ライフサイエンスコーパス: optical imaging

1 re detectable by magnetic resonance (MR) and optical imaging.

2 ing power of X-rays to increase the depth of optical imaging.

3 croneedle penetration following staining and optical imaging.

4 using laser tweezers, particle tracking and optical imaging.

5 imaging and the resolution limits of diffuse optical imaging.

6 echniques, such as two-photon microscopy and optical imaging.

7 pocytes scatter light and limit the depth of optical imaging.

8 icroscope, magnetic tip, or super-resolution optical imaging.

9 t up to 1700 nm for high-performance in vivo optical imaging.

10 lar imaging agent for magnetic resonance and optical imaging.

11 nal techniques such as X-ray diffraction and optical imaging.

12 iction using novel 3-dimensional tomographic optical imaging.

13 me were monitored with 14.0-T MR imaging and optical imaging.

14 nfrared (NIR) and short-wave infrared (SWIR) optical imaging.

15 imit severely the performances of biomedical optical imaging.

16 plays the same role as the point emitter in optical imaging.

17 ssessment of the severity of psoriasis using optical imaging.

18 ed to achieve real-time calcium fluorescence optical imaging.

19 xenograft model by sequential immuno-PET and optical imaging.

20 ar, when combined with long-term, wide-field optical imaging.

21 green and red upconversion luminescence for optical imaging; 2) Efficient nonradiative relaxation an

22 ed by in vivo indocyanine green-enhanced NIR optical imaging (3.86-fold increase in radiant efficienc

23 ommonly used FDA-approved agent for clinical optical imaging, administered through injections only, d

24 Consequently, this pH-activatable optical imaging agent may be clinically beneficial in di

25 We exploit its use as an optical imaging agent to specifically target PARP1 expre

26 comprises a DCNP core, acting as the NIR-II optical imaging agent, and a PDA shell, acting as the PA

27 her established using PSMA-based nuclear and optical imaging agents and by biodistribution, blocking,

28 SCLC xenografts using PSMA-based nuclear and optical imaging agents.

29 somal nanoparticles can serve as bimodal PET/optical imaging agents.

30 Quantitative analysis of contrast-enhanced optical imaging allows for potential therapeutic monitor

31 Optical imaging allows for simultaneous recording from n

32 ery small numbers of tumor cells via in vivo optical imaging and also allows the isolation and analys

33 Both external optical imaging and autoradiography confirmed the high s

34 to treatment with paclitaxel was measured by optical imaging and by analysis of lactate dehydrogenase

35 photon tags contributes to high-dimensional optical imaging and characterization in numerous fields.

36 e impedance results have been validated with optical imaging and flow cytometry analysis that were pe

37 (SPECT) positron emission tomography (PET), optical imaging and magnetic resonance imaging (MRI).

38 Optical imaging and micro-SPECT imaging at 1 d after the

39 parallel biophotonics fields such as in vivo optical imaging and optogenetics, are spearheading their

40 In this issue of Neuron, using in vivo optical imaging and optogenetics, Hill et al. (2015) rep

41 ty of this device can be further expanded to optical imaging and patterned electrical microstimulatio

42 oteins, and have been explored as agents for optical imaging and photosensitization of tumors in pre-

43 clots within the lungs with NIR fluorescence optical imaging and positron-emission tomography.

44 The optical imaging and radiotracer studies confirmed that g

45 We used voltage-sensitive dye optical imaging and somatosensory and motor behavioral t

46 Here, we combine room-temperature nano-optical imaging and spectroscopic analysis of excitons i

47 es it enables novel solutions for high-speed optical imaging and spectroscopy.

48 Advances in optical imaging and statistical analyses of acquired opt

49 Optical imaging and stimulation are widely used to study

50 city of the readout instrumentation based on optical imaging and the implementation of microfluidics

51 es the traditional depth limits of ballistic optical imaging and the resolution limits of diffuse opt

52 visual cortical areas using intrinsic signal optical imaging and then injected fluorescently tagged r

53 We first discuss general considerations in optical imaging and then present salient characteristics

54 Bioluminescent optical imaging and transcutaneous ultrasonographic imag

55 Here we used intrinsic signal optical imaging and two-photon calcium imaging to map vi

56 rical microstimulation in tree shrews, using optical imaging and voltage-sensitive dyes.

57 lation was combined with molecular genetics, optical imaging, and biochemistry to show that Nck-depen

58 disease activity index [SDAI]), ICG-enhanced optical imaging, and DCE MR imaging.

59 Through the combination of gene expression, optical imaging, and quantitative behavioral approaches,

60 nce nanoparticles have been demonstrated for optical imaging applications in living mice.

61 Here, we demonstrate an optical imaging approach featuring quantitative phase im

62 otential of this 24-colour (super-multiplex) optical imaging approach for elucidating intricate inter

63 This study thus proposes a molecular optical imaging approach for noninvasive evaluation of c

64 ate a nondestructive high-throughput electro-optical imaging approach to quantitatively measure elect

65 we used in vivo phage display methods and an optical imaging approach: fluorescence molecular tomogra

66 lieve bridge across scales and will focus on optical imaging approaches that put opioid drug action "

67 of human skin abnormalities by non-invasive optical imaging are aided by spectroscopic methods that

68 In particular, MR and optical imaging are an attractive combination that can b

69 Recent advances in molecular biology and optical imaging are being applied to astrocytes in new a

70 Nanoprobes for MRI and optical imaging are demonstrated.

71 /magnetic resonance imaging and multichannel optical imaging are particularly promising because they

72 as to develop and assess near-infrared (NIR) optical imaging as a novel noninvasive method of detecti

73 ioallantoic membrane of chicken embryos with optical imaging as an in vivo reference standard.

74 fluorescent contrast agents are emerging in optical imaging as sensitive, cost-effective, and nonhar

75 allow for simultaneous electrophysiology and optical imaging, as well as optogenetic modulation of th

76 these guided modes is demonstrated with nano-optical imaging at the near-infrared (NIR) wavelength (1

77 Wavefront shaping techniques enable optical imaging at unprecedented depth, but attaining su

78 Super-resolution optical imaging based on the switching and localization

79 Super-resolution microscopy allows optical imaging below the classical diffraction limit of

80 enges towards the clinical implementation of optical-imaging biomarkers for the early detection of ca

81 ization of disease states could benefit from optical-imaging biomarkers.

82 have increased the achievable resolution of optical imaging, but few fluorescent proteins are suitab

83 segmentation aspects in the context of cell optical imaging, (c) histogram and co-occurrence summary

84 Unfortunately, conventional optical imaging cannot provide the spatial resolutions n

85 Multi-modal three dimensional (3D) optical imaging combining both structural sensitivity an

86 However, absorption of IR light by common optical imaging components makes mid-IR light incompatib

87 Intraoperative optical imaging could address this unmet clinical need.

88 cular phenotyping from multicontrast in vivo optical imaging data.

89 tions.Optical clearing of tissue has enabled optical imaging deeper into tissue due to significantly

90 We developed molecular assays and portable optical imaging designs that permit on-site diagnostics

91 Real-time optical imaging detected a strong tdTomato fluorescent s

92 uman testing and approval of investigational optical imaging devices as well as contrast agents for s

93 ored the feasibility of repurposing existing optical imaging devices for fluorescence-guided surgery.

94 inated the potential for existing open-field optical imaging devices with overlapping excitation and

95 Dynamic optical imaging (e.g. time delay integration imaging) is

96 Process-integrated optical imaging enabled to identify the printing failure

97 aptive optics (HAO) has pushed the limits of optical imaging, enabling high-resolution near diffracti

98 Optical imaging experiments in mice under isoflurane ane

99 Modern optical imaging experiments not only measure single-cell

100 We start with optical imaging experiments on CA1 in mice as they run a

101 d metadata of cellular electrophysiology and optical imaging experiments.

102 xpression, and magnetic resonance and direct optical imaging for blood-brain barrier permeability and

103 s demonstrate the utility of superresolution optical imaging for measuring the size of AQP4 supramole

104 Herein we explore optical imaging for NSCLC surgery using the well-studied

105 h hemodynamic measurements (intrinsic-signal optical imaging) from monkey primary visual cortex (V1)

106 introduced as a theranostic nanoplatform for optical imaging guided photothermal therapy (PTT) using

107 f hyperbolic phonon polaritons in near-field optical imaging, guiding, and focusing applications.

108 Optical imaging has become a central tool for in vivo tr

109 Optical imaging has become a powerful tool for studying

110 Optical imaging has offered unique advantages in materia

111 Optical imaging has revolutionized our ability to monito

112 Background Multispectral optical imaging has the capability of resolving hemoglob

113 pite recent rapid progress, super-resolution optical imaging has yet to be widely applied to non-biol

114 Considerable advances in cancer-specific optical imaging have improved the precision of tumor res

115 Near-infrared optical imaging holds promise for high-resolution, deep-

116 ndent memory function, we determined through optical imaging how memory is encoded at the whole-netwo

117 Here, we used integrated optical imaging in a rat self-administration and a mouse

118 Optical clearing methods can facilitate deep optical imaging in biological tissue by reducing light s

119 Optical imaging in clinical and preclinical settings can

120 We use in vivo optical imaging in Drosophila to analyze sensory adaptat

121 uper-resolution microscopy techniques enable optical imaging in live cells with unprecedented spatial

122 00-1,700 nm) window is ideal for deep-tissue optical imaging in mammals, but lacks bright and biocomp

123 el structure is reconstructed by deep tissue optical imaging in serial sectioning techniques.

124 s with specificity, allowing high-resolution optical imaging in the live mouse.

125 ctable 1 week after infection by noninvasive optical imaging in the spleen, from where it spread rapi

126 ising method for deep-tissue high-resolution optical imaging in vivo mainly owing to the reduced scat

127 e electromagnetic spectrum are essential for optical imaging in vivo.

128 Using single molecule optical imaging in Xenopus oocytes, we found that MEC-4

129 proteins has led to significant advances in optical imaging, including the unambiguous tracking of c

130 tially resolved chemical analysis, including optical imaging, inserted sensors and probes such as ele

131 Here, we describe an optical-imaging instrument that integrates a visible mul

132 The integrative optical imaging (IOI) method was employed to evaluate di

133 her, this study reveals that superresolution optical imaging is a powerful approach for studying epid

134 Optical imaging is a powerful noninvasive approach used

135 Raman-based optical imaging is a promising analytical tool for label

136 High-resolution optical imaging is critical to understanding brain funct

137 ution at the cellular level and sensitivity, optical imaging is highly attractive for identifying cel

138 Optical imaging is important for understanding brain fun

139 Sensitive and fast optical imaging is needed for scientific instruments, ma

140 Fast and sensitive optical imaging is primarily used to track luciferase-ex

141 Optical imaging is uniquely suited to assess organoid fu

142 Intrinsic signal optical imaging (ISI) is a rapid and noninvasive method

143 vidual M1 sites with ICMS + intrinsic signal optical imaging (ISOI).

144 on (ICMS) concurrently with intrinsic signal optical imaging (ISOI).

145 using in vivo indocyanine green-enhanced NIR optical imaging, magnetic resonance imaging, and ex vivo

146 ted Raman histology (SRH)(5-7), a label-free optical imaging method and deep convolutional neural net

147 An improved version of the integrative optical imaging method has been developed that substanti

148 and image the oscillation with a near field optical imaging method, from which we determine the size

149 tion have been examined with a dual-modality optical imaging method.

150 e, we developed quantitative superresolution optical imaging methodology to measure AQP4 cluster size

151 uronal activity with single-cell resolution, optical imaging methods have revolutionized neuroscience

152 Endoscopy uses optical imaging methods to investigate tissue in a non-d

153 key property that, despite many advances in optical imaging methods, remains difficult to define and

154 an optical microscopy and other conventional optical imaging methods.

155 In this article, we review optical imaging modalities alternative to fluorescence i

156 study is to provide an overview of emerging optical imaging modalities and novel artificial intellig

157 We used optical imaging, MRI, and field potential and potassium

158 interrogated by macroscopic and microscopic optical imaging, nuclear medicine imaging, MRI, and even

159 optoacoustic imaging device that fuses laser optical imaging (OA) with grayscale ultrasonography (US)

160 We used optical imaging of action potentials and [Ca(2+)]i trans

161 Optical imaging of biofilms with single-cell resolution

162 This article reviews optical imaging of both radionuclide- and beam-based ion

163 Herein we describe a method for nanoscopic optical imaging of buried polymer nanostructures without

164 ation and simultaneous fast, high resolution optical imaging of cardiac excitation waves.

165 Optical imaging of DU-145 prostate cancer cells treated

166 Optical imaging of fast events and processes is essentia

167 fragment complementation biosensor based on optical imaging of Firefly luciferase (FLuc), to quantit

168 Conventional optical imaging of functional activation in the brain is

169 r noninvasive PET imaging and intraoperative optical imaging of GRPr-expressing malignancies.

170 ogy, in vivo two-photon calcium imaging, and optical imaging of intrinsic signal in a mouse model of

171 ve cortical areas, we undertook simultaneous optical imaging of intrinsic signals in macaque V1, V2,

172 l interactions in V1 of the tree shrew using optical imaging of intrinsic signals, optogenetic stimul

173 Non-invasive deep-tissue three-dimensional optical imaging of live mammals with high spatiotemporal

174 Label-free optical imaging of nanoscale objects faces fundamental c

175 Non-invasive optical imaging of neuronal voltage response signals in

176 We investigated the feasibility of optical imaging of NF-kappaB transcription factor activa

177 lymerase 1 (PARP1) is a promising target for optical imaging of OSCC with the fluorescent dye PARPi-F

178 ances in the MR, PET, SPECT, ultrasound, and optical imaging of ovarian cancer.

179 can be used for noninvasive PET imaging and optical imaging of prostate cancer.

180 ew microscopy methods that allow single-cell optical imaging of radionuclides are reviewed.

181 icles within bulk aqueous solutions or using optical imaging of single particles.

182 hrough the surface of the brain, and in-vivo optical imaging of sound-evoked activity was achieved th

183 ar optical susceptibilities, allowing direct optical imaging of the atomic edges and boundaries of a

184 combine electrical measurements and magneto-optical imaging of the domain wall displacement with mic

185 Using high-resolution optical imaging of the meninges in living animals, we sh

186 Optical imaging of the OB has proven to be a key tool in

187 Although high-resolution optical imaging of the whole brain in small animals has

188 Multiple scattering limits the contrast in optical imaging of thick specimens.

189 Optical imaging of this novel murine model, coupled with

190 Optical imaging of TMDs using photoluminescence and Rama

191 ols that allow for markedly improved in vivo optical imaging of tumorigenic processes.

192 Optical imaging of voltage indicators based on green flu

193 Three-dimensional (3D) optical imaging of whole biological organs with microsco

194 Optical imaging of whole, living animals has proven to b

195 PET and NIRF optical imaging offer complementary clinical application

196 t be imaged using these standard techniques, optical imaging offers a unique imaging alternative.

197 Furthermore, biodistribution studies through optical imaging (OI) and the use of radiolabelled polyme

198 step towards in vivo deep tissue noninvasive optical imaging, optogenetics and photodynamic therapy.

199 ng techniques, such as electrophysiology and optical imaging, or whole-brain imaging methods, such as

200 .15, P < .0001) and relative bioluminescence optical imaging photon signal (0.57 x 10(7) photons per

201 .15, P < .0001) and relative bioluminescence optical imaging photon signal (0.57 x 10(7) photons per

202 Here we introduce a unique optical imaging platform and methodology for label-free

203 a low cost, high throughput, and multiplexed optical imaging platform.

204 rent techniques (magnetic resonance imaging, optical imaging, positron emission tomography, X-ray com

205 Here we report a near-infrared optical imaging probe highly specific to the hypoxic tum

206 ng L-012, an ROS-sensitive chemiluminescence optical imaging probe, and analyzed the expression of hy

207 Here, we show that AND-gate optical imaging probes that require the processing of tw

208 n silica layer, were synthesized and used as optical imaging probes under a differential interference

209 Contrast-enhanced NIR optical imaging provides a sensitive, rapid, and noninva

210 Optical imaging provides a useful platform because of it

211 Optical imaging relying on endogenous fluorescence has b

212 Advanced optical imaging revealed rapid persistent GPVI-Fc bindin

213 ue for compatibility with low input samples, optical imaging, scalability, and portability.

214 edented power gain is expected to enable new optical imaging, sensing, manipulation and treatment app

215 several applications such as nano-resolution optical imaging, sensors, and plasmonic circuits.

216 Optical imaging showed antigen-specific fluorescent sign

217 In vivo optical imaging shows that the antibody-piloted nanocapt

218 tent luminescence are attractive for in vivo optical imaging since they have a long lifetime that all

219 to cortical vasculature and imaged using 2D-optical imaging spectroscopy (2D-OIS).

220 performed concurrently with two-dimensional optical imaging spectroscopy measuring hemodynamic chang

221 oked cortical hemodynamic responses, we used optical imaging spectroscopy to produce functional maps

222 Here, we present an optical imaging strategy to visualize glycogen in live c

223 Our findings are consistent with optical imaging studies in monkeys and support the notio

224 encephalography, magnetoencephalography, and optical imaging studies in patients and animal models ha

225 ctive functions of microglia with a focus on optical imaging studies that have revealed a role of the

226 After systemic administration, optical imaging suggests that the micelles would passive

227 o shortwave infrared (SWIR) light, rendering optical imaging superior in this region.

228 ices are acquired with a preclinical in vivo optical imaging system across the entire rodent brain in

229 d controls was also performed by an external optical imaging system and autoradiography.

230 The limited resolution of a conventional optical imaging system stems from the fact that the fine

231 oncurrently using a wide-field multicontrast optical imaging system.

232 Because of the limited depth of field of optical imaging systems, one of the major challenges in

233 essment of metamaterial or metasurface-based optical imaging systems.

234 This optical imaging technique allows for monitoring of key m

235 localization microscopy (PLM), a pointillist optical imaging technique for the detection of nanoscale

236 A high-resolution, three-dimensional, optical imaging technique for the murine brain was devel

237 y developed a new isotropic 1-mum resolution optical imaging technique termed micro-optical coherence

238 Here, we report a functional low-coherence optical imaging technique that allows in vivo depth-reso

239 mography (OCT) is a noninvasive, label-free, optical imaging technique that can visualize live cells

240 spectra, label-free; however, when using any optical imaging technique, including SRS, there is an ad

241 processes of a single gold nanowire with an optical imaging technique.

242 roximately 43 to 360 nm using a micron-scale optical imaging technique.

243 f neuronal activity in the living brain with optical imaging techniques became feasible owing to the

244 pare in vivo radiologic imaging with ex vivo optical imaging techniques for assessing hypoxia, microv

245 The development of optical imaging techniques has led to significant advanc

246 Confocal and multiphoton optical imaging techniques have been powerful tools for

247 ,in vitroandin vivoelectrophysiological, and optical imaging techniques in genetically manipulated mi

248 A comprehensive review of studies evaluating optical imaging techniques is performed.

249 Among optical imaging techniques light sheet fluorescence micr

250 Existing high-dimensional optical imaging techniques that record space and polariz

251 Using pH mapping, various optical imaging techniques, and biochemical assays, we d

252 Optical imaging techniques, such as light detection and

253 bsorption at depths greater than traditional optical imaging techniques.

254 ls emanating from the brain's surface, using optical imaging techniques.

255 monitoring of neural activity in vivo using optical imaging techniques.

256 mitochondrial network using state-of-the-art optical-imaging techniques.

257 Recent advances in optical imaging technologies and chemical tissue clearin

258 Conventional optical imaging technologies had led to misidentificatio

259 or the widespread clinical implementation of optical-imaging technologies.

260 However, optical imaging technology has heretofore lacked the com

261 An optical imaging technology probes breast tissue elastici

262 ronmental microbiomes and the limitations of optical imaging technology(3-6).

263 esent a theory for time-resolved integrative optical imaging that incorporates a time-dependent effec

264 ven the significant clinical implications of optical imaging, there is an urgent need to standardize

265 For nuclear imaging techniques and optical imaging these agents are absolutely necessary.

266 staging and pre-surgical planning, and with optical imaging to aid surgical removal of tumors, would

267 vasive in vivo PET/MRI to measure hypoxia or optical imaging to analyze ROS expression.

268 Here, we use optical imaging to determine that exogenously administer

269 re, we use single-nanoparticle-level electro-optical imaging to measure structure-function relationsh

270 Here, we used real-time integrative optical imaging to measure the diffusion properties of f

271 directly examine this relationship, we used optical imaging to observe odor-evoked activity in popul

272 coherency tomography (OCT) are two powerful optical imaging tools that allow visualization of dynami

273 -modal (magnetic resonance and near infrared optical imaging) uMUC1-specific probe (termed MN-EPPT) c

274 of energy-minimizing numerical modeling and optical imaging uncovers the internal structure and topo

275 l quantification of cell viability by simple optical imaging using "single cell adhesion dot arrays"

276 We performed real-time optical imaging using a handheld dual-axes confocal fluo

277 readout using magnetic nanobeads (MNBs); (2) optical imaging using magnetic microbeads (MMBs).

278 Fluorescent optical imaging using near infrared (NIR) dyes tagged to

279 the active form of MMP-12 can be detected by optical imaging using RXP470.1-based probes.

280 Voltage-sensitive dye optical imaging verified functional, bilateral whisker r

281 ere we report a microscopy technique for the optical imaging, via the spectral tracing of deuterium (

282 Non-invasive optical imaging was conducted on lesions and non-lesiona

283 At different times during tumor development, optical imaging was performed using a S100A9-specific pr

284 Optical imaging was used to determine the cell coordinat

285 ecting this material subcutaneously in mice, optical imaging was used to quantitatively monitor phago

286 Using optical imaging we investigated blood flow regulation at

287 in vitro CSD in chick retina with intrinsic optical imaging, we addressed the role of NR2A in CSD.

288 In analogy with optical imaging, we show that PTIR takes advantage of su

289 With sub-diffraction, three-dimensional, optical imaging, we visualised nsP3-positive structures

290 IgG diffusion coefficients from integrative optical imaging were similar to those obtained from ex v

291 od will expand the scope of applications for optical imaging, where fully non-invasive interrogation

292 s likewise monitored in vivo by non-invasive optical imaging, where gel localization to the affected

293 in vivo imaging and analysis that widens the optical imaging window to the near-infrared spectrum, th

294 Optical imaging with a fluorochrome-labeled version of t

295 responses have been studied in monkeys using optical imaging with a limited field of view over visual

296 Furthermore, intraoperative optical imaging with IntegriSense 680 allowed good delin

297 Femtosecond nonlinear optical imaging with nanoscale spatial resolution would

298 Here, we combine dye-free optical imaging with optogenetic actuation to achieve dy

299 Optical imaging with visible light provides high resolut

300 o circumvent these constraints, we performed optical imaging with voltage-sensitive dye (VSD) in an a