ライフサイエンスコーパス: optical fiber

1 able internal reflection elements or tapered optical fibers).

2 mic clocks connected by a 75-meter length of optical fiber.

3 crochannel and orthogonal to the axis of the optical fiber.

4 t chemosensors located in the cladding of an optical fiber.

5 a CCD camera), that emerges from a multimode optical fiber.

6 e extracted into the polymeric coating of an optical fiber.

7 a 40-m-long continuous chemically sensitive optical fiber.

8 silanized 125 micrograms diameter multimode optical fiber.

9 ter integrated with a relatively inexpensive optical fiber.

10 nO nanostructure onto the unclad core of the optical fiber.

11 alyte due to the fabrication of the probe on optical fiber.

12 was used to determine the orientation of the optical fiber.

13 onal atoms in distant cavities coupled by an optical fiber.

14 pattern multiple light windows on a tapered optical fiber.

15 is delivered into the brain through a single optical fiber.

16 invading the recording domain of the second optical fiber.

17 lasmon resonance (SPR) on the surface of the optical fiber.

18 return from NV centers delivered by the same optical fiber.

19 ss radio-frequency (RF) signal transfer over optical fiber.

20 abricated onto the planar region of d-shaped optical fibers.

21 ns emitted from each atom and guided through optical fibers.

22 semiconductors within microstructured silica optical fibers.

23 e (SNARF-1) were sequentially deposited onto optical fibers.

24 ory of polarization mode dispersion (PMD) in optical fibers.

25 pled to a 64-channel photomultiplier tube by optical fibers.

26 ts of low-cost multimode plastic-clad silica optical fibers.

27 detect photons scattered by the cladding in optical fibers.

28 um generation and track a GHz pulse train in optical fibers.

29 rn that cannot be achieved with conventional optical fibers.

30 imit on the information transfer capacity in optical fibers.

31 enging to generate deep-UV SHs especially in optical fibers.

32 capacity N-times with respect to single mode optical fibers.

33 take advantage of the typical peculiarity of optical fibers.

34 ed Cherenkov radiation - dispersive waves in optical fibers.

35 skull, form a transcranial window or implant optical fibers.

36 in PDMS and the encapsulation of a multimode optical fiber (100-microm core diameter) in the PDMS; th

37 e is fixed by the diameter of the individual optical fibers (25 microm), while the outer radius is de

38 oxygen-sensing film coated at the end of an optical fiber [a Pt(II) porphyrin immobilized in polysty

39 The implementation of sensor over optical fiber adds up other advantages such as real time

40 ocation along the CBORR by placing a tapered optical fiber against the CBORR, thus enabling on-column

41 light generated by four-wave mixing (FWM) in optical fibers against uncorrelated photons originating

42 detection setup by using a long, single-mode optical fiber and a fast photodiode.

43 al flexibility, and growing functionality of optical fiber and fiber optic devices are enabling sever

44 Using an erbium-doped optical fiber and measuring the time evolution of the pu

45 o coupling between the photonic modes of the optical fiber and the localized surface plasmon resonanc

46 red on simple, disposable plastic coupons or optical fibers and are interrogated using a miniature fi

47 tion methods, thanks to the light guiding in optical fibers and small distance between the fiber tips

48 nd electronic applications such as nonlinear optical fibers and solar cells.

49 result has been a renaissance of interest in optical fibers and their uses.

50 the core of a large-core-diameter (365 mum) optical fiber, and allows for nearly 100% light coupling

51 conducted to the microscope in a single-mode optical fiber, and images are scanned using vibrations o

52 applied to data transmission over multimode optical fiber, and the result is an optical multiplexing

53 Optical fibers are an established platform for both comm

54 Because the optical fibers are constructed and the functional materi

55 re completely flat on the surface, where two optical fibers are fixed in a long optical path length c

56 Furthermore, two optical fibers are integrated into the device and aligne

57 e fashion (interstitial treatments) in which optical fibers are placed intratumorally through needles

58 a reference material and in combination with optical fibers are read-out via a compact phase-fluorome

59 The optical fibers are used to minimize electromagnetic inte

60 Hydrogel optical fibers are utilized for continuous glucose sensi

61 Intraoperative tissues are illuminated by optical fibers arranged in a ring around a center-mounte

62 An inexpensive optical fiber-array enables the capture of the transmitt

63 d(2+) was demonstrated using microstructured optical fiber as the sensing platform which is important

64 enum sulphide (ZnO/MoS2) over unclad core of optical fiber as the transducer layer followed by the la

65 te clinical signs had hematic fluid in their optical fibers at postmortem, presumably limiting NIr ex

66 A new easy-to-use, homemade optical fiber based cell for bidimensional spectroelectr

67 An optical fiber based well array platform was used for sim

68 Optical fibers based on this waveguide mechanism support

69 An optical fiber-based 3D hybrid cell consisting of a coaxi

70 We developed a robust optical fiber-based biofilm sensor ready to be applied i

71 A buried optical fiber-based detection module and a micro-stirrin

72 Optical fiber-based mapping systems are used to record t

73 Our device integrates an optical fiber-based, on-chip detection unit with a dropl

74 A home-built dual-color optical-fiber-based time-resolved near-infrared (IR) flu

75 lopment of a surface plasmon resonance (SPR) optical fiber biosensor based on tilted fiber Bragg grat

76 An evanescent wave optical fiber biosensor based on titania-silica-coated l

77 This paper reports on the application of an optical fiber biosensor for real-time analysis of cellul

78 Furthermore, we demonstrated that the optical fiber biosensors can be easily regenerated for r

79 Surface Plasmon resonance (SPR) optical fiber biosensors constitute a miniaturized count

80 detection of C-reactive protein (CRP) using optical fiber Bragg gratings (FBGs).

81 The optical fiber bridge is easy to implement, inexpensive,

82 ice is reported that employs an out-of-plane optical fiber bridge to generate two excitation and two

83 rsion coefficient, inherent in many types of optical fibers, broadens and eventually destroys all ini

84 ing radioactivity was transmitted through an optical fiber bundle and imaged by an intensified charge

85 lanar bead arrays, flow-through microarrays, optical fiber bundle arrays and nanobarcodes.

86 An optical fiber bundle containing 6000 individual 3.1-mum-

87 An optical fiber bundle containing approximately 50,000 ind

88 The platform utilizes an optical fiber bundle containing approximately 50,000 ind

89 sition-sensitive photomultiplier tube via an optical fiber bundle made of 8 x 16 square multiclad fib

90 g, fabricated through chemical etching of an optical fiber bundle, and coated with gold, was used for

91 ded into the etched microwells of an imaging optical fiber bundle.

92 hemically etched into the surface of a glass optical fiber bundle.

93 etched distal end of a 3200-microm-diameter optical fiber bundle.

94 head equipped with a UV-LED light source and optical fiber bundles for efficient fluorescence light c

95 diameter) into microwells created by etching optical fiber bundles.

96 urrent sensors are prepared with 100-microns optical fiber but could also be prepared using submicrom

97 iable photonic sensor assembly by bending an optical fiber by 90 degrees and molding its tip into a s

98 n the surface of a long-period grating (LPG) optical fiber by immersion alternately in poly-allylamin

99 aneous decay, photon leakage of cavities and optical fibers by choosing the experimental parameters a

100 The tip of a thin (200 microm) optical fiber can detect the coherent activity of a smal

101 cts with a probe molecule immobilized on the optical fiber, can be monitored in real-time.

102 ution networks, including the development of optical fibers capable of differentiating biomass from c

103 way in extreme aspect ratio, small-diameter optical fiber capillary templates.

104 Optetrode manufacture employs a unique optical fiber-centric coaxial design approach that yield

105 Microstructured optical fibers containing microchannels and Bragg gratin

106 by a special probe tip, which consists of an optical fiber core for light passage, surrounded by a go

107 MBs have been designed and immobilized on an optical fiber core surface via biotin-avidin or biotin-s

108 e the fluorescence is collected end-on by an optical fiber coupled to a photomultiplier, thus, creati

109 ived interest as it can potentially increase optical fiber data transmission capacity N-times with re

110 ricated by mounting a commercial double-clad optical fiber (DCF) onto two piezo bimorphs that are ali

111 mors were thermally ablated by percutaneous, optical fiber-delivered, NIR radiation using a 3.5-W ave

112 Our sensor head is an optical fiber device just a few millimeters thick and ye

113 We implanted an optical fiber device that delivered NIr (670 nm) to the

114 to aminopropyltriethoxysilane, onto a glass optical fiber end-face transducer, thus producing a nove

115 We have prepared a novel optical fiber evanescent wave DNA biosensor using a newl

116 However, in plastic optical fibers, experimental and theoretical results ind

117 Optical fiber extrinsic Fabry-Perot interferometry (EFPI

118 The utility of a two-photon optical fiber fluorescence probe (TPOFF) for sensing and

119 as the light source, piped the light with an optical fiber from the flash through a collimating lens

120 Optical fibers guide light between separate locations an

121 An optical fiber has been developed with a maneuverable min

122 onstrations of quantum digital signatures in optical fiber have typically been limited to operation o

123 Although acutely implanted optical fibers have previously been used in such studies

124 rs, using a plastic scintillator mated to an optical fiber, have been tested in the laboratory with t

125 neurons of the somatosensory cortex using an optical fiber imaging approach.

126 Detection was achieved by using the surround optical fiber immunoassay (SOFIA) to measure the product

127 Anesthetized, ovariectomized mice had optical fibers implanted in the vicinity of GnRH neurons

128 nal optical transformers onto the core of an optical fiber in a single step, mimicking the 'campanile

129 Using a laser-coupled optical fiber in conjunction with a recording microelect

130 a new device based on the use of UV-vis bare optical fibers in a long optical path length configurati

131 Poly(methyl methacrylate) (PMMA) optical fibers in a series of different diameters were u

132 hototherapy delivered to murine lungs via an optical fiber increased the rate of CO elimination while

133 e longitudinal hippocampal artery through an optical fiber inserted into the brain.

134 lving stereotaxic insertion of a micron-size optical fiber into mouse brain.

135 ntation procedure of introducing the sensing optical fiber into the middle-ear and its aiming at the

136 2-mm-diameter laser beam, and the detection optical fiber is 5 mm in diameter.

137 nique for lipase enzyme immobilization on an optical fiber is reported.

138 developed an approach in which a near-field optical fiber is translated toward the cell surface.

139 When an etched optical fiber is used to deliver laser energy to a sampl

140 A continuous chemically sensitive optical fiber is used with optical time-of-flight chemic

141 the bandwidth of multimode glass and plastic optical fibers is modal dispersion, in which different o

142 500 in aqueous solutions using a liquid core optical fiber (LCOF) Raman cell made from Teflon-AF.

143 first steps in manipulating complex light in optical fibers, likely providing new opportunities for h

144 photon pairs, which are distributed over an optical fiber link of 55 m in one experiment, or over a

145 al bend-coupled small-core-diameter (50 mum) optical fiber loop.

146 Physisorption of BSA-Ac onto a fused-silica optical fiber lowers the accessibility of Ac to O2, wher

147 A biocompatible step-index optical fiber made of poly(ethylene glycol) and alginate

148 We also convert one of them, the optical fiber/micropillar hybrid, into a soft optical co

149 jacent holes at the tip of a microstructured optical fiber (MOF).

150 An optical-fiber-nanowire hybridized UV-visible photodetect

151 rincipal light source powering the worldwide optical fiber network.

152 pacity is rapidly reaching limits imposed by optical fiber nonlinear effects.

153 se in the power that can be propagated in an optical fiber of two orders of magnitude.

154 e array was fabricated by coating individual optical fibers of 25-microm diameter with a 1-microm lay

155 s the development of an innovative plasmonic optical fiber (OF) immunosensor for the detection of cyt

156 iniature spectrometer, LED light source, and optical fibers on a rotating benchtop apparatus, the lig

157 errogated by light polarized radially to the optical fiber outer surface, so as to maximize the optic

158 hototherapy delivered to murine lungs via an optical fiber placed in the esophagus.

159 Blue light was delivered via an optical fiber placed near the surface of the infected CN

160 For this purpose, a simple coupled-optical-fiber-polydimethylsiloxane (PDMS) microdevice wa

161 y argon laser radiation delivered through an optical fiber positioned by a manual micromanipulator.

162 signals produced are measured via two joined optical fibers positioned closely to the backside of the

163 illumination (753 nm for 20 minutes) through optical fibers prepositioned in target tissues by using

164 o layers of sol-gel coating to the end of an optical fiber probe end.

165 n this work, we report the development of an optical fiber probe that could potentially find use as a

166 Using a ruggedized optical fiber probe with a diamond-based ATR, we have co

167 second from each site before biopsy using an optical fiber probe.

168 he MBs have been immobilized onto ultrasmall optical fiber probes through avidin-biotin binding.

169 The application of hollow-core optical fibers provides a miniaturized sample container

170 re successfully deposited on a side-polished optical fiber, providing an efficient evanescent wave in

171 In single-mode optical fibers, Rayleigh scattering serves as the domina

172 Implanted optical fibers readily interface with in vivo electrophy

173 on of the fundamental thermodynamic noise in optical fiber resonators and shows that the actual therm

174 Coating the membrane onto the surface of an optical fiber resulted in a device with high pH-sensing

175 nt in the liver and kidney by using a single optical fiber resulted in well-demarcated cylindrical zo

176 of magnitude on our bend-coupled small-core optical fiber results, in which a detection limit of 5.3

177 vision multiplexing (MDM)- using a multimode optical fiber's N spatial modes as data channels to tran

178 The use of a flexible optical fiber scope is an accurate, fast, and practical

179 tion by chest roentgenogram (CXR) and by the optical fiber scope.

180 r the fabrication and characterization of an optical fiber sensor for the detection of profenofos bas

181 ime-BSA, was covalently immobilized onto the optical fiber sensor surface.

182 Optical fiber sensors using fluorescent probes distribut

183 lms are commonly used to prepare fluorescent optical fiber sensors.

184 urther, the realization of sensor probe over optical fiber substrate adds remote sensing and online m

185 based sensor for urinary p-cresol testing on optical fiber substrate is developed.

186 cteriophage T4 was covalently immobilized on optical fiber surface and the E. coli binding was invest

187 efficient optical gate can be realized in an optical fiber that has been engineered with molecular-sc

188 Over 1.1 kilometers of a specially designed optical fiber that minimizes mode coupling, we achieved

189 Optical fibers that have been pulled to a distal-end dia

190 ray comprises approximately 3,000 individual optical fibers that were etched chemically.

191 o be accomplished by noisy channels (such as optical fibers) that generally result in exponential att

192 e similarity of these spicules to commercial optical fibers, the absence of any birefringence, the pr

193 m into long-lived acoustic excitations in an optical fiber through the process of stimulated Brilloui

194 cond time scales using the dispersion in the optical fiber, thus, slowing down the ultrafast signal t

195 r that is attached covalently to a silanized optical fiber tip surface by photocontrolled polymerizat

196 vious probes which utilized a power-limiting optical fiber to transmit the laser pulses through the p

197 We used ultrashort pulses in microstructured optical fibers to demonstrate the formation of an artifi

198 e describe a method to construct implantable optical fibers to readily manipulate neural circuit elem

199 are generating a new assessment of multimode optical fibers to serve as high-speed fiber links.

200 APD) detectors coupled, via short lengths of optical fibers, to arrays of lutetium oxyorthosilicate (

201 loped a methodology based on special tapered optical fibers (TOFs) to deliver highly localized light

202 e of an argon ion laser and monitored via an optical fiber using a miniature spectrometer.

203 ay of complex light manipulation in few-mode optical fibers using optical MMs.

204 of dye-labeled cytochrome c' attached to the optical fiber via colloidal gold, along with fluorescent

205 The proximal end of the optical fiber was attached to a 15-mW, 635-nm diode lase

206 An optical fiber was implanted just dorsal to the hippocamp

207 The optical fiber was used to couple light into the microcha

208 The tip of the optical fiber was visible through several centimeters of

209 A bundle of optical fibers was assembled with each fiber carrying a

210 a microfluidic system integrated with buried optical fibers was developed to detect viral pathogens o

211 ing approximately 600 individual gold-coated optical fibers was dipped into epoxy.

212 REVIEW The most important feature of an optical fiber waveguide is its bandwidth, which defines

213 e techniques for fabricating nanometer-sized optical fibers, we describe the various types of transdu

214 roscope objective or high numerical aperture optical fiber were used for collection of the fluorescen

215 Optical fibers were chronically implanted to selectively

216 Optical fibers were used for connecting the detector hea

217 er microarray technology based on bundles of optical fibers where the probes are packed in hexagonal

218 ensor is based on gold-nanoparticle-modified optical fiber, where the gold nanoparticle surface has b

219 p of a 1,000-microns (0.03937-inch)-diameter optical fiber, which allowed retention in soft tissue af

220 ore that is attached to the distal end of an optical fiber, which binds free Cu(II) with high affinit

221 olymer coating is deposited on the tip of an optical fiber, which can then be used to record the pH b

222 e polymer consecutively on the endface of an optical fiber, which formed the FP cavity.

223 p with an optical path length of 7mm between optical fibers, which were placed into the microchip, us

224 ons entirely between first order solitons in optical fibers whose propagation evolution is described

225 Successful use of implantable optical fibers will allow for long-term control of mamma

226 by reducing the laser beam size by using an optical fiber with 25 mum core diameter in a vacuum matr

227 A novel optical fiber with a diffusing tip for direct intramural

228 lix symmetry were produced by twisting glass optical fiber with a noncircular core cross section as i

229 employs a long-period grating written on an optical fiber with a resonance wavelength that is sensit

230 odes can be (de)multiplexed over a multimode optical fiber with higher than -15 dB mode selectivity a

231 self-recovery is demonstrated on single-mode optical fibers with 80 microns diameter (3.1 microns act

232 ers of scintillator crystals coupled through optical fibers with acceptable performance in terms of e

233 Using optical fibers with enhanced Rayleigh backscattering pro

234 We demonstrate that optical fibers with tapered tips can be used to illumina

235 a wavelength of 689 nm delivered through an optical fiber, with irradiance of 1800 mW/cm2 and fluenc