ライフサイエンスコーパス: intravital imaging

1 perties of brain T(RM) cells was revealed by intravital imaging.

2 time and space, making it ideally suited for intravital imaging.

3 amics during regeneration using confocal and intravital imaging.

4 ous reasons, from utilization in longer-term intravital imaging.

5 e in situ requires animal models amenable to intravital imaging.

6 detected using ex vivo explants and in vivo intravital imaging.

7 ved human blood vessels, as verified through intravital imaging.

8 o and in vivo as shown by flow cytometry and intravital imaging.

9 toxin as shown by compartmental staining and intravital imaging.

10 t membrane (3D rBM) cultures, and mice using intravital imaging.

11 With the advance of intravital imaging, a number of recent papers revealed a

12 Intravital imaging and 3D immunofluorescence reconstruct

13 Intravital imaging and computational analyses have been

14 Using a combination of dynamic intravital imaging and confocal multiplex microscopy, we

15 lumination, and offers new opportunities for intravital imaging and control of cardiac function.

16 Using intravital imaging and flow cytometry, we found impaired

17 he tumor microenvironment, as observed using intravital imaging and flow cytometry.

18 Using intravital imaging and fluorescence molecular tomography

19 Intravital imaging and genetic approaches indicated that

20 also describe how to apply state-of-the-art intravital imaging and hearing assessment techniques to

21 Intravital imaging and image-based cell sorting of a mou

22 Using intravital imaging and loss of function experiments, we

23 or naive CD4(+) and CD8(+) T cells, then use intravital imaging and mathematical modeling to relate c

24 pulation of tumor cells by multiphoton-based intravital imaging and microarray-based expression profi

25 keleton in podocytes and other cell types by intravital imaging and other conventional light microsco

26 By intravital imaging and super-resolution microscopy, we s

27 we review the technical advances afforded by intravital imaging and their contributions to our unders

28 Here, we performed intravital imaging and ultrastructural analyses of micro

29 tative histological imaging, flow cytometry, intravital imaging, and an assessment of single-cell RNA

30 Through single-cell RNA sequencing, intravital imaging, and CD8(+) T cell blocking studies i

31 nitors into immunodeficient mice, we used an intravital imaging approach to follow cartilage maturati

32 Using advanced intravital imaging approaches and newly created reporter

33 LT-HSCs) and that is compatible with current intravital imaging approaches in the calvarial bone marr

34 in vivo in the primary tumor measured using intravital imaging are significantly increased by ErbB1

35 oncept of virological synapses and introduce intravital imaging as a tool to visualize retroviral spr

36 study, we track individual myeloma cells by intravital imaging as they colonize the endosteal niche,

37 Using an intravital imaging assay of filamentation during mammali

38 Intravital imaging confirmed the uptake of exosomes in n

39 Intravital imaging, coupled with mechanistic studies in

40 ost-pathogen interactions in zebrafish using intravital imaging, Davis and Ramakrishnan provide evide

41 than single-photon excitation, has extended intravital imaging deeper into tissues, with minimal pho

42 Intravital imaging demonstrated a transendothelial migra

43 Intravital imaging demonstrated cooperation in which INV

44 Intravital imaging demonstrated MA cargo distributed bot

45 ic parasites combined with reporter mice and intravital imaging demonstrated that replication in and

46 Therefore, intravital imaging demonstrates that local myelin recogn

47 We used a combination of intravital imaging, ear infection and skin abscess model

48 Intravital imaging emerged as an indispensible tool in b

49 Intravital imaging enables to study dynamic tumour-strom

50 Intravital imaging experiments further revealed steady-s

51 Intravital imaging for bacterial phagocytosis, assessmen

52 Using 3D, time-lapse intravital imaging for direct visualization of the muscl

53 These findings stress the need for intravital imaging for dissecting the fine mechanisms of

54 Here we used a combination of confocal intravital imaging, genetically engineered mice, and ant

55 Intravital imaging has started to uncover tumor-related

56 Recent progresses in intravital imaging have enabled highly-resolved measurem

57 Recent advancements in intravital imaging have led to in vivo analysis of endoc

58 Intravital imaging highlighted the notable dilatation of

59 perties were evaluated using high-resolution intravital imaging, histology, whole-pancreas visualizat

60 -dimensional flow cytometry data paired with intravital imaging, immunohistochemistry, and multiplexe

61 Two-photon intravital imaging in Agtr1a-GCaMP6s mice revealed that

62 Using intravital imaging in an antigen-loss CD19-negative rela

63 ongitudinal assessment of AKT activity using intravital imaging in conjunction with image stabilizati

64 cal and performance advance that facilitates intravital imaging in diverse contexts in higher organis

65 Intravital imaging in live zebrafish embryos revealed th

66 th self-peptide-presenting APCs observed via intravital imaging in mice, indicating a potential funct

67 ose tissue, as demonstrated by single-photon intravital imaging in mice.

68 Intravital imaging in tumor-bearing mice revealed that s

69 Due to its natural transparency, intravital imaging in zebrafish does not require any sur

70 More recently, the introduction of intravital imaging into the GC field has opened the door

71 Although intravital imaging is a powerful tool for understanding

72 Intravital imaging is an invaluable tool for understandi

73 this revolution possible and demonstrate how intravital imaging is beginning to provide quantitative

74 Through ligand-receptor mapping and intravital imaging, it was found that alveolar macrophag

75 Intravital imaging (IVI) offers these capabilities, and

76 Serial intravital imaging, MD nerve growth factor receptor and

77 al environment, and to extend the utility of intravital imaging methods for estimating the mechanical

78 and plug-in by presenting data collected via intravital imaging of a mouse model of breast cancer.

79 Developing in vivo real-time intravital imaging of alveoli revealed AMs crawling in a

80 Four-dimensional intravital imaging of APAP-induced mouse liver injury id

81 e developed a unique mouse model that allows intravital imaging of autonomous lymphatic vessel contra

82 Intravital imaging of BRAF-mutant melanoma cells contain

83 Intravital imaging of cancer stem cells could be of grea

84 Multispectral and longitudinal intravital imaging of capillary LEC shape and actin reve

85 Using intravital imaging of cardiac transplants, we uncover th

86 s in shaping cell-mediated immunity by using intravital imaging of CD4(+) T cell interactions with de

87 7BL/6 background provide a valuable tool for intravital imaging of corneal lymphatic vessels and valv

88 Intravital imaging of CXCR4-expressing MCF-7 cells revea

89 Real-time intravital imaging of CXCR6(GFP/+) mouse skin reveals de

90 Super-resolution and intravital imaging of developing Drosophila melanogaster

91 Intravital imaging of exteriorized livers was performed

92 Intravital imaging of fluorescently labeled amphiphilic-

93 in the peripheral nervous system (PNS) using intravital imaging of growing dorsal root ganglia (DRG)

94 Our approach combines intravital imaging of growth cone dynamics in developing

95 High-resolution intravital imaging of HER2+ early-stage cancer cells rev

96 Intravital imaging of immune cells can be negatively imp

97 re not tailored for the specific problems of intravital imaging of immune cells.

98 des, opening the possibility of non-invasive intravital imaging of immune trafficking in lymph nodes

99 platelet aggregometry, bleeding assays, and intravital imaging of laser-induced arterial thrombus fo

100 cells using the novel approach of continuous intravital imaging of Lgr5- Confetti mice.

101 Intravital imaging of livers in control mice revealed si

102 tal blood pressure analyzer and we performed intravital imaging of livers of mice.

103 Intravital imaging of LPS showed a delayed clearance fro

104 Intravital imaging of lymph nodes revealed that all thre

105 A model system that allows long-term intravital imaging of lymph nodes would facilitate the s

106 erized, we developed a facile method for the intravital imaging of mammary cells in transgenic mice t

107 e, using retrospective study of patients and intravital imaging of mice, we identify some of these ne

108 Intravital imaging of mouse LNs revealed persistent, but

109 Intravital imaging of nanoparticle extravasation and tum

110 ulse-energy multiphoton microscopy (MPM) for intravital imaging of neurons and oligodendrocytes in th

111 Through intravital imaging of NSCs and their progeny, we identif

112 icroscopy platform that enables longitudinal intravital imaging of otherwise optically inaccessible t

113 To facilitate long-term intravital imaging of pancreatic remodeling, we designed

114 Intravital imaging of post-ischemic kidneys revealed red

115 In this study, we used intravital imaging of reactive lymph nodes (LNs) to show

116 Quantification of reporter mRNA and intravital imaging of reporter expression in the outer s

117 Here we use intravital imaging of signalling reporter cell-lines com

118 Furthermore, using intravital imaging of solid tumors, we showed that Ab re

119 n combined with two-photon laser microscopy, intravital imaging of surgically exposed lymph nodes pro

120 Intravital imaging of the bone marrow showed that CP tre

121 n imaging approach called LIMB (longitudinal intravital imaging of the bone marrow) to analyze cellul

122 Longitudinal analysis of mice using 2-photon intravital imaging of the brain through cranial windows

123 at the site of inflammation in the CNS using intravital imaging of the brainstem of EAE-affected livi

124 and organic dyes that allow high-resolution intravital imaging of the different mural cell subtypes.

125 Whole-mount and intravital imaging of the ileum and ileum-draining colle

126 ndow (CLNW) surgical preparation that allows intravital imaging of the inguinal lymph node in mice.

127 s review, we examine the approaches used for intravital imaging of the kidney and summarize the insig

128 the 1950s enabled imaging of live cells and intravital imaging of the kidney; however, confocal micr

129 Intravital imaging of the liver in mice confirmed that t

130 Through intravital imaging of the liver in mice, we show that IR

131 Here, using the Window for High-Resolution Intravital Imaging of the Lung (WHRIL), we study the liv

132 Stable, high-resolution intravital imaging of the lung has become possible throu

133 ently implantable window for high-resolution intravital imaging of the murine lung that allows the mo

134 se, and subsequently allows for longitudinal intravital imaging of the murine lymph node and surround

135 cells moving in live rats were generated by intravital imaging of the primary tumor in situ on a las

136 In this study, using time-lapse intravital imaging of the spleen, we identify a tropism

137 Standard fluorophores hamper simultaneous intravital imaging of these components.

138 Here, using oxidative lipidomics and intravital imaging of transplanted mouse lungs that are

139 ersion properties that allow high-resolution intravital imaging of vascular endothelium for periods o

140 Intravital imaging of vascular transgenic larvae reveale

141 Despite advances in intravital imaging, optical imaging of the lung during a

142 etastases or micrometastases are detected by intravital imaging or fluorescence microscopy.

143 g techniques is the current lack of suitable intravital imaging probes.

144 Intravital imaging revealed a failure of the mutant neut

145 Intravital imaging revealed a spatiotemporal macrophage

146 Intravital imaging revealed greater neutrophilic inflamm

147 Intravital imaging revealed heterogeneous cell behaviour

148 Intravital imaging revealed immune complexes moving alon

149 Intravital imaging revealed impaired bile secretion into

150 Intravital imaging revealed improved vascular patency in

151 The use of intravital imaging revealed that activated CD4(+) T cell

152 Intravital imaging revealed that commensal-specific T ce

153 Intravital imaging revealed that EGFP-kindlin-3-reconsti

154 erstood "macrophage disappearance reaction." Intravital imaging revealed that resident macrophages we

155 Real-time intravital imaging revealed that the treatment with CCL5

156 Intravital imaging revealed that within the inguinal lym

157 Intravital imaging reveals that vessel growth in murine

158 Intravital imaging reveals the iPS-cell-derived putative

159 ng our recently developed quantitative liver intravital imaging, RNA sequence analysis, and biochemic

160 s of multiphoton microscopy to thick-tissue "intravital" imaging, second-harmonic generation (SHG) fr

161 he same tumor microenvironment over multiple intravital imaging sessions in living mice.

162 Intravital imaging showed that CpG-C-activated microglia

163 Furthermore, intravital imaging showed that virus spread and lesion f

164 Intravital imaging shows that CCT129254 or AT13148 treat

165 Intravital imaging shows that macrophages and tumor cell

166 Intravital imaging shows that TBMs are stationary cells

167 Intravital imaging shows these cells moving freely withi

168 Here, we used a combination of intravital imaging, single-cell ablation, and cuprizone-

169 ransparent cranial windows normally used for intravital imaging studies in mice to include a turnable

170 The intravital imaging studies using a chronic calvarial bon

171 in vitro functional assays and confocal and intravital imaging studies.

172 However, intravital imaging suggests that early B-cell recognitio

173 Here we report the development of a new intravital imaging system for studying LC efflux and inf

174 is issue of JEM, Cleary et al. present a new intravital imaging technique using a 3D-printed window d

175 Advances in live tissue and intravital imaging technologies combined with the abilit

176 Here, we demonstrated by intravital imaging that B cells are rapidly recruited to

177 ting ways stem cells are being visualized by intravital imaging, the intriguing discoveries that have

178 provides access to the mouse cerebellum for intravital imaging, thereby allowing for a detailed char

179 Our results demonstrate that intravital imaging through the placenta window can be a

180 Using intravital imaging to capture stem cell dynamics after i

181 Here we use intravital imaging to demonstrate that secretion of exos

182 Here we have used intravital imaging to demonstrate that transfer of arthr

183 we use in vivo B cell competition models and intravital imaging to examine the adhesive mechanisms go

184 Here, we used intravital imaging to explore how microbiota affect the

185 y and transcriptomics, must be combined with intravital imaging to fully understand a cell's phenotyp

186 FP-ki mice and performed single, nonterminal intravital imaging to investigate BSCB permeability simu

187 Here we used intravital imaging to investigate the mechanisms by whic

188 Here, we used microfabricated channels and intravital imaging to observe and manipulate T-cell kina

189 Here, we review the contribution of intravital imaging to our understanding of cell-mediated

190 We used two-photon intravital imaging to show that, after exiting high-endo

191 presents a new discovery effort that employs intravital imaging to study immune players directly in t

192 Here we use intravital imaging to track the cellular dynamics of meg

193 Here we use intravital imaging to track the fate of mouse skin epith

194 We used intravital imaging to visualize the behavior of human CL

195 mechanisms have been hindered by the lack of intravital imaging tools capable of multiparametric prob

196 tional endocrine tissue, facilitating stable intravital imaging under anesthesia-free, physiological

197 Two-photon intravital imaging used to map vessel growth through tim

198 ansport across mouse brain capillaries using intravital imaging, validating the ability of the platfo

199 Intravital imaging was performed on mice expressing comm

200 Intravital imaging was used for quantification of growth

201 Using intravital imaging, we also determined that high-avidity

202 res, microfluidic devices, mouse models, and intravital imaging, we demonstrate that ROCK-Myosin II a

203 Using intravital imaging, we established that, upon anti-CD20

204 y multiple approaches, including multiphoton intravital imaging, we found that antigen capture by sin

205 Using intravital imaging, we found that retinal curvature is i

206 Using intravital imaging, we found that selection is mediated

207 Using mouse models and multiphoton intravital imaging, we have identified a crucial effect

208 Using intravital imaging, we observe that these dominant CAFs

209 Here, by intravital imaging, we reveal that RANKL-stimulated oste

210 mic/epigenomic analysis, flow cytometry, and intravital imaging, we show that BCG and beta-glucan rep

211 Through mouse intravital imaging, we show that dermal papilla fibrobla

212 Using intravital imaging, we show that knockout of Ccn1 in end

213 Here, using intravital imaging, we show that Kupffer cells (KCs) in

214 Here, using two-photon intravital imaging, we show that SAP deficiency selectiv

215 in vivo invasion assay and multiphoton-based intravital imaging, we show that the interaction between

216 By intravital imaging, we show that the less malignant tumo

217 als from the BCR, CXCR5, and CD40, and using intravital imaging, we show that WNK1 regulates migratio

218 Using intravital imaging, we tracked interactions established

219 The combination of functional analysis by intravital imaging with cellular characterization has re

220 eir size has precluded experiments involving intravital imaging with cellular resolution.

221 propose an approach that integrates dynamic intravital imaging with computer geometric modeling and

222 The combination of quantitative intravital imaging with deep transcriptomes identified 4

223 Intravital imaging with surgical exposure of the lymph n