ライフサイエンスコーパス: wavefront

1 of two activities known as the clock and the wavefront.

2 the segmentation clock and the FGF signaling wavefront.

3 rea was observed with a different activation wavefront.

4 c pachymetry, and topography-derived corneal wavefront.

5 tal conduction limiting fusion of electrical wavefronts.

6 ces much larger than the wavelength to shape wavefronts.

7 ght and left ventricular (LV) pacing-derived wavefronts.

8 membrane potential gradients to initiate new wavefronts.

9 s, characterized by 2 to 4 broad propagating wavefronts.

10 mponent) consisted of 92%+/-1% of epicardial wavefronts.

11 modify near-infrared (lambda=915 nm) optical wavefronts.

12 in more widespread light-induced propagating wavefronts.

13 erers rationally arranged to control optical wavefronts.

14 citable gap, which led to block of reentrant wavefronts.

15 Simultaneous measurements of wavefront aberration and lower tear meniscus were perfor

16 s and simulate the implantable collamer lens wavefront aberration's pattern for small- and large-inci

17 al calculations suggest that certain corneal wavefront aberrations affect corneal pseudoaccommodation

18 otal), corneal, higher-order, and astigmatic wavefront aberrations at 24 months.

19 inal images of ICLs were calculated from the wavefront aberrations for each ICL and all conditions of

20 was comparable to CLMI and anterior corneal wavefront aberrations in detecting KC.

21 rmed consent issues and reports showing that wavefront aberrations increase with increasing pupil siz

22 High-order wavefront aberrations increased and uncorrected visual a

23 Wavefront aberrations of the -3, -6, and -12 diopter (D)

24 orneal resistance factor [CRF]), and corneal wavefront aberrations were assessed before and a year af

25 -contrast visual acuity and anterior corneal wavefront aberrations were measured by standard methods.

26 Corneal and ocular wavefront aberrations were recorded together with clinic

27 efractive astigmatism, contrast sensitivity, wavefront aberrations, and refractive error-related qual

28 open for approximately 18 seconds, while CS, wavefront aberrations, and RI images were collected.

29 rneal asymmetry and corneal as well as total wavefront aberrations.

30 WaveTec Vision Systems Inc, Aliso Viejo, CA) wavefront aberrometer measured aphakic refractive measur

31 he Optiwave Refractive Analysis (ORA) System wavefront aberrometer was used to obtain aphakic refract

32 Wavefront aberrometry measures (Zywave; Bausch & Lomb, R

33 system quality in terms of contrast, whereas wavefront aberrometry measures the optical quality in te

34 active correction, contrast sensitivity, and wavefront aberrometry.

35 ast sensitivity measurement is compared with wavefront aberrometry.

36 ce demonstrating that the observed molecular wavefronts act to slow clock oscillations.

37 unusual phenotype indicative of the loss of wavefront activity.

38 r model, we found that the mesoscopic, local wavefront acts as the forcing term of the ictal process,

39 ze and fine-grained irregularities in ocular wavefront after PRK, suggesting that attenuation of the

40 ll as shaping the evolving propagating ictal wavefront, although the exact mechanism of these cerebro

41 ances have been made in our understanding of wavefront analysis and its usefulness in vision correcti

42 Historically, wavefront analysis has been implemented in corneal refra

43 spinning TIRF), atomic force microscopy, and wavefront analysis of beams passing through the objectiv

44 New advances in wavefront analysis offer an opportunity for greater refi

45 of all higher-order aberrations measured by wavefront analysis remains controversial.

46 ole eye must be considered when implementing wavefront analysis.

47 biosensing, beam shaping, optical switching, wavefront-analysis, and device miniaturization.

48 more excitable tissue allowing collision of wavefront and back.

49 d thus cause fragmentation of the activation wavefront and contribute to electrogram spreading.

50 phase variation, holds a great potential for wavefront and dispersion engineering.

51 ndex inhomogeneity in the sample distort the wavefront and enlarge the focal spot, which reduces the

52 correlation effect is specific to the ictal wavefront and is absent interictally or from action pote

53 place conventional free-space components for wavefront and polarization control.

54 ng there were more occurrences of fragmented wavefronts and hence more filaments than during electric

55 hase maps helped to highlight high-curvature wavefronts and rotors.

56 ctivity organizes into a submillimeter-sized wavefront, and this activity correlates significantly wi

57 as a consequence of geometrical squeezing of wavefronts, and describes newly established or speculati

58 enerate a random sequence of phase-modulated wavefronts, and the resulting intensity speckle patterns

59 and conduction velocity as the depolarizing wavefront approaches the epicardial surface.

60 n in peak I(Na) and electrotonic load as the wavefront approaches the epicardial surface.

61 e transmission matrix is determined, optimal wavefronts are computed that focus the incident beam to

62 of speed-of-sound (for example, 6 nm ps(-1)) wavefronts are influenced by spatially varying nanoscale

63 cidence, so that by 10 minutes of VF, 27% of wavefronts arise from intramural foci.

64 Wavefronts associated with reaction-diffusion and self-a

65 sub-picosecond nucleation and the launch of wavefronts at step edges and resolve dispersion behaviou

66 rrays of nano-scatterers that modify optical wavefronts at subwavelength spatial resolution.

67 lar coupling resulted in fragmented and wavy wavefronts; at high coupling wavefronts became smoother.

68 mented and wavy wavefronts; at high coupling wavefronts became smoother.

69 tecting fusion between tachycardia and paced wavefronts, but this is often difficult for atrial tachy

70 upling drives the propagation of an emergent wavefront, can be used to provide mechanistic and testab

71 Electron beams with helical wavefronts carrying orbital angular momentum are expecte

72 ally destroys microbubbles, and measures the wavefront change to compute and render a suitable time-r

73 measured by using surface profilometry, and wavefront changes were computed from curvature differenc

74 We reasoned that wavefronts circling the pivot should broaden the amplitu

75 ntrant (n=43/50 [86%]) occurring in areas of wavefront collision (n=21; median 0.5; quartiles 0-2 per

76 ies) and conduction (retrograde propagation, wavefront collisions, conduction blocks, and re-entry),

77 Here, we report an iterative wavefront compensation technique that takes advantage of

78 nherent in these monolayers on the resulting wavefront conduction.

79 O's ability to perform spatially independent wavefront control further enables 3D nonplanar imaging.

80 We experimentally demonstrated unparalleled wavefront control in a broadband optical wavelength rang

81 g telescopes--both require exceedingly clean wavefront control in the optics.

82 In this Letter, we present an iterative wavefront control method that either minimizes or maximi

83 establish the position of the determination wavefront, controlling where new somites are permitted t

84 laser ophthalmoscopy (AOSLO) under optimized wavefront correction allows for routine imaging of fovea

85 Traditional approaches to adaptive optics wavefront correction are not effective in thick or multi

86 The complex wavefront correction is obtained and directly conjugated

87 ve optics (MPAO), which enables simultaneous wavefront correction over a field of view of 450 x 450 m

88 By adopting a wavefront correction strategy, the FPM method can also c

89 , 10 seizures), in which propagating seizure wavefronts could be readily identified, to investigate t

90 Consequently, wavefronts could survive intramurally in the simplified

91 er rotation, bath-loading induced transmural wavefront curvature dominates, significantly increasing

92 ram fractionation from changes in activation wavefront curvature in experimental canine infarction.

93 ith harmonic order of the intensity profile, wavefront curvature, and complex coherence factor is mea

94 spiral waves, including phase singularities, wavefront curvature, and dominant frequency maps, are di

95 ls modulates bath-loading induced transmural wavefront curvature.

96 tissue-fluid interface, inducing transmural wavefront curvature.

97 aves collide, yielding regions with negative wavefront curvature.

98 Vector field analysis of AF wavefronts demonstrates that omnipolar EGMs can account

99 odel of somitogenesis, in which a travelling wavefront determines the spatial position of somite form

100 ement with local activation time methods for wavefront direction and velocity within 25 cm/s and 30 d

101 eak-to-peak voltage (Vpp) from variations in wavefront direction relative to electrode orientation an

102 ct model, the LBs are a source of activation wavefront discontinuity and electrogram fractionation, w

103 er the synergistic or counteracting roles of wavefront distortion and birefringent walk-off, respecti

104 le imaging depth is fundamentally limited by wavefront distortions caused by aberration and random sc

105 nique can rapidly measure highly complicated wavefront distortions encountered in deep tissue imaging

106 Adaptive optics by direct imaging of the wavefront distortions of a laser-induced guide star has

107 ed to marginally increase disorganisation of wavefronts during arrhythmias in the complex model.

108 ly, we quantified the dynamics of excitation wavefronts during episodes of simulated tachyarrhythmias

109 VT, photon scattering, combined with complex wavefront dynamics, results in optical action potentials

110 ormed by rapid and highly uniform activation wavefronts emanating from sites distal to the former sit

111 calculates the Zernike values of an infrared wavefront emerging from the eye.

112 THz to infrared (IR) source with a Gaussian wavefront, emitted from nano-pore-structured metallic th

113 Recent breakthrough in wavefront engineering shows great promises in controllin

114 ss this challenge, internal-guide-star-based wavefront engineering techniques--for example, time-reve

115 Despite the significant advances made in wavefront engineering through metasurfaces, most of thes

116 HOAs) and optical quality, by using measured wavefront error (WFE) data from a cat photorefractive ke

117 measured aberration, root mean square (RMS) wavefront error and volume modulation transfer function

118 Residual RMS wavefront error in induction of KC aberrations on normal

119 ution of the telescope by 30-50%, limited by wavefront error in the optics, but that was insufficient

120 orrection reduced the total root mean square wavefront error, on average, from 0.30 microm to 0.05 mi

121 l acuity with low amount of decentration and wavefront error.

122 The average higher order RMS wavefront errors for the posterior corneas were 1.04, 0.

123 Wavefront errors from the anterior and posterior corneal

124 Wavefront errors from the anterior corneal surface were

125 ution optical mapping showed that epicardial wavefront expansion was slower and more anisotropic in L

126 f conduction block (CB) as sites where an AP wavefront failed to propagate.

127 ibition in seizures: while inhibition at the wavefront fails, allowing seizure propagation, feedforwa

128 The wavefront from leading pacemaker site propagated first t

129 d new optical mapping technology to image VF wavefronts from nearly the entire epicardial surface of

130 n time and smaller scar volume combined with wavefront fusion on the paced ECG, anticipate higher pro

131 4.02]), indicators of ventricular activation wavefront fusion, were positive predictors of reverse re

132 Wavefront guided customized corneal ablations are safe,

133 Wavefront-guided (WFG) and wavefront-optimized (WFO) pla

134 he changes in higher-order aberrations after wavefront-guided ablation with IntraLase femtosecond las

135 Hz IntraLase iFS; Abbott Medical Optics Inc) wavefront-guided ablation.

136 Compared with conventional treatments, wavefront-guided ablations can achieve a reduction in pr

137 Both wavefront-guided and wavefront-optimized treatments are

138 Wavefront-guided and WF-optimized LASIK using the Alcon

139 Wavefront-guided as well as wavefront-optimized treatmen

140 technology continue to improve outcomes with wavefront-guided corneal ablations in primary treatments

141 idence supporting the efficacy and safety of wavefront-guided corneal ablations.

142 Optimized aspherical as well as wavefront-guided corneal excimer laser treatments have c

143 milar outcomes between topography-guided and wavefront-guided customized corneal ablations while expl

144 be a major limitation of a truly successful wavefront-guided excimer laser procedure, surgeons shoul

145 udies suggest that it is possible to perform wavefront-guided excimer light amplification by stimulat

146 Wavefront-guided eyes also achieved better best-correcte

147 refractions were -0.13 +/- 0.46 diopters in wavefront-guided eyes whereas in wavefront-optimized eye

148 y of 20/12.5 or better (30 eyes, 56%) in the wavefront-guided group compared to those receiving wavef

149 Wavefront-guided IntraLASIK offers a safe and effective

150 s induction of higher order aberrations than wavefront-guided laser in situ keratomileusis.

151 Wavefront-guided Laser-assisted in situ keratomileusis (

152 -eight eyes of 34 patients were treated with wavefront-guided LASIK and PRK.

153 ye of each patient was randomized to undergo wavefront-guided LASIK by the AMO Visx CustomVue S4 IR e

154 the US Food and Drug Administration approved wavefront-guided monovision for mild to moderate myopia.

155 Wavefront-guided photorefractive keratectomy offers bett

156 Wavefront-guided PRK and LASIK are more predictable and

157 To examine whether wavefront-guided refractive surgery has a role in correc

158 ltifocal lenses derive an added benefit from wavefront-guided refractive surgery over conventional su

159 rneas, many of which are poor candidates for wavefront-guided therapy.

160 However, wavefront-guided treatment platforms appear to offer sig

161 still increased higher-order aberrations and wavefront-guided treatments also did not achieve the eli

162 Optimized aspherical as well as custom wavefront-guided treatments attempt to reduce the induct

163 Wavefront-guided treatments did have better results in s

164 treatments in 67-88% of patients and reserve wavefront-guided treatments for those who have above ave

165 ccentricity of the average cornea as well as wavefront-guided treatments that attempt to reduce the i

166 while molecular components of the clocks and wavefronts have now been identified in the pre-somitic m

167 organize from the wafer edge as propagating wavefronts having well defined velocities.

168 her quantitative evaluation of the clock and wavefront hypothesis.

169 atients during 2 distinct wavefronts, with 3 wavefronts in 7 patients.

170 Mbtps1 is required to (i) maintain the Fgf8 'wavefront' in the presomitic mesoderm that underpins axi

171 n the epicardial surface and therefore, that wavefront infusion from nonepicardial sources was not st

172 ographic optical elements steer the emerging wavefront into the wavefront sensor, while simultaneousl

173 Huygens principle, are able to mould optical wavefronts into arbitrary shapes with subwavelength reso

174 lens is capable of transforming cylindrical wavefronts into planar ones, and generating a directive

175 ts with specific anterior chamber pathology, wavefront intraocular lenses may not be appropriate.

176 appears compartmentalized as the stimulated wavefront is rerouted to the scar border.

177 re, we propose an original easy-to-implement wavefront manipulation concept to achieve ultrabroadband

178 mic and miniature X-ray optics for focusing, wavefront manipulation, multicolour dispersion, and puls

179 fully overcome the challenging alignment and wavefront-matching constraints in DOPC, reflecting the r

180 The accuracy of the wavefront may be compromised in eyes with multifocal IOL

181 g substrate mapping, an alternate activation wavefront may increase the sensitivity to detect arrhyth

182 Here we show that a clock-and-wavefront mechanism is unnecessary for somite formation.

183 erm is segmented into somites by a clock and wavefront mechanism.

184 in all of these species a similar 'clock-and-wavefront' mechanism operates to control somitogenesis;

185 ous multifocal IOLs to help understand how a wavefront might return from the IOL and be captured by a

186 an alternative formulation of the clock and wavefront model in which oscillator coupling, already kn

187 tly accepted interpretation of the clock and wavefront model of somitogenesis is that a posteriorly m

188 ormulation of a new version of the Clock and Wavefront model proposed by Pourquie and co-workers.

189 traveling along the body axis (the clock-and-wavefront model) is generally believed to control somite

190 cant weight to Cooke and Zeeman's 'clock and wavefront' model of somitogenesis, in which a travelling

191 and refraction, polarization filtering, and wavefront modulation.

192 es of V(F)(*)( approximately 0.2) indicate a wavefront moving away from the surface, high values of V

193 ate values of V(F)(*) ( approximately 0.4) a wavefront moving parallel to the surface.

194 igh values of V(F)(*) ( approximately 0.6) a wavefront moving toward the surface, and intermediate va

195 The wavefront of a light beam propagating across an interfac

196 The effects of varying the wavefront of activation on ventricular scar characteriza

197 8 in the presomitic mesoderm constitutes the wavefront of determination which sweeps along the body a

198 eceiver, which is associated with the spiral wavefront of OAM beams.

199 By adjusting the wavefront of the optical field incident on the transmitt

200 y addressable fashion is challenging, as the wavefront of the scattered light is highly disordered.

201 underwent voltage maps during a minimum of 2 wavefronts of activation.

202 faces, has mainly focused on controlling the wavefronts of light propagating in free space.

203 of spatial wavelength (the distance between wavefronts) of the arrhythmia.

204 began as an organized focal source or broad wavefront on the right ventricular (RV) free wall.

205 his problem using photoacoustic feedback for wavefront optimization.

206 Wavefront-guided (WFG) and wavefront-optimized (WFO) platforms for refractive surge

207 diopters in wavefront-guided eyes whereas in wavefront-optimized eyes the refractions were -0.41 +/-

208 xamined the refractive and visual outcome of wavefront-optimized laser in situ keratomileusis (LASIK)

209 xcimer laser system; the fellow eye received wavefront-optimized LASIK by the Alcon Allegretto Wave E

210 ont-guided group compared to those receiving wavefront-optimized treatment (22 eyes, 41%) (P = 0.016)

211 Both wavefront-guided and wavefront-optimized treatments are able to correct myopi

212 sy access to both technologies suggest using wavefront-optimized treatments in 67-88% of patients and

213 Wavefront-guided as well as wavefront-optimized treatments yield high predictability

214 cumenting the shape and location of the aura wavefront or scotoma in the visual field at one minute i

215 , optical upstroke morphology reveals the 3D wavefront orientation near the surface.

216 ation being dependent on activation rate and wavefront orientation with respect to the LB.

217 oss-linking, improvements in topographic and wavefront parameters evident at 1 year were seen to cont

218 d the curvature, elevation, pachymetric, and wavefront parameters were analyzed in each group and com

219 served with different ventricular activation wavefronts, particularly in septal locations and in pati

220 seconds after seizure onset, following ictal wavefront passage.

221 raocular lens for a patient's individualized wavefront pattern, thus allowing for a 'custom-fitted' i

222 beyond that of infarction is contrary to the wavefront phenomenon.

223 e in CV and concomitant change in transmural wavefront profiles upon both propagation and arrhythmia

224 The uniformity of wavefront propagation as measured by the square of the c

225 om omnipolar electrograms were compared with wavefront propagation from optical and electric-mapping

226 eling approach makes it possible to simulate wavefront propagation in a manner analogous to performin

227 hroughout the myocardial wall and interrupts wavefront propagation into illuminated tissue.

228 imilar to model-generated fractionation with wavefront propagation parallel to the LB (6.7+/-3.1 defl

229 ular signal shape that would be generated by wavefront propagation parallel to versus perpendicular t

230 ) was similar to model-generated values with wavefront propagation perpendicular to the LB (9.4+/-2.4

231 -ray reflective optics they can maintain the wavefront properties with nearly 100% reflectivity, and

232 itate more-effective elimination of existing wavefronts, rapid closing down of excitable gaps, and su

233 far-field phase-conjugated patterns through wavefront reconstruction by means of diffraction.

234 manifest refraction closely approximates the wavefront refraction and good results after refractive s

235 Manifest and wavefront refractions were performed at each postoperati

236 ever, in isolated small series, reproducible wavefront refractions--in which the manifest refraction

237 st demonstration of a tunable flat lens with wavefront-reshaping capabilities.

238 In breakout tachycardias, splitting of wavefronts resulted in 2 to 4 incomplete circuits.

239 usting the helicity of structures, while the wavefront revolution plays a dominant role in reducing t

240 light pulse, including pulse front tilt and wavefront rotation.

241 Advances in wavefront sensing and laser technology continue to impro

242 gards to the lower and HOA, to the different wavefront sensing devices and software, Tscherning and H

243 Wavefront sensing was performed in the awake-behaving st

244 ns include spectroscopy, optical tomography, wavefront sensing, and imaging.

245 scanned, laser-induced guide star and direct wavefront sensing, we demonstrate adaptive correction of

246 reak-up time shorter than 5 seconds, using a wavefront sensor and an anterior segment optical coheren

247 ts is achieved in less than 15 seconds using wavefront sensor feedback to the pumps.

248 ive error is measured using a Shack-Hartmann wavefront sensor that calculates the Zernike values of a

249 ements steer the emerging wavefront into the wavefront sensor, while simultaneously providing an unob

250 Through the combination of wavefront sensorless adaptive optics and the use of dual

251 Because each such wavefront sequence constitutes a continuous activation f

252 near CB sites but could be traced to normal wavefront sequences away from CB sites.

253 Metasurfaces capable of diverse wavefront shaping according to wavelengths and polarizat

254 By wavefront shaping and optimization, we observe the gener

255 the need for any subsequent measurements or wavefront shaping iterations.

256 Recently developed ultrasound-guided wavefront shaping methods are addressing this challenge,

257 Ca(2+) imaging with 2P activation by optical wavefront shaping should make second generation PTL-cont

258 The use of wavefront shaping to compensate for scattering has broug

259 Utilizing wavefront shaping via a spatial light modulator (SLM), w

260 dedness, promising polarization-controllable wavefront shaping, polarization sensing, and environment

261 trol of a broadband light source by means of wavefront shaping.

262 Metasurfaces are a family of novel wavefront-shaping devices with planar profile and subwav

263 Here, we demonstrate a wavefront-shaping scheme that allows clear imaging throu

264 A recently developed class of wavefront-shaping techniques now aims to overcome this l

265 To successfully operate in vivo, these wavefront-shaping techniques typically require feedback

266 a discordant region of scar, with one of the wavefronts showing voltage >1.5 mV.

267 The obtained X-ray wavefront shows excellent agreement with the dynamical c

268 provides genetic evidence that FGFs are the wavefront signal and identifies the specific FGF ligands

269 last growth factor (FGF) activity may be the wavefront signal, which maintains the PSM in an undiffer

270 compute and render a suitable time-reversed wavefront solution for focusing.

271 s key features of propagating waves, such as wavefront speed and entropy.

272 ieve helicity-controlled multiple structured wavefronts such as vortex beams carrying orbital angular

273 ession is tightly regulated by the clock and wavefront system in the posterior PSM.

274 advantages and limitations with our current wavefront technology and reviews the evidence supporting

275 The application of wavefront technology continues to expand the surgical op

276 Wavefront technology is still evolving to address curren

277 we critically review the recent advances in wavefront technology with specific attention to its appl

278 r from action potential activity outside the wavefront territory.

279 OPC) system characterizes and plays back the wavefront that focuses through the scattering layer.

280 The set of wavefronts that were so related (the dominant component)

281 an object on the retina--and hence returning wavefronts theoretically could be captured in a similar

282 ibution and evolution of wave velocities and wavefront thicknesses were observed to be intimately lin

283 interacts with a maturation wave called the wavefront to produce the periodic series of somites.

284 yse electron wavefunctions, especially their wavefronts, to obtain information regarding the material

285 Electrode orientation-independent cardiac wavefront trajectory and speed at a single location for

286 ch allows a heuristic search for the optimal wavefront under laser-plasma conditions that is not know

287 These indicate that greater wavefront velocities should be associated with (i) laten

288 always expected to result in greater plaque wavefront velocities.

289 mpact of these parameters on rates of plaque wavefront velocity (rates of radial plaque enlargement),

290 The wavefront was reconstructed by zonal methods, and image

291 Concordance between wavefronts was lower in patients with mixed scar compare

292 Concordance between wavefronts was measured by calculating percentage of ove

293 ity, keratometry, and Scheimpflug and ocular wavefront (WASCA, Carl Zeiss Meditec AG) measurements we

294 Using a kinematic model to represent wavefront-waveback interactions, we first analytically d

295 Endo-to-epicardial wavefronts were studied during right atrial or ventricul

296 , resulting in the impression of propagating wavefronts when a series of bars move consecutively.

297 A travelling wavefront, which slows oscillations along the AP axis, i

298 The number of wavefronts with respect to time was significantly less c

299 e performed in 29 patients during 2 distinct wavefronts, with 3 wavefronts in 7 patients.

300 A few corneal wavefront Zernike aberrations changed after treatment (P