Objective〓〖WTBZ〗To observe the clinical features of autoimmune optic neuropathy (AON). 〖WTHZ〗Methods〓 〖WTBZ〗The clinical data of 58 patients with AON from Jan. 2006 to Dec. 2007 were retrospectively analyzed. The patients had undergone routine ophthalmological, neurological examination, visual field test, all set of autoimmune antibody test, brain MRI. 〖WTHZ〗Results〓〖WTBZ〗In 93 eyes of 58 patients with AON, the lowest best corrected visual acuity (BCVA) was lt;01 in 68 eyes (731%), 10 patients (172%) had other symptoms of nervous system, 14 patients (241%) had lesions of nonneurological system. Positive antinuclear antibody was found in 43 patients (796%); other abnormal antibodies were also found, including antiSSA/SSB, antidsDNA, antihistonic, anticardiolipin, and antihuman leukocyte antigen B27 antibodies. Systematic connective tissue disease presented in 20 patients (345%), such as sicca syndrome, systemic lupus erythematosus, and Behcet disease. 32 patients (552%) had abnormal brain MRI, and the BCVA of 49 eyes (777%) improved significantly after hospitalization. 〖WTHZ〗Conclusion〓〖WTBZ〗Patients with AON always have poor visual function, some of whom associate with other systems, as well as damages to other parts of the nervous system. While some AON patients are secondary to systemic connective tissue disease involving the optic nerve, the majority of these patients are isolated autoimmune optic neuropathy.
Serpiginous choroiditis (SC) is infrequent, chronic and posterior uveitis displaying a geographic pattern of choroiditis easy to recur. Studies reveal that the active lesions of inflammatory processes are mainly localized to the choriocapillaris and retinal pigment epithelium cells. SC may manifest with variable features, although a creeping pattern of choroiditis, extending from the juxtapapillary area, with grayish yellow discoloration. Fundus fluorescein angiography, indocyanine green angiography, fundus auto-fluorescence and optical coherence tomography are helpful to diagnose atypical SC. In addition, these image examinations can evaluate the activity and progression of lesion, and detect any complication that might occur. SC is mainly distinguished from multifocal SC related with tuberculosis or virus and etc. Pathogenesis is unclear, an organ-specific autoimmune inflammation or infection seems likely to be the underlying process. It is mainly using glucocorticoid with immunosuppressant therapy at present. Timely and effectively control inflammation can effectively prevent vision loss, choroidal neovascularization and choroidal scar in SC patients.
ObjectiveTo observe the clinical effect of microincision vitreoretinal surgery (VRS) assisted with intravitreal injection of ranibizumab (IVR) in severe proliferative diabetic retinopathy (PDR) treatment.
MethodsThis is a prospective non-randomized controlled clinical study. A total of 60 patients (70 eyes) with severe PDR diagnosed were enrolled and divided into IVR group (31 patients, 35 eyes) and control group (29 patients, 35 eyes). IVR group patients received an intravitreal injection of 0.05 ml ranibizumab solution (10 mg/ml) first, and 3 or 4 days later they received 23G microincision VRS. Control group patients only received 23G microincision VRS. The follow-up time was 3 to 12 months with an average of (4.5±1.8) months. The logarithm of the minimal angle of resolution (logMAR) best corrected visual acuity (BCVA), intraocular pressure, the central retinal thickness (CRT) and retinal reattachment, and the incidence of postoperative complications were comparatively analyzed.
ResultsThere was no topical and systemic adverse reactions associated with the drug after injection in IVR group. The incidence of post-operative vitreous hemorrhage (VH) in IVR group and control group was 8.6% and 28.6% at 1 week after surgery, 0.0% and 17.1% at 1 month after surgery, 0.0% and 8.6% at 3 month after surgery respectively. The differences were statistically significant for 1 week (χ2=4.63, P < 0.05) and 1 month (χ2=4.56, P < 0.05), but was not statistically significant for 3 months (χ2=0.24, P > 0.05). The mean post-operative logMAR BCVA of IVR group (0.81±0.40) and control group (1.05±0.42) have all improved than their pre-operative BCVA, the difference was statistically significant (t=12.78, 4.39; P < 0.05). The mean logMAR BCVA of IVR group is higher than BCVA of control group, the difference was statistically significant (t=-2.36, P < 0.05). The average post-operative CRT in IVR group was thinner than that of control group, the difference was statistically significant (t=-2.53, P < 0.05). The incidence of a transient high intraocular pressure in IVR group (14.3%) was lower than that in control group (34.3%), the difference was statistically significant (t=4.79, P < 0.05). The incidence of retinal reattachment (t=0.35), epiretinal membrane (χ2=0.97), neovascular glaucoma (χ2=0.51) was no difference between these two groups (P > 0.05).
ConclusionThe minimally invasive VRS assisted by IVR treatment for severe PDR can effectively prevent postoperative VH, reduce CRT and improve visual acuity.
Objective To observe the change of diffusion upper limit of macromol ecules through pathological retina and the difference between the layers of retina. Methods Retinal edema was emulated by establishing branch retinal vein occlusion (RVO) model in miniature pig eyes under photodynamic method. Two days later, the retinas of both eyeballs were peeled off. The diffusion test apparatus was designed by ourselves. FITC-dextrans of various molecular weights (4.4, 9.3, 19.6, 38.9, 71.2 and 150 kDa) and Carboxyfluorescein (376 Da) were dissolved in RPMI1640 solutions and diffused through inner or outer surface of retina. The rate of transretinal diffusion was determined with a spectrophotometer. Theoretical maximum size of molecule (MSM) was calculated by extrapolating the trend-linear relationship with the diffusion rate. In separate experiments to determine the sites of barrier to diffusion, FITC-dextrans were applied to either the inner or outer retinal surface, processed as frozen sections, and viewed with a fluores cence microscope. Results FITC-dextrans applying to inner retinal surface, 4.4 kDa dextrans were largely blocked by inner nuclear layer (INL); 19.6,71.2 kDa dextrans were blocked by the nerve fiber layer (NFL) and inner plexiform layer; 15.0 kDa dextrans were blocked by NFL. FITC-dextrans applying to outer retinal surface, most dextrans with various molecular weights were blocked before outer nuclear layer (ONL). No matter applying to the inner or outer surface, Carboxyfluore scein can diffuse through the whole retina and aggregate at INL and ONL. After RVO, the inner part of retina became edema and cystoid, loosing the barrier function. Compared with the normal retina, the MSM in RVO tissues increased (6.5plusmn;0 39nm Vs 6.18plusmn;0.54nm, t=4.143, P=0.0001). Conclusions A fter RVO, the barrier function of inner part of retinal is destroyed and the upper limit of diffusion macromolecule size increased, which is nevertheless limited. ONL acts as bottle-neck barriers to diffusion, if the outer part of retina is damaged, the change of the diffusion upper limit will be prominent. (Chin J Ocul Fundus Dis,2008,24:197-201)
ObjectiveTo observe the effect of Crocin on structure and the expression of tumor necrosis factor-alpha; (TNF-alpha;) and interleukin-1beta; (IL-1beta;) in rat retina after injury by ischemia-reperfusion. Methods A total of 80 Sprague-Dawley male rats at the age of 8 -10 weeks were divided into control group, model group, low-dose Crocin group and high-dose Crocin group, with 20 rats in each group. The rats of control group were not treated. The rats in model, low-dose Crocin and high-dose Crocin group were induced with normal saline by anterior chamber perfusion creating a retinal ischemia-reperfusion (RIR) model. The rats of the low-dose Crocin and highdose Crocin group received intraperitoneal injection with different doses of Crocin solution (5 mg/kg, or 50 mg/kg) 30 minutes prior to ischemic injury and one time per day after successful RIR. Optical microscopy was used to observe the retinal structure. Enzymelinked immunosorbent assay (ELISA) was used to measure the expression of TNF-alpha; and IL-1beta; 6, 12, 24 and 48 hours after RIR. ResultsThe retinal structure of control group was normal. Pathological changes were found in the RIR model and low-dose Crocin group, such as retinal edema, disorganized structure and loosely packed cells. The degree of pathological changes in lowdose Crocin group was less than the RIR model group. The retinal structure of high-dose Crocin group was similar to the control group. The expression of TNF-alpha; was the highest at 24 hours after modeling, while the expression of IL-1beta; was the highest at 12 and 48 hours after RIR modeling. Six, 12, 24 and 48 hours after RIR modeling, compared with the control group, the TNF-alpha; expression of model (t=5.42, 7.94, 9.32, 9.18;P<0.05 ), low-dose Crocin (t=3.94, 4.12, 4.98, 3.84;P<0.05) and high-dose Crocin group (t=2.13, 2.34, 2.96, 2.78;P>0.05) were increased. Compared with the RIR model group, the TNF-alpha; expression of low-dose Crocin (t=3.95, 4.56, 4.01, 5.12) and high-dose Crocin group (t=5.23, 7.65, 7.74, 7.63) was decreased. Compared with the control group, the IL-1beta; expression of model (t=7.23, 7.87, 7.15, 15.60), low-dose Crocin (t=5.65, 5.10, 5.54, 6.87;P<0.05) and high-dose Crocin group (t=4.38, 5.21, 4.56, 4.75) was increased (P<0.05). Compared with the model group, the IL-1beta; expression of low.dose Crocin group was decreased significantly 48 hours after RIR modeling (t=7.56,P<0.05); but it decreased significantly at each time point in high-dose Crocin group (t=6.94, 5.36, 6.05, 10.50;P<0.05). Conclusion Crocin can improve the retinal pathologic changes, while down-regulating TNF-alpha; and IL-1beta; expression in RIR rats.
ObjectiveTo observe the therapeutic effect of intravitreous injection with triamcinolone acetonide (TA) on diffused diabetic macular edema.MethodsIntravitreous injection with TA was performed on 21 patients with diabetic macular edema who had undergone ocular-fundus examination, fundus fluorescein angiography (FFA), and optical coherence tomography (OCT). The followup duration was 1 month, 3, and 6 months. The visual acuity, intraocular pressure, and retinal thickness at the macular area before and after the treatment, examined by ETDRS eye chart, noncontact tonometer, and OCT respectively, were observed and compared.ResultsOne month, 3, and 6 months after the injection, the mean extent of improvement of visual acuity was 7.5, 9.1 (including 2-line improvement in 10 eyes which occupied 48%), and 5.1 letters respectively; while the decrease of retinal thickness at macula was 143 μm (decrease of 33%), 184 μm (decrease of 42%), and 151 μm (decrease of 35%) respectively.ConclusionsIntravitreous injection with TA is effective for diffused diabetic macular edema in a short term (about 3 months).(Chin J Ocul Fundus Dis, 2005,21:217-219)
At present, intravitreal injections of anti-VEGF agents is the main method for the treatment of macular edema secondary to retinal vein occlusion (RVO), which can significantly inhibit neovascularization, release macular edema and improve the vision of patients. However, VEGF is a survival factor of vascular endothelial cells, whether it can lead to the progress of retinal ischemia and it has an effect on retinal capillaries deserves our clinical attention. Most scholars currently think that the anti-VEGF agents will not aggravate the occlusion of retinal capillaries in the treatment of macular edema secondary to RVO from the aspects of the changes of perifoveal capillary arcade, the quantification of foveal avascular zone area, retinal nonperfusion area and retinal vascular density of the superficial and deep capillary plexus In addition, the changes of these indicators may be related to the number of times patients need treatment, visual prognosis and so on. In the future, with the gradual popularization of OCT angiography and the prolongation of the number and time of anti VEGF drug treatment, we look forward to the study of larger samples and longer follow-up time to further analyze the influence of the retinal capillary after anti-VEGF therapy in patients with macular edema associated with RVO.
Objective
To observe the clinical effect of intravenous thrombolytic therapy for central retinal artery occlusion (CRAO) with poor effect after the treatment of arterial thrombolytic therapy.
Methods
Twenty-four CRAO patients (24 eyes) with poor effect after the treatment of arterial thrombolytic therapy were enrolled in this study. There were 11 males and 13 females. The age was ranged from 35 to 80 years, with the mean age of (56.7±15.6) years. There were 11 right eyes and 13 left eyes. The visual acuity was tested by standard visual acuity chart. The arm-retinal circulation time (A-Rct) and the filling time of retinal artery and its branches (FT) were detected by fluorescein fundus angiography (FFA). The visual acuity was ranged from light sensation to 0.5, with the average of 0.04±0.012. The A-Rct was ranged from 18.0 s to 35.0 s, with the mean of (29.7±5.8) s. The FT was ranged from 4.0 s to 16.0 s, with the mean of (12.9±2.3) s. All patients were treated with urokinase intravenous thrombolytic therapy. The dosage of urokinase was 3000 U/kg, 2 times/d, adding 250 ml of 0.9% sodium chloride intravenous drip, 2 times between 8 - 10 h, and continuous treatment of FFA after 5 days. Comparative analysis was performed on the visual acuity of the patients before and after treatment, and the changes of A-Rct and FT.
Results
After intravenous thrombolytic therapy, the A-Rct was ranged from 16.0 s to 34.0 s, with the mean of (22.4±5.5) s. Among 24 eyes, the A-Rct was 27.0 - 34.0 s in 4 eyes (16.67%), 18.0 - 26.0 s in 11 eyes (45.83%); 16.0 - 17.0 s in 9 eyes (37.50%). The FT was ranged from 2.4 s to 16.0 s, with the mean of (7.4±2.6) s. Compared with before intravenous thrombolytic therapy, the A-Rct was shortened by 7.3 s and the FT was shortened by 5.5 s with the significant differences (χ2=24.6, 24.9; P<0.01). After intravenous thrombolytic therapy, the visual acuity was ranged from light sensation to 0.6, with the average of 0.08±0.011. There were 1 eye with vision of light perception (4.17%), 8 eyes with hand movement/20 cm (33.33%), 11 eyes with 0.02 - 0.05 (45.83%), 2 eyes with 0.1 - 0.2 (8.33%), 1 eye with 0.5 (4.17%) and 1 eye with 0.6 (4.17%). The visual acuity was improved in 19 eyes (79.17%). The difference of visual acuity before and after intravenous thrombolytic therapy was significant (χ2=7.99, P<0.05). There was no local and systemic adverse effects during and after treatment.
Conclusion
Intravenous thrombolytic therapy for CRAO with poor effect after the treatment of arterial thrombolytic therapy can further improve the circulation of retinal artery and visual acuity.
OBJECTlVE:To evaluate the value of inhibiting effect of the verapamil(Ver)on human selcral fibroblast (HSF).
METHODS:The rate al inhibition of Ver,5-Fu,heparin(Hep)and
dexamethasone(Dex)to cultured HSF was respectively determined by MTT method and enzyme linked immunosorbent assay. In addition,the rate of inhibition of Ver associated with 5-Fu Hep and
Dex to cultured HSF was respectively determined.
RESULTS:The rate of cellular proliferation of cultured HSF was found to be significantly reduced(Plt;0.05),when the concentration of Ver was
20mg/L,and further reduced when 5-Fu,Hep or Dex was added even in smaller dose (5~10mg/L)of Ver.
CONCLUSION: Tbe effect of inhibition of cellular proliferation of 5-Fu, Hep and Dex in eye could be enbenced by Ver.
(Chin J Ocul Fundus Dis,1996,12: 98-100)
In the expert consensus published by the Pediatrics in 2013, it was first proposed that anti-VEGF drugs can be considered for retinopathy of prematurity (ROP) with stage 3, zone Ⅰ with plus disease. However, there are many problems worth the attention of ophthalmologists, including the advantages and disadvantages of anti-VEGF therapy compared with traditional laser therapy, systemic and ocular complications after anti-VEGF therapy, and what indicators are the end points of anti-VEGF therapy. Combined with this consensus and numerous research findings, we recommend that the first treatment for anti-VEGF or laser therapy should be considered from disease control effects. For the threshold and pre-threshold lesions, the effect of anti-VEGF therapy for zoneⅡ lesions is better than that for zone Ⅰ lesions and the single-time effective rate is high. So, it is suggested that anti-VEGF therapy should be preferred for the first treatment. The choice of repeat treatment should be considered from the final retinal structure and functional prognosis. Laser therapy is advisable for the abnormal vascular regression slower and abnormalities in the posterior pole. It can reduce the number of reexaminations and prolong the interval between re-examinations. However, the premature use of laser has an inevitable effect on peripheral vision field. Excluding the above problems, supplemental therapy can still choose anti-VEGF therapy again. Most of the children with twice anti-VEGF therapy are sufficient to control the disease. Anti-VEGF therapy should be terminated when there are signs such as plus regression, threshold or pre-threshold lesions controlled without recurrence, peripheral vascularization, etc.
