ライフサイエンスコーパス: evanescent

1 t claims for big improvements turn out to be evanescent.

2 data suggest that 1) minor depression is not evanescent; 2) minor depression is characterized by mood

3 plane image of the critical angle separating evanescent and far-field fluorescence emission component

4 uction and the response to induction in both evanescent and permanent kidney forms.

5 hile high-frequency propagating modes become evanescent at the THz scale.

6 to generate any cell type of the body, is an evanescent attribute of embryonic cells.

7 ree-space and loss of high-spatial-frequency evanescent components.

8 ophozoites of both strains often established evanescent contact with macrophages.

9 Exploiting evanescent coupling between the mu-fibre and the cavity,

10 ab destroys the broad reflection band due to evanescent coupling of electromagnetic field in the slab

11 en by the optical force and read out through evanescent coupling of the guided light to the dielectri

12 While the evanescent coupling scheme works well for planar optical

13 By integrating optical polymers through evanescent coupling to silicon waveguides, we greatly in

14 can be launched into these wires by optical evanescent coupling.

15 n: ratiometric analysis using monochromatic, evanescent darkfield illumination (RAMEDI).

16 mbines magnetic tweezers with objective-side evanescent darkfield microscopy.

17 ent mass and that myosin thick filaments are evanescent, dissociating partially during relaxation and

18 ine several expressions used for calculating evanescent electric field amplitudes in supported lipid

19 n the accuracy of assumptions made about the evanescent electric field amplitudes in the membrane.

20 tunnel through the vacuum gap by coupling to evanescent electric fields, providing additional channel

21 EM) is a technique to produce and then image evanescent electromagnetic fields on the surfaces of nan

22 ese excitations, known as plasmons, can have evanescent electromagnetic fields that are orders of mag

23 it should be possible to achieve imaging of evanescent electromagnetic fields with electron pulses w

24 Analogously, the phase properties of evanescent emission lead to a method of producing a smal

25 ore, diffusing in the exponentially decaying evanescent excitation field.

26 An evanescent excitation generates a signal from an antigen

27 Evanescent excitation has been used recently with a vari

28 The phase properties of the evanescent excitation lead to a method of creating a sub

29 cessful hybridization events were read using evanescent excitation monitored by an imaging microscope

30 f molecules at the interface with a decaying evanescent excitation to predict the fluorescence intens

31 in which a bright flash of strongly decaying evanescent field ( approximately 64 nm exponential decay

32 l calculations it is also predicted that the evanescent field above the nickel films penetrates deepe

33 des serve as optical transducer for tailored evanescent field absorption analysis.

34 spectroscopy for simultaneous spectroscopic evanescent field absorption and scanning probe measureme

35 concept, the detection of acetone in D2O via evanescent field absorption is demonstrated achieving a

36 Evanescent field absorption measurements indicate a sign

37 s for plasma membranes were investigated via evanescent field absorption spectroscopy of a model anal

38 nts of oil in water using mid-infrared (MIR) evanescent field absorption spectroscopy via fiberoptic

39 taxy (MBE) as waveguide enabling sensing via evanescent field absorption spectroscopy, as demonstrate

40 duced processes at IR waveguide surfaces via evanescent field absorption spectroscopy.

41 elated bulk spectral changes by mid-infrared evanescent field absorption spectroscopy.

42 for liquid-phase chemical sensing utilizing evanescent field absorption spectroscopy.

43 e constant and rate of diffusion through the evanescent field agree with previous results, and all me

44 romolecule such as DNA can extend beyond the evanescent field and analyte interaction results in a la

45 Using alternating evanescent field and epifluorescence illumination, we sh

46 ulates both the accumulation of GLUT4 in the evanescent field and the fraction of this GLUT4 that is

47 obe as an overlap integral of the nanowire's evanescent field and the probe's response function.

48 solated molecules excited either through the evanescent field at the quartz-liquid interface or as a

49 static, moving vertically in and out of the evanescent field but with little lateral motion.

50 d is illustrated for the example of infrared evanescent field chemical sensors.

51 heres containing gold nanoparticles in their evanescent field combine the light guiding properties of

52 r-mode profiles and to preferentially select evanescent field concentrations such as the axial hotspo

53 iented membrane probe excited by a polarized evanescent field created by total internal reflection (T

54 ments demonstrated that diffusion out of the evanescent field determined the track lifetimes.

55 spectrum within the penetration depth of the evanescent field due to displacement of water molecules

56 e fluorophore was excited directly or by the evanescent field due to the surface plasmon resonance.

57 interrogating oil-in-water emulsions via the evanescent field emanating from the waveguide surface, a

58 ybridization assay sensor that relies on the evanescent field excitation of fluorescence from surface

59 With total internal reflection fluorescence, evanescent field excitation, supercritical angle fluores

60 The WGM has an evanescent field extending into the capillary core and r

61 The evanescent field extends into the core and is sensitive

62 single, FM1-43-stained synaptic vesicles by evanescent field fluorescence microscopy, and tracked th

63 h high temporal and spatial resolution using evanescent field fluorescence microscopy.

64 s(3,4)P(2)/PtdIns(3,4,5)P(3), as measured by evanescent field fluorescence microscopy.

65 ly developed magnetically assisted transport evanescent field fluoroassays (MATEFFs), takes advantage

66 IA approach, Magnetically-Assisted Transport Evanescent Field Fluoroimmunoassays (MATEFFs), which see

67 s involved granules that were present in the evanescent field for at least 12 s.

68 s involved granules that were present in the evanescent field for no more than 0.3 s, indicating that

69 y-coated membranes were illuminated with the evanescent field from a totally internally reflected las

70 In this method, the evanescent field from an internally reflected excitation

71 laser at 644 nm and a right-angled prism for evanescent field generation on prism surface.

72 E penetrates into the exponentially decaying evanescent field in close vicinity (a few micrometer) to

73 The decay of evanescent field intensity beyond a dielectric interface

74 le angles, and corrected for angle-dependent evanescent field intensity using "reference" images acqu

75 tes using total internal reflection where an evanescent field interacts with bound antibody immobiliz

76 opy experiments the penetration depth of the evanescent field into the stratum corneum is comparable

77 he measurement of key properties such as the evanescent field into the vacuum cladding with nanometer

78 The evanescent field is made accessible through the use of a

79 erformed at the SPR sensor surface where the evanescent field is the strongest.

80 An evanescent field is used to excite cleaved AMC and the r

81 single-molecule level by imaging within the evanescent field layer using total internal reflection f

82 erfaces were monitored by imaging within the evanescent field layer using total internal reflection f

83 te interface can be fluorescently excited by evanescent field light polarized either perpendicular or

84 r beam epitaxy for use in mid-infrared (MIR) evanescent field liquid sensing.

85 Evanescent field microscopy has shown that, during exocy

86 We have used evanescent field microscopy to image Annexin 2-GFP in li

87 Using two-color evanescent field microscopy, we imaged the lipid probe F

88 single granules in live cells were imaged by evanescent field microscopy.

89 The cell surface was imaged by evanescent field microscopy.

90 In order to exploit the whole evanescent field of BSW, extended three-dimensional hydr

91 e to a change of its average position in the evanescent field of excitation and can be associated wit

92 anoscale object that subsequently enters the evanescent field of the cavity perturbs the system from

93 eled biological complexes are excited by the evanescent field of the guided light.

94 in the local refractive index probed by the evanescent field of the guided optical mode in the devic

95 the Belinfante momentum to particles in the evanescent field of waveguides depends in a non-trivial

96 s formed at the antinodes of a standing-wave evanescent field on a nanophotonic waveguide.

97 recovery, bleach time, bleach intensity, and evanescent field penetration depth; the model included i

98 300-nm region measurably illuminated by the evanescent field resulting from total internal reflectio

99 biosensors are advantageous combinations of evanescent field sensing and optical phase difference me

100 range reveal a substantial potential of MIR evanescent field sensing devices for on-line in situ env

101 nce of thin film optical waveguides used for evanescent field sensing of liquid chemical and biologic

102 he polymer coating is performed by utilizing evanescent field spectroscopy in the fingerprint range (

103 ses optical gradient forces generated in the evanescent field surrounding hybrid photonic-plasmonic s

104 rs from diffraction limit due to the loss of evanescent field that carries subwavelength information.

105 support a highly-penetrating surface plasmon evanescent field that extends well into the dielectric m

106 IR) detector elements-serving as on-chip MIR evanescent field transducers in combination with tunable

107 y and tracked them in three dimensions in an evanescent field where the nanoparticles appeared bright

108 eviously derived models for diffusion in the evanescent field within the nanostructure, the diffusion

109 within 100 nm of the plasma membrane (in the evanescent field).

110 , it is possible to confine even further the evanescent field, and by varying the angle of incidence,

111 f the two chemical species, the depth of the evanescent field, and the size of the observed area on t

112 ear surface region of a sensor area with the evanescent field, any change of the refractive index of

113 ogenerated ferricyanide within the resulting evanescent field, beyond the optical interface, was dete

114 in solution diffuse through the depth of the evanescent field, but do not bind to the surface of inte

115 single atoms falling through the resonator's evanescent field, we determine the coherent coupling rat

116 senting BCECF translational diffusion in the evanescent field, were in the range 2.2-4.8 ms (0.2-1 ms

117 his work demonstrates the feasibility of new evanescent field-based biosensors that can specifically

118 Evanescent field-based fluorescence detection enabled mo

119 yond the conventional monotonic decay of the evanescent field.

120 in push and twist a probe Mie particle in an evanescent field.

121 resence of the gold nanoparticles within the evanescent field.

122 en the sample surface and the UME within the evanescent field.

123 e rate of diffusion through the depth of the evanescent field.

124 e to the enhanced intensity of the resonance evanescent field.

125 diffusion coefficient, and the depth of the evanescent field.

126 orescence microscopy utilizing the generated evanescent field.

127 both electric and magnetic components of the evanescent field.

128 abeling experiments and when visualized with evanescent-field fluorescence microscopy.

129 t various pHs and ionic strengths within the evanescent-field layer (EFL) at a water/fused-silica int

130 nic strengths within the 180-nanometer-thick evanescent-field layer at a fused-silica surface.

131 wide range of incident angles with different evanescent-field layer thicknesses, the fluorescence int

132 wide range of incident angles with different evanescent-field layer thicknesses, the fluorescence int

133 proteins in different colors, and two-color evanescent-field microscopy was used to view single gran

134 ough quantitative analysis and modeling that evanescent fields must be precisely matched between FRET

135 measure the optical interaction between the evanescent fields of microfiber and ovarian cancer inter

136 e-, orientation-, and polarization-dependent evanescent fields on the surfaces of A431 cancer cells a

137 f plasmon waves in biological samples, these evanescent fields reflect the changes in EGFR kinase dom

138 zing the enhanced sensitivity of superchiral evanescent fields to mesoscale chiral structure.

139 Here we demonstrate a superlens for electric evanescent fields with low losses using perovskites in t

140 eview existing techniques for characterizing evanescent fields, and we provide a roadmap for comparin

141 ample surface, we observe a maximum of these evanescent fields.

142 cting with the external medium through their evanescent fields.

143 asured the collective extension of DNA using evanescent fluorescence.

144 red both dsDNA occupancy and extension using evanescent fluorescence.

145 se electric guided CADP modes induced by the evanescent guided Lamb acoustic waves and remained Landa

146 ted for the elliptical Gaussian shape of the evanescent illumination after background subtraction.

147 odes (supported in the SiN nanomembranes) by evanescent interactions with the third object.

148 g the change in refractive index (RI) in the evanescent layer.

149 Evanescent light-light that does not propagate but inste

150 An experimental probe, evanescent magneto-optic Kerr effect (e-MOKE) spectrosco

151 electron-hole pairs due to the tunneling of evanescent modes from the thermal radiator to the photov

152 y black body radiation, at shorter distances evanescent modes start to contribute, and at separations

153 conceptualization of systems capitalizing on evanescent modes such as thermophotovoltaic converters a

154 geometry-dependent because of conduction via evanescent modes, approaching the theoretical value 4e(2

155 transport near the Dirac point is carried by evanescent modes, resulting in unconventional "pseudo-di

156 eds the blackbody limit due to tunnelling of evanescent modes.

157 combination of electromagnetic tweezers and evanescent nanometry that readily captures the forced un

158 The evanescent nature of reactive oxygen and nitrogen specie

159 s a partial catalog of the problems that the evanescent nature of trainees' relationships with others

160 of the incident light through the holes and evanescent near-field from plasmonic excitations.

161 TIRF) confines fluorescence excitation by an evanescent (near) field, and it is a popular contrast ge

162 on Spin Echo Spectroscopy (GINSES), where an evanescent neutron wave probes the fluctuations close to

163 onal neurotransmitter that causes release of evanescent NO; and (c) ATP acts in parallel with the VIP

164 nsitive label-free biosensor technique using evanescent optical waves generated at a biocompatible su

165 hat exactly the opposite can be the case for evanescent optical waves.

166 sides, addition of electron beams transforms evanescent oscillations to the standing ones.

167 th decent performance by taking advantage of evanescent photon tunneling from the emitter to the abso

168 f nonreciprocity even under weak-coupling to evanescent photons.

169 nce of this subset and the cells' relatively evanescent presence in the periphery suggest that these

170 titative imaging that demonstrates discrete, evanescent, quantized proteolytic events attributable to

171 l granules of activated neutrophils, lead to evanescent quantum bursts of proteolytic activity before

172 combination has been tested by detecting the evanescent scattering from bacterial spores at the senso

173 luoRBT) combines magnetic tweezers, infrared evanescent scattering, and single-molecule FRET imaging,

174 These gap junctions must be evanescent since individual oocytes lose contact with sh

175 nsitivity, especially for devices exploiting evanescent spectroscopy.

176 nt results favor thermal magnons rather than evanescent spin waves as the mediator of the coherent ac

177 Evanescent standing wave (SW) illumination is used to ge

178 an efficiently tunnel through low-decay-rate evanescent states of perovskite oxide SrTiO(3) resulting

179 a-related conditions that include relatively evanescent symptoms and a few longer-lasting ones.

180 chnique depends on interaction with only the evanescent tails of the fields, allowing for a minimally

181 ium ions have been studied using the optical evanescent technique of dual polarization interferometry

182 Since the coupling between the two fibers is evanescent, the attenuation of the excitation pulse is l

183 architecture that exploits inherently strong evanescent THz field arising within the aperture to miti

184 tion from ballistic to pseudo-diffusive like evanescent transport below a carrier density of ~10(10)

185 theoretical prediction for the emergence of evanescent transport mediated pseudo-diffusive transport

186 ms are extracted with high isolation through evanescent tunneling.

187 eys to make decisions based on a sequence of evanescent, visual cues assigned different logLR, hence

188 linear optical cavity-based system combining evanescent wave (EW) with high-sensitive cavity ring-dow

189 luorophore is monitored as a function of the evanescent wave absorption of an analyte-sensitive indic

190 This study reports a reusable evanescent wave aptamer-based biosensor for rapid, sensi

191 The depth of the evanescent wave at different layers was altered by tunin

192 ng analyte-containing medium by means of the evanescent wave at the fiber boundary.

193 The concentration detection limit of the MB evanescent wave biosensor is 1.1 nM.

194 zed in a polymer matrix, as detected with an evanescent wave biosensor, was investigated.

195 Evanescent wave biosensors have found a wide array appli

196 The application of evanescent wave cavity ring-down spectroscopy (EW-CRDS)

197 Evanescent wave cavity ringdown spectroscopy (EW-CRDS) i

198 sociation kinetics and diffusion through the evanescent wave contribute to the fluorescence fluctuati

199 sociation kinetics and diffusion through the evanescent wave contribute to the fluorescence fluctuati

200 We have prepared a novel optical fiber evanescent wave DNA biosensor using a newly developed mo

201 duct of two near-field factors: the depth of evanescent wave excitation and a distance-dependent coup

202 ends on two near-field factors: the depth of evanescent wave excitation and a distance-dependent coup

203 liter with an automated array biosensor and evanescent wave excitation for fluorescence measurements

204 The limited evanescent wave excitation volume makes it possible to m

205 s fit to a model describing diffusion in the evanescent wave excitation.

206 Combining the advantages of evanescent wave fiber optic sensor and microfluidic tech

207 We have developed a disposable evanescent wave fiber optic sensor by coating a molecula

208 An evanescent wave fiber optic sensor for detection of Esch

209 g diode based sensor and the other one is an evanescent wave fiber optic sensor.

210 The subfield of evanescent wave fluorescence biosensors has also matured

211 We used multicolor evanescent wave fluorescence microscopy imaging to follo

212 We used evanescent wave fluorescence microscopy to observe assem

213 Fluorescence in the film was excited by the evanescent wave from attenuated total reflection spectro

214 s based on the excitation confinement of the evanescent wave generated at the glass/cell interface.

215 ver, the effective path length, d(e), of the evanescent wave in an ATR measurement, i.e., the equival

216 lished optical fiber, providing an efficient evanescent wave interaction.

217 t for sensor coating, a waveguide to provide evanescent wave interrogation, and it can be easily exte

218 An evanescent wave is generated by total internal reflectio

219 emblies in bacteria lacking MCP complexes by evanescent wave microscopy [6].

220 Using evanescent wave microscopy and green fluorescent protein

221 ugh a single molecular contact is tracked by evanescent wave microscopy as a force is exerted through

222 Here we developed a dual-color evanescent wave microscopy method to simultaneously meas

223 Direct observation of actin filaments by evanescent wave microscopy showed that cofilins from fis

224 Using in vitro evanescent wave microscopy, we demonstrated that GMF pot

225 us to fully characterize all propagating and evanescent wave modes from the MetaSurfaces.

226 ssion is due to the enhanced propagating and evanescent wave modes inside the ADNZ medium thanks to t

227 nanoplasmonic absorption of the fiber optic evanescent wave occurs.

228 ch or exceed the distance encompassed by the evanescent wave of the surface plasmon.

229 An evanescent wave optical fiber biosensor based on titania

230 of excitation; that is, it does not require evanescent wave or surface-plasmon excitation.

231 ation), the detection volume is a product of evanescent wave penetration depth and distance-dependent

232 ated with the maximum overlap between the IR evanescent wave penetration depth and the analyte diffus

233 A single evanescent wave possesses a spin component, which is ind

234 Fiber-optic evanescent wave spectroscopy (FEWS)-FTIR with endoscope-

235 easured by infrared reflection-absorption or evanescent wave spectroscopy) during increase in protein

236 tives, nonlinear methods, fluorescence dyes, evanescent wave tailoring, and point-spread function eng

237 on, d(p), to estimate the path length of the evanescent wave through the sample.

238 We demonstrate the use of the calibrated evanescent wave to resolve the 20.1 +/- 0.5-nm step incr

239 The measured evanescent wave transfer function was then used to conve

240 r a broad visible spectrum and the waveguide evanescent wave was used to excite the Raman signals of

241 sociation kinetics and diffusion through the evanescent wave, in solution, contribute to the fluoresc

242 of contributions from diffusion through the evanescent wave, in solution, has been published previou

243 mats has subsections on planar, fiber optic, evanescent wave, refractive index, surface plasmon reson

244 paves the way for the establishment of novel evanescent wave-based systems.

245 es the metal layer and illuminates muscle by evanescent wave.

246 the distance-dependent intensity decay of an evanescent wave.

247 g angle with the depth of penetration of the evanescent wave.

248 tection on a liquid-solid interface based on evanescent wave.

249 ng refraction, total internal reflection and evanescent wave.

250 Azimuthal beam scanning makes evanescent-wave (EW) excitation isotropic, thereby produ

251 anescent-wave sensors to detect the mid-(IR) evanescent-wave absorbance spectra of small areas of bio

252 ically active solid-liquid interface for the evanescent-wave cavity-ring-down spectroscopic (EW-CRDS)

253 ee orders of magnitude over the conventional evanescent-wave coupling.

254 offers important advantages over traditional evanescent-wave detection strategies which rely on recor

255 An automated array biosensor based on evanescent-wave excitation has been developed for the de

256 One unknown hampering the interpretation of evanescent-wave excited fluorescence intensities is the

257 Evanescent-wave excited fluorescence technology has been

258 A "turn-on" evanescent-wave fiber biosensor based on functional nucl

259 d neuropeptidergic vesicles by wide-field or evanescent-wave microscopy shows that a separate immobil

260 ion spectra obtained in the transmission and evanescent-wave modes are discussed.

261 ticles synthesized beforehand, or in-situ by evanescent-wave photopolymerization on the fiber.

262 compared to previous sizes and geometries of evanescent-wave sensors (e.g., commercially available in

263 Fiber-optic near-ultraviolet evanescent-wave sensors have been constructed, and their

264 strips 30-50 microm thick and 2 mm wide, as evanescent-wave sensors to detect the mid-(IR) evanescen

265 g require the quantitative interpretation of evanescent-wave-excited images.

266 ctively detected by following changes in the evanescent-wave-induced fluorescence anisotropy of the i

267 TIRF-FOB are (i) fluorescence is excited via evanescent waves and amplified via liposomes; (ii) the u

268 gs illuminate the unusual transverse spin in evanescent waves and explain recent experiments that hav

269 24% of the generated evanescent waves are not absorbed by nano-TiO(2) and ret

270 propagating waves are focused and, moreover, evanescent waves are reconstructed in the image plane.

271 Evanescent waves are ubiquitous at interfaces with optic

272 dy the lateral and vertical distributions of evanescent waves around the image plane of such a lens,

273 e technique uses the unique polarizations of evanescent waves generated by total internal reflection

274 se component of the spin angular momentum of evanescent waves gives rise to lateral optical forces on

275 stigations into the near-field properties of evanescent waves have revealed polarization states with

276 This superlens would allow the recovery of evanescent waves in an image via the excitation of surfa

277 rse-spin angular-momentum-density shifts for evanescent waves in magneto-optic waveguide media.

278 r momentum conversion in magneto-optic media evanescent waves in opposite propagation-directions.

279 imit of light, which is causd by the loss of evanescent waves in the far field that carry high spatia

280 length objects by transforming the scattered evanescent waves into propagating waves in an anisotropi

281 The metamaterial converts evanescent waves into propagative waves exciting trapped

282 impedance analysis and optical sensing using evanescent waves like SPR.

283 mbdaSH/4 (or lambdapump/8) without involving evanescent waves or subwavelength apertures.

284 ercome the diffraction limit by transforming evanescent waves responsible for imaging subwavelength f

285 These modes are evanescent waves that form, for example, surface plasmon

286 ect on the propagation and penetration of IR evanescent waves through the film.

287 ial variations of the wave field (carried by evanescent waves), as the one created by edges or small

288 cal spots can actually be formed without any evanescent waves, making far-field, label-free super-res

289 a conventional biosensor waveguide based on evanescent waves, the ARROW structure is designed to all

290 ature information of an object is carried by evanescent waves, which exponentially decays in space an

291 ontact of soft objects and the scattering of evanescent waves.

292 ting light, but extraordinary confinement of evanescent waves.

293 instead of diverging, because of the role of evanescent waves.

294 resolved images by restoring propagative and evanescent waves.

295 re recorded from a patient with the multiple evanescent white dot syndrome (MEWDS) and an enlarged bl

296 ngioid streaks (ASs) and coincident multiple evanescent white dot syndrome (MEWDS) who developed chor

297 lated macular degeneration (n = 1), multiple evanescent white dot syndrome (n = 1), and nonspecific r

298 Multiple evanescent white dot syndrome is a rare self-limiting co

299 ue-like phantoms beyond the phononic crystal evanescent zone and Fresnel zone of the emitter.

300 ere rapidly and selectively bound within the evanescent zone of multimode laser-illuminated fibers.