ライフサイエンスコーパス: parafoveal

1 muli were peripheral but the goal was foveal/parafoveal.

2 as the inferred movement goal was foveal and parafoveal.

3 It is known that maturation of the parafoveal (10 degrees eccentric) rod outer segments and

4 with ILM peeling, predominantly in temporal parafoveal (20%) and perifoveal (19%) rings.

5 chloroquine retinopathy within 15 years (102 parafoveal, 23 pericentral).

6 AMD demonstrated lower VD, especially in the parafoveal (29.8% +/- 6.3% vs 33.0% +/- 5.7%, P < .001)

7 resolves three unexplained phenomena: 1) the parafoveal advantage in segmentation, 2) the uniform imp

8 tive to monocular text presentation for both parafoveal and foveal lexical processing during reading.

9 B2 are differentially spliced in the foveal, parafoveal and macular regions.

10 he fovea), or mixed (retinal changes in both parafoveal and pericentral areas).

11 sity was calculated from en face OCTA of the parafoveal and perifoveal regions in each of the 3 plexu

12 age were represented by mean gray value over parafoveal and perifoveal regions.

13 icant increases were observed in the foveal, parafoveal and perifoveal regions.

14 Parafoveal and perifoveal VD performed significantly wor

15 Parafoveal and perifoveal VD were significantly lower in

16 ean [SD] age, 55.1 [12.1] years) had reduced parafoveal and perifoveal vessel density by 12.6% (95% C

17 Preplanned primary measures were parafoveal and perifoveal vessel density, total avascula

18 At both parafoveal and peripheral eccentricities, infants' value

19 red between infants and controls and between parafoveal and peripheral eccentricities.

20 (A(O), T(D)) differed significantly between parafoveal and peripheral eccentricities.

21 On the other hand, parafoveal and peripheral eigengraus are equal in ROP su

22 decreased with age until by age 26 weeks the parafoveal and peripheral thresholds were equal and were

23 ionally been studied in the lower-resolution parafoveal and peripheral visual field.(1-4) It is not k

24 d a more severe fluorescein leakage over the parafoveal and the perifoveal regions than the responsiv

25 vascular density changes were absent in the parafoveal and whole areas of the deep retinal plexus.

26 meter, 50 ms duration) presented 10 degrees (parafoveal) and 30 degrees (peripheral) from a central f

27 superficial capillary plexus in the foveal, parafoveal, and full macular regions and foveal avascula

28 exhibited significantly thinner perifoveal, parafoveal, and overall ONL compared to controls (P < .0

29 1 evaluable eyes) was 7.7 dB and for foveal, parafoveal, and perifoveal loci were 20.2, 11.8, and 5.8

30 s, foveal avascular zone (FAZ) area, foveal, parafoveal, and perifoveal vascular density (VD) were ev

31 ual acuity of 6/9 or better, and an abnormal parafoveal annulus of high density AF.

32 Fundus autofluorescence imaging showed a parafoveal annulus of increased autofluorescence.

33 trols (P < .05) and cone density loss in the parafoveal area (2 degrees; <12%-16%) during follow-up.

34 SD], 36.7 [4.8] vs 33.5 [2.0]; P = .006) and parafoveal area (38.7 [5.6] vs 34.7 [2.6]; P = .005).

35 signal void area in comparison with both the parafoveal area (p < 0.0001) and the perifoveal area (p

36 ined patients with diabetes detect their own parafoveal area defects are 51% and 82%, respectively.

37 e monitoring of the early natural history of parafoveal area disease processes.

38 depending on the Vascular Entoptoscope used: parafoveal area subtends approximately 9.7 degrees).

39 On the parafoveal area, mean VD was lower in patients with anir

40 of retinal vasculature abnormalities in the parafoveal area.

41 subjects they were concentrated in the nasal parafoveal area.

42 VD in the foveal and parafoveal areas at the level of the superficial and dee

43 apillary plexuses (DCP-VD) of the foveal and parafoveal areas were examined in detail.

44 Mean scotopic thresholds over parafoveal areas within the ring were markedly elevated

45 ital aniridia, higher in foveal and lower in parafoveal areas, especially when FH is severe, which is

46 aled low reflectance areas in the foveal and parafoveal areas.

47 Twenty-two patients (22/40, 55%) had patchy parafoveal atrophy and flecks; 8 (20%) had numerous flec

48 sion with central sparing (RLCS), simulating parafoveal atrophy observed in patients with progressive

49 ective vitreous opacities within 5 foveal or parafoveal B-scans (vitreous opacity ratio).

50 Here we show that visual acuity in the parafoveal belt can be immediately improved by deliverin

51 age in the foveal (beta = -0.211, P < .001), parafoveal (beta = -0.305, P < .001), and full macular r

52 ine retinopathy does not always develop in a parafoveal (bull's eye) pattern, and a pericentral patte

53 f AOSLO imaging, it is possible to visualize parafoveal capillaries and identify AV channels noninvas

54 FD-300, AI, perimeter, and vessel density of parafoveal capillaries in deep capillary plexus precedin

55 The parafoveal capillaries were clearly visible when the mot

56 The SD, VD, and FD of the parafoveal capillaries were lower in uveitic eyes compar

57 a marked improvement in the contrast of the parafoveal capillaries when compared to the unprocessed

58 Quantitative analysis of parafoveal capillary density and morphology in uveitis d

59 Detailed images of the parafoveal capillary network were generated with custom

60 aneous assessment of several features of the parafoveal capillary network.

61 ed as an automated FAZ (aFAZ) >=0.5 mm(2) or parafoveal capillary nonperfusion (CNP) >=1 quadrant if

62 loroquine retinopathy, 153 (76%) had typical parafoveal changes, 24 (12%) also had a zone of pericent

63 iewing all the scans, poor identification of parafoveal CNP was the most common reason for erroneous

64 report two main results: (1) Supra-threshold parafoveal colour perception remains largely unaffected

65 The slower development of parafoveal compared with peripheral thresholds in subjec

66 ging revealed a foveal lesion and diminished parafoveal cone density in both eyes compared to two age

67 ed 9 months after onset and revealed reduced parafoveal cone density in the affected and non-affected

68 the foveal lesion was still present and the parafoveal cone density increased but remained reduced e

69 However, our 2 cases showed that parafoveal cone density recovered during follow-up but d

70 Here, we investigate parafoveal cone function in CHM using adaptive optics op

71 Parafoveal cone mosaics of 10 CHM and four normal-sighte

72 Parafoveal contrast thresholds showed a steeper decline

73 Optical coherence tomography macula showed parafoveal cystoid macular edema bilaterally.

74 Type 2 (10 cases), demonstrated rupture of parafoveal cysts or schisis mainly from epiretinal membr

75 tive to the characteristic patterns of early parafoveal damage and is prepared to retest fields and a

76 Conversely, all cases with a clear degree of parafoveal damage on SD-OCT showed at least some focal s

77 f toxic effects categorized as early (patchy parafoveal damage shown on field or objective testing),

78 12%) had pericentral retinopathy without any parafoveal damage.

79 t more consistent than red fields in showing parafoveal damage.

80 .2 +/- 3.8 and 25.8 +/- 1.9, P < .0001), and parafoveal dark-adapted (21.1 +/- 2.8 dB and 23.2 +/- 1.

81 Similarly, parafoveal dark-adapted sensitivity was topographically

82 ignificantly lower VAD and VSD at foveal and parafoveal DCP (all P < 0.02).

83 CP and DCP VD and negatively correlated with parafoveal DCP VD (CC: -0.770, -0.719, 0.377, respective

84 However, the parafoveal deep capillary plexus (DCP) VD was lower than

85 Whole image and parafoveal deep macular vessels in glaucoma eyes (21.0%+

86 omatous eyes had lower temporal and inferior parafoveal deep vasculature values than NAION eyes (P =

87 oveal scotoma (IPFS), and combined nasal and parafoveal defect, and the association between type of V

88 Patients and control subjects without parafoveal defects rarely report defects not visible pho

89 sessions, changes of foveal, perifoveal and parafoveal densities, macular whole image vessel density

90 The high sensitivity of parafoveal depression on mfERG and its relationship to c

91 ted parafoveal thresholds also have elevated parafoveal eigengraus.

92 s stopped when decreased reflectivity of the parafoveal ellipsoid zone is detected by SD-OCT, the pro

93 Participants performed foveal and parafoveal face and house discrimination tasks for uprig

94 n SD-OCT showed at least some focal spots of parafoveal field loss.

95 ively for measures of foveal avascular area, parafoveal flow, and vascular density.

96 ccording to fluid localization: 19 cases had parafoveal fluid (of whom 9 also had subfoveal fluid).

97 e demonstrate a laser-induced mouse model of parafoveal GA progression, starting at 2 weeks post-lase

98 ogical receptive field dimensions of primate parafoveal ganglion cells by convolving Gaussian-blurred

99 6, p < 0.001) and negatively correlated with parafoveal GCC thickness (r=-0.357, p = 0.041).

100 iPD patients with lower parafoveal GCIPL and pRNFL thickness at baseline present

101 use of optical coherence tomography-measured parafoveal GCIPL thickness to monitor neurodegeneration

102 In the macular region of both eyes, parafoveal greying with crystalline deposits and changes

103 to be adjusted to recognize pericentral and parafoveal hydroxychloroquine retinopathy.

104 and four of the six demonstrated foveal and parafoveal hyperfluorescence on FAF.

105 challenged with consistent errors in foveal/parafoveal image motion during tracking.

106 pattern analysis, we demonstrate that future parafoveal images could be decoded at the feature and ca

107 Although the locus of toxic damage is parafoveal in many eyes, Asian patients often show an ex

108 Parafoveal increased AF size remained stable for 2 to 5

109 Parafoveal increased AF was seen in all 33 patients in 1

110 =[- 0.293 to 0.380], p = 0.801, I(2) = 80%), parafoveal inferior VD (Hedges' g = 0.176, 95% CI=[- 0.1

111 In spite of the reduced visual acuity, parafoveal information plays an important role in natura

112 ed a large foveal lesion and thinning of the parafoveal inner retina.

113 A normative database was created measuring parafoveal intercapillary area (PICA) to determine if an

114 Our central to parafoveal investigations suggest that high-level vision

115 Foveal fluid correlated more with BCVA than parafoveal IRF/SRF.

116 us photographs and FAs as a small, singular, parafoveal lesion, although a large minority of lesions

117 identified typical hyporeflective tear-drop parafoveal lesions, which corresponded to OCTA flow defi

118 s were trained to decode SF presented at one parafoveal location and cross-tested on SF from either t

119 l modulations of these signals peaked at the parafoveal locations and such modulations wore off as vi

120 eptive fields were shifted to represent more parafoveal locations for the amblyopic eye, compared wit

121 ccade, the decoding time of peripheral SF at parafoveal locations was earlier, indicating predictive

122 donors, rod loss exceeded cone loss at most parafoveal locations, and in one donor, rod density was

123 For a texture for which performance peaks at parafoveal locations, endogenous attention improves perf

124 ing (approximately 4 mum/y) and deepening of parafoveal loss in moderate cases, but the breadth of th

125 rence tomography (OCT) examinations revealed parafoveal loss of the photoreceptor inner/outer segment

126 ing characteristic curves of the superficial parafoveal/macular VDs were 0.816 (95% CI, 0.735-0.897)

127 or, inferior, temporal, and nasal sectors of parafoveal maps, were matched with central VF locations.

128 4 +/- 4.5 dB and 25.8 +/- 2.0 dB, P = .005), parafoveal mesopic (23.2 +/- 3.8 and 25.8 +/- 1.9, P < .

129 Parafoveal mesopic sensitivity was significantly topogra

130 To evaluate the reproducibility of parafoveal microvascular anatomy of 7 different optical

131 OCT scans were graded for parafoveal morphologic stage of RRD and foveal photorece

132 f 16 normal and 2 of 16 pathologic retinas), parafoveal mosaic patterns appeared denser with better i

133 existed between the superficial macular and parafoveal mVD and MD16 (r = 0.52 and 0.54, P < 0.001).

134 =[- 0.132 to 0.585], p = 0.263, I(2) = 76%), parafoveal nasal VD (Hedges' g = - 0.043, 95% CI=[- 0.33

135 ith a pipeline mechanism in which foveal and parafoveal objects are processed in parallel but at diff

136 category-specific information of foveal and parafoveal objects can be extracted in succession within

137 How much detail can be derived about parafoveal objects in this short time interval, during w

138 A 3 x 3-mm full-thickness parafoveal OCTA scan was obtained from each participant.

139 .78 um, p=0.004) with a history of ON showed parafoveal OPL thinning compared with healthy controls (

140 .78 um, p=0.004) with a history of ON showed parafoveal OPL thinning compared with healthy controls (

141 ommended screening studies and classified as parafoveal or pericentral pattern.

142 50 msec, blue stimuli presented 10 degrees (parafoveal) or 30 degrees (peripheral) eccentric in the

143 2(o), 50 msec, blue stimuli presented 10(o) (parafoveal) or 30(o) (peripheral) eccentric were measure

144 entational similarity analysis revealed that parafoveal orthographic neighbours (e.g., "writer" vs. "

145 and ELM (P < .0001 and P = .048), foveal and parafoveal outer retinal thicknesses (P = .046 and P = .

146 The foveal and parafoveal outer retinal thicknesses were reduced in eye

147 ), test the hypothesis that elevation of the parafoveal over peripheral dark-adapted threshold is due

148 site of adaptation accounts for elevation of parafoveal over peripheral thresholds.

149 t also had a higher mean gray value over the parafoveal (p < 0.001) and the perifoveal (p < 0.001) re

150 vs. 1813 g, P = 0.02) than patients with the parafoveal pattern, but they were diagnosed at a more se

151 Mean parafoveal photoreceptor density was 14 988 cells/mm(2)

152 participants with good-quality imaging, the parafoveal photoreceptor mosaic, vascular flow, and vari

153 strong retinal eQTL signal, pinpointing the parafoveal photoreceptor outer segment layer.

154 tifacts and resolve blood flow in 3 distinct parafoveal plexuses.

155 The thicknesses of 512 parafoveal points in the 10 retinal layers were obtained

156 ified, at an accelerated time course, at all parafoveal positions.

157 concentric zones (designated as the foveal, parafoveal, posterior, peripheral, anterior, and ciliary

158 Parafoveal preview benefit (PB) is an implicit measure o

159 We find neural evidence for lexical parafoveal processing by combining a rapid invisible fre

160 We investigated parafoveal processing during natural reading by recordin

161 Moreover, this lexical parafoveal processing is associated with individual read

162 when fixating on the pre-target word reflect parafoveal processing of the target word.

163 ws a binocular advantage for both foveal and parafoveal processing of words during natural reading.

164 Moreover, the neuronal mechanisms supporting parafoveal processing remain poorly understood.

165 This early and extensive parafoveal processing supports the rapid word processing

166 tly, the degree of orthographic and semantic parafoveal processing was correlated with individual rea

167 To measure parafoveal processing, we flickered the target words at

168 ading should incorporate the concept of deep parafoveal processing.

169 ver the timing and brain regions involved in parafoveal processing.

170 Are different parafoveal quadrants (superior, inferior, temporal, and

171 rmine any potential benefit of the foveal to parafoveal ratio in children with IP.

172 The foveal to parafoveal ratios were greater than 0.57 in 6 eyes of 3

173 For cells with central-parafoveal receptive fields, attention reduced spatial i

174 GCIPL thickness in the parafoveal region (1- to 3-mm ring) presented the larges

175 the control group, with no difference in the parafoveal region (p = 0.0774).

176 patients compared to normal subjects in the parafoveal region 1.0-3.0 mm from the fovea, but were si

177 Retinal thickness was reduced in the parafoveal region in patients with GRM6 mutations as a r

178 AOSLO videos were acquired in the parafoveal region of one eye from control subjects and f

179 and decreased vessel density in the inferior parafoveal region of the deep capillary plexus (p = 0.03

180 The retinal vasculature in the parafoveal region was assessed.

181 In the parafoveal region, deep vascular density was significant

182 also showed prolonged FLIO lifetimes in the parafoveal region, whereas age-matched healthy subjects

183 hologic and functional loss at the foveal to parafoveal region, whereas the MS patients showed evenly

184 expression was also found in the foveal and parafoveal region.

185 nsities were calculated at peripapillary and parafoveal regions using optical coherence tomography an

186 g of the GC-IPL in the superior and temporal parafoveal regions was associated with worse long-term v

187 y fundus changes localized to the foveal and parafoveal regions, normal ERG amplitudes, absence of a

188 he women also showed significant thinning in parafoveal regions.

189 ecamylamine, while recording single cells in parafoveal representations in awake fixating macaque V1.

190 tive field components and encoded edges with parafoveal resolution.

191 microscopy to show that every S cone in the parafoveal retina synapses principally with a single OFF

192 , RPE disturbance, photoreceptor layer loss, parafoveal retinal atrophy, and outer retinal/intrachoro

193 pplied to the videos to generate montages of parafoveal retinal capillaries.

194 h which they can detect and locate their own parafoveal retinal defects untrained.

195 ps demonstrate significant correlation, once parafoveal retinal ganglion cell (RGC) displacement is t

196 ree parameters were examined: stimulus size, parafoveal retinal locus (superior, inferior, temporal,

197 stigate the autoregulatory response in the 3 parafoveal retinal plexuses under hyperoxia.

198 Parafoveal retinal thickness, parafoveal retinal volume,

199 dies using optimized entoptic viewing of the parafoveal retinal vasculature have shown that normal su

200 l diameter, and flow in interconnected small parafoveal retinal vessels (< 50 um) of nine healthy par

201 Parafoveal retinal thickness, parafoveal retinal volume, and all of the choroidal thic

202 ication of retinopathy into 1 of 3 patterns: parafoveal (retinal changes 2 degrees -6 degrees from th

203 th diabetes were able to visualize their own parafoveal retinopathy entoptically, and most untrained

204 Abnormalities in parafoveal ring amplitudes or ring ratios were considere

205 The radius of the parafoveal ring of high density varied between 1.5 degre

206 r syndrome type 2 were ascertained who had a parafoveal ring of high-density AF and a visual acuity o

207 The presence of a parafoveal ring of increased AF was an early indicator o

208 A parafoveal ring of increased AF was observed, and electr

209 hysiology of Vision (ISCEV) standard ERGs, a parafoveal ring of increased high density on fundus AF i

210 or objective testing), moderate (a 50%-100% parafoveal ring of optical coherence tomography thinning

211 tients among those with HCQ toxicity who had parafoveal ring scotomas but a normal-appearing SD-OCT.

212 t the foveal center (P = 0.038) and within a parafoveal ring spanning an eccentricity of 5 degrees to

213 superficial capillary plexus density in the parafoveal ring was significantly lower in eyes with pee

214 thickness and inner retinal thickness in the parafoveal ring were significantly lower in peeled eyes

215 perautofluorescent dot, hyperautofluorescent parafoveal ring, hypoautofluorescent lesions around fove

216 sistent structural changes especially in the parafoveal ring, ILM peeling for idiopathic large FTMH d

217 o test the hypothesis that the late-maturing parafoveal rod photoreceptors are more vulnerable than p

218 ic findings of a selective vulnerability for parafoveal rod photoreceptors in AMD.

219 ry of ROP is evidence that the late-maturing parafoveal rods are more affected by the ROP disease pro

220 The authors showed previously that parafoveal rods, but not cones, decrease during the cour

221 Foveal and parafoveal RPE cell densities increased with age.

222 ated segmentation of all retinal layers in a parafoveal scan in 1 randomly selected eye of each parti

223 utomatically segment all retinal layers in a parafoveal scan using the new segmentation application p

224 ge VD (wiVD) and whole-image GCC (wiGCC) and parafoveal scans, as well as localized regions of intere

225 ied into initial nasal defect (IND), initial parafoveal scotoma (IPFS), and combined nasal and parafo

226 osely spaced grids is warranted in eyes with parafoveal scotomas.

227 Parafoveal scotopic sensitivity of the older subjects wa

228 Parafoveal SCP vessel-length density (VLD) was also eval

229 In contrast to GCC thinning, VD loss in the parafoveal sectors demonstrated significant correlations

230 Similarly, parafoveal semantic neighbours (e.g., "writer" vs. "auth

231 pattern deviation plots consistently showed parafoveal sensitivity losses in early retinopathy.

232 , 50 msec duration) presented at 10 degrees (parafoveal site) or 30 degrees (peripheral site) from a

233 However, this only holds for foveal and parafoveal stimulation.

234 earlier findings that for briefly presented parafoveal stimuli, positive and negative valence percep

235 asymmetry in threat processing, we combined parafoveal stimulus presentation and the contralateral P

236 was more extensive in the temporal and nasal parafoveal subfields of the deep plexus with sickle SC o

237 =[- 0.212 to 0.337], p = 0.656, I(2) = 70%), parafoveal superior VD (Hedges' g = 0.043, 95% CI=[- 0.2

238 f both pursuit and saccadic eye movements to parafoveal targets.

239 gaze and its immediate vicinity, even after parafoveal task performance had been raised to a foveal

240 Parafoveally in both eyes, leakage from parafoveal telangiectasia was apparent.

241 - 0.357 to 0.445], p = 0.830, I(2) = 73.5%), parafoveal temporal VD (Hedges' g = 0.063, 95% CI=[- 0.2

242 outcomes included foveal VD, parafoveal VD, parafoveal temporal/superior/nasal/inferior VD, and FAZ

243 In contrast, inner retinal perifoveal and parafoveal thickness and volume measurements were decrea

244 Severity of CME, as assessed by foveal-to-parafoveal thickness ratio, within the CME group correla

245 inner nuclear layer thickness, and foveal-to-parafoveal thickness ratio.

246 We highlight parafoveal thickness to be particularly susceptible to s

247 ntitatively (central foveal thickness [CFT], parafoveal thickness, maximum height) and qualitatively

248 Secondary outcome measures included temporal parafoveal thickness, presence of the inner nuclear laye

249 Outer retinal perifoveal and parafoveal thicknesses and volumes were consistently inc

250 Progressive parafoveal thinning and fovea avascular zone remodelling

251 final visit of 1 patient who developed focal parafoveal thinning, a toxic effect of hydroxychloroquin

252 The parafoveal threshold elevation is due to rod dysfunction

253 eigengraus are equal in ROP subjects without parafoveal threshold elevation.

254 Both ROP subjects with elevated parafoveal thresholds also have elevated parafoveal eige

255 On average, parafoveal thresholds in subjects with ROP reached the a

256 The rate of change of parafoveal thresholds was significantly faster than the

257 A parafoveal unclosed hole was found in 1 eye (4%) during

258 djacent to V3v, and dorsal V4 is adjacent to parafoveal V3d.

259 In every infant, the parafoveal value of T(D) was higher (by 0.3-0.6 log unit

260 Foveal and parafoveal vascular area density (VAD) and vascular skel

261 tically significant reduction in superficial parafoveal vascular density (P-value = 0.026), inner ret

262 eal vascular density (P-value = 0.889), deep parafoveal vascular density (P-value = 0.830), choroidal

263 rrelated with foveal avascular zone area and parafoveal vascular density in the superficial and deep

264 Foveal and parafoveal vascular density were calculated.

265 ography (OCTA) was used to assess foveal and parafoveal vascular parameters.

266 I=[- 0.121 to 0.201], p = 0.628, I(2) = 0%), parafoveal VD (Hedges' g = 0.044, 95% CI=[- 0.357 to 0.4

267 retinal nerve fiber layer (RNFL) thickness, parafoveal VD and ganglion cell-inner plexiform layer (G

268 ll complex (wiGCC) thickness and macular VD (parafoveal VD and perifoveal VD) were obtained from 6 x

269 acuity (BCVA) was positively correlated with parafoveal VD at SCP and VD of foveal area at CC.

270 Black subjects had lower foveal and parafoveal VD in the SCP (p = 0.043 and p = 0.014) and t

271 Among all biomarkers, higher inner parafoveal VD in the superficial layer at baseline corre

272 For eyes with DME, parafoveal VD in the superficial layer at baseline was a

273 To predict visual improvement, outer parafoveal VD in the superficial layer at the baseline s

274 It seems that parafoveal VD of SCP and foveal VD of CC are good biomar

275 ctor, but also progressive peripapillary and parafoveal VD reduction in the DH and non-DH regions as

276 However, the parafoveal VD slopes did not differ significantly betwee

277 However, the parafoveal VD slopes did not differ significantly betwee

278 The preoperative SCP parafoveal VD was 43.06 +/- 2.67% in good responder pati

279 The preoperative DCP parafoveal VD was 45.66 +/- 2.21% in good responder pati

280 Extracted outcomes included foveal VD, parafoveal VD, parafoveal temporal/superior/nasal/inferi

281 subjects had a trend toward lower foveal and parafoveal VD.

282 the rate of change of the peripapillary and parafoveal VDs were significant (P < 0.01).

283 surements of superficial and deep foveal and parafoveal vessel density (FVD, PFVD) and choricapillary

284 0.001, r= -0.636), and deep vascular plexus parafoveal vessel density (p < 0.001 r=-0.596).

285 1, r = - 0.622), superficial vascular plexus parafoveal vessel density (p < 0.001, r= -0.556), deep v

286 le (MCP), and deep capillary plexuses (DCP): parafoveal vessel density (VD), adjusted flow index (AFI

287 e vessel density, foveal vessel density, and parafoveal vessel density of superficial and deep vascul

288 image vessel density, foveal vessel density, parafoveal vessel density, perifoveal vessel density, an

289 rs, including foveal avascular zone metrics, parafoveal vessel length density (VD), and perfusion den

290 es, consisted of the representation of right parafoveal vision in the left visual cortex, the bilater

291 fect that encroaches into their right foveal/parafoveal visual field.

292 ficantly older, 19.5 weeks, for rod-mediated parafoveal visual sensitivity.

293 receptive field of the electrode was central/parafoveal with a contralateral bias.

294 fixated foveal word but also preprocess the parafoveal word to its right, thereby facilitating subse

295 ings suggest fast hierarchical processing of parafoveal words across distinct brain regions, enhancin

296 However, the extent to which parafoveal words are previewed and integrated into the e

297 In reading, information from parafoveal words is extracted before direct fixation; ho

298 hemoperfusion density in the foveal and the parafoveal zone of the macular region, and low VEGF-A co

299 However, the parafoveal zone showed a strong circular trend (P < 0.01

300 , deep temporal parafovea, and deep superior parafoveal zones (P = .008, P = .015, and P = .005, resp