow velocity of 0.7 m/s, typical flow for DWDS.

204 ce achieved over 90% capture efficiency at a flow velocity of 4 mm/s, a speed that was roughly two or

205 al confidence in around 8 s using TCCD and a flow velocity of 5 cm s(-1).

206 astolic function (E/E'; ratio of peak mitral flow velocity of early rapid filling [E] to early diasto

207 tolerance of embryos depends on egg size and flow velocity of the surrounding water.

208 urea can significantly decrease elevated TCD flow velocities, often into the normal range.

209 ar resistance resulted in augmented coronary flow velocity on second exertion (both P<0.001).

210 We found no influence of pH or flow velocity on the diffusion coefficients through 0.8

211 In addition, the impact of the longitudinal flow velocity on the shape of the artificial LUV of two

212 In significant stenoses, flow velocity over the resting wave-free period and hype

213 After PCI, resting flow velocity over the wave-free period increased little

214 a significant reduction in mean renal artery flow velocity (P = 0.045) and renal cortical tissue perf

215 ifference (P = 0.219), and mean renal artery flow velocity (P = 0.319) were similar.

216 assessed coronary wave intensity and phasic flow velocity patterns to unravel changes in cardiac-cor

217 rial pressure-to-middle cerebral artery mean flow velocity phase difference (p < .05) in the low freq

218 Mean blood flow velocity predicted incident depressive symptoms (od

219 and relaxation, it increases coronary blood flow velocity, predominantly by increasing the dominant

220 ar to that observed on free surfaces if fast flow velocities predominate and if the time-dependent re

221 o stenosis severity measured by the coronary flow velocity-pressure gradient relation (r=0.69; P<0.00

222 FR, absolute coronary flow, and the coronary flow velocity-pressure gradient relation were calculated

223 titative coronary angiography, intracoronary flow velocity probes, and pharmacologic stressor agents.

224 Also presented are the results on the plug-flow velocity profile of blood, the apparent viscosity,

225 The cardiac cycle influences the blood flow velocity profiles systematically in retinal arterie

226 We reconstructed flow-velocity profiles and vertical mixing using canopy

227 Simultaneous intracoronary pressure and flow velocity recordings were made in unobstructed coron

228 This study suggests that a low retinal blood flow velocity reflects in a visually distinct contrast r

229 anaemia and high transcranial doppler (TCD) flow velocities, regular blood transfusions can effectiv

230 ut its effects on transcranial Doppler (TCD) flow velocities remain undefined.

231 /-0.07 vs. 0.31+/-0.08 nmol/L), and coronary flow velocity reserve (2.35+/-0.60 vs. 2.81+/-0.78 s) wi

232 rate as fractional flow reserve and coronary flow velocity reserve (area under the curve, 0.77; 95% C

233 n fractional flow reserve (FFR) and coronary flow velocity reserve (CFVR) may reflect important coron

234 sure-only indices (iFR and FFR) and coronary flow velocity reserve (CFVR) was compared using correlat

235 nfarct-related artery, to determine coronary flow velocity reserve (CFVR), diastolic deceleration tim

236 ry physiological parameters such as coronary flow velocity reserve and the more widely used fractiona

237 sthoracic Doppler echocardiography, coronary flow velocity reserve assessment, and coronary angiogram

238 Coronary flow velocity reserve in patients with AS was lower, 1.9

239 which can be accurately assessed by coronary flow velocity reserve in reference vessels (refCFVR).

240 Coronary flow velocity reserve increased significantly from 1.9+/

241 well as fractional flow reserve and coronary flow velocity reserve.

242 ance and a concomitant increase in hyperemic flow velocity, resulting in immediate improvement in cor

243 Simulations sampling different flow velocities reveal that under flow, beta-hairpin fol

244 For each flow velocity, serial axial scans were obtained with 16-

245 tions and CT measurements were made for each flow velocity setting.

246 gle-channel flow phantom with constant water flow velocity settings of 25.3, 43.9, and 70.5 cm/sec.

247 d precise, simultaneous calculation of blood flow velocity, shear stress and drug distribution.

248 llary blood volume rather than microvascular flow velocity, suggesting a specific action of cocaine t

249 sample environment parameters such as fluid flow velocity, temperature, and presence of a binding ma

250 tween low flow velocities and medium or high flow velocities, the graders' sensitivity ranged from 88

251 We show that, under low ambient flow velocities, these vortices, rather than molecular d

252 A range of flow velocities through the LS detector, at which accura

253 regulate their own deformability and thereby flow velocity through capillaries in response to physiol

254 optimal AV delay (BiV-Opt) enhanced coronary flow velocity time integral by 15% (7%-25%) (P=0.007), L

255 The majority of the increase in coronary flow velocity time integral occurred in diastole (69% [4

256 were not significantly different in coronary flow velocity time integral or waves.

257 e have experimentally determined the optimal flow velocities to characterize or count single molecule

258 stimated from the ratio of early transmitral flow velocity to early mitral annular diastolic velocity

259 by the ratio of peak early diastolic mitral flow velocity to peak early diastolic mitral annular vel

260 in the ratio of peak early diastolic mitral flow velocity to peak early diastolic mitral annular vel

261 in the ratio of peak early diastolic mitral flow velocity to peak early diastolic mitral annular vel

262 lative wall thickness, the early transmitral flow velocity to peak early diastolic mitral annular vel

263 age C1 (ratio of peak early diastolic mitral flow velocity to peak early diastolic mitral annular vel

264 the source and for low values of groundwater flow velocity, transverse dispersion coefficient, molecu

265 to the trajectories of trypanosomes even at flow velocities up to approximately 40 times higher than

266 ilateral transcranial middle cerebral artery flow velocities using Doppler and jugular vein oxygen sa

267 iated with lower middle cerebral artery mean flow velocity variability (1.0 +/- 1.0 [cm.sec(-1)] Hz v

268 (3-7 d) ischemia-induced increases in blood flow velocity, vessel lumen diameter, and red blood cell

269 irment of microhemodynamics, including blood flow velocity, volumetric blood flow, and functional cap

270 Flow velocity was calculated as the ratio of distance be

271 Low mean middle cerebral artery flow velocity was defined as middle cerebral artery flow

272 r than SV luminal diameters (P=0.029), blood flow velocity was greater in RA than SV (P=0.008), and v

273 Baseline flow velocity was higher and baseline microvascular resi

274 rward portion of clean collectors, where the flow velocity was lowest.

275 In 51 vessels, intracoronary pressure and flow velocity was measured distal to the stenosis at res

276 coronary intervention, intracoronary Doppler flow velocity was measured in the infarct-related artery

277 Flow velocity was measured over the whole cardiac cycle

278 The greatest increase in hyperemic flow velocity was observed when treating stenoses below

279 Lymphatic flow velocity was quantified by performing spin labeling

280 In patients with AS, hyperemic flow velocity was significantly lower as compared with c

281 9]; P=0.01), but basal average peak coronary flow velocity was unchanged, indicating LV stunning post

282 velocity of Gd-DTPA to be equal to the fluid flow velocity, we used a simple model of peritumoral int

283 Mean peak systolic (caudal) CSF flow velocities were 6.7 cm/sec in the IS group and 3.6

284 The mean CT measurements of flow velocity were 34.2, 53.9, and 80.8 cm/sec for slow,

285 Distal coronary pressure and flow velocity were assessed with sensor-equipped guidewi

286 Measurements of carotid pressure and flow velocity were made in the carotid artery of 65 heal

287 intervention of a CTO, coronary pressure and flow velocity were measured at baseline and hyperemia in

288 Intracoronary pressure and flow velocity were measured at rest and maximal hyperemi

289 1 (39 stenoses), intracoronary pressure and flow velocity were measured distal to the stenosis; in p

290 Intracoronary pressure and flow velocity were measured immediately before and after

291 Invasive pressure and flow velocity were measured in 216 stenoses from 186 pat

292 ate coronary stenosis, coronary pressure and flow velocity were measured using a dual sensor-equipped

293 volume (rBV), relative blood flow, and blood flow velocity were quantified.

294 hout exertions, distal coronary pressure and flow velocity were recorded in the culprit vessel using

295 Intracoronary pressure and flow velocity were simultaneously assessed at rest and a

296 [rBV], relative blood flow [rBF], and blood flow velocity) were measured on both 3D and 2D data sets

297 ion conductance and a higher electroosmotic flow velocity, whereas, in the tip-to-base direction, th

298 potential change on the SiNW depends on the flow velocity, width of the microfluidic channel and the

299 y time integral imply a compromised systolic flow velocity with AS that is restored after TAVI, sugge

300 served to decrease linearly with increase in flow velocity, with no observed response at the highest