ライフサイエンスコーパス: multiphoton microscopy

1 ic and collagen content and morphology using multiphoton microscopy.

2 extrans, assessed by intravital quantitative multiphoton microscopy.

3 Kinetics of corneal leukocytes by intravital multiphoton microscopy.

4 and processes per cell visualized in vivo by multiphoton microscopy.

5 n imaging techniques, including confocal and multiphoton microscopy.

6 its, by far the largest of any label used in multiphoton microscopy.

7 he focal point specificity characteristic of multiphoton microscopy.

8 gratory speed of pDCs as shown by intravital multiphoton microscopy.

9 asoconstrictor endothelin-1 using intravital multiphoton microscopy.

10 vapour deposited monolayer MoS2 samples with multiphoton microscopy.

11 nd closure up to 6 hours by autofluorescence multiphoton microscopy.

12 in CD were evaluated with flow cytometry and multiphoton microscopy.

13 This result was further confirmed with multiphoton microscopy.

14 olecules with deeper tissue penetration than multiphoton microscopy.

15 time to expected ovulation using intravital multiphoton microscopy.

16 r optical properties of few-layer GaSe using multiphoton microscopy.

17 when measured using intravital quantitative multiphoton microscopy.

18 uorescently labelled ipRGCs visualized using multiphoton microscopy.

19 onitored plaque formation in real time using multiphoton microscopy.

20 e regulatory co-factor 2 (NHERF2-/- mice) by multiphoton microscopy.

21 l orders of magnitude lower than traditional multiphoton microscopies.

22 We were also first to use multiphoton microscopy, a non-invasive and label-free im

23 bled intravital observation of xenografts by multiphoton microscopy, allowing us to visualise the ste

24 Multiphoton microscopy allows for deep tissue penetratio

25 d at depths beyond the reach of conventional multiphoton microscopy and adaptive optics methods, albe

26 ingle-cell RNA sequencing, three-dimensional multiphoton microscopy and bone marrow transplantation a

27 s) to the drug-eluting scaffold and employed multiphoton microscopy and fluorescence lifetime imaging

28 Using intravital multiphoton microscopy and fluorescently labeled nanopar

29 Parallel studies using multiphoton microscopy and in vivo microdialysis reveale

30 We used multiphoton microscopy and longitudinal imaging to monit

31 botic nonlinear optical system for iterative multiphoton microscopy and opto-micromachining.

32 Using complementary multiphoton microscopy and quantitative analyses in wild

33 Multiphoton microscopy and scanning electron microscopy

34 ative brain tissues and in cultures by using multiphoton microscopy and second-harmonic generation fr

35 By combining multiphoton microscopy and sequencing, we show that tens

36 the recent preclinical insights gained using multiphoton microscopy and suggests future advances that

37 By incorporating multiphoton microscopy and the dsLNA biosensor, we perfo

38 A combination of multiphoton microscopy and voltage-clamp recording was u

39 e macula densa plaque using four-dimensional multiphoton microscopy and wide-field fluorescence micro

40 hat circumvents the technical limitations of multiphoton microscopy and, as a result, provides unprec

41 ns in the mouse OB using calcium indicators, multiphoton microscopy, and diverse olfactory stimuli.

42 r scanning modalities including confocal and multiphoton microscopy, and offers artifact free reconst

43 The diameter of vessels was assessed with multiphoton microscopy, and the amount of renal collagen

44 nce laser techniques, including confocal and multiphoton microscopy, are opening new avenues for cell

45 image-guided therapeutic interventions, and multiphoton microscopy as the appropriate method of vali

46 tumor cell motility in the primary tumor by multiphoton microscopy, as well as a dramatically reduce

47 gical readouts, and sophisticated intravital multiphoton microscopy-based imaging of liver in mice.

48 Here, we demonstrate that multiphoton microscopy can be used to visualize the micr

49 Multiphoton microscopy can resolve fluorescent structure

50 into the mouse deep dermis using intravital multiphoton microscopy combined with a skin window techn

51 Intravital multiphoton microscopy data show that sunitinib induces

52 Multiphoton microscopy enables imaging deep into scatter

53 Multiphoton microscopy enables live imaging of the renal

54 als (quantum dots) as fluorescent labels for multiphoton microscopy enables multicolor imaging in dem

55 infiltration, as monitored by 3-dimensional multiphoton microscopy ex vivo.

56 Multiphoton microscopy facilitated repeated imaging deep

57 extracellular matrix fibers, revealed using multiphoton microscopy, forms in the brain.

58 Using a combination of intravital multiphoton microscopy, genetically modified mice and no

59 erization and performance standardization of multiphoton microscopy hardware across a large user base

60 Although intravital multiphoton microscopy has addressed this limitation, th

61 veral years, in vivo imaging of tumors using multiphoton microscopy has emerged as a powerful preclin

62 Multiphoton microscopy has emerged as the primary imagin

63 Multiphoton microscopy has enabled unprecedented dynamic

64 Multiphoton microscopy has gained enormous popularity be

65 Intravital multiphoton microscopy has provided powerful mechanistic

66 travital microscopy (IVM) techniques such as multiphoton microscopy have been developed to visualize

67 Cryogenic electron and multiphoton microscopy have enabled mechanistic structur

68 re and exogenous contrast agents that enable multiphoton microscopy, however, limit the ability to in

69 High resolution multiphoton microscopy imaged the spread across rat brai

70 features are confirmed by coregistration of multiphoton microscopy images with conventional histolog

71 Here we report that multiphoton microscopy imaging of polytene nuclei in liv

72 in vivo, we observed cortical neurons using multiphoton microscopy in a mouse model of amyloid patho

73 Multiphoton microscopy in acute hippocampal slices confi

74 of tubular cell structure and function with multiphoton microscopy in an intact, functioning organ.

75 (n=6) arterial wall damage was quantified by multiphoton microscopy in ex vivo samples.

76 Using multiphoton microscopy in live cells, we show that free

77 ate cells (PSC) in culture and in situ using multiphoton microscopy in pancreatic lobules.

78 lasers have stimulated the broad adoption of multiphoton microscopy in the modern laboratory.

79 Using multiphoton microscopy in vivo, we imaged synaptic relea

80 Overall, these data suggest that multiphoton microscopy is a highly sensitive and promisi

81 Multiphoton microscopy is a powerful technique for deep

82 Multiphoton microscopy is a powerful tool in neuroscienc

83 Multiphoton microscopy is the current method of choice f

84 In vivo, multiphoton microscopy is used to image through an intac

85 Through intravital multiphoton microscopy (IV-MPM), allowing the means to a

86 Here, we have used in vivo multiphoton microscopy, laser speckle imaging of CBF, an

87 Here we demonstrate high-pulse-energy multiphoton microscopy (MPM) for intravital imaging of n

88 Multiphoton microscopy (MPM) has emerged as one of the m

89 Multiphoton microscopy (MPM) has found a niche in the wo

90 , reflectance confocal microscopy (RCM), and multiphoton microscopy (MPM) have advanced significantly

91 Multiphoton microscopy (MPM) holds promise as a noninvas

92 We analyzed multiphoton microscopy (MPM) images corresponding to 15

93 Multiphoton microscopy (MPM) is a nonlinear fluorescence

94 e responsible for the high compliance phase, multiphoton microscopy (MPM) of the dome of the voided b

95 Here we report the development of serial multiphoton microscopy (MPM) of the same glomeruli over

96 Recent translation of multiphoton microscopy (MPM) to clinical practice raises

97 h signals, we used high-resolution live-cell multiphoton microscopy (MPM) to directly observe cellula

98 e we developed an imaging approach that uses multiphoton microscopy (MPM) to directly visualize podoc

99 By applying the new technique of multiphoton microscopy (MPM) with clearing to a new mous

100 g (COM), optical coherence tomography (OCT), multiphoton microscopy (MPM), and line scan Raman micros

101 As evidenced by intravital multiphoton microscopy of Ccr2 reporter mice, CCR2(+) mo

102 Multiphoton microscopy of collagen hydrogels produces se

103 Using longitudinal intravital multiphoton microscopy of DC(GFP)/MC(RFP) reporter mice,

104 Long-term time-lapse multiphoton microscopy of embryonic mouse cortex reveals

105 Multiphoton microscopy of embryos produced by these worm

106 Here, we show how multiphoton microscopy of fluorescently tagged BDNF in b

107 ntitate dendritic protein synthesis, we used multiphoton microscopy of green fluorescent protein synt

108 Multiphoton microscopy of kidney sections confirmed that

109 We have used time-lapse multiphoton microscopy of living Tg(fli1:EGFP)y1 zebrafi

110 By high-resolution multiphoton microscopy of mammary carcinoma in mice, we

111 al procedure suitable for time-lapse in vivo multiphoton microscopy of mouse spinal cord without the

112 tion multiplex static imaging and intravital multiphoton microscopy of Mycobacterium bovis BCG-induce

113 Intravital multiphoton microscopy of potential-indicating rhodamine

114 l death were assessed by intravital confocal/multiphoton microscopy of rhodamine 123 (Rh123) and prop

115 and MPT were detected by intravital confocal/multiphoton microscopy of rhodamine 123, propidium iodid

116 archers to IVM technologies, with a focus on multiphoton microscopy of rodents, and discusses challen

117 We employed in vivo multiphoton microscopy of the genetically encoded Ca(2+)

118 This study demonstrates that multiphoton microscopy of the isolated perfused kidney i

119 of state-of-the-art tools, including in vivo multiphoton microscopy of the midbrain helped in identif

120 RECENT FINDINGS: Imaging modalities like multiphoton microscopy, optical coherence tomography, Co

121 oscopy over relatively short periods, and by multiphoton microscopy over more extended periods that i

122 Using multiphoton microscopy, Pittsburgh compound B (PIB) was

123 Multiphoton microscopy relies on nonlinear light-matter

124 Multiphoton microscopy revealed more efficient interacti

125 After induction of inflammation, multiphoton microscopy revealed that approximately 20% o

126 Moreover, intravital multiphoton microscopy revealed that Debio0719 reduced t

127 Resonant-scanning multiphoton microscopy revealed that in vivo arterial st

128 Confocal and multiphoton microscopy revealed that the paleness of lcd

129 Multiphoton microscopy reveals that intercalating cells

130 Intravital multiphoton microscopy reveals that Stat3 silencing comb

131 Here, multiphoton microscopy reveals the direct transformation

132 aging over 3D volumes in living retina using multiphoton microscopy should now allow fundamental mech

133 the imaging of the skin hair follicles using multiphoton microscopy showed that it opened the follicu

134 Isothermal titration calorimetry and multiphoton microscopy showed that L9 and the other most

135 Multiphoton microscopy showed that the predominant orien

136 nte Carlo-based radiative transport model of multiphoton microscopy signal collection in skin, establ

137 Advanced imaging, including multiphoton microscopy, small-angle X-ray scattering, an

138 Most multiphoton microscopy studies in biological systems hav

139 in probe choice and experimental design for multiphoton microscopy studies.

140 Here, we used multiphoton microscopy techniques and transgenic mice th

141 t parasites combined with flow cytometry and multiphoton microscopy techniques to understand the even

142 dvantage of recent technological advances in multiphoton microscopy that have allowed its application

143 rm and methodology for label-free multimodal multiphoton microscopy that uses a novel photonic crysta

144 We now show, using in vivo multiphoton microscopy, that FITC-labeled F(ab')2 fragme

145 Using serial intravital multiphoton microscopy through a thinned-skull cranial w

146 ion and progression of CAA in Tg2576 mice by multiphoton microscopy through cranial windows.

147 magnetic resonance imaging and confocal and multiphoton microscopy to correlate the structural remod

148 We used QDs and emission spectrum scanning multiphoton microscopy to develop a means to study extra

149 hods ranging from fluorescence, confocal and multiphoton microscopy to electron microscopic imaging a

150 The mixer is used in conjunction with multiphoton microscopy to examine the fast Ca2+-induced

151 We have combined this model with multiphoton microscopy to image differences in cell beha

152 We used multiphoton microscopy to image the stimulus-response de

153 The efficient application of multiphoton microscopy to intrinsic imaging requires kno

154 Herein, we used in vivo multiphoton microscopy to investigate NET formation in t

155 We have used time-lapse multiphoton microscopy to map the migration and settling

156 ident microglia in living mice and then used multiphoton microscopy to monitor these cells over time.

157 Here, we use multiphoton microscopy to obtain quantitative data of el

158 Here, we employed nonlinear multiphoton microscopy to quantify collagen fiber organi

159 We utilized multiphoton microscopy to quantify the dynamic behavior

160 c architecture, we used longitudinal in vivo multiphoton microscopy to sequentially image young APPsw

161 issue of Cell, Langen et al. use time-lapse multiphoton microscopy to show how Drosophila photorecep

162 Here we use brain slice multiphoton microscopy to show that substantia nigra dop

163 In this study, we use multiphoton microscopy to show, for the first time, that

164 With increasing applications of multiphoton microscopy to thick-tissue "intravital" imag

165 To address this, we used intravital multiphoton microscopy to visualize immune cell interact

166 Here we used multiphoton microscopy to visualize the dynamics and act

167 Using in vivo multiphoton microscopy together with fluorescently label

168 Multiphoton microscopy utilizing second harmonic generat

169 By using multiphoton microscopy, Voxx software, and the Tie-2 mou

170 In vivo time-lapse multiphoton microscopy was used to analyze the remodelin

171 METHODS AND Multiphoton microscopy was used to image deep within car

172 Multiphoton microscopy was used to image renal dendritic

173 eted to neuronal mitochondria and intravital multiphoton microscopy, we find increased mitochondrial

174 Using transcranial in vivo multiphoton microscopy, we find that fmr1 KO mice have s

175 Using multiphoton microscopy, we found five major differences

176 Reflected Image Macroscopy (PRIM) System and multiphoton microscopy, we measured ex vivo intravesical

177 Using intravital multiphoton microscopy, we measured presynaptic activity

178 Using multiphoton microscopy, we observed and monitored amyloi

179 Using conditional mutants and intravital multiphoton microscopy, we show here that the lipid medi

180 Using intravital multiphoton microscopy, we show previously unrecognized

181 Using in vivo multiphoton microscopy, we show that morpholino-mediated

182 Using multiphoton microscopy, we show that, in vivo, CD11c(+)

183 Further, using multiphoton microscopy, we show the utility of this tool

184 ly used imaging methods such as confocal and multiphoton microscopy, when combined with techniques su

185 inescence (2PEL) - the processes crucial for multiphoton microscopy, which allows deeper imaging of t

186 veloped for bladder cancer detection through multiphoton microscopy, will significantly improve the s

187 We here combine multiphoton microscopy with ad hoc reporter mice express

188 tive mouse kidneys were imaged in situ using multiphoton microscopy with and without Ang II and Ang I

189 n vivo were assessed by combining intravital multiphoton microscopy with flow cytometry and functiona

190 al imaging systems that combine confocal and multiphoton microscopy with inertia-free laser scanning.