ライフサイエンスコーパス: fiber-optic

1 regnated face of the plate by a three-legged fiber optic.

2 mum, molecular weight cut-off: 10 kDa) using fiber optics.

3 ontrol and cannot be adjusted using standard fiber optics.

4 d using a diode pumped solid state laser and fiber-optics.

5 Here, we report a plasmonic fiber optic absorbance biosensor (P-FAB) strategy for ma

6 Activation of the fiber optic, accomplished with a one-click mechanism, en

7 asonography, OCT catheters consist of simple fiber optics and contain no transducers within their fra

8 or SDM systems but also broadly for few-mode fiber optics and its applications in amplifiers, lasers,

9 external tethers associated with traditional fiber optic approaches.

10 this technology in our study, we employed a fiber optic array to create thousands of femtoliter-size

11 Because of the advantages of the fiber-optic array platform over other array formats, inc

12 uorescence-activated cell sorting (FACS) and fiber-optic array scanning technology (FAST) to identify

13 Here we report an approach that uses fiber-optic array scanning technology (FAST), which appl

14 analysis of many yeast cells contained in a fiber-optic array, allowing for thorough characterizatio

15 ns were synthesized and included in a custom fiber-optic array.

16 A fiber-optic assay for amplified DNA products has been de

17 -shelf components, such as LEDs, trifurcated fiber optic assembly, a capillary Z-type flow cell, and

18 c microprobe made with a built-in monolithic fiber-optic ball lens, which achieves ultrahigh-resoluti

19 specifically ZIF-8 and ZIF-93, are grown on fiber optic based surface plasmon resonance (FO-SPR) sen

20 Computer simulations of the fiber optics based on the finite element method (FEM) we

21 in the potential research avenue of SPR and fiber optics based SPR for chemical and biological sensi

22 work, the development and testing of a novel fiber-optic based label-free biosensor is presented, who

23 We developed a portable fiber-optic based OCT imaging device that requires only

24 They use a novel fiber optic-based method to simultaneously image and exc

25 Fiber optic-based near-infrared spectroscopy (FONIRS) se

26 ve developed a unique accessory, noncontact, fiber optic-based Raman spectroscopy device that has the

27 Fiber-optics-based cuvetteless micro-spectrophotometry h

28 A fiber optic bead-based sensor array platform has been em

29 expression was assayed by a high-throughput fiber-optic bead array consisting of 388 genes and by RN

30 r is reported that employs a cascade of four fiber-optic beam splitters connected in series to genera

31 A label-free fiber optic biosensor based on a long period grating (LP

32 We propose the first black phosphorus (BP) - fiber optic biosensor for ultrasensitive diagnosis of hu

33 ved using the same immunoassay reagents in a fiber optic biosensor or a planar array biosensor.

34 evels in seawater using a fluorescence-based fiber optic biosensor.

35 sed, total internal reflection fluorescence, fiber-optic biosensor (TIRF-FOB) for protein detection,

36 A fiber-optic biosensor array is described for the simulta

37 We developed a fiber-optic biosensor for the detection of CCHF IgG anti

38 A new, portable fiber-optic biosensor has been used to detect staphyloco

39 We showed that the fiber-optic biosensor is 10-times more sensitive than co

40 We believe that the fiber-optic biosensor is a suitable alternative to ELISA

41 fic, sensitive assay for SEB on the portable fiber-optic biosensor permits easy monitoring of clinica

42 A fiber-optic biosensor using an aptamer receptor has been

43 In this study, a fluorescence-based fiber-optic biosensor was used to quantify the heterogen

44 Finally, we evaluated the fiber-optic biosensor with two CCHF patient sera.

45 d herein investigates a novel arrangement of fiber-optic biosensors based on a tilted fiber Bragg gra

46 Submicrometer fiber-optic biosensors have been developed and used to m

47 tify molecular interactions using disposable fiber-optic biosensors that address samples from an open

48 Fiber-optic biosensors that are selective for nitric oxi

49 This fiber optic bridge was integrated into a single cell ana

50 A fixed, fused fiber optic bundle, less than 1 millimeter in diameter,

51 In this paper, a novel, fiber-optic bundle based detection system is introduced,

52 A fiber-optic bundle was used for the gas detection and sh

53 A fiber-optic bundle, positioned approximately 2 mm from a

54 d attached to the common end of a bifurcated fiber-optic bundle.

55 s paper, we present a platform incorporating fiber-optic bundles and antibody-based microarrays to pe

56 en fabricated on the distal face of coherent fiber-optic bundles.

57 Here, we redress this problem by using a fiber-optic cable to couple an infrared (IR) laser to a

58 Images of the end facets of these fiber optic cables were captured using the smart phone a

59 istances through corrosion-free, lightweight fiber optic cables.

60 have emerged to transform telecommunication fiber-optic cables into dense seismic arrays that are co

61 y for transgene delivery and implantation of fiber-optic cables to produce light-dependent activation

62 ew other oncological applications in which a fiber optic can be threaded to the desired locations via

63 ng the inhibitory opsin archaerhodopsin, and fiber-optic cannulae were implanted above the indirect p

64 (DPC) and finally detected by a miniaturized fiber optic CCD spectrophotometer at 520 nm, exploiting

65 d an indirect detection sensor (scintillator/fiber-optic/CCD) for electron energy-loss spectroscopy.

66 A 3.7 Fr catheter with a fiber-optic channel was constructed based on a 40 MHz cl

67 The transmitted light is read by a fiber-optic charge coupled device (CCD) spectrometer.

68 ponents, in complete analogy to thin-film or fiber-optic chemical sensors.

69 e periodic groundwater sampling method and a fiber-optic CO2 sensor for real-time in situ monitoring

70 Measurements by the fiber-optic CO2 sensor, showing obvious leakage signals,

71 elecommunication revolution, but single-mode fiber-optic communication systems have been driven to th

72 We believe that BP-fiber optic configuration opens a new bio-nano-photonic

73 We implemented a fiber-optic confocal fluorescence endomicroscope to dire

74 Fiber-optics confocal microscopy images resembled images

75 Fourier analysis of fiber-optics confocal microscopy images showed that the

76 g heart using extracellular fluorophores and fiber-optics confocal microscopy.

77 tissues in living rat hearts with real-time fiber-optics confocal microscopy.

78 e scanning tip of the SECM was replaced by a fiber optic connected to a xenon lamp and was rapidly sc

79 (ERY) detection method is proposed using the fiber optic core decorated with the coatings of silver a

80 A fiber-optic coupled attenuated total reflection (ATR)-FT

81 em, as a multiplexed detector with multiple, fiber-optic-coupled, fluorescence-detection cells excite

82 Integrating organic nanorobots to inorganic fiber optics creates a hybrid system that we demonstrate

83 th superficial and even deep-seated by using fiber optic delivered light.

84 typically requires remote light sources and fiber-optic delivery schemes that impose considerable ph

85 A structures were integrated within portable fiber optic detection system, what is important for the

86 d growing functionality of optical fiber and fiber optic devices are enabling several new modalities

87 Small size fiber optic devices integrated with chemically sensitive

88 hine learning to delineate data harnessed by fiber-optic distributed acoustic sensors (DAS) using fib

89 d imagery and custom high spatial resolution fiber-optic distributed temperature sensors reveal compl

90 A high-density fiber-optic DNA microarray sensor was developed to monit

91 In this study, a fiber-optic DNA microarray using microsphere-immobilized

92 This work suggests that fiber-optic DNA microarrays can be used for rapid and se

93 sticide has been achieved by manufacturing a fiber-optic dual-head device containing both analyte-sen

94 This mechanism has allowed preparation of fiber optic dye-based nitric oxide sensors, which have b

95 on-invasive modality that uses assemblies of fiber optic emitters and detectors on the cranium for vo

96 hrough which nanoplasmonic absorption of the fiber optic evanescent wave occurs.

97 Fiber-optic evanescent wave spectroscopy (FEWS)-FTIR wit

98 y sensing formats has subsections on planar, fiber optic, evanescent wave, refractive index, surface

99 A fiber-optic fiber attached to a bundle of drivable micro

100 nm) using a custom-built 1.7-cm path length fiber-optic flow cell.

101 A micrometer-sized fiber-optic fluorescence biosensor for glucose has been

102 Fiber-optic fluorescence imaging systems include portabl

103 A novel fiber-optic fluorescence sensor based on a controlled-re

104 couples an automatic cigarette smoke machine fiber-optic fluorometer for real-time monitoring of the

105 zed surface plasmon resonance (LSPR)-coupled fiber-optic (FO) nanoprobe is reported as a biosensor th

106 laser absorption spectrometer making use of fiber optics for delivery and return of low intensity di

107 s for pharmacological infusions and tethered fiber optics for optogenetics, are not ideal for minimal

108 sive to prepare and can be easily coupled to fiber optics for remote sensing capabilities.

109 to overcome the limitations of conventional fiber optics-for example, by permitting low-loss guidanc

110 This work demonstrates that the fiber-optic FP/HW Raman diagnostic platform developed ha

111 oved by about 20% compared to that of larger fiber-optic glucose sensors.

112 The results open the door to a new area of fiber optic-guided sensitizer delivery for the potential

113 When a fiber-optic illuminator is placed in contact with the en

114 ese SERS probes are fabricated from coherent fiber-optic imaging bundles, allowing for the formation

115 fluorescent dye morin was immobilized on the fiber-optic imaging sensor, which allowed the in situ lo

116 gated by in situ fluorescence imaging with a fiber-optic imaging sensor.

117 We have developed a fiber-optic imaging technique termed optical frequency-d

118 the use of a surface plasmon resonance (SPR) fiber-optic immunosensor for selective cellular detectio

119 es light-induced neuronal excitation without fiber-optic implantation; that is, this opsin enables tr

120 YFP or control eYFP protein and intracranial fiber optic implants.

121 mvents problems associated with conventional fiber-optics, including limited signal collection effici

122 The functionalized prGO film coated on the fiber-optic interferometer shows high sensitivities for

123 urgery, pediatric procedural sedation, awake fiber-optic intubation, cardiac surgery, and bariatric s

124 characterized by voltammetry, electrolysis, fiber-optic IR spectroscopy, and ESR measurements.

125 y was assessed and recorded using transnasal fiber-optic laryngoscopy.

126 ck-looped heating system, utilizing a 980-nm fiber optic laser, was integrated into nsPEF electrodes

127 oped a novel technique in which with a 23 Ga fiber optic light pipe is used to identify the cut ends

128 2.5 minutes to unilateral illumination with fiber-optic light ranging from 5,000 to 10,000 lux.

129 methanol/acetic acid (6:4) and quantified by fiber optic linear array spectrophotometry based on the

130 iginated from the need to biofunctionalize a fiber optic Long Period Grating (LPG) that is tuned in a

131 ample volumes and the use of a high-density, fiber-optic microarray format make this method highly ad

132 In contrast, the fiber-optic microarray platform described herein is anal

133 for parallel analysis of mRNA isoforms on a fiber-optic microarray platform.

134 The fiber-optic microarray system has a detection limit of 1

135 We applied a fiber-optic microarray to record cellular communication

136 performed using fluorescence detection on a fiber-optic microarray.

137 Since fiber-optic microarrays can be prepared with different p

138 The new fiber-optic microbial biosensor is an ideal tool for on-

139 A fiber-optic microbial biosensor suitable for direct meas

140 We report a nonconcurrent dual-modality fiber-optic microendoscope (named SmartME) that integrat

141 However, fiber optic microendoscopes have limited optical section

142 Fiber optic microendoscopy has shown promise for visuali

143 Miniaturized fiber optic microscopy permits cellular level imaging in

144 The detection limit of a fiber-optic microsensor array was investigated for simul

145 A fiber optic microsphere-based oligonucleotide array is d

146 broblast cells into an optically addressable fiber-optic microwell array such that each microwell acc

147 graphene oxide (prGO) film is deposited on a fiber-optic modal interferometer, acting as both the flu

148 We report an innovative fiber optic nano-optrode based on Long Period Gratings (

149 nd ultrasensitive biosensing method based on fiber optic nanogold-linked immunosorbent assay is repor

150 Fiber-optic near-ultraviolet evanescent-wave sensors hav

151 ng quantum circuits and optical photons in a fiber optic network.

152 ively demonstrates that regionally extensive fiber-optic networks can effectively be utilized for a h

153 and experimental realization of a SPR based fiber optic nicotine sensor having coatings of silver an

154 A fiber-optic OCT imaging system was used to image the mur

155 his research presents a novel, time-resolved fiber-optic "Optrode" system for accurate real-time in s

156 ualizing the surface of the vocal folds with fiber-optic or rigid endoscopy and using stroboscopic or

157 onance spectroscopy and of O2 consumption by fiber-optic oximetry.

158 partial pressure by surgical insertion of a fiber optic oxygen probe into granulomas in the lungs of

159 Measurements using the fiber-optic oxygen sensor were 132 +/- 7.5 mm Hg (day 0)

160 i-OVA) and anti-mouse IgG antibody using the fiber optic particle plasmon resonance (FOPPR) biosensor

161 A fiber optic particle plasmon resonance (FOPPR) immunosen

162 Henceforth, this DNAzyme-based fiber optic PCR assay provides a universally applicable,

163 A fiber-optic periodontal endoscope was developed to aid i

164 microspheres, interrogated with a dedicated fiber-optic phase-sensitive luminometer.

165 Here, using fiber-optic photometry combined with optogenetic and mol

166 The presented method for preparing fiber optic plasmonic sensors provides high throughput a

167 developed a novel system using a specialized fiber-optic platform and have combined it with statistic

168 A probe (0.5 mm in diameter) with fiber-optic PO2, PCO2, and pH sensors was placed percuta

169 tter than that achieved using a conventional fiber-optic portable spectrometer.

170 asured using an applanation tonometer with a fiber-optic pressure sensor.

171 r for LPS detection based on a facile U-bent fiber optic probe (UFOP) technology.

172 er studies with an endoscopically compatible fiber optic probe are under way for multicenter clinical

173 A fiber optic probe consisting of a 1.0 mm coherent image

174 The experiments were performed on the fiber optic probe fabricated with Ag/ZnO: graphene layer

175 A multispectral fiber optic probe has been developed that enables simult

176 A near infrared spectroscopic fiber optic probe was placed over the hypothenar eminenc

177 optical spectroscopic technique along with a fiber optic probe was used to test the hypothesis that d

178 a plasmonic sandwich immunoassay on a U-bent fiber optic probe with gold plasmonic (AuNP) labels func

179 Spectra were measured by means of a fiber optic probe, and they were analyzed using an analy

180 The study confirms that using GO modified fiber optic probe, the sensitivity is enhanced to 24% an

181 Using a 250-mum-wide fiber optic probe, we captured nanometer sarcomere lengt

182 om human cortical bone using microscope- and fiber optic probe-based Raman systems and tested whether

183 ion is collected with the aid of a cryogenic fiber optic probe.

184 ye of a FRET pair to the end of a near-field fiber optic probe.

185 is monitored simultaneously in situ, using a fiber optic probe/diffuser to provide the UV light to ac

186 obtained intermittently through the use of a fiber-optic probe (for the case of oxygen) and biochemic

187 e topography is analyzed by scanning a sharp fiber-optic probe across the sample using shear force fe

188 ecorded at 4.2 K with the aid of a cryogenic fiber-optic probe and a commercial spectrofluorimeter.

189 med in a matter of seconds with the aid of a fiber-optic probe directly inserted into the liquid cryo

190 ploying a standard excitation source where a fiber-optic probe is coupled to a tungsten-halogen lamp,

191 Here, we demonstrate a specifically designed fiber-optic probe that enables thermal activation with s

192 Here, we demonstrate an ultracompact fiber-optic probe where a diamond microcrystal with a we

193 near-field interaction of light from a sharp fiber-optic probe with a sample of interest to image sur

194 erials and equipment, utilizing a bifurcated fiber-optic probe, standard disk electrodes of millimete

195 e light (473 nm) via a chronically implanted fiber-optic probe.

196 perature (4.2 K) with the aid of a cryogenic fiber-optic probe.

197 rine-19 magnetic resonance relaxometry and a fiber-optic probe.

198 The choice of fiber optic probes (fused silica versus polymer), the op

199 ular in vivo biosensing when using ultrathin fiber optic probes for research purposes.

200 DiFC uses custom-designed, dual fiber optic probes that are placed in contact with the s

201 xperiments were performed with two different fiber optic probes viz.

202 in the renal cortex and medulla, combination fiber-optic probes comprising a fluorescence optode to m

203 Fiber-optic probes have been developed for FTIR in livin

204 The antibodies were immobilized on silica fiber-optic probes via five different immobilization str

205 pic measurements from two different kinds of fiber-optic probes.

206 ve this limitation with the use of cryogenic fiber-optic probes.

207 we developed a scintillating balloon-enabled fiber-optic radionuclide imaging (SBRI) system to improv

208 We have developed a novel 785 nm excitation fiber-optic Raman endoscope that can simultaneously acqu

209 us fingerprint (FP) and high-wavenumber (HW) fiber-optic Raman endoscopy associated with genetic algo

210 17, 646, and 751 cm(-1))) from the ball-lens fiber-optic Raman probe for quantitative analysis of fib

211 ire Raman signals generated from a ball-lens fiber-optic Raman probe for quantitative analysis of in

212 spectroscopy system coupled with a ball-lens fiber-optic Raman probe is used for in vivo oral tissue

213 ctroscopy system coupled with a miniaturized fiber-optic Raman probe was utilized to realize real-tim

214 ork aims to assess the clinical utility of a fiber-optic Raman spectroscopy with nature-inspired gene

215 tic Raman probe for quantitative analysis of fiber-optic Raman spectroscopy.

216 tical NO2(-) ion sensor was performed with a fiber optic reflectance spectrophotometer.

217 , combining non-invasive techniques, such as fiber optic reflectance spectroscopy (FORS), Raman spect

218 e, commercial diode array spectrometer and a fiber-optic reflectance probe monitors the wavelength of

219 In this study, fiber-optic reflection-based pH micro (mu)-probes (tip d

220 In this work, using a simple macroscopic, fiber-optic resonator where the nonreciprocity is induce

221 A fiber optic salivary cortisol sensor using a contemporar

222 d laser characteristics compared RNA and DNA fiber optic SAs with other nonlinear optic materials.

223 We report the development of an all-fiber-optic scanning endomicroscope capable of high-reso

224 chemical imaging is achieved by combining a fiber-optic scanning probe microscope with laser-induced

225 Distributed fiber-optic sensing technology coupled to existing subse

226 er' configuration, bridging the FRET and the fiber-optic sensing technology, may serve as a platform

227 y provides a tunable pulsed random laser for fiber-optic sensing, speckle-free imaging, and laser-mat

228 This fiber optic sensor (FOS) operates by monitoring the LPFG

229 Combining the advantages of evanescent wave fiber optic sensor and microfluidic technology, an all-f

230 have developed a disposable evanescent wave fiber optic sensor by coating a molecularly imprinted po

231 The fiber optic sensor detects targets in the low nM range a

232 An evanescent wave fiber optic sensor for detection of Escherichia coli (E.

233 In this piece of work, a fiber optic sensor has been fabricated and characterized

234 covalently immobilized on the surface of the fiber optic sensor.

235 nsor and the other one is an evanescent wave fiber optic sensor.

236 the development of a nitric oxide selective fiber optic sensor.

237 Silica-based distributed fiber-optic sensor (DFOS) systems have been a powerful t

238 earch represents the first report of in situ fiber-optic sensor monitoring of oxygen content from the

239 Fiber optic sensors are widely used in environmental, bi

240 Fiber-optic sensors based on referenced read-out with a

241 CO2, and pHm, monitored simultaneously using fiber-optic sensors in a single, small probe placed perc

242 or in performance to conventional leaky-mode fiber optic silica HWGs having similar optical pathlengt

243 oscopy (FEWS)-FTIR with endoscope-compatible fiber-optic silver halide probes is feasible, and could

244 A micrometer-size, fluorescent fiber-optic sodium sensor is described, based on a highl

245 aveguide capillary cell (LWCC) and miniature fiber optic spectrometer, with detection wavelength set

246 In this paper, we report the use of an NIR fiber-optic spectrometer with a high-speed diode array f

247 around a standard microscope and a portable fiber-optic spectrometer.

248 ibers and are interrogated using a miniature fiber-optic spectrometer.

249 hese light sources is comparable to standard fiber-optic spectrophotometer light sources.

250 e has been monitored using either a portable fiber-optic spectrophotometer or the built-in camera of

251 al light transmission were determined with a fiber-optic spectrophotometer.

252 ound specificity as compared to conventional fiber optic SPR sensor (detection limit: 391 CFU/mL, sen

253 sixfold reduction in the detection limit of fiber-optic strain sensing using this configuration.

254 rdi et al. described an ultrahigh-resolution fiber-optic strain sensor.

255 ased seismic survey was conducted close to a fiber-optic submarine cable, and 50 km-long distributed

256 sed for bioassay development on a home-built fiber optic surface plasmon resonance (FO-SPR) biosensor

257 e ligation chain reaction (LCR) assay on the Fiber Optic Surface Plasmon Resonance (FO-SPR) platform,

258 In this study, a solid-phase, fiber optic surface plasmon resonance (FO-SPR) technique

259 disulfide (MoS(2)) nanosheets functionalized fiber optic surface plasmon resonance (SPR) immunosensor

260 Fiber optic surface plasmon resonance (SPR) sensor utili

261 A home-built fiber optic surface plasmon resonance platform (FO-SPR)

262 channel multianalyte sensing probe employing fiber optic surface plasmon resonance technique.

263 In this paper we used an in house developed fiber-optic surface plasmon resonance (FO-SPR) biosensor

264 present a short immunoassay (10 min) using a fiber-optic surface plasmon resonance (FO-SPR) biosensor

265 tration in serum using an in-house developed fiber-optic surface plasmon resonance (FO-SPR) biosensor

266 Fiber-optic surface plasmon resonance (SPR) sensors are

267 Fiber optic-surface plasmon resonance (FO-SPR) can overc

268 tured illumination microendoscopy (DSIMe), a fiber optic system that can perform structured illuminat

269 related single-photon counting (TCSPC)-based fiber optics system to measure the intensity, emission s

270 The fiber-optic system uses a Complementary Metal-Oxide Sili

271 The usefulness of a fiber optic technique for generating singlet oxygen and

272 has >10-fold greater sensitivity than prior fiber-optic techniques and attains the noise minimum set

273 re validated with SPR using both Biacore and fiber optic technology.

274 d visible light (<1mWcm(-2)) with the aid of fiber optics technology.

275 ress towards a miniaturized, multifunctional fiber-optic technology that integrates informational com

276 acoustic sensing deployed on regional unlit fiber-optic telecommunication infrastructure (dark fiber

277 ht at different colors, forming the basis of fiber-optic telecommunication networks that shuttle data

278 Reference measurements with fiber optic temperature sensors confirm the accuracy of

279 Fiber-optic temperature sensors were inserted into the f

280 ke optogenetic approaches that rely on rigid fiber optics tethered to external light sources, these n

281 imal behavior, light-delivery systems beyond fiber optic tethering and large, head-mounted wireless r

282 ehaving subjects, without limitations set by fiber optic tethers or operational lifetimes constrained

283 fication of glucose by smartphone-integrated fiber optics that overcomes existing technical limitatio

284 The fiber optic tip delivered pheophorbide molecules and sin

285 se the use of a robust, biopsy needle-based, fiber-optic tool for routine clinical quantification of

286 This probe integrates a fiber-optic tract for the delivery of laser light with a

287 r pressure was measured noninvasively with a fiber optic transducer.

288 arily on visual examinations supplemented by Fiber Optic Transillumination (FOTI) and radiography, wi

289 ld Method - DSTM), bitewing radiography, and Fiber Optic Transillumination (FOTI).

290 to the achievable capacity in long distance fiber optic transmission systems.

291 O) modulators encode electrical signals onto fiber optic transmissions.

292 describe the concept of a novel implantable fiber-optic Turbidity Affinity Sensor (TAS) and report o

293 ber facilitate ultrashort pulse delivery for fiber-optic two-photon fluorescence imaging.

294 addition) was monitored with backscattering fiber optics under strongly attenuated laser power (7 mW

295 ndependent electrospray interface as well as fiber optic UV detection.

296 er we have described a potentially miniature fiber-optic vibrometer based on a modified Michelson int

297 nipulated, polarized, and read out through a fiber-optic waveguide integrated with a two-wire microwa

298 Using appropriate light sources guided by fiber optics, we determined a detection limit of 10(2) C

299 A fiber optic with a ring electrode can also be used to el

300 ization of a surface plasmon resonance based fiber optic xanthine sensor using entrapment of xanthine