ライフサイエンスコーパス: anterior chamber

1 however without inflammatory reaction of the anterior chamber.

2 h managed successfully by air filling of the anterior chamber.

3 creased and the XEN implant was found in the anterior chamber.

4 an inflammatory reaction was observed in the anterior chamber.

5 GDD was implanted without connection to the anterior chamber.

6 rs for migration of the DEX implant into the anterior chamber.

7 y to fibrovascular tissue contraction in the anterior chamber.

8 brane dye DiO and injected into normal mouse anterior chamber.

9 phema, or a severe fibrinous reaction of the anterior chamber.

10 lk of resistance to aqueous outflow from the anterior chamber.

11 n during development and resulted in shallow anterior chambers.

12 omplications included silicone oil in a deep anterior chamber (3 eyes in each group), untreatable hyp

13 ubconjunctiva, XEN45 stent migrated into the anterior chamber 7 months post-operatively and a case of

14 cone oil emulsification and migration to the anterior chamber (7.0% vs 11.9%), recurrent retinal deta

15 te were also performed: angle-supported (AS) anterior chamber (AC) (n = 47), iris-fixated (IF) (n = 2

16 Increased anterior chamber (AC) cell and LF values were observed w

17 status, previous vitreoretinal surgery, and anterior chamber (AC) cells and flare.

18 The purpose of this study was to report the anterior chamber (AC) depth and the attack of angle-clos

19 e uveitis; uveitis duration >10 vs <6 years; anterior chamber (AC) flare >grade 0; cataract; macular

20 corneal ECD (PCECD) in the area of the tube; anterior chamber (AC) flare; tube insertion entry site p

21 OCT) of the anterior segment (AS) to measure anterior chamber (AC) inflammation (both flare and cells

22 sure was whether or not postoperative double anterior chamber (AC) occurred.

23 effects of TH disruption on inflation of the anterior chamber (AC) of the swim bladder were available

24 Anterior chamber (AC) thermocouple temperature measureme

25 ry, an oxygen sensor was introduced into the anterior chamber (AC) via peripheral corneal paracentesi

26 In each eye, the anterior chamber (AC) was graded for cellular activity a

27 with active noninfectious anterior uveitis (anterior chamber [AC] cell count >=11 cells) were random

28 d both surgeries produced similar changes in anterior chamber and angle parameters.

29 effects model was used to compare changes in anterior chamber and angle variables with consideration

30 The angularity of the anterior chamber and associated anatomic changes.

31 tion was defined as deepening of the central anterior chamber and IOP of 21 mmHg or less (on 2 succes

32 The anterior chamber and lateral ventricle of anaesthetized

33 n provided detectable DSP levels in both the anterior chamber and vitreous chamber of the eye for at

34 was defined by a >/=2-step decrease of both anterior chamber and vitreous haze inflammation levels,

35 solution of cystoid macular edema (CME), and anterior chamber and vitreous inflammation were assessed

36 e no significant differences in baseline VA, anterior chamber and vitreous inflammation, presence of

37 on, delayed-onset painless vision loss, mild anterior chamber and vitreous inflammation, sectoral ret

38 extravasation from dilated vessels into the anterior chamber and vitreous, vitreous inflammation, vi

39 n of aqueous humor from the posterior to the anterior chamber, and (3) a compressible versus an incom

40 ma with anterior segment dysgenesis, shallow anterior chamber, and cataract were observed.

41 r complete intraoperative air filling of the anterior chamber, and correlation between donor age and

42 A steeper cornea, shallower anterior chamber, and greater lens thickness were the ma

43 e reference group of cataract surgery in the anterior chamber angle (16.2 +/- 5.0 vs. 13.0 +/- 3.9 mm

44 To compare structural differences in the anterior chamber angle (ACA) and related optic component

45 rface (AOD500 and AOD750, respectively), and anterior chamber angle (ACA) in the nasal and temporal q

46 Direct imaging of the anterior chamber angle (ACA) is possible using UBM and O

47 lighting and angle-of-incidence variation on anterior chamber angle (ACA) measurements acquired by ti

48 y and AS-OCT imaging in each quadrant of the anterior chamber angle (ACA).

49 verse correlation between CCT and pO2 in the anterior chamber angle (P = .048).

50 stigate age- and position-related changes of anterior chamber angle anatomy in normal, healthy eyes.

51 logic factors such as increased pO(2) in the anterior chamber angle and the posterior chamber to decr

52 to diminished surgery-induced damage to the anterior chamber angle and trabecular meshwork, and redu

53 No correlation between limbus-anterior chamber angle distance and axial length was est

54 Additional measurements included the limbus-anterior chamber angle distance with AS-OCT and the axia

55 Wider anterior chamber angle is associated with greater trabec

56 to assess the effect of diurnal variation on anterior chamber angle measurements, as well as, to re-t

57 Anterior chamber angle metrics did not differ significan

58 Anterior chamber angle status was evaluated by swept-sou

59 eir fellow eyes, LPI resulted in significant anterior chamber angle widening and increased anterior c

60 PACS or PAC/PACG, LPI results in significant anterior chamber angle widening seen on both ASOCT and g

61 ed with greater postoperative opening in all anterior chamber angle width parameters in both univaria

62 ecular meshwork anteroposterior length and 3 anterior chamber angle width parameters measured at diff

63 ative and postoperative measurements for the anterior chamber angle width parameters were compared by

64 abecular meshwork anteroposterior length and anterior chamber angle width parameters.

65 between baseline and LPI-induced opening of anterior chamber angle width parameters.

66 ular meshwork anteroposterior length and all anterior chamber angle width parameters: AOD250 (P < .00

67 ular meshwork anteroposterior length and all anterior chamber angle width parameters: AOD250 (P = .00

68 y assessing ocular biometric determinants of anterior chamber angle width.

69 helial cell density, anterior chamber depth, anterior chamber angle, and patient satisfaction were as

70 Anterior chamber angle, AOD500, TISA500, ACD, and lens p

71 fissure between the artificial iris and the anterior chamber angle, preventing further pupil constri

72 It is characterised by an open anterior chamber angle, raised intraocular pressure (IOP

73 posterior iris support in apposition to the anterior chamber angle.

74 cant glaucoma from pigment collecting in the anterior chamber angle.

75 diffuse pigmentation involving episclera and anterior chamber angle.

76 The anterior-chamber angle-supported PIOL changes its positi

77 The superior and inferior anterior chamber angles of the eyes were measured in sup

78 atients were hyperopic, and some had shallow anterior chamber angles that predisposed them to angle-c

79 anifested with pupillary membranes, immature anterior chamber angles, loss of pigment and thinning of

80 In PCG, defects in the anterior chamber aqueous humor outflow structures of the

81 ma drainage device (GDD) implantation in the anterior chamber are associated with corneal complicatio

82 r chamber depth (cACD) (P < .001), and lower anterior chamber area (ACA) (P < .001), as well as great

83 sed to measure anterior chamber depth (ACD), anterior chamber area (ACA), anterior chamber volume (AC

84 Anterior chamber depth (ACD), anterior chamber area (ACA), iris thickness (IT), iris a

85 iris configuration had significantly smaller anterior chamber area (P = .03) and volume (P = .01) com

86 cal coherence tomography (ASOCT) parameters (anterior chamber area, volume, and width [ACA, ACV, ACW]

87 ure, lens vault, anterior chamber depth, and anterior chamber area, were compared between early PACD

88 nterior chamber angle widening and increased anterior chamber area.

89 sular porosity of CERA GDDs connected to the anterior chamber at 1 week was 2.46 (0.36; 95% CI, 1.55-

90 lammation, defined as absence of cell in the anterior chamber at 2 weeks and absence of rebound iriti

91 Anterior chamber BGI insertion is associated with ECD lo

92 Before and 1, 2, 3, 4, and 5 years after anterior chamber BGI insertion, we evaluated the central

93 e first study to describe the correlation of anterior chamber bleeding after laser peripheral iridoto

94 The incidence of anterior chamber bleeding with and without antiplatelet

95 57% [8/14]), vitreous cell (64% [9/14]), and anterior chamber cell (50% [7/14]).

96 Anterior chamber cell and flare.

97 ntage of patients with remission, defined as anterior chamber cell and vitreous haze scores of 0 or 0

98 meeting the primary end point because of 1+ anterior chamber cell at 2 weeks and 4 prednisolone-trea

99 and moderately-but robustly-correlated with anterior chamber cell count (correlation coefficient ran

100 he summed ocular inflammation score of zero (anterior chamber cell count = 0 and absence of flare) by

101 Increasing (time-updated) anterior chamber cell grade was associated with increase

102 atory lesions, best corrected visual acuity, anterior chamber cell grade, and vitreous haze grade.

103 ard to three secondary end points (change in anterior chamber cell grade, change in vitreous haze gra

104 al or inflammatory retinal vascular lesions, anterior chamber cell grade, vitreous haze grade, and vi

105 The primary outcome measure was anterior chamber cell grades at day 28 comparing XG-102

106 has a higher recurrence rate and shows more anterior chamber cell infiltration compared with HLA-B27

107 ent had a hypopyon (0.5 mm), and the average anterior chamber cell was 1.8+ (range 0 to 4+).

108 s demonstrated faster times to resolution of anterior chamber cell, vitreous cell, and CME in the cry

109 vs 33%), tumor basal dimension (6 vs 7 mm), anterior chamber cells (16% vs 30%), and vitreous cells

110 independently associated with outcome: >=1+ anterior chamber cells (odds ratio [OR] 1.66, 95% confid

111 e independently associated with outcome: >1+ anterior chamber cells (OR 1.66, 95% CI, 1.09-2.52); >2m

112 ilateral granulomatous keratic precipitates, anterior chamber cells +++, bilateral synechiae, bilater

113 ts (9.9%) had intraocular inflammation only (anterior chamber cells and flare, vitreous inflammatory

114 Anterior chamber cells count on OCT did not differ betwe

115 orrected visual acuity, Khodadoust line, and anterior chamber cells demonstrated a significant increa

116 Anterior chamber cells on OCT increased among all cell c

117 djusted hazard ratio [aHR], 43.1; P = .004), anterior chamber cells or flare >/= 3+ (aHR, 25.6, P < .

118 one of three clinical parameters is met: >1+ anterior chamber cells, >2mm infiltrate, or infiltrate <

119 any 1 of 3 clinical parameters is met: >=1+ anterior chamber cells, >=2 mm infiltrate, or infiltrate

120 ops or surgery in the other eye (aHR, 4.17); anterior chamber cells: 1+ (aHR, 1.43) and >/=2+ (aHR, 1

121 be attributed partly to changes in angle and anterior chamber configuration, although these parameter

122 ars to also be proportional to the degree of anterior chamber deepening induced by cataract surgery.

123 Anterior chamber depth (4.03+/-1.06 mm preoperatively vs

124 factors for increased EC loss were a shallow anterior chamber depth (ACD) (P </= 0.005) and a smaller

125 The results of axial length (AL), anterior chamber depth (ACD) and anterior chamber volume

126 [M2]) as well as the pre- and postoperative anterior chamber depth (ACD) and pupil diameter (PD).

127 The aim was to compare the anterior chamber depth (ACD) measurements taken with Orb

128 700, and central corneal thickness (CCT) and anterior chamber depth (ACD) values obtained from both d

129 mong LT, LD, LV, age, axial length (AL), and anterior chamber depth (ACD) were analyzed.

130 Anterior chamber depth (ACD), anterior chamber area (ACA

131 Custom software was used to measure anterior chamber depth (ACD), anterior chamber area (ACA

132 The parameters included were iris area, anterior chamber depth (ACD), anterior chamber width (AC

133 k Co., Tokyo, Japan) was performed to obtain anterior chamber depth (ACD), axial length (AL), lens th

134 o evaluate the intrasession repeatability of anterior chamber depth (ACD), central (CCT) and peripher

135 corneal thickness (CCT), aqueous depth (AD), anterior chamber depth (ACD), crystalline lens thickness

136 Axial length (AL); anterior chamber depth (ACD), defined as the distance fr

137 Axial length (AL), anterior chamber depth (ACD), keratometry (K) over a 2.5

138 y readings, central corneal thickness (CCT), anterior chamber depth (ACD), lens thickness (LT), AL an

139 eal thickness, vitreous chamber depth (VCD), anterior chamber depth (ACD), lens thickness (LT), corne

140 er measurements calculated by formulas using anterior chamber depth (ACD), lens thickness (LT), or wh

141 Outcome variables included anterior chamber depth (ACD), lens thickness (LT), vitre

142 Independent variables, including anterior chamber depth (ACD), lens vault (LV), iris curv

143 nd anterior chamber volume (ACV; R = 0.848), anterior chamber depth (ACD; R = 0.818), spherical error

144 CI: 0.04, 0.18; beta: 0.05; P = .003), lower anterior chamber depth (B: -0.57; 95% CI: -0.83, -0.30;

145 baseline AOD; 95% CI, -0.67 to -0.53 mm) and anterior chamber depth (beta = 0.07-mm change/1-mm incre

146 parameters (P = .013 for all), less central anterior chamber depth (cACD) (P < .001), and lower ante

147 xial length, corneal power (K), preoperative anterior chamber depth (corneal epithelium to lens), and

148 (P < .001), older age (P = .006), and deeper anterior chamber depth (P = .015) were associated with l

149 components measurements (axial length [AL], anterior chamber depth [ACD], corneal radius of curvatur

150 Anterior chamber depth adjustment based on lens design s

151 Anterior chamber depth and angle width in pseudophakic e

152 eoperative and postoperative measurements of anterior chamber depth and angle width included the angl

153 Anterior chamber depth and angle, endothelial cell count

154 t); axial curvatures; asphericity of cornea; anterior chamber depth and volume; and iridocorneal angl

155 istory, best-corrected visual acuity, limbal anterior chamber depth assessment, frequency-doubling te

156 of axial length (AL), corneal curvature, and anterior chamber depth measurements of 2 new devices, 1

157 The definition of anterior chamber depth should be stated as measured from

158 ISA), iris area, iris curvature, lens vault, anterior chamber depth, and anterior chamber area, were

159 Axial length, anterior chamber depth, and central corneal power were m

160 ound central corneal thickness; pachymetric, anterior chamber depth, and corneal backscatter variable

161 phere plus half negative cylinder, while AL, anterior chamber depth, and corneal curvature were asses

162 associated determinants (axial length [AL], anterior chamber depth, and corneal curvature) with the

163 trast sensitivity, endothelial cell density, anterior chamber depth, anterior chamber angle, and pati

164 Anterior chamber depth, anterior chamber width, crystall

165 ens thickness, shorter axial length, shallow anterior chamber depth, anteriorly positioned lens, and

166 the axial length, corneal curvature radius, anterior chamber depth, central corneal thickness, and p

167 OD750 and axial length, and greater baseline anterior chamber depth, iris curvature, and lens vault (

168 error, axial length (AL), corneal curvature, anterior chamber depth, lens thickness, and central corn

169 How axial length-a sum of the anterior chamber depth, lens thickness, and vitreous cha

170 tion, small pupil, prior ocular surgery, and anterior chamber depth, we found that glaucoma cases wer

171 rence tomography (ASOCT) parameters, namely, anterior chamber depth, width, and area (ACD, ACW, and A

172 L, corneal curvature, and the measurement of anterior chamber depth.

173 was no relationship between birth weight and anterior chamber depth.

174 = 0.07-mm change/1-mm increment of baseline anterior chamber depth; 95% CI, 0.04-0.1 mm) were signif

175 posterior cornea; central corneal thickness; anterior chamber depth; and axial length.

176 en also exhibited steeper corneas, shallower anterior chamber depths, thicker lenses, and higher degr

177 vitrectomy histories present a high risk of anterior chamber dexamethasone implant migration.

178 Those patients who experienced anterior chamber dexamethasone implant migrations were i

179 ding the Descemet graft inside the recipient anterior chamber, either as stand-alone techniques or us

180 were no cases of implant migration into the anterior chamber, endophthalmitis, or retinal detachment

181 othelial graft is performed on an artificial anterior chamber, endothelial side up.

182 -level constant pressure perfusion following anterior chamber exchange.

183 l hyperemia (OR, 2.6; 95% CI, 1.02-6.5), and anterior chamber fibrin on examination (OR, 2.7; 95% CI,

184 l technique treats the cause by removing the anterior chamber fibrous complex after administration of

185 Positive correlations between the values of anterior chamber flare and absolute CT changes in both t

186 g eyes (n = 2, P < 0.005), as fluid from the anterior chamber flows around the lens equator toward th

187 Anterior chamber fluid and/or vitreous and/or intraocula

188 PCR analysis of the anterior chamber fluid is important for the confirmation

189 a diagnosis of retained lens fragment in the anterior chamber following otherwise uncomplicated phaco

190 rior chamber (n = 7), with connection to the anterior chamber for 1 week (n = 5), and with connection

191 r 1 week (n = 5), and with connection to the anterior chamber for 4 weeks (n = 5).

192 IOL calcifications after anterior chamber gas tamponade in DMEK lead to visual im

193 cluding a history of anterior uveitis and an anterior chamber glaucoma drainage device.

194 l curvature (HR, 1.74; P = 0.008), shallower anterior chamber (HR, 0.22; P = 0.008), and longer axial

195 s from 15 healthy, normal subjects underwent anterior chamber imaging using a Visante time-domain AS-

196 icantly associated with an increased risk of anterior chamber implant migration (P = 0.008).

197 icantly associated with an increased risk of anterior chamber implant migration (P = 0.009).

198 rall, 4 eyes of four patients (0.63%) showed anterior chamber implant migrations.

199 s the influences of different factors on the anterior chamber implant migrations.

200 Artificial iris anterior chamber implants are associated with sight-thre

201 Artificial iris anterior chamber implants were originally developed for

202 15%, 10%, and 0% (P = .001), shallow central anterior chamber in 22.5%, 22.5%, and 7.5% (P = .003), a

203 and 7.5% (P = .003), and shallow peripheral anterior chamber in 65%, 60%, and 17.5% (P = .004) of ch

204 ; however, significantly more eyes with flat anterior chambers in the double-plate group required ant

205 he degree of subclinical inflammation of the anterior chamber increases.

206 ransient corneal edema (n = 4) and transient anterior chamber inflammation (n = 1), which resolved fo

207 nd/or cycloplegics in eyes that demonstrated anterior chamber inflammation and intraocular pressure-l

208 Active anterior chamber inflammation was noted in 30 eyes (40%)

209 bilateral serous retinal detachments without anterior chamber inflammation, with no previous ocular h

210 weeks, patient-reported pain, and detectable anterior chamber inflammation.

211 sted viewing at the surgical microscope with anterior chamber infusion offers the ergonomic and optic

212 ntraocular pressure control using continuous anterior chamber infusion) with those of external draina

213 Intraocular pressure was maintained with an anterior chamber infusion.

214 ected if the patient is treated in time with anterior chamber injection of gas.

215 posterior chamber intraocular lens, 1.43 for anterior chamber intraocular lens [IOL], 2.83 for aphaki

216 266), but not more likely than those with an anterior chamber intraocular lens or who were aphakic.

217 atients who were aphakic, 4 patients with an anterior chamber intraocular lens, 2 patients with a scl

218 -risk recipients, aphakic eyes and eyes with anterior chamber intraocular lens, and eyes with PK (com

219 endothelial syndrome, aniridia, aphakia, and anterior chamber intraocular lenses, among others.

220 monstrating scleral invasion (n = 15) and/or anterior chamber invasion (n = 3).

221 the choroid, postlaminar optic nerve, and/or anterior chamber invasion received six cycles of adjuvan

222 In 6 eyes (50%) anterior chamber invasion was clinically detectable.

223 h at least 6-month follow-up were evaluated: anterior chamber IOL (ACIOL), iris-claw IOL, retropupill

224 Non-anterior chamber IOL techniques were less likely to repo

225 Invasion of the anterior structures (anterior chamber, iris, ciliary body/muscle) was detecte

226 Choices include anterior chamber lenses, iris- or scleral-sutured lenses

227 on because of recurrent tumor and persistent anterior chamber lesions.

228 OP transducers were calibrated bi-weekly via anterior chamber manometry.

229 te the incidence of and risk factors for the anterior chamber migration of an intravitreal dexamethas

230 The anterior chamber migration of an intravitreal dexamethas

231 e identified, as well as the reasons for the anterior chamber migration.

232 ollowing 3 groups: with no connection to the anterior chamber (n = 7), with connection to the anterio

233 ation of a DEX intravitreal implant into the anterior chamber occurred in 6 patients who were aphakic

234 3D OCT imaging of pH and lactic acid in the anterior chamber of a fish eye was realized by GTNPs@PAN

235 from induced pluripotent stem cells into the anterior chamber of a transgenic mouse model of glaucoma

236 viral injection of active TGF-beta1 into the anterior chamber of all wild-type and MMP-2 KO mice led

237 ataractous lens that was dislocated into the anterior chamber of her left eye.

238 DiO-labeled TMSCs injected into the anterior chamber of normal mice localized primarily in T

239 l microscopy of islets transplanted into the anterior chamber of the eye allowed to investigate kinet

240 , we transplanted "reporter islets" into the anterior chamber of the eye of leptin-deficient mice.

241 controls drainage of aqueous humor from the anterior chamber of the eye primarily by regulating extr

242 ections of small amounts of betagal into the anterior chamber of the eye produced similar numbers of

243 ome (PDS), and its deposition throughout the anterior chamber of the eye.

244 thalmia, periocular edema and absence of the anterior chamber of the eye; additionally, fish with het

245 ntibody fragment ESBA105 penetrated into the anterior chamber of the human eye at therapeutic levels.

246 of acapsular glomeruli transplanted into the anterior chamber of the mouse eye.

247 In 1 eye in group A, a dislocation in the anterior chamber of the posterior chamber intraocular le

248 Better control of anterior chamber or vitreous activity is associated with

249 During follow-up, reductions in anterior chamber or vitreous cellular activity or in vit

250 ms of endophthalmitis (eg, decreased vision, anterior chamber, or vitreous cells) in the 5 cases pres

251 iated with vitritis (P = .005); cells in the anterior chamber (P = .007); the highest fluorescein ang

252 and frequency of management change based on anterior chamber paracentesis and PCR.

253 Anterior chamber paracentesis with PCR of aqueous fluid.

254 diagnosis of anterior uveitis who underwent anterior chamber paracentesis with PCR.

255 ed 419 patients treated with ocular massage, anterior chamber paracentesis, and/or hemodilution (cons

256 atment with glaucoma medications, performing anterior chamber paracentesis, or increasing the interva

257 ous humor of patients undergoing therapeutic anterior chamber paracentesis.

258 ge in management because of PCR results from anterior chamber paracentesis.

259 tation of the AcrySof Cachet angle-supported anterior chamber pIOL (Alcon Laboratories, Inc., Fort Wo

260 piscleral vascular congestion (40% vs. 16%), anterior chamber reaction (30% vs. 14%), hyphema (15% vs

261 No significant differences in postoperative anterior chamber reaction (P = 0.7) or LPI area (P = 0.9

262 ation: 24% with only vitritis, 16% with only anterior chamber reaction, and 60% with both.

263 20/100 to 20/400, corneal edema and opacity, anterior chamber reaction, or stromal neovascularization

264 There was mild anterior chamber reaction.

265 chambers in the double-plate group required anterior chamber reformation (P= .03).

266 n IOP occurred sooner in eyes that underwent anterior chamber reformation in clinic (P < .002).

267 ay shorten the time to anatomic recovery and anterior chamber reformation may hasten IOP recovery.

268 High-resolution, corneal quad, and anterior chamber scans were also obtained.

269 = 3), ciliary body involvement (n = 2), and anterior chamber seeding (n = 3).

270 Anterior chamber seeding following intraophthalmic arter

271 risk features in these 145 patients included anterior chamber seeds (n = 25, 17%), iris infiltration

272 stopathology were defined as the presence of anterior chamber seeds, iris infiltration, ciliary body

273 gic features were defined as the presence of anterior chamber seeds, iris infiltration, ciliary body/

274 ude: entire stent found at the bottom of the anterior chamber several months after uncomplicated inse

275 Fibroblasts injected in mouse anterior chamber showed distributed localization in corn

276 Pseudoexfoliation eyes without shallow anterior chamber, small pupils, or apparent zonulopathy

277 On ultrasound biomicroscopy the anterior chamber structures were difficult to differenti

278 vs DMEK, the use of SF6 gas vs room air for anterior chamber tamponade, and the presence of hydrophi

279 Pretreatment with glaucoma medications, anterior chamber tap, vitreous reflux, longer intervals

280 Anterior chamber temperature during PPC and grading of o

281 disposable cartridge and delivered into the anterior chamber under continuous irrigation using a bim

282 as well as elevated IOP, demonstrating that anterior chamber vascular development is sensitive to Te

283 ength (AL), anterior chamber depth (ACD) and anterior chamber volume (ACV) differed as a function of

284 er depth (ACD), anterior chamber area (ACA), anterior chamber volume (ACV), iris curvature (I-Curv),

285 elation was detected between angle means and anterior chamber volume (ACV; R = 0.848), anterior chamb

286 sions, defective iridocorneal angle, reduced anterior chamber volume and corneal neovascularization.

287 hickness, vitreous length, axial length, and anterior chamber volume were moderately correlated with

288 ive to minimize vitreous traction, stabilize anterior chamber volume, maintain capsular and zonular i

289 detection of the implant migration into the anterior chamber was 13 days (range, 5-44 days).

290 After surgery, double anterior chamber was observed in 2 cases (2.5%), both ma

291 complications, an increased risk of shallow anterior chamber was observed in the limbal-based group.

292 Ultrasound biomicroscopy (UBM) images of the anterior chamber were acquired.

293 hanges were restricted to the cornea and the anterior chamber, where they caused profound uveal infla

294 etected in the risk of postoperative shallow anterior chamber, which was increased in the limbal-base

295 ere iris area, anterior chamber depth (ACD), anterior chamber width (ACW), and lens vault (LV).

296 Anterior chamber depth, anterior chamber width, crystalline lens rise, and the d

297 (ACD), lens vault (LV), iris curvature (IC), anterior chamber width, lens thickness, vitreous cavity

298 s) using polystyrene bead injection into the anterior chamber with 126 control CD1 and 128 control B6

299 f the surgery, immediately after filling the anterior chamber with air, categorized into low (<10 mm

300 ocated in the inferior angle or the inferior anterior chamber, with 13% of cases requiring gonioscopy