ライフサイエンスコーパス: choriocapillaris

1 ment epithlium (RPE) defects and loss of the choriocapillaris.

2 eration of the RPE, and secondary leakage of choriocapillaris.

3 ffectiveness may be limited by damage to the choriocapillaris.

4 e across Bruch's membrane (BrM) to reach the choriocapillaris.

5 r RPE-derived VEGF in the maintenance of the choriocapillaris.

6 using behavior was observed in the subfoveal choriocapillaris.

7 , but perhaps also in the maintenance of the choriocapillaris.

8 al pigment epithelium (RPE)-Bruch's membrane-choriocapillaris.

9 d RPE is a critical function mediated by the choriocapillaris.

10 GA, RPE atrophy was more severe than loss of choriocapillaris.

11 No area was completely devoid of choriocapillaris.

12 neurosensory retina, and reperfusion of the choriocapillaris.

13 between the retinal pigmented epithelium and choriocapillaris.

14 es in a thinned retina with abnormal RPE and choriocapillaris.

15 onstrated that the bolus of dye perfused the choriocapillaris.

16 ypically more sluggish in CNV than in normal choriocapillaris.

17 ment epithelium (RPE), Bruch's membrane, and choriocapillaris.

18 ns extended in both the outer retina and the choriocapillaris.

19 vascular network in the outer retina and the choriocapillaris.

20 racellular lipid and vasodegeneration of the choriocapillaris.

21 seen in the deep capillary plexus (DCP) and choriocapillaris.

22 ll, mature-appearing B cells that spared the choriocapillaris.

23 ll, mature-appearing B cells that spared the choriocapillaris.

24 n face image averaging on OCTA images of the choriocapillaris.

25 xuses but also a vascular rarefaction of the choriocapillaris.

26 nal pigment epithelium (RPE), and underlying choriocapillaris.

27 ike deposits in Bruch's membrane, as well as choriocapillaris.

28 ed to OCTA flow deficits at the level of the choriocapillaris.

29 AMN may result from a vascular insult in the choriocapillaris.

30 a of RPE loss showed persistent but rarefied choriocapillaris.

31 scularization) compared with nonpathological choriocapillaris (205.1 +/- 46.9 PMNs/mm2 in pathologica

32 ent epithelial (RPE) complex, 78.22 (24.39); choriocapillaris, 25.77 (17.57); Sattler layer, 18.59 (1

33 HGF/SF was most intense at the level of the choriocapillaris, a finding that is significant because

34 Age and hypertension affect the choriocapillaris, a flat layer of capillaries that may s

35 EM), whereas others have substantial RPE and choriocapillaris alterations (e.g., LO-SD).

36 alyses highlight a necessary balance between choriocapillaris anatomical and functional parameters to

37 apillaris filling pattern in relation to the choriocapillaris anatomy as imaged by OCTA.

38 aked 4 h after LPS injection in the temporal choriocapillaris and 4 and 36 h after LPS injection in t

39 increased over background binding to healthy choriocapillaris and blocked by an Scg3-neutralizing ant

40 terol is localized mainly to deposits in the choriocapillaris and Bruch's membrane and on the surface

41 ature, like that of the yolk sac and the eye choriocapillaris and hyaloid vascular systems, develops

42 howed localization of FHR-2 and FHR-5 in the choriocapillaris and in drusen.

43 g of the ligand-modified quantum dots in the choriocapillaris and intraretinal capillaries upon i.v.

44 cular loss during disease progression in the choriocapillaris and larger vessels in the deeper choroi

45 ally heterogenous molecular exchange between choriocapillaris and outer retina.

46 roidal microvasculature, particularly in the choriocapillaris and peripapillary regions.

47 source is the choriocapillaris, and both the choriocapillaris and photoreceptors require trophic and

48 c administration may impair functions of the choriocapillaris and retina.

49 be another oxidative injury stimulus to the choriocapillaris and RPE, and may explain the associatio

50 er 1 (NBC1) is specifically expressed in the choriocapillaris and that missense mutations in CA4 link

51 pvOCT imaging of the microvasculature of the choriocapillaris and the anterior choroidal vasculature

52 likely to disseminate, can be traced to the choriocapillaris and the draining vortex veins and 2) HG

53 en the number of hyperreflective foci in the choriocapillaris and the Sattler layer and disease durat

54 eir blind-ended capillary branches enter the choriocapillaris and the walls of large veins.

55 AC was localized to Bruch's membrane and the choriocapillaris and was detectable at low levels as ear

56 al and choroidal circulations (including the choriocapillaris) and avoidance of dye injection-related

57 Their primary nutrient source is the choriocapillaris, and both the choriocapillaris and phot

58 tive foci in the Bruch membrane/RPE complex, choriocapillaris, and Sattler layer increased proportion

59 prominent at the Bruch membrane/RPE complex, choriocapillaris, and Sattler layer, correlate with dise

60 olved images of the retinal vasculature, the choriocapillaris, and the vessels in Sattler's and Halle

61 municates with the central retinal vein, the choriocapillaris, and with large veins of the optic nerv

62 generated using the "retina," "avascular," "choriocapillaris," and "outer retina to choriocapillaris

63 inal angiogram, outer retinal angiogram, and choriocapillaris angiogram.

64 Defects in RPE, photoreceptors, and the choriocapillaris are characteristic of age-related macul

65 We quantified "percent choriocapillaris area of nonperfusion" (PCAN) in eyes wi

66 tree, classifying the transcriptome of human choriocapillaris, arterial, and venous endothelial cells

67 h areas of reduced flow in the choroidea and choriocapillaris as apparent in OCT-A.

68 al FAs and with incomplete RPE repopulation, choriocapillaris atrophy, and outer retinal degeneration

69 a progressive degeneration characterized by choriocapillaris atrophy, RPE and BrM abnormalities, cul

70 minent outer collagenous layer deposits, and choriocapillaris basement membrane duplication/splitting

71 Quantitative analysis of the area of the choriocapillaris bed and RPE was performed by automated

72 Black subjects had decreased choriocapillaris BFA in the total 3 mm area (p = 0.011)

73 To study choriocapillaris blood flow in age-related macular degen

74 e was to examine the feasibility of rotating choriocapillaris, Bruch's membrane (BM), and retinal pig

75 Furthermore, FHR-4 accumulates in the choriocapillaris, Bruch's membrane and drusen, and can c

76 oxidized lipoprotein deposits located in the choriocapillaris, Bruch's membrane, and retinal pigment

77 in AMD retina and significantly lower in the choriocapillaris, Bruch's membrane, and RPE basal lamina

78 condition resulting from undulations in the choriocapillaris, Bruch's membrane, retinal pigment epit

79 lasma LDL readily enters the RPE through the choriocapillaris but is not found homogeneously througho

80 dest positional or hydrostatic pressure, the choriocapillaris capacity is, and this is measurable in

81 revealed elevated zinc concentrations in the choriocapillaris (CC) (mean 45, range 28-77 ppm), retina

82 udy was to examine the relationships between choriocapillaris (CC) and retinal pigment epithelial cha

83 structural and functional maturation of the choriocapillaris (CC) and to determine when fenestration

84 lexus (SVP), deep capillary plexus (DCP) and choriocapillaris (CC) as detected on optical coherence t

85 As such, we seek to characterize the choriocapillaris (CC) at each stage of the disease proce

86 stood, particularly the relationship between choriocapillaris (CC) dysfunction and phenotypic variabi

87 measure the age-dependent changes in macular choriocapillaris (CC) flow deficits (FDs) in normal eyes

88 n strategy that was developed to measure the choriocapillaris (CC) flow deficits (FDs) under drusen w

89 t rates (ERs) of geographic atrophy (GA) and choriocapillaris (CC) flow deficits (FDs), mean choroida

90 en RPE-BM distances and previously published choriocapillaris (CC) flow deficits in any subregions.

91 To report variation of choriocapillaris (CC) flow in widefield in high in myopi

92 Choriocapillaris (CC) images were quantified for VAD and

93 Choriocapillaris (CC) imaging of normal eyes with swept-

94 coherence tomography angiography allows for choriocapillaris (CC) imaging.

95 (SCP) and deep (DCP) capillary plexuses and choriocapillaris (CC) in patients with Best vitelliform

96 he retinal pigment epithelium (RPE), and the choriocapillaris (CC) in Stargardt disease (STGD).

97 ment of vascular density (VD) of retinal and choriocapillaris (CC) in various stages of diabetic reti

98 In advanced AMD, new vessels from choriocapillaris (CC) invade through the Bruch's membran

99 graphy angiography (OCTA) of the retinal and choriocapillaris (CC) vasculatures in normal subjects an

100 The retinal layers, choriocapillaris (CC), Sattler's layer (SL), Haller's la

101 angiography (OCTA) data were collected, and choriocapillaris (CC), Sattler's layer, and Haller's lay

102 t epithelium (RPE) in the maintenance of the choriocapillaris (CC).

103 the disease course, in particular regarding Choriocapillaris (CC).

104 as well as large choroidal blood vessels and choriocapillaris (CC).

105 y plexus (SCP), deep capillary plexus (DCP), choriocapillaris (CC)] was calculated at baseline and at

106 d with secondary sequellae involving RPE and choriocapillaris cell loss.

107 ls and AMD or GA eyes (P > 0.05), suggesting choriocapillaris changes are more prevalent in AMD than

108 Peripheral choriocapillaris closure was observed as well as dilated

109 ssive age-related changes in the RPE-Bruch's-choriocapillaris complex that have features that may be

110 nges in the retinal pigment epithelium (RPE)/choriocapillaris complex were quantified in dry and wet

111 larged Haller vein bordering the infiltrate, choriocapillaris compression and loss of choroidal archi

112 l choriocapillaris in 25 (83%), and abnormal choriocapillaris confined to the tumor apex in 17 (58%).

113 on these anatomical analyses reveal that the choriocapillaris contains regions where the transport of

114 subRPE lipid-rich deposits called drusen and choriocapillaris degeneration), and HIF-alpha stabilizat

115 wet age-related macular degeneration (ARMD), choriocapillaris degeneration, and glomerular thrombotic

116 Morphometric analyses of choriocapillaris density (cross-sectional area of capill

117 The peripheral choriocapillaris density displayed the same pattern as i

118 gic analysis revealed a similar reduction in choriocapillaris density in the irradiated area of eyes

119 The submacular choriocapillaris density was higher in eyes with AMD (0.

120 structural aging to the RPE-Bruch's membrane-choriocapillaris developed in mice treated with low-dose

121 VEGF188/188 mice exhibited normal choriocapillaris development.

122 trate that RPE-derived VEGF is essential for choriocapillaris development.

123 upport the view that the human HVS, like the choriocapillaris, develops by hemo-vasculogenesis, the p

124 uman eyes, we show that the thickness of the choriocapillaris does not vary significantly over large

125 e formation of outer retinal tubulations and choriocapillaris dropout.

126 Choriocapillaris dysfunction can be detected in the nonn

127 on of C5a peptides may lead to activation of choriocapillaris endothelial cells in AMD.

128 However, choriocapillaris endothelial cells in organ culture resp

129 ssess severity of deposits, BrM changes, and choriocapillaris endothelial morphology.

130 The choriocapillaris endothelium displayed fenestration loss

131 The choriocapillaris endothelium was variably hypertrophic.

132 rous retinal detachments, a pachychoroid and choriocapillaris enlargement.

133 ), choroidal thickness (in micrometers), and choriocapillaris-equivalent thickness (CCET, in micromet

134 scans (CV 8.0%) and good reproducibility of choriocapillaris-equivalent thickness (CV 27.9%).

135 ve analysis of the choroidal vasculature and choriocapillaris-equivalent thickness demonstrated excel

136 ation of choroidal vasculature thickness and choriocapillaris-equivalent thickness of the macula, and

137 e interval [CI] 163.7-180.5 mum) and average choriocapillaris-equivalent thickness was 23.1 mum (95%

138 hickness was 8.0% (95% CI 6.3%-9.4%), and of choriocapillaris-equivalent thickness was 27.9% (95% CI

139 Choriocapillaris-equivalent thickness was thinner in hea

140 Local choroidal vasculature and choriocapillaris-equivalent thicknesses were determined.

141 variation (CV) of choroidal vasculature and choriocapillaris-equivalent thicknesses.

142 The retinal pigment epithelium and choriocapillaris exhibited regional preservation.

143 plicated in future longitudinal studies, the choriocapillaris FD may prove to be a useful parameter f

144 At baseline, choriocapillaris FDs from different regions outside the

145 nolayer provides barrier resistance, induces choriocapillaris fenestration, and supports the formatio

146 rated from photoreceptor outer segments, and choriocapillaris fenestrations were decreased.

147 Posterior pole choriocapillaris filling pattern in relation to the chor

148 visible on blue autofluorescence, while the choriocapillaris filling was normal on fluorescein angio

149 In the posterior pole, the choriocapillaris fills in the pattern of discrete units

150 En-face slabs of choriocapillaris flow (CC-slab) or outer nuclear layer s

151 Deep capillary plexus and choriocapillaris flow also improved.

152 Choriocapillaris flow and retinal sensitivity improved w

153 such as the choroidal vascularity index and choriocapillaris flow area, which are crucial for a thor

154 In GA, choriocapillaris flow deficit decreased (r = -0.40; 95%

155 OCT angiography images were used to study choriocapillaris flow deficit percent (CCFD).

156 Choriocapillaris flow deficit was inversely correlated w

157 Choriocapillaris flow deficit was significantly greater

158 Choriocapillaris flow deficit was significantly greater

159 had larger areas of DDAF (100% cRORA) and of choriocapillaris flow deficits (all P < 0.01).

160 Choriocapillaris flow deficits inversely correlated with

161 macular and choroidal thickness on OCT; and choriocapillaris flow deficits on OCT angiography.

162 d a significant topographic association with choriocapillaris flow deficits percentage (CC FD%; beta

163 Choriocapillaris flow voids (CC-FVs) increased from grad

164 En-face analysis of SS-OCTA choriocapillaris flow voids provide a non-invasive metho

165 ution of microspheres revealed little if any choriocapillaris flow.

166 pigment epithelium (RPE), and (4) masking of choriocapillaris flow.

167 ies and vascular dropout observed within the choriocapillaris for pvOCT are compared with regional GA

168 In addition, RGCC was the most up-regulated choriocapillaris gene in a donor diagnosed with AMD.

169 utine visualization of retinal capillary and choriocapillaris hemodynamics of the intact eye.

170 We found that the choriocapillaris highly and specifically expresses the r

171 After averaging, en face choriocapillaris images showed a meshwork appearance.

172 The 9 registered choriocapillaris images were then averaged.

173 this transformation was then applied to the choriocapillaris images.

174 n 1 eye, below the Bruch membrane within the choriocapillaris in 1 eye, and in the larger choroidal v

175 oid" spots were detected at the level of the choriocapillaris in 15 patients (88.2%).

176 ralesional granularity in 14 (47%), abnormal choriocapillaris in 25 (83%), and abnormal choriocapilla

177 t be targeted to prevent damage to the aging choriocapillaris in AMD.

178 Surviving choriocapillaris in areas with complete RPE loss was hig

179 Qualitatively, the choriocapillaris in areas with RPD showed focal dark reg

180 luation, GA eyes showed persisting, rarefied choriocapillaris in correspondence of retinal pigment ep

181 Treatments to protect the choriocapillaris in early AMD are needed.

182 in the retinal pigment epithelium (RPE) and choriocapillaris in eyes of deceased donors with age-rel

183 RPE basal lamina, intercapillary septa, and choriocapillaris in eyes with AMD may be permissive for

184 otal number of PMNs was increased within the choriocapillaris in five diabetic eyes (170.9 +/- 12.9 P

185 lusion we report quantitative mapping of the choriocapillaris in myopic eyes compared with an age-mat

186 An evaluation of the status of choriocapillaris in the 2 groups was performed.

187 The presence of lesions in the choriocapillaris in the absence of retinal pigment epith

188 Surviving choriocapillaris in the area of RPE atrophy was signific

189 ents with STGD revealed an extensive loss of choriocapillaris in the central area with persisting tis

190 RPE atrophy was significantly narrower than choriocapillaris in the control subject and in normal ar

191 generate local, repetitive angiograms of the choriocapillaris in the rat and to assess the similarity

192 epithelium (RPE), Bruch's membrane, and the choriocapillaris in the setting of characteristic extrac

193 of spatial variations in the anatomy of the choriocapillaris in three additional human eyes indicate

194 inal layers, retinal pigment epithelium, and choriocapillaris in treatment and control eyes were unre

195 Imaging of the choriocapillaris in vivo is challenging with existing te

196 Histologically, CNV extended from the choriocapillaris into the subretinal space.

197 helium (RPE) and retinal disruption, without choriocapillaris involvement.

198 n ciliary body, retinal pigmented epithelium-choriocapillaris, iris, and neurosensory retina are pred

199 n ciliary body, retinal pigmented epithelium-choriocapillaris, iris, and neurosensory retina.

200 enular vessels connected to the plane of the choriocapillaris is non-random, and that venular inserti

201 l abnormalities supports the hypothesis that choriocapillaris is the primary site of pathology in SC,

202 subfoveal medium choroidal vessel layer and choriocapillaris layer thickness were significantly redu

203 subfoveal medium choroidal vessel layer and choriocapillaris layer thicknesses are significantly red

204 nd that of the medium choroidal vessel layer-choriocapillaris layer was 52.9 +/- 20.6 mum beneath the

205 from modest to extensive thickenings of the choriocapillaris layer.

206 s and metabolites between the retina and the choriocapillaris, leading to photoreceptor dysfunction a

207 To examine and quantify choriocapillaris lesions in active and quiescent serpigi

208 In inactive scars, the areas of retinal and choriocapillaris lesions were similar and did not change

209 En face SS-OCT imaging at the choriocapillaris level showed focally enlarged vessels i

210 OCTA reveals areas of non-perfusion at choriocapillaris level, proving that it is an essential

211 Clusters of choriocapillaris lobules were observed and appeared simi

212 Multimodal imaging is most consistent with choriocapillaris loss exceeding photoreceptor loss.

213 o better understand the mechanism leading to choriocapillaris loss in AMD.

214 ICG angiograms revealed choriocapillaris loss in large lesions and in some 500-m

215 vessels were preserved; in 200 mum lesions, choriocapillaris loss was not detectable.

216 Choriocapillaris loss was observed in early AMD (Bonferr

217 In contrast, after 4 days of hyperoxia the choriocapillaris lumenal diameters and percent vascular

218 r contour (n = 15) and thinned or compressed choriocapillaris (n = 2), thinned (n = 3) or thickened (

219 stabilization or STAT3 overactivation induce choriocapillaris neovascularization and type-I wet AMD p

220 Choriocapillaris non-perfusion, detectable via early-pha

221 However, methods to study the choriocapillaris noninvasively have been inadequate in t

222 with RPD have significantly larger areas of choriocapillaris nonperfusion compared with eyes with dr

223 n VEGFrpe-/- mice) results in the absence of choriocapillaris, occurrence of microphthalmia, and the

224 ally, loss of endothelial cells (ECs) of the choriocapillaris occurs early in AMD concomitant with el

225 tive evaluation of endothelial injury in the choriocapillaris of live animals, which detects disease

226 ies and especially strongly expressed in the choriocapillaris of the human eye.

227 he feasibility of noninvasively studying the choriocapillaris of the living rat using the technique o

228 rat and to assess the similarity between the choriocapillaris of the rat and that of the subhuman pri

229 ge choroidal vessels and at the level of the choriocapillaris on OCT (P < 0.001).

230 e averaging can improve visualization of the choriocapillaris on OCTA images, transforming the images

231 ry detail, they do not adequately reveal the choriocapillaris or other microvascular features beneath

232 r," "choriocapillaris," and "outer retina to choriocapillaris (ORCC)" slabs automatically provided by

233 CA IV immunostaining is limited to the choriocapillaris overlying the retina, whereas CA XIV is

234 sional granularity (P = .0005), and abnormal choriocapillaris (P = .0001).

235 The number of rolling microspheres in the choriocapillaris peaked 4-10 h after LPS injection.

236 sensitivity, supporting the hypothesis that choriocapillaris perfusion correlated with macular funct

237 visual acuity deficits (LLVADs) and central choriocapillaris perfusion deficits were investigated to

238 g the choroidal vascularity index (CVI), and choriocapillaris perfusion density (PD) on structural OC

239 alized, patient regained visual function and choriocapillaris perfusion was completely restored.

240 Outer retinal structure and choriocapillaris perfusion were more abnormal in RPGR- t

241 revealed a pathologic neovascular network in choriocapillaris plexus, probably the result of a fibrov

242 ks, average inner retinal PO2, normalized to choriocapillaris PO2, was higher in diabetic rats than i

243 Choriocapillaris regeneration appeared nearly normal by

244 was found to cause significant inhibition of choriocapillaris regeneration without apparent effect on

245 RPE/choriocapillaris regions contained approximately four ti

246 The choroidal vessels and choriocapillaris remained patent in the transplant bed.

247 space up to 3 months after surgery, and the choriocapillaris remains patent in the transplant bed, a

248 ing potential insight into the mechanisms of choriocapillaris response to complement injury and choro

249 atrophy (GA) is characterized by the loss of choriocapillaris, retinal pigment epithelium (RPE) and p

250 A loss of the choriocapillaris/retinal pigment epithelium left a "wind

251 Inhibition of choriocapillaris revascularization by genistein was sign

252 of the retina and retinal pigment epithelium-choriocapillaris (RPE-CC) complex and increased reflecti

253 The choriocapillaris segmentation of OCT-A revealed the pres

254 In the normal monkey eye the RPE and choriocapillaris show generalized recovery with preserva

255 In the SAM P(8), vascular casts of the choriocapillaris showed a mild but significant decrease

256 The vascular density of the choriocapillaris showed a trend toward decreasing in ass

257 he disease, the area of hypoperfusion in the choriocapillaris significantly increased as visualized o

258 percentage was measured from a 16-mum thick choriocapillaris slab after compensation and binarizatio

259 OCTA manifested a focal dark area in the choriocapillaris slab corresponding to flow signal voids

260 slab (22.0%), "avascular" slab (17.1%), and "choriocapillaris" slab (14.6%).

261 All donors had retinal capillaries and choriocapillaris staining for IgA.

262 voids forms a scale invariant pattern in the choriocapillaris starting at a size much smaller than a

263 the role of RPE-derived soluble VEGF on the choriocapillaris survival, we used mice that produce onl

264 al thickness, resulting in rescue of the RPE/choriocapillaris that continues to perfuse, hence sparin

265 We show that as a result of the form of the choriocapillaris, the blood flow is decomposed into a te

266 dly leads to vision loss and ablation of the choriocapillaris, the major blood supply for the outer r

267 AMD) is characterized by degeneration of the choriocapillaris, the vascular supply of retinal photore

268 Algorithms were used to quantify choroid and choriocapillaris thicknesses.

269 (35%) choroidal shadowing deep to the nevus, choriocapillaris thinning overlying the nevus (94%), ret

270 choroidal nevi were found to have overlying choriocapillaris thinning.

271 e similarity between the rat and the primate choriocapillaris, thus indicating that the rat is an acc

272 otoreceptors consume glucose supplied by the choriocapillaris to support phototransduction and outer

273 ges in the retinoid re-supply route from the choriocapillaris to the photoreceptors.

274 vide a characterization of the human RPE and choriocapillaris transcriptome, offering potential insig

275 VEGFR2 was detected in the choriocapillaris underlying the RPE.

276 electin glycoprotein ligand-Ig (rPSGL-Ig) in choriocapillaris using a scanning laser ophthalmoscope (

277 tor-A levels were negatively correlated with choriocapillaris vascular density.

278 aocular pressure normalized, the retinal and choriocapillaris vascular perfusion showed focal defects

279 ments that comprise each lobular area of the choriocapillaris vascular plexus.

280 and drusen, (2) RPE cell bodies, and (3) the choriocapillaris' vascular density and rod- and cone-med

281 Choriocapillaris vessel density (VD) in macular and peri

282 im of this study was to evaluate retinal and choriocapillaris vessel density using optical coherence

283 increased FAZ and loss of nasal and temporal choriocapillaris volume.

284 r lesions that destroyed photoreceptors, the choriocapillaris was also compromised, even when no chan

285 The choriocapillaris was imaged with better resolution of mi

286 Quantitative analysis of area of choriocapillaris was performed by automated image analys

287 tension within both the outer retina and the choriocapillaris was present in 90% and 69% of cases on

288 ntrols in CRVO group (p < 0.001) and PFVD of choriocapillaris was significantly reduced compared to c

289 RPE and choriocapillaris were analyzed by transmission electron

290 cular features of the retinal plexus and the choriocapillaris were analyzed on OCTA and compared with

291 cture and microvasculature of the retina and choriocapillaris were examined.

292 vascular zone, and only flow deficits in the choriocapillaris were noted.

293 FVD and overall PFVD of choriocapillaris were significantly reduced compared to

294 betic and nondiabetic choroidal capillaries (choriocapillaris) were analyzed in the flat perspective

295 a reticulum of flattened laminae, and in the choriocapillaris where ovoid-to-spindle-shaped SM cells

296 ebrates branched geometries predominate, the choriocapillaris, which is the microvascular bed that is

297 y slower subsequent revascularization of the choriocapillaris, which paralleled the RPE wound healing

298 eability capillaries are also present in the choriocapillaris, which supplies the retinal pigment epi

299 sed numbers of PMNs were present in areas of choriocapillaris with pathological changes (loss in APas

300 hich photoreceptors acquire glucose from the choriocapillaris with the help of the retinal pigment ep