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1 icroscope, magnetic tip, or super-resolution optical imaging.
2 t up to 1700 nm for high-performance in vivo optical imaging.
3 lar imaging agent for magnetic resonance and optical imaging.
4 using laser tweezers, particle tracking and optical imaging.
5 nal techniques such as X-ray diffraction and optical imaging.
6 iction using novel 3-dimensional tomographic optical imaging.
7 me were monitored with 14.0-T MR imaging and optical imaging.
8 ide range of applications in cell and tissue optical imaging.
9 orophore (IRdye800CW) to allow near-infrared optical imaging.
10 erent anti-Stokes Raman scattering nonlinear optical imaging.
11 ular deprivation (MD) using intrinsic signal optical imaging.
12 sensitivity, detectability and linearity in optical imaging.
13 es for individual cells at the resolution of optical imaging.
14 icrosurgical preparation of live animals for optical imaging.
15 ith properties desirable for single-molecule optical imaging.
16 mal surrounding brain tissue, as measured by optical imaging.
17 diagnostically active quantum dots (QDs) for optical imaging.
18 velopment using exposed-cortex multispectral optical imaging.
19 imodality approaches such as PET/MRI and PET/optical imaging.
20 2 to chromatic and achromatic stimuli, using optical imaging.
21 croneedle penetration following staining and optical imaging.
22 imaging and the resolution limits of diffuse optical imaging.
23 echniques, such as two-photon microscopy and optical imaging.
24 pocytes scatter light and limit the depth of optical imaging.
25 green and red upconversion luminescence for optical imaging; 2) Efficient nonradiative relaxation an
26 ed by in vivo indocyanine green-enhanced NIR optical imaging (3.86-fold increase in radiant efficienc
27 her established using PSMA-based nuclear and optical imaging agents and by biodistribution, blocking,
30 Quantitative analysis of contrast-enhanced optical imaging allows for potential therapeutic monitor
34 ery small numbers of tumor cells via in vivo optical imaging and also allows the isolation and analys
36 Here, we report high-throughput real-time optical imaging and broadband in situ spectroscopy of in
37 to treatment with paclitaxel was measured by optical imaging and by analysis of lactate dehydrogenase
39 rtially closing the gap between conventional optical imaging and electron microscopy for elucidation
42 (SPECT) positron emission tomography (PET), optical imaging and magnetic resonance imaging (MRI).
44 e in responders was significantly reduced in optical imaging and MR imaging (optical imaging: mean, -
45 Quantitative perfusion measurements with optical imaging and MR imaging correctly identified pati
46 ect antibodies bound within the eye, we used optical imaging and observed accumulation of the antibod
47 parallel biophotonics fields such as in vivo optical imaging and optogenetics, are spearheading their
49 ty of this device can be further expanded to optical imaging and patterned electrical microstimulatio
50 hese findings, we conclude that fluorescence optical imaging and photoacoustic imaging are promising
51 oteins, and have been explored as agents for optical imaging and photosensitization of tumors in pre-
55 intracellular interrogation was verified by optical imaging and recording the transmembrane resting
59 es the traditional depth limits of ballistic optical imaging and the resolution limits of diffuse opt
60 We first discuss general considerations in optical imaging and then present salient characteristics
64 samples of blood and tissue and with in vivo optical imaging and were refined by microscopic examinat
65 simultaneous neuroimaging (intrinsic-signal optical imaging) and electrode recordings from alert, ta
66 n of behavioral measures, electrophysiology, optical imaging, and biochemical and electrochemical rec
67 lation was combined with molecular genetics, optical imaging, and biochemistry to show that Nck-depen
69 compared with tumor therapeutic response and optical imaging, and tumors were histologically analyzed
71 otential of this 24-colour (super-multiplex) optical imaging approach for elucidating intricate inter
72 we used in vivo phage display methods and an optical imaging approach: fluorescence molecular tomogra
73 of human skin abnormalities by non-invasive optical imaging are aided by spectroscopic methods that
75 Recent advances in molecular biology and optical imaging are being applied to astrocytes in new a
77 /magnetic resonance imaging and multichannel optical imaging are particularly promising because they
78 Molecular imaging technologies, especially optical imaging, are uniquely suited to illuminate compl
79 as to develop and assess near-infrared (NIR) optical imaging as a novel noninvasive method of detecti
80 fluorescent contrast agents are emerging in optical imaging as sensitive, cost-effective, and nonhar
81 allow for simultaneous electrophysiology and optical imaging, as well as optogenetic modulation of th
86 have increased the achievable resolution of optical imaging, but few fluorescent proteins are suitab
87 ing tritium-labeled particles and that using optical imaging, but quantitative divergence existed.
88 segmentation aspects in the context of cell optical imaging, (c) histogram and co-occurrence summary
89 single ryanodine receptor channel recording, optical imaging (Ca(2+) and membrane potential), and con
92 tions.Optical clearing of tissue has enabled optical imaging deeper into tissue due to significantly
93 We developed molecular assays and portable optical imaging designs that permit on-site diagnostics
95 uman testing and approval of investigational optical imaging devices as well as contrast agents for s
96 ored the feasibility of repurposing existing optical imaging devices for fluorescence-guided surgery.
97 inated the potential for existing open-field optical imaging devices with overlapping excitation and
99 us injections of Dox@PEG-HAuNS, fluorescence optical imaging (emission wavelength = 600 nm, excitatio
101 aptive optics (HAO) has pushed the limits of optical imaging, enabling high-resolution near diffracti
106 xpression, and magnetic resonance and direct optical imaging for blood-brain barrier permeability and
108 s demonstrate the utility of superresolution optical imaging for measuring the size of AQP4 supramole
109 ble for single-channel electrophysiology and optical imaging from a wide variety of preparations, ran
110 introduced as a theranostic nanoplatform for optical imaging guided photothermal therapy (PTT) using
111 f hyperbolic phonon polaritons in near-field optical imaging, guiding, and focusing applications.
114 pite recent rapid progress, super-resolution optical imaging has yet to be widely applied to non-biol
115 Considerable advances in cancer-specific optical imaging have improved the precision of tumor res
116 ndent memory function, we determined through optical imaging how memory is encoded at the whole-netwo
117 distribution of P-Dex was investigated using optical imaging, immunohistochemistry, and fluorescence-
118 Optical clearing methods can facilitate deep optical imaging in biological tissue by reducing light s
119 tion of myeloperoxidase (MPO) activity using optical imaging in infiltrating neutrophils under inflam
125 ising method for deep-tissue high-resolution optical imaging in vivo mainly owing to the reduced scat
128 proteins has led to significant advances in optical imaging, including the unambiguous tracking of c
132 her, this study reveals that superresolution optical imaging is a powerful approach for studying epid
135 ution at the cellular level and sensitivity, optical imaging is highly attractive for identifying cel
139 using in vivo indocyanine green-enhanced NIR optical imaging, magnetic resonance imaging, and ex vivo
140 y reduced in optical imaging and MR imaging (optical imaging: mean, -21.5%; MR imaging: mean, -41.0%;
141 h), while in nonresponders it was increased (optical imaging: mean, 10.8%; P = .075; MR imaging: mean
142 We have developed a quantitative in vivo optical imaging method for detection of CA IX as a marke
143 e, we developed quantitative superresolution optical imaging methodology to measure AQP4 cluster size
144 uronal activity with single-cell resolution, optical imaging methods have revolutionized neuroscience
150 optoacoustic imaging device that fuses laser optical imaging (OA) with grayscale ultrasonography (US)
152 on of multiplexed immunolabeling in vivo for optical imaging of AML cellxenografts that provides repr
156 Herein we describe a method for nanoscopic optical imaging of buried polymer nanostructures without
159 fragment complementation biosensor based on optical imaging of Firefly luciferase (FLuc), to quantit
160 achieve this goal, one promising approach is optical imaging of fluorescent calcium indicators, but t
164 on, we evaluated in vitro force contraction, optical imaging of inflammation, echocardiography and bl
168 tecture of the visual cortex was assessed by optical imaging of intrinsic signals, and chondroitinase
169 l interactions in V1 of the tree shrew using optical imaging of intrinsic signals, optogenetic stimul
171 extures of boojums using polarized nonlinear optical imaging of molecular alignment and explain our f
174 lymerase 1 (PARP1) is a promising target for optical imaging of OSCC with the fluorescent dye PARPi-F
176 mum in size, large enough to enable in situ optical imaging of particle orientation, were synthesize
177 synaptophysin, and SV2A via mutagenesis and optical imaging of pHluorin-tagged proteins in cultured
180 hrough the surface of the brain, and in-vivo optical imaging of sound-evoked activity was achieved th
181 ar optical susceptibilities, allowing direct optical imaging of the atomic edges and boundaries of a
182 combine electrical measurements and magneto-optical imaging of the domain wall displacement with mic
191 t be imaged using these standard techniques, optical imaging offers a unique imaging alternative.
192 Furthermore, biodistribution studies through optical imaging (OI) and the use of radiolabelled polyme
193 d on the basis of serum luciferase activity, optical imaging (OI) of the fluorescent protein mCherry,
194 step towards in vivo deep tissue noninvasive optical imaging, optogenetics and photodynamic therapy.
195 ng techniques, such as electrophysiology and optical imaging, or whole-brain imaging methods, such as
196 .15, P < .0001) and relative bioluminescence optical imaging photon signal (0.57 x 10(7) photons per
197 .15, P < .0001) and relative bioluminescence optical imaging photon signal (0.57 x 10(7) photons per
199 f well-defined compositions using a powerful optical imaging platform consisting of confocal spectros
200 rent techniques (magnetic resonance imaging, optical imaging, positron emission tomography, X-ray com
202 ng L-012, an ROS-sensitive chemiluminescence optical imaging probe, and analyzed the expression of hy
203 n silica layer, were synthesized and used as optical imaging probes under a differential interference
209 uced structures, three-dimensional nonlinear optical imaging reveals that topological charge is conse
210 edented power gain is expected to enable new optical imaging, sensing, manipulation and treatment app
211 nation therapy group did both MR imaging and optical imaging show substantial decreases in apparent d
213 tent luminescence are attractive for in vivo optical imaging since they have a long lifetime that all
214 performed concurrently with two-dimensional optical imaging spectroscopy measuring hemodynamic chang
215 oked cortical hemodynamic responses, we used optical imaging spectroscopy to produce functional maps
219 encephalography, magnetoencephalography, and optical imaging studies in patients and animal models ha
221 ctive functions of microglia with a focus on optical imaging studies that have revealed a role of the
225 The limited resolution of a conventional optical imaging system stems from the fact that the fine
226 Because of the limited depth of field of optical imaging systems, one of the major challenges in
229 localization microscopy (PLM), a pointillist optical imaging technique for the detection of nanoscale
230 y developed a new isotropic 1-mum resolution optical imaging technique termed micro-optical coherence
231 Here, we report a functional low-coherence optical imaging technique that allows in vivo depth-reso
232 optical responses, we developed a nonlinear optical imaging technique that allows rapid and all-opti
233 mography (OCT) is a noninvasive, label-free, optical imaging technique that can visualize live cells
235 spectra, label-free; however, when using any optical imaging technique, including SRS, there is an ad
238 tems that can be exploited, for example, for optical imaging techniques and different fluorescence as
239 f neuronal activity in the living brain with optical imaging techniques became feasible owing to the
241 ,in vitroandin vivoelectrophysiological, and optical imaging techniques in genetically manipulated mi
243 t the SF organization previously revealed by optical imaging techniques simply reflects non-stimulus-
252 is is made possible by integrating ultrafast optical imaging technology, self-focusing microfluidic t
254 ndow from ca. 600 to 1000 nm used, e.g., for optical imaging, the absolute Phi(f) of a set of NIR chr
255 ven the significant clinical implications of optical imaging, there is an urgent need to standardize
257 ing to offer high-resolution cross-sectional optical imaging through several millimeters to centimete
258 staging and pre-surgical planning, and with optical imaging to aid surgical removal of tumors, would
261 ing cocaine intoxication, we used microprobe optical imaging to compare dynamic changes in intracellu
263 erefore took advantage of recent advances in optical imaging to develop an assay to visualize collage
265 cinoma (ccRCC) might benefit from the use of optical imaging to facilitate the intraoperative detecti
269 directly examine this relationship, we used optical imaging to observe odor-evoked activity in popul
270 using gene targeting, electrophysiology, and optical imaging to study the response properties of TAAR
275 SIGNIFICANCE: Bioluminescent and fluorescent optical imaging was combined with X-ray and muCT imaging
276 At different times during tumor development, optical imaging was performed using a S100A9-specific pr
281 in vitro CSD in chick retina with intrinsic optical imaging, we addressed the role of NR2A in CSD.
282 After mapping the IAF, AAF, and AI by using optical imaging, we injected a distinct fluorescent trac
284 With sub-diffraction, three-dimensional, optical imaging, we visualised nsP3-positive structures
286 IgG diffusion coefficients from integrative optical imaging were similar to those obtained from ex v
287 s likewise monitored in vivo by non-invasive optical imaging, where gel localization to the affected
288 in vivo imaging and analysis that widens the optical imaging window to the near-infrared spectrum, th
289 pressing ccRCC xenografts were visualized by optical imaging with (125)I-girentuximab-IRDye800CW.
297 o circumvent these constraints, we performed optical imaging with voltage-sensitive dye (VSD) in an a
298 y means of intracellular recordings and fast optical imaging with voltage-sensitive dyes, we show tha
300 al modalities including ultrasound, MRI, and optical imaging without the need for current or new intr
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