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1 tered subretinal hemorrhages external to the macula.
2 al pigment epithelium (CHRRPE) involving the macula.
3 ts of 52 highly myopic eyes with dome-shaped macula.
4 scotomas were more prevalent in the central macula.
5 us cavity, no longer casting a shadow on the macula.
6 eral retina in a single shot centered on the macula.
7 ss associated with geographic atrophy of the macula.
8 on and outer retinal streaks in the superior macula.
9 sess the impact of a vitreous opacity on the macula.
10 domain optical coherence tomography (OCT) of macula.
11 with specific retinal diseases affecting the macula.
12 ion histologic images of the preserved donor macula.
13 least frequently located within the central macula.
14 ans through the center of the optic disc and macula.
15 and 6 x 6-mm OCT angiograms centered at the macula.
16 r cube OCT revealed a circular shadow on the macula.
17 s in which these clearly originated from the macula.
18 e periphery without end-stage disease in the macula.
19 ot optimal for detecting early damage of the macula.
20 cations in the retinal periphery and central macula.
21 esulting in impaired fluid resorption in the macula.
22 used in two consecutive sessions to scan the macula.
23 sed to compare VCT, StCT, and TCT across the macula.
24 oroidal thickness does not change within the macula.
25 l-domain optical coherence tomography of the macula.
26 nds, whereas type 1 lesions spared the outer macula.
27 he transpupillary thermotherapy scar and the macula.
28 nasal to the optic disc, and temporal to the macula.
29 large majority of which affected the central macula.
30 iagnosed with arRP and pseudocoloboma of the macula.
31 strates the arcuate course of the NFL in the macula.
32 nd 7.83 +/- 1.55 mm(3), respectively, at the macula.
33 with IRX1 preferentially expressed in fetal macula.
34 ystoid intraretinal fluid collections in the macula.
35 ere performed to test sensitivity across the macula.
36 ed accordingly to maintain an exudation-free macula.
37 ging of the superior, inferior, and/or nasal macula.
38 red to patients with disease confined to the macula.
39 eral multiple early-onset yellow dots at the macula.
40 mporal margin of the coloboma closest to the macula.
41 ue architecture of the fovea and surrounding macula.
42 ateral symmetric multiple yellow dots at the macula.
43 to quantitate individual networks within the macula.
44 continuously across the central 3 mm of the macula.
45 nd retinal pigment epithelium atrophy in the macula.
46 d by advanced AMD and drusen temporal to the macula.
49 creased to 0.95, 0.99, 0.87, and 0.93 for 3D macula, 3D optic disc, radial, and line scans, respectiv
52 er cracks were more prevalent in the central macula (51%) than in the nasal (19%), temporal (14%), in
54 of AMN that affects the middle layers of the macula above the OPL as diagnosed with SD-OCT imaging.
55 ferent types of retinal fluid in the central macula affect the reproducibility of choroidal thickness
56 examined, 81.1% had AMD-like changes in the macula alone (13.6%), periphery alone (10.1%), and both
57 3 OCT angiography instruments in the central macula, an area where the superficial and deep vascular
60 rformed on a 3 x 3-mm region centered on the macula and en face angiograms of the superficial and dee
63 The average total retinal thicknesses of the macula and fovea in the patients with achromatopsia were
67 treal ranibizumab injections, overall in the macula and in neovascular and non-neovascular areas, fro
68 By comparison, average sensitivity in the macula and mid periphery declined by 0.38 and 0.61 dB/ye
70 and pigmentary abnormalities in the central macula and no evidence of macular fluid on routine OCT i
77 raster 3D-OCT scans (512 x 128) covering the macula and optic nerve from each eye using 3D-OCT-1000.
78 optical coherence tomography (SD OCT) of the macula and optic nerve head (ONH), infrared reflectance,
79 ively the possible structural changes of the macula and optic nerve head in the free eyes of unilater
81 l-domain optical coherence tomography of the macula and optic nerve head using the Heidelberg Spectra
85 mography (FD-OCT) system was used to map the macula and peripapillary regions of the retina in 56 eye
86 th AMD, RPE mtDNA damage was measured in the macula and peripheral sections from individual donors.
87 between ischemia and vascular leakage in the macula and periphery, it was only macular ischemia and r
88 y allows mapping of light sensitivity of the macula and provides topographic information on visual fu
89 have bilateral outer retinal streaks in the macula and the superior peripheral retina on both ophtha
90 ed with extensive drusen accumulation in the macula and throughout the fundus, as well as with a high
91 hemorrhagic and exudative changes within the macula and/or peripapillary region leading to vision los
92 FHs involved the periphery, 83% involved the macula, and 71% involved multiple layers of the retina.
93 , peripapillary pigment (PPP), drusen in the macula, and drusen elsewhere, whereas 3D-OCT scans were
95 choriocapillaris-equivalent thickness of the macula, and evaluated repeat variability in normal subje
96 lated at the cornea, vitreous base, equator, macula, and orbit apex for pressures known to cause tymp
98 the position of the lacquer crack within the macula, and the relationships between perforating sclera
99 e at one visit, despite achievement of a dry macula, are associated with retreatment at the next visi
101 ow that all types of sub-RPE deposits in the macula, as well as in the periphery, contain numerous HA
103 Atypical for RP features included mottled macula at an early age and peripapillary sparing of the
104 rior to diagnosis and chorioretinitis in the macula at presentation were associated with >/= 2 Snelle
107 n which dilated fundus photographs (disc and macula centered) were obtained and graded for the presen
110 The concentric rings method consists of 6 macula-centered concentric rings divided into 12 segment
111 ild," "moderate," or "severe" and at least 2 macula-centered FA images over a minimum of 6 months wer
112 "macula-centered image(s) only" if only the macula-centered image of one or both eyes was gradable,
114 53 (72%; 95% CI, 65-78) patients, success of macula-centered image(s) only in 47 (22%; 95% CI, 17-28)
115 ry (P = .093), and the frequency of gradable macula-centered image(s) only increased with increasing
116 ial" if both images of 1 eye were gradable, "macula-centered image(s) only" if only the macula-center
119 cluded and underwent consecutive, registered macula-centered spectral-domain optical coherence scans
120 group (II); a significant thinning of total macula, central fovea, ganglion cell layer (GCL), gangli
121 Neurodegenerative diseases affecting the macula constitute a major cause of incurable vision loss
123 corded region of macular pigment loss in the macula correlated well with Muller's cell depletion.
124 l participants underwent OCTA imaging of the macula covering a 3 x 3-mm area using OCTA software (Cir
125 and volume changes between visits with a dry macula ("D") and immediate preceding visits ("D-1") were
127 r upregulation of NOS1beta expression in the macula densa affects sodium excretion and salt-sensitive
128 onship between (a) NaCl concentration at the macula densa and (b) glomerular filtration rate or glome
129 a is a primary NOS1 isoform expressed in the macula densa and regulates the tubuloglomerular feedback
131 ice had decreased hyperfiltration, decreased macula densa cyclooxygenase-2 expression, decreased albu
137 tubuloglomerular feedback through increased macula densa sodium and chloride delivery, leading to af
141 mmon abnormality associated with dome-shaped macula, detected by SD OCT in 44% of the cases with no a
146 arcades in 3 eyes (27%), and throughout the macula extending nasal to the optic nerve in 2 eyes (18%
147 ntral macula in 6 eyes (55%), throughout the macula extending to the outside of the temporal arcades
150 nt between FA and OCTA scans centered on the macula for capillary nonperfusion (intraclass correlatio
153 hed: Group 1 had dysfunction confined to the macula; Group 2 had macular and generalized cone system
154 r genes related to zeaxanthin binding in the macula (GSTP1), carotenoid cleavage (BCMO1), cholesterol
155 One patient with end-stage disease in the macula had normal periphery results on the color images.
156 retinal detachment in 2 (12%), a dome-shaped macula in 1 (6%), a choroidal neovascularization-related
159 strated schisis cavities only in the central macula in 6 eyes (55%), throughout the macula extending
160 d deep capillary plexus (DCP) in the central macula in all 6 patients were compared with 5 normal sub
161 An optically empty space was seen above the macula in all eyes, and corresponded to the premacular b
162 bnormalities in the perifoveal region of the macula in all eyes, whereas FA appeared normal in 9 of 1
163 igate retinal and choroidal thickness at the macula in anterior (AU) and intermediate (IMU) uveitis a
167 nd healthy controls underwent imaging of the macula in both eyes with a swept-source optical coherenc
168 enrolled in the Ranibizumab for Edema of the Macula in Diabetes: Protocol 3 with High Dose (READ-3) s
172 , we evaluated the functional changes of the macula in response to pharmacological treatment through
173 and analyze retinal light sensitivity of the macula in STGD1 using fundus-controlled perimetry (micro
174 possessing a visual streak similar to human macula-in the study of diabetic retinopathy and diabetic
175 ons typically appear first in the perifoveal macula, initially sparing the foveal center, and over ti
177 easures (occurrence of significant center of macula involvement, optical coherence tomography [OCT]-d
179 tenance of otolith tethering to the saccular macula is dependent on tectorin alpha (tecta) function,
180 nsduction and survival of cones in the human macula is essential for color vision and for visual acui
183 To directly test a long-held belief that the macula is selectively damaged with AMD, RPE mtDNA damage
187 es were overlaid digitally based on disc and macula location onto stereographically projected UWF ima
188 has been shown that the functionality of the macula lutea depends on the nutritional uptake of lutein
190 evaluating involvement of the center of the macula may differ, probably because of macular pigmentat
193 tumors were unilateral (n = 7), involved the macula (n = 3), and had a mean distance to the foveola o
194 tance and MultiColor imaging, located at the macula, nasal or superonasal to the fovea, which did not
197 ted the serial cross-sectional images of the macula obtained using the Spectralis OCT (HRA+OCT; Heide
199 o evaluate segmentation accuracy of a normal macula of a white man in his 60s as an emblematic exampl
202 ndomized clinical trial (Lutein Influence on Macula of Persons Issued From AMD Parents [LIMPIA]) with
209 was diagnosed in 15 patients (88.2%) in the macula-off RD group, leaving 2 patients (11.8%) unaffect
211 significantly increased risk of developing a macula-off retinal detachment in patients who did not un
214 enon of an imaging artifact appearing at the macula on near-infrared reflectance and MultiColor imagi
217 higher incidence of aniseikonia, compared to macula-on RD patients, following retina reattachment.
221 d positioning is prescribed to patients with macula-on retinal detachment (RD) to prevent RD progress
223 of conjunctival erosion and 1 inferotemporal macula-on retinal detachment, which were successfully re
224 pseudophakic (79.1% vs 78.0%; P = 0.88), and macula-on versus macula-off (77.9% vs 81.1%; P = 0.68) g
226 nges such as circumferential fibrosis of the macula or peripapillary area and "torpedo-like" lesions
228 ess was also subnormal in the superotemporal macula (P<0.0001), where it varied with visual acuity (P
231 R for CM (with 100% of the dose given to the macula) present major changes at both plexuses but also
232 ny/increased intraocular pressure (IOP); (7) macula pucker/epiretinal membrane; (8) cataract; and (9)
239 jects were imaged using a 3-dimensional (3D) macula scan covering a nominal 6 x 6-mm area with a reso
240 n artifact on 3D scans (optic disc scan, 7%; macula scan, 9%), whereas segmentation failure occurred
241 nts underwent a 3-dimensional optic disc and macula scanning protocol with a prototype SS OCT (Topcon
243 However, the pigeon retina and the human macula share a number of structural and functional prope
248 mates are the only mammals to possess a true macula similar to humans, and spontaneously develop drus
254 inherited degenerative disease of the human macula that results in progressive and irreversible cent
255 ic patch of subretinal fluid temporal to the macula that was associated with orange polygonal pigment
256 disease may develop serous elevations of the macula that we classify as acquired vitelliform detachme
258 itially obtained VA gain and thinning of the macula that were maintained for two years, but were lost
259 ion and metabolism of these nutrients in the macula, the best way to measure MPOD, and the clinical b
261 erence tomography [OCT]-determined center of macula thickness, application of focal photocoagulation)
262 a, subretinal haemorrhage, subretinal fluid, macula thickness, macular scar, subretinal fibrosis).
263 r NF1 who had >/=2 volumes acquired over the macula using handheld OCT during sedation for clinically
264 the human vestibular endorgan, the utricular macula, using postmortem specimens from individuals with
266 domain optical coherence tomography (SD-OCT) macula volume scans centered at the fovea and fundus aut
268 by pro re nata injections until a fluid-free macula was achieved on optical coherence tomography.
270 tion between baseline and the visit when the macula was completely dry or when the central subfield t
271 detachments compared with those in which the macula was detached (logMAR 0.18 vs 0.42; P <0.005).
277 osterior retinal cystoid degeneration, a dry macula was obtained in 75% and 25% of the eyes at 1 mont
278 ence group with subretinal fluid only, a dry macula was obtained in 89.5% and 100% of the eyes at 1 m
283 elay of diagnosis and chorioretinitis in the macula were associated with visual loss in these patient
284 ssociated with less probability of preserved macula were diagnosis in 2009, older age, worse vision,
286 d axial (vertical) distribution of HF in the macula were evaluated with pairwise signed-rank tests.
291 0/32 to 20/320 and DME involving the central macula were randomly assigned to intravitreous ranibizum
293 the relative anatomical preservation of the macula, which suggested the presence of a therapeutic wi
295 s of 48 eyes in 33 patients with dome-shaped maculas who were referred because of decreased vision.
296 s and a large yellowish lesion involving the macula with an overlying sub-retinal detachment, extendi
298 s characterized by cavitation in the central macula with or without typical cystoid macular edema.
299 nts demonstrated splitting of the OPL in the macula with relatively preserved visual acuity (>/= 20/4
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