Objective To measure the macular function of the fellow eye in patients with unilateral retinal vein occlusion (RVO). Methods A total of 24 cases of unilateral RVO were diagnosed by fundus fluorescein angiography (FFA), and multifocal ERG (mfERG) was recorded by RETI scan. The mfERG data of 24 fellow eyes of those RVO patients, and 18 normal control eyes were analyzed and compared. The parameters included the amplitude density, latency of the P1 and N1 wave in 6 concentric circles and 4 quadrants of the mfERG graphics. Results The amplitude densities of P1 and N1 wave in first and second concentric circles of RVO fellow eyes were significantly lower than normal eyes (t=4.520, 2.147; P<0.05). There was no significant difference (P>0.05) of P1/N1 latency in any concentric circles or quadrants between RVO fellow eyes and normal eyes. Conclusion The central fovea of the RVO fellow eyes was functionally impaired.
Objective To observe the changes of photopic negative response (PhNR) of electroretinography (ERG) in patients with retinal vein occlusion (RVO). Methods A total of 30 patients (30 eyes) with retinal vein occlusion (RVO) diagnosed by indirect ophthalmoscopy and fundus fluorescein angiography (FFA) were selected; the unaffected fellow eyes of the patients and another 25 healthy agematched individuals (50 eyes) were cllected as the normal control. All of the patients underwent the examination of visual acuity, visual field, and flashERG (FERG); the normal control ones underwent FERG. In the 30 patients with RVO, there were 14 with central RVO (CRVO) and 16 with branch RVO (BRVO). According to the disease history and results of FFA, the patients were divided into 3 time groups: lt;1 month, 1-3 months, and gt;3 months; according to the types of RVO, the patients were divided into ischemic and nonischemic group. The amplitude of PhNR and other parameters were analysed. The relationship among the amplitude of PhNR and RVO types and time course were analyzed.Results The amplitude of PhNR in the CRVO and BRVO eyes was (28.20plusmn;5.8) and (36.96plusmn;4.71) mu;V, respectively; those in the unaffected fellow and control eyes was (61.25plusmn;3.93) and (59.33plusmn;16.92) mu;V, respectively; the amplitude of PhNR was significantly smaller in the CRVO and BRVO eyes than those in the unaffected fellow or control eyes (F=10.69 and 9.80,P<0.001; F=9.69 and 9.75,P<0.001). The amplitude of PhNR in ischemic and nonischemic group in CRVO eyes was (22.77plusmn;15.73) and (36.63plusmn;12.91) mu;V, respectively; the difference between the two groups was significant(t=6.54, Plt;0.01). The amplitude of PhNR in ischemic and nonischemic group in BRVO eyes was (32.39plusmn;13.22) and (46.73plusmn;10.43) mu;V, respectively; there was no significant difference between the two groups(t=2.12, Plt;0.05). The amplitude of PhNR was (24.58plusmn;14.60) and (27.94plusmn;15.73) mu;V, respectively, in CRVO and BRVO eyes with lt; 1 month disease course; was (50.39plusmn;13.80) and (58.69plusmn;12.43) mu;V in those with 1-3 months disease course; and was (25.40plusmn;19.94) and (34.48plusmn;16.72) mu;V in those with >3 months diseases course. Significant difference was found between the 1-3 months group and >3 months group in CRVO eyes(F=4.30,Plt;0.01). Conclusions The amplitude of PhNRs was significantly smaller in RVO eyes than those in the unaffected fellow or control eyes.The amplitude of PhNR amplitude of ischemic type was smaller than that of nonischemic type. The amplitude of PhNR has descending,ascending,and descending tendency during the disease courses.
Retinal vein occlusion (RVO) is affected by multiple factors, and there are lots of misunderstanding and disputation on the diagnosis and treatment. Compared with the natural disease course of RVO, there was no safe and effective treatment for RVO at present. Necessary investigation and disputation is helpful to make objective conclusion. We should objectively analyze and evaluate the results of investigation from home and abroad. (Chin J Ocul Fundus Dis, 2007, 23: 155-158)
Objective To probe the possibility of electroretinogram(ERG)maximum combined response for typing branch retinal vein occlusion(BRVO). Methods BRVO were divided into ischemic or nonischemic type according to the appearance of fundus fluorescein angiography.The ERG data were used to define the retinl function:a,b-wave amplitude and impact time,b/a-wave ratio,oscillatory potential OP1,OP2,OP3,OP4 amplitude implicit time and Ops amplitude. Results The ERG b-wave and OPs amplitude were significantly lower in ischemic group than those in nonischemic group. Conclusion With the REG test,the decline of b-wave and OPs amplitude of the maximum combined response might be as a reference of ischemic type BRVO. (Chin J Ocul Fundus Dis,1998,14:10-11)
ObjectiveTo observe the characteristics of optical coherence tomography (OCT) angiography (OCTA) in retinal vein occlusion (RVO). MethodsProspective and observational study. Clinical examination of 81 consecutive patients (86 eyes) diagnosed with RVO were included in the study, in which the branch retinal vein occlusion in 47 eyes, central retinal vein occlusion in 39 eyes. Forty-five patients were male and 36 patients were female. Aged from 28 to 76 years old, the mean age was (55.36±10.01) years old. Comprehensive optical and imaging examination were performed, including fundus photography, fundus fluorescein angiography (FFA), spectral domain OCT, en face OCT and OCTA. The retinal blood flow imaging scan mode and the optic disc blood flow imaging scan mode were performed, the scanning region in the macular area were 3 mm×3 mm, 6 mm×6 mm, 8 mm×8 mm respectively, around the optic disc were 3 mm×3 mm and 4.5 mm×4.5 mm. Each region scans 2 times. The characteristics of foveal avascular zone change, macular edema, non-perfusion and optical disc edema in OCTA and their corresponding FFA and en face OCT were observed. ResultsBy OCTA, 67 eyes (77.9%) for foveal avascular zone change, 23 eyes (26.7%) for macular edema, 40 eyes (46.5%) for non-perfusion, and 33 eyes (38.4%) for optical disc edema can be detected. The foveal avascular zone change can be indentified as the tranformation, destruction and even vanish of the arch in superfacial layer of retinal macular area, acompanied with the dilatation and thickening of capillary vessels, the occlusion and expanding of capillary vessels arounded the foveal avascular zone in the deep layer of macular area. Those performances were more clear than FFA. The main expression of macular edema was low signal and was not as clear as en face OCT. The tortuosity and expansion of retinal vessels, density decreasing and even occlusion or abnormal traffic branch of capillary vessels can be observed in non-perfusion. These observations were similar to FFA. However, pieces of highly signal identical with non-perfusion area can be detected in chroid capillary. The representation of optical disc edema was the brush-like expanding of capillary vessels aroud optical disc. ConclusionsOCTA can help for observing the abnormal changing of capillary vessels in foveal avascular zone and macular edema, non-perfusion and optical disc edema. Foveal avascular zone change showed occlusion and expanding of capillary vessels around the foveal avascular zone in the deep layer of macular area. Macular edema showed the weak signal. Non-perfusion showed tortuosity and expansion of retinal vessels, density decreasing and even occlusion or abnormal traffic branch of capillary vessels. Optical disc edema showed brush-like expanding of capillary vessels around optical disc.
ObjectiveTo assess the consistency of diagnostic results using optical coherence tomography angiography (OCTA) and fundus fluorescein angiography (FFA) in the central retinal vein occlusion (CRVO). MethodsThis is a retrospective case series of 26 eyes of 26 patients with CRVO. There were 10 females (10 eyes) and 16 males (16 eyes). The mean age was (49.19±10.50) years. The mean course of the disease was (27.81±21.60) days. Simultaneous OCTA and FFA were performed in all patients using 7-standard field of Early Treatment Diabetic Retinopathy Study (ETDRS) to evaluate the microaneurysms, nonperfused areas, optical disc/retinal neovascularization and macular edema. The consistency was evaluated using weighted Kappa statistic values. Kappa≥0.75, consistency is excellent; 0.60≤Kappa < 0.75, consistency is good; 0.40≤Kappa < 0.60, consistency is general; Kappa < 0.40, consistency is poor. ResultsBased on OCTA, microaneurysms were found in 23 eyes, nonperfused areas in 16 eyes, optical disc/retinal neovascularization in 8 eyes and macular edema in 21 eyes. Based on FFA, 23 eyes were diagnosed to have microaneurysms, 14 eyes have nonperfused area, 8 eyes have optical disc/retinal neovascularization, 22 eyes have macular edema. The consistency was excellent for microaneurysms and optical disc/retinal neovascularization (Kappa=0.772, 0.766; P < 0.01), good for nonperfused areas and macular edema (Kappa=0.703, 0.600,P < 0v01). ConclusionThere is high consistency between OCTA and FFA in the diagnosis of microaneurysms, macular edema, nonperfused areas and optical disc/retinal neovascularization in CRVO patients.
Objective To observe the angiographic features of patients with retinal vein occlusion (RVO) by ultra-wide-field fluorescein angiography (UWFA) and compare with the conventional 7 standard field (7SF) imaging. Methods This is a retrospective clinical description study. Fifty-eight eyes of 56 RVO patients were included. There were 25 males (26 eyes) and 31 females (32 eyes). The age ranged from 25 to 69 years, with a mean age of (48.12±18.56) years. The course of disease was from 2 days to 25 months, with a mean course of (12.78±11.35) months. Thirty eyes were diagnosed with central RVO (51.72%), 26 eyes were diagnosed with branch RVO (44.83%) and 2 eyes were diagnosed with hemicentral RVO (3.45%). Retinal laser photocoagulation was performed in 11 eyes (18.97%). All patients received examinations of UWFA (British Optomap 200Tx imaging system) and optical coherence tomography (OCT). Using the protocol for obtaining 7SF images as described in the Early Treatment Diabetic Retinopathy Study, 7 circular regions with a range of 30 degrees were combined as the 7SF template to determine the observation area. This template was then overlaid on the UWFA image to identify the potential viewable area of 7SF. The visualized retinal area, retinal non-perfusion area, retinal neovascularization area, and laser spot area of UWFA and 7SF were quantified by a retinal specialist. In addition, the OCT images of the affected eye were observed and analyzed to confirm the existence of macular edema. Correlation analysis was done between retinal non-perfusion, retinal neovascularization and macular edema detected by UWFA. Results The results of UWFA and 7SF examination were the same. Compared with 7SF, UWFA showed 3.53 times more retinal visual area, 3.31 times more non-perfusion area, 1.94 times more neovascularization area, and 3.59 times more laser spots (t=72.13, 4.69, 1.76, 5.78;P=0.000, 0.005, 0.102, 0.000). Lesions of 11 eyes (18.97%) were found outside the range of 7SF images. By UWFA, non-perfusion area correlated with neovascularization and macular edema (χ2=12.13, 4.82;P=0.000, 0.028;C=0.42, 0.28). Non-perfusion area anterior to the equator have significantly correlations with macular edema (χ2=6.32,P=0.012,C=0.31), but non-perfusion posterior to the globe equator have no relevance with macular edema (χ2=2.88,P=0.090, C=0.22). Conclusions UWFA can detect more peripheral retinal lesions than 7SF images. By UWFA, non-perfusion area has correlation with neovascularization and macular edema.
Objective To observe the difference of macular microvascular features in superficial and deep vascular plexi in patients with branch retinal vein occlusion (BRVO). Methods A total of 63 BRVO patients (63 eyes) were enrolled in this study. There were 28 males (28 eyes) and 35 females (35 eyes). The patients aged from 39 to 74 years, with the mean age of (59.76±8.48) years. All eyes were evaluated by optical coherence tomography angiography (OCTA). The macular angiography scan protocol covered a 3 mm×3 mm area. The focus of angiography analysis included superficial vascular plexus and deep vascular plexus. The following vascular morphological parameters were assessed in these two plexi: foveal avascular zone (FAZ) enlargement, capillary non-perfusion (CNP) occurrence, microvascular abnormalities (MA) appearance, and vascular congestion (VC) signs. The FAZ area was measured by the built-in software. The macular microvascular morphology changes in superficial and deep vascular plexi were compared through McNemar test. Results The superficial and deep plexi showed FAZ enlargement in 43 eyes (68.3%) and 50 eyes (79.4%), CNP in 51 eyes (81%) and 50 eyes (79.4%), MA in 62 eyes (98.4%) and 62 eyes (98.4%), VC in 23 eyes (36.5%) and 52 eyes (82.5%), respectively. FAZ area was (0.55±0.37) mm2. There was no difference in CNP (P=1.000) and MA (P=1.000) between superficial and deep plexi. But, there was difference in FAZ enlargement (P=0.039) and VC signs (P<0.001) between superficial and deep plexi. Conclusion Deep vascular plexus showed more FAZ enlargement and VC sign than superficial plexus in BRVO patients.
Objective To observe the alterations of macular vascular density and the area of foveal avascular zone (FAZ) in branch retinal vein occlusion (BRVO) eyes. Methods A retrospective case-control study. Forty-five patients with unilateral BRVO and macular edema were enrolled in this study. Optical coherence tomography angiography (OCTA) was performed on the BRVO and fellow eyes. The scanning region in the macular area was 3 mm×3 mm. Macular vascular density and FAZ area in the superficial and deep retinal capillary plexi were measured in all eyes. The values of macular vascular density and FAZ area between BRVO eyes and fellow eyes, affected sector and unaffected sector were compared. Results The mean overall vascular density measured in the entire scan was lower in BRVO eyes compared with fellow eyes in both the superficial and deep capillary plexus (t=14.186, 9.468; P<0.05). The reduce degree of vascular density in the deep capillary plexus (7.65%) was higher than that in the superficial plexus (7.27%). In the superficial plexus, the vascular density was lower in the affected sector and the unaffected sector of the BRVO eyes compared with the corresponding sector in the fellow eyes (t=15.386, 9.435; P<0.05). The FAZ area enlarged in the BRVO eyes compared with the fellow eyes in the superficial capillary plexus and in the deep capillary plexus (t=3.216, 5.119; P<0.05). The degree of enlargement of FAZ area in the deep capillary plexus (0.19 mm2) was higher than that in the superficial plexus (0.11 mm2). Conclusions In eyes with BRVO, quantitative OCTA measurements confirm that vascular density decreased and FAZ area enlarged in the superficial and deep capillary plexi. The reduce degree of vascular density and enlargement degree of FAZ area in the deep capillary plexus are higher than those in the superficial plexus.