ライフサイエンスコーパス: microvasculature

1 (cancer, healthy mucosa, smooth muscle, and microvasculature).

2 nd assessed their interactions in the dermal microvasculature.

3 ory state and clot formation in the cerebral microvasculature.

4 activation, and leukocyte recruitment in the microvasculature.

5 ering platelets gate-keepers of the inflamed microvasculature.

6 ine arterial and venous macrovasculature and microvasculature.

7 ve microperfusion data from gated human foot microvasculature.

8 a course and its relation to the normal iris microvasculature.

9 of pulsatile energy to the delicate cerebral microvasculature.

10 gene expression and stabilize the pulmonary microvasculature.

11 e cells are integral components of the brain microvasculature.

12 thogenic variants, mainly affects the kidney microvasculature.

13 formly partition red blood cells through the microvasculature.

14 ical changes in the cellular elements of the microvasculature.

15 d delivery and tethering of TLN in the organ microvasculature.

16 s undergo interactions within the glomerular microvasculature.

17 a progressive lung disease of the pulmonary microvasculature.

18 ervable surrogate for the neural or systemic microvasculature.

19 and inhibited the reactivity of the cerebral microvasculature.

20 ostatic factors needed to produce functional microvasculature.

21 t the structure and function of human kidney microvasculature.

22 t the loss of plasma-borne proteins from the microvasculature.

23 inical assessment of major blood vessels and microvasculature.

24 d delivery and tethering of TLN in the organ microvasculature.

25 to IL-1beta-induced activation of the brain microvasculature.

26 factors influencing the size of the retinal microvasculature.

27 because of its ability to cytoadhere in the microvasculature.

28 y (18)F-FDG imaging, but also in peritumoral microvasculature.

29 ascular wall in large vessels and within the microvasculature.

30 ate normal and retarded transit scenarios in microvasculature.

31 ials and their specific roles in bioprinting microvasculature.

32 CSE and 3-MST are expressed in the human microvasculature.

33 eing physiological functions of the cerebral microvasculature.

34 icative of autonomic hypersensitivity in the microvasculature.

35 sional architecture and flow patterns of the microvasculature.

36 eased nodal density, and decreased pulmonary microvasculature.

37 erapeutic strategies targeting the pulmonary microvasculature.

38 thrombi in the high sheer environment of the microvasculature.

39 odeling are linked to dynamic changes in the microvasculature.

40 ercussions of SCA on skeletal muscle and its microvasculature.

41 mation of freestanding luminal multicellular microvasculature.

42 nd function of newly formed tumor stroma and microvasculature.

43 ts the cell's ability to transport oxygen in microvasculature.

44 s with growth and refinement of the cerebral microvasculature.

45 ginates from the involvement of the coronary microvasculature.

46 dropout of pericytes that enwrap the retinal microvasculature.

47 unoreactivity were often associated with the microvasculature.

48 -Tg mice show a morphologically disorganized microvasculature.

49 ylcholine-mediated vasodilation in the renal microvasculature.

50 CD31 and CD34 revealed a sparse microvasculature.

51 the red blood cell's ability to sequester in microvasculature.

52 f 20-HETE to myogenic tone in the mesenteric microvasculature.

53 entrapment of sickled red blood cells in the microvasculature.

54 itochondrial damage was evaluated in retinal microvasculature.

55 Flow was observed in the macular microvasculature.

56 Retinopathy was detected in trypsin-digested microvasculature.

57 s not affect NO-mediated VD in the cutaneous microvasculature.

58 method to evaluate the choroidal and retinal microvasculature.

59 us formation in the pericontusional cortical microvasculature.

60 ging to achieve improved characterization of microvasculature.

61 and veins of the mouse macrovasculature and microvasculature.

62 ll adhesion to the endothelial lining of the microvasculature.

63 ar extravascular space, and (c) water in the microvasculature.

64 , opening a way to engineer patient-specific microvasculature.

65 es and erythrocytes sickle and adhere in the microvasculature, a process dependent on the concentrati

66 regression of the peritubular and glomerular microvasculature, accompanied by tubulointerstitial dama

67 tion of monocytes marginated within the lung microvasculature, achieved by pretreating mice with i.v.

68 hypertensive disorders during pregnancy with microvasculature adaptations in the offspring in childho

69 ring pregnancy is associated with persistent microvasculature adaptations in their children.

70 ween indices of cardiac function and retinal microvasculature, adjusting for age, sex, body mass inde

71 d that aggregates are present throughout the microvasculature, affecting cell distribution and blood

72 xhibited a steady ingrowth of blood-perfused microvasculature along with an increase in amplitude of

73 ents, which are characterized by dense leaky microvasculature and acidic extracellular pH (pHe ) valu

74 n glucose nevertheless restores the cerebral microvasculature and ameliorates disease.

75 to survive in vivo by sequestering IE in the microvasculature and avoiding splenic clearance mechanis

76 VR demonstrated abnormalities in the macular microvasculature and capillary network, in addition to t

77 owever, no mechanistic link between systemic microvasculature and congestion, a central feature of th

78 , Myh11+ mural cells detach from the retinal microvasculature and differentiate into myofibroblasts t

79 ic delivery enables widespread access to the microvasculature and draining to the APC-rich perivascul

80 Special attention is given to the microvasculature and hepatic mononuclear phagocytic syst

81 res of native in vivo human dermal lymphatic microvasculature and is stable over many weeks.

82 ach, including direct visualization of renal microvasculature and measurement of oxygen kinetics and

83 he visualization and quantification of tumor microvasculature and perfusion.

84 ing visualization of major blood vessels and microvasculature and providing images of hemoglobin oxyg

85 The mechanisms underlying repair of the microvasculature and recovery of kidney function are poo

86 fected RBC (iRBC) sequestration in the brain microvasculature and resulting sequelae.

87 erial oxygen delivery to the skeletal muscle microvasculature and subsequent diffusive oxygen deliver

88 mes likely mediated by interactions with the microvasculature and the cardiomyocyte.

89 retention were mainly dictated by the tumor microvasculature and the enhanced permeability and reten

90 effects of HIV-1 infection on the pulmonary microvasculature and the modulatory effects of the PPAR-

91 ed us to analyze and interrogate the cardiac microvasculature and the tissue resident macrophage dist

92 Insulin resistance is present in muscle microvasculature and this may contribute to decreased in

93 brovascular system and gray matter, altering microvasculature and tissue structure.

94 critical for the development of a functional microvasculature and vascular remodeling.

95 tion, suggesting that Notch functions in the microvasculature and/or veins to induce AVM.

96 ence of activated leukocytes in the cerebral microvasculature, and blood-brain barrier leakage, indic

97 g injury (VILI), NETs were found in the lung microvasculature, and circulating NET components increas

98 lso displayed increased net neurogenesis and microvasculature, and diminished astrocyte hypertrophy a

99 e-endothelial cell interactions in the brain microvasculature, and increased inflammation in brain (i

100 that insulin enters endothelial cells of the microvasculature, and studies with large vessel-derived

101 validated K(trans) as an indicator of plaque microvasculature, and the reproducibility of K(trans) wa

102 ctins constitutively expressed by the marrow microvasculature, and thus for marrow homing, we conduct

103 al imaging techniques for assessing hypoxia, microvasculature, and tumor growth.

104 ve endothelial-attached sickle RBCs from the microvasculature are expected to be critical for optimal

105 beneficial effects of endurance training on microvasculature are widely known.

106 ause spatial and temporal data suggested the microvasculature as a common site of origin for these ce

107 r tissue-stressing effects on parenchyma and microvasculature as the ventilated compartment shrinks f

108 ce results in defects in retinal and cardiac microvasculature as well as heart development.

109 ne the mean erythrocyte speed in the retinal microvasculature, as well as the intravisit and intervis

110 Greatly waned neurogenesis, diminished microvasculature, astrocyte hypertrophy and activated mi

111 CTA yields images of the normal and diseased microvasculature at all levels of the retina, with highe

112 emerging as a powerful technique for imaging microvasculature at depths beyond the ~1 mm depth limit

113 iving subjects, including detection of tumor microvasculature at twice the depth achievable with conv

114 ional and structural alterations in cerebral microvasculature before and after experimental cerebral

115 development and organization of the coronary microvasculature beyond the earliest developmental stage

116 and the fact that it is not specific for the microvasculature but interrogates the entire coronary ci

117 rived pericytes populate the entire coronary microvasculature, but differentiate into caSMCs at arter

118 ) will cause occlusion if they sickle in the microvasculature, but have minimal (or no) consequences

119 Half a century ago, detailed studies of the microvasculature by electron microscopy revealed that un

120 ing responses into components related to the microvasculature (capillaries and small venules) and the

121 in cell culture dishes coated with cerebral microvasculature cells (bEnd.3) and under dynamic flow c

122 Microvasculature changes between the 3 groups and correl

123 alciparum-infected erythrocytes (IEs) in the microvasculature contributes to pathogenesis of severe m

124 ion of platelet-neutrophil aggregates in the microvasculature contributes to tissue damage during sep

125 vascular degeneration, predominantly in the microvasculature, contributes to dry AMD progression.

126 p formation, and thrombosis in the pulmonary microvasculature culminated in right ventricular dysfunc

127 CL10, was significantly upregulated, whereas microvasculature CXCL12 expression was significantly dec

128 BACS attenuated microvasculature damage in the lung grafts when compared

129 ed during ex vivo lung perfusion (EVLP), and microvasculature damage was assessed using 2-photon micr

130 diated repletion of the protein averts brain microvasculature defects and prevents disease, whereas a

131 tumor perfusion efficacy, hypoxic burden and microvasculature density) impact BB2r-targeted agent del

132 n, showing both morphological and functional microvasculature details at super-resolution within a sh

133 Here, we evaluated the coronary and renal microvasculature during CRMS development in obese diabet

134 ever, imaging this organ and its complicated microvasculature during different forms of renal patholo

135 ive ANGPT1-TIE2 signaling to destabilize the microvasculature during pathologic disorders like inflam

136 or neuroscience research and for visualizing microvasculature dynamics involved in tumor angiogenesis

137 imary human small airway epithelial and lung microvasculature endothelial cells as well as on the cap

138 otes CXCR4-mediated T cell adhesion to brain microvasculature endothelial cells.

139 roperties and markers expanded radially from microvasculature explants.

140 TM expression is decreased in liver and lung microvasculature exposed to low SS but not in blood vess

141 scular bed-specific anticoagulant pathway in microvasculature exposed to low SS.

142 8 week-, and 12 week-old NOD mice, and their microvasculature, extracellular matrix, and immune cell

143 To assess the morphology of brain microvasculature far more rigorously than what is possib

144 characterized by glial invasion of terminal microvasculature followed by release of individual plate

145 advancement toward the development of human microvasculature for basic and translational studies.

146 review of recent applications of bioprinted microvasculature for disease modeling, drug testing, and

147 ological environment in the inflamed venular microvasculature for platelet aggregation thereby effect

148 We propose the concept of reactive microvasculature for the evolution of reactive stroma at

149 etical analyses revealed that the subsurface microvasculature formed interconnected loops with a topo

150 site of origin for these cells, we analyzed microvasculature fragments in organ culture.

151 limits arterial pulsatility and protects the microvasculature from potentially harmful fluctuations i

152 The peripapillary microvasculature from the internal limiting membrane to

153 After 9 months of diabetes, the retinal microvasculature from untreated diabetic mice demonstrat

154 en level-dependent measurements that reflect microvasculature function.

155 Microvasculature functions at the tissue and cell level,

156 es the unique ability to study metabolic and microvasculature functions in skeletal muscle using phos

157 l organization and hemodynamics of the tumor microvasculature give rise to unique microvascular niche

158 e- and small-vessel replacements, functional microvasculature has been particularly challenging to en

159 nding of how this supply is regulated in the microvasculature has evolved from viewing erythrocytes (

160 MICT), but its effect on the skeletal muscle microvasculature has not been studied in obese individua

161 raining (MICT), but its effect on the muscle microvasculature has not been studied.

162 ial fibrosis, enhanced preservation of renal microvasculature, improvement in renal blood flow, and l

163 to suppress projection artifacts and resolve microvasculature in 3 plexuses around the macula.

164 organogenesis as well as fine features like microvasculature in a brain and pigmented epithelium in

165 intrinsic self-assembly capability to create microvasculature in a deliverable matrix, has vast ramif

166 constituted a three-dimensional human kidney microvasculature in a flow-directed microphysiologic sys

167 enriched colocalization with murine retinal microvasculature in a model of diabetic retinopathy.

168 howed strong inflammatory involvement of the microvasculature in a murine model of cerebral malaria.

169 een coronary arterial dilatation and retinal microvasculature in a pilot setting, in order to further

170 ntial equipment to enhance classification of microvasculature in a reliable and proficient manner in

171 on and transmigration of Tregs in the dermal microvasculature in a two-challenge model of contact sen

172 erence standard for invasively assessing the microvasculature in clinical trials.

173 preciation of the importance of the coronary microvasculature in determining patient outcomes has gro

174 o establish an essential role of the hepatic microvasculature in embryonic hematopoiesis.

175 GF-CC neutralization had no effects on renal microvasculature in healthy animals.

176 d analysis toolset to visualize the coronary microvasculature in intact embryonic hearts and quantify

177 ary structure was integrated with pancreatic microvasculature in its entirety.

178 n inherent to the lungs, facilitating robust microvasculature in lung grafts after transplantation, l

179 In contrast, the hepatic microvasculature in NICD(OE-HEC) mice revealed a special

180 Analysis of the retinal microvasculature in ORP2 knock-out mice generated during

181 g modality to quantify the retinal capillary microvasculature in patients with diabetes.

182 Microvasculature in peri-infarct area, infarct size, and

183 provided detailed imaging of the perifoveal microvasculature in sickle cell disease.

184 ions of Borg5, septin, and actomyosin in the microvasculature in the context of development and disea

185 Evaluate and compare the retinal microvasculature in the superficial capillary plexus (SC

186 remodelling and barrier function in retinal microvasculature in vitro and in vivo.

187 inimally invasive manner and form functional microvasculature in vivo.

188 ic control and subsequent changes in retinal microvasculature, in a pilot study of 55 pediatric T1D p

189 hysiologically and morphologically realistic microvasculature including endothelial cell lined leaky

190 During T1D the islet microvasculature increases permeability, allowing nanopa

191 -1.2 per year), tubulitis (1.5, 1.3-1.8) and microvasculature injury (2.9, 1.4-5.7).

192 nclusion, pediatric RTR with de novo DSA and microvasculature injury were at risk of allograft failur

193 er cell migration/invasion toward angiogenic microvasculature is a key step in metastatic spread.

194 D, but what causes them and why the cerebral microvasculature is affected have never been adequately

195 The lung microvasculature is essential for gas exchange and commo

196 endothelial cells (ECs) and pericytes in the microvasculature is fundamental for vascular growth and

197 The microvasculature is important for vertebrate organ devel

198 Transport of insulin across the microvasculature is necessary to reach its target organs

199 further complicated as cytoadherence in the microvasculature is still a matter of investigations.

200 on molecule 1 (ICAM-1) upregulation in brain microvasculature is the only one correlated to cerebral

201 s angiogenesis, but the effect on the kidney microvasculature is unknown.

202 B (ETB) receptors, overexpressed in the lung microvasculature, is associated with accumulation of pro

203 modeling system not only mimics the retinal microvasculature, it also allows for the examination of

204 flow pulsatility into the susceptible renal microvasculature, leading to dynamic constriction or ves

205 uitment and activation within the glomerular microvasculature, leading to neutrophil-dependent tissue

206 nd function resulting in obliteration of the microvasculature.Lytic EC injury: Lethal exposure to DSA

207 d physiological deformation of the pulmonary microvasculature may exacerbate vascular injury during R

208 low pulsatility into the low-impedance renal microvasculature may mediate this association.

209 Changes in the retinal microvasculature may mirror small vessel cerebrovascular

210 These noninvasive microvasculature measures should be evaluated further as

211 sing sRBC adhesion in our microfluidic human microvasculature models.

212 e is known about how the blood and lymphatic microvasculature modulates cystogenesis.

213 reviously been suggested that the intestinal microvasculature network directs the migration of enteri

214 haemic tissue after stroke, associating with microvasculature, neurons and AD-plaques, Abeta, also, b

215 hat VEGF protects the retinal and glomerular microvasculature, not only through VEGFR2-mediated vascu

216 iently deposit 20-30mum large bubbles in the microvasculature, occluding blood flow for ~5-10min.

217 adult EC line (D3) derived from the cerebral microvasculature of a hippocampal biopsy.

218 ing and VEGFR distribution were found in the microvasculature of brain and retina but not lung, indic

219 Using intravital microscopy of cremasteric microvasculature of chimeric LSP1-deficient mice, we sho

220 TIE2, is robustly up-regulated in the renal microvasculature of diabetic rodents, thereby reducing T

221 evel molecular regulation of the hippocampal microvasculature of female mice and may provide one of t

222 it is more dangerous when it develops in the microvasculature of injured tissues and organs.

223 and vascular cell adhesion molecule-1 in the microvasculature of kidneys and liver, although messenge

224 The tracheal microvasculature of mice, with conditionally deleted or

225 acoustic microscopy (OR-PAM) to quantify the microvasculature of ovarian and fallopian tube tissue.

226 get for reducing the oxidative milieu in the microvasculature of patients with CAD.

227 es hemolysis and vasoocclusive events in the microvasculature of patients with sickle cell disease (S

228 effects of an endurance training program on microvasculature of skeletal muscle in SCD patients.

229 -mediated inflammatory disease affecting the microvasculature of skin and muscle.

230 ive penetration of pulsatile energy into the microvasculature of target organs that operate at low va

231 falciparum-infected erythrocytes within the microvasculature of the brain plays a key role in the de

232 tions of the same 5 gene families damage the microvasculature of the brain that leads to dementia.

233 ivax-adherent parasite subpopulations in the microvasculature of the human spleen.

234 Here we show that PMo are enriched in the microvasculature of the lung and reduce tumor metastasis

235 ng visualization of the individual layers of microvasculature of the retina and the choroid by compar

236 ages (e.g. labeled cells, molecular targets, microvasculature) of optically cleared tissue slices.

237 rom glial cells, can stabilize the quiescent microvasculature or enrich local neuronal microcircuits

238 (iRBCs) to host endothelial receptors in the microvasculature, or cytoadhesion, is associated with se

239 Without techniques to image the coronary microvasculature over the whole heart, it is likely we a

240 n of S. lugdunensis was evaluated in a mouse microvasculature perfusion model and a new mouse model o

241 Extravasation rates and microvasculature permeabilities were significantly diffe

242 gents can be used to measure increased islet microvasculature permeability and indicate asymptomatic

243 Beyond this metabolic dilation, the microvasculature plays a critical role in modulating vas

244 Infected erythrocyte sequestration in the microvasculature plays a critical role in the developmen

245 lial dysfunction and insulin resistance, and microvasculature plays a critical role in the regulation

246 CE-MRI to provide insights into the cerebral microvasculature post-TBI.

247 solated MB events for full reconstruction of microvasculature preclude the clinical translation of th

248 155 inhibition after ischemia supports brain microvasculature, reduces brain tissue damage, and impro

249 asodilator signalling across elements of the microvasculature remain an important area of focus for n

250 function; however, the effect of RIPC on the microvasculature remains unclear.

251 lly, p66Shc mediated the diabetes-induced BM microvasculature remodeling.

252 Compromised microvasculature resulting from disrupted bronchial arte

253 umber of EPCs incorporated into the lesions' microvasculature, resulting in an improved early vascula

254 However, current hCOs lack microvasculature, resulting in limited oxygen and nutrie

255 art, it is likely we are underestimating the microvasculature's impact on normal development and dise

256 able future cohort studies to understand the microvasculature's role in diseases such as hypertrophic

257 Regional peripapillary microvasculature showed decreased VD and flow in POAG wi

258 ventional phenotype that originated from the microvasculature surrounding the OB and not the peripher

259 prove oxygen delivery-steps toward effective microvasculature-targeted therapies.

260 Tumor microvasculature tends to be malformed, more permeable,

261 olution imaging of the retinal and choroidal microvasculature that compares favorably with FA.

262 y the effect of systemic risk factors on the microvasculature that was previously not accessible in a

263 ed formation, studies for the development of microvasculature, the connecting bridge between them, ha

264 e effects of full-length netrin-1 on retinal microvasculature, the VI-V fragment promoted vascular pe

265 nervation had a long-term effect on the limb microvasculature: The rapid and joint-localized vascular

266 Maintaining the microvasculature throughout the transplant process could

267 cells with FGF9 can differentiate the tumor microvasculature to an extent not observed previously.

268 vasodilator response of the skeletal muscle microvasculature to insulin and exercise is of critical

269 mpair the vasodilator response of the muscle microvasculature to insulin, exercise and VEGF-A and red

270 -dimensional microfluidic model of the human microvasculature to recapitulate the environment wherein

271 optotic and anti-inflammatory roles in brain microvasculature to reduce ischemic cerebral vascular an

272 UMI to achieve highly sensitive detection of microvasculature using conventional line-by-line ultraso

273 To evaluate the retinal microvasculature using OCT-A in patients with type 2 dia

274 luate the ability of measurements of retinal microvasculature using OCTA to distinguish healthy eyes

275 on quantitative measurements of the retinal microvasculature using optical coherence tomography angi

276 asibility of rendering retinal and choroidal microvasculature using PV-OCT was compared qualitatively

277 The coronary microvasculature was found to follow the known helical o

278 as systemically administered, patency of the microvasculature was maintained.

279 Retinal microvasculature was measured using computer software (S

280 logical fluid shear stresses observed in the microvasculature was shown to reduce neutrophil activati

281 To further resolve the tumor microvasculature, we performed correlated UM of fluoresc

282 Quantitative parameters from the retinal microvasculature were measured on binarized and skeleton

283 dothelial (L-E) interactions in the cerebral microvasculature were then quantified in vivo using intr

284 between retinoblastoma cells and surrounding microvasculatures were studied using a transgenic zebraf

285 a landmark microanatomical structure at the microvasculature where cancer cells enter the blood stre

286 neutrophils adhere at distinct sites in the microvasculature where these immune cells effectively pr

287 e leads to sequestration of infected RBCs in microvasculature, which enables the parasite to evade th

288 ng2 blockade induced regression of the tumor microvasculature while decreasing the proportion of nonp

289 the creation of self-supporting multilayered microvasculature with a distinct circular lumen followin

290 d induce autonomic hypersensitivity of their microvasculature with an increased propensity toward vas

291 les across tumor and non-tumor mammary gland microvasculature with and without application of RF hype

292 A key factor is tumor microvasculature with complex effects including convecti

293 ution of biomaterials design for bioprinting microvasculature with physiological complexity.

294 We examined the retinal microvasculature with swept-source OCT-A and a semiautom

295 s of HDL/ApoA-I may connect the pathology of microvasculature with that of large vessels (atheroscler

296 licle, and degeneration and atrophy of brain microvasculature with visual evoked potential anomalies.

297 g of circulating tumour cells into the brain microvasculature; within this unique microenvironment, t

298 ulting in a profound diminution of the brain microvasculature without compromising the blood-brain ba

299 that can visualize the retinal and choroidal microvasculature without the injection of exogenous dyes

300 ography (OCT-A) is able to visualize retinal microvasculature without the need for injection of fluor