ObjectiveTo create a new scleral buckling surgery using noncontact wide-angle viewing system and 23-gauge intraocular illumination for the treatment of rhegmatogenous retinal detachment (RRD), and to evaluate its safety and effectiveness. MethodsA scleral buckling surgery using noncontact wide-angle viewing system and 23-gauge intraocular illumination was performed in 6 eyes of 6 patients with RRD, including 2 males and 4 females. The mean age was 51 years old with a range from 23 to 66 years old. Proliferative vitreoretinopathy (PVR) were diagnosed of grade B in all 6 eyes. Duration of retinal detachments until surgery was 5.8 days with a range from 2 to 13 days. The mean preoperative intraocular pressure (IOP) was 12 mmHg with a range from 9 to 15 mmHg (1 mmHg=0.133 kPa). A 23-gauge optic fiber was used to provide an intraocular illumination. Fully examination of the ocular fundus and cryoretinopexy of retinal breaks was performed under a noncontact wide-angle viewing system. Subretinal fluid drainage through the sclerotomy and buckling procedure were performed under the operating microscope. Intravitreal injection of sterile air bubble was performed in 4 eyes. Antibiotic eye drops was applied in all eyes postoperatively, and all the eyes were followed up for at least 6 months. ResultsRetinal reattachment was achieved in all eyes, and the conjunctiva healed well. The best corrected visual acuity (BCVA) increased in all eyes. The mean postoperative IOP was 15 mmHg with a range from 12 to 19 mmHg. No complications were found intra and postoperatively. ConclusionsThis new scleral buckling surgery using noncontact wide-angle viewing system and 23-gauge intraocular illumination for RRD is safe and effective. Advantages such as higher successful rate, less complication, shorter operating time, and less discomfort of patients were showed comparing with the previous scleral buckling surgery using indirect ophthalmoscope.
Emergency treatment of ocular trauma is a systematic and complicated work. Rapid and correct diagnosis and treatment are needed to maximize the recovery of ocular structure and function. In recent years, China has made remarkable progress in the emergency treatment of eye trauma, including the development of Expert consensus on the norms of emergency treatment of eye trauma in China (2019), the establishment of a national ocular trauma database, and the development of VisionGo artificial Intelligence prediction system for eye trauma. These measures improve the treatment level of ocular trauma and provide support for the prediction of postoperative visual acuity in severely dull eyes. However, with the development of economy and society, the characteristics of ocular trauma in our country have changed. For example, the majority of hospitalized patients were open eye injuries, farmers and workers were the main occupational groups, and the proportion of eye injuries caused by traffic injuries increased year by year, and the proportion of women and minors increased. Although the annual loss of life of eye trauma disability in China has decreased faster than the world average, the emergency treatment of eye trauma still faces many challenges, such as regional differences, insufficient primary medical resources, lack of standardized training, and insufficient promotion of emergency treatment standards. In order to cope with these challenges, it is necessary to further strengthen the popularization of science and technology for the prevention and treatment of eye trauma, standardize the emergency treatment process, strengthen the training of grass-roots medical personnel, strengthen the safety of emergency surgery, and pay special attention to the particularity of children's ocular trauma. In addition, relevant research has been actively carried out to establish a complete database of emergency patients with eye trauma to promote the accurate prevention and treatment of ocular trauma.
Objective To observe the effect of diabetic retinopathy on endothelial progenitor cells (EPCs) from peripheral blood. Methods Sixty male Wistar rats were divided into control group and diabetes group. The rats in diabetes group were induced with streptozotocin (STZ) injection for diabetic retinopathy model. Flow cytometry was used to identify and count the number of EPCs from peripheral blood at 1 week, 1, 3 and 6 months after injection. All eyeballs were examined by hematoxylin and eosin (HE) staining, periodic acidSchiff's (PAS) staining of trypsin-digested retinal vessels flat preparation and transmission electron microscope. EPCs count, and the relationship between DR morphological changes and EPCs count were compared and analyzed. Results The quantity of EPCs from peripheral blood at 1 week, 1, 3 and 6 months after STZ injection were 25plusmn;7, 28plusmn;8, 39plusmn;7, 43plusmn;7 cells per 200 000 monocytes respectively, which decreased compared with the control group 45plusmn;4 cells per 200 000 monocytes (F=8.933,Plt;0.01). The quantity of EPCs was gradually increased at 1 week, 1, 3 and 6 months after STZ injection, accompanied with responsive pathological changes of retinal structure and vessels. The thickness of retina at 1 week and 1 month after injection were reduced slightly. The number of retinal ganglion cells reduced, with the time passing by. Endothelial cells were edema, mitochondrial was swollen, capillary basement membrane was thicken, lumen was significant stenosis, lumen occlusion and retinal artery aneurysm were observed at 6 months after STZ injection. Conclusion The number of EPCs increases gradually throughout the development of DR.
Objective To analyze the pathogeny of vitreous re-hemorrhage in proliferative diabetic retinopathy (PDR) after vitrectomy, and to evaluate the treatment effects. Methods The clinical data of 315 eyes of 302 patients with PDR who had undergone vitrectomy were retrospectively analyzed. Thirty-two eyes with vitreous re-hemorrhage after the treatment had undergone vitrectomy again. The follow-up duration was 3-48 months (average 12 months). Results The occurrence of vitreous hemorrhage after vitrectomy was 10%. The reasons included fibrovascular ingrowth at the sclera incision (28%), residual neovascularization membrane or inappropriately treated vascular stump on the surface of optic nerve (19%), insufficient photocoagulation on retina (22%), residual epiretinal neovascularization membrane (9%), retinal vein occlusion (6%), and ocular trauma (16%). Re-hemorrhage occurred 1-210 days (average 51 days) after vitrectomy. The patients with re-hemorrhage underwent cryotherapy for fibrovascular at the incision site, removal of residual neovascularization membrane on the optic nerve and retina, electrocoagulation of the vascular stump, complementary retinal photocoagulation and binding up of two eyes. After the re-treatment, the visual acuity increased in 91% and decreased in 9%. The postoperative complications mainly included vitreous re-hemorrhage, posterior synechia of the iris, lens sclerosis, and delayed healing of corneal epithelium. Conclusion The main reasons of vitreous re-hemorrhage after vitrectomy in patients with PDR include fibrovascular ingrowth at sclera incision, residual neovascularization membrane or inappropriately treated vascular stump on the surface of optic nerve, insufficient photocoagulation on retina, residual epiretinal neovascularization membrane, retinal vein occlusion, and ocular trauma. The efficient methods in preventing and treating re-hemorrhage after vitrectomy are appropriate management of insection sites, completely removal of residual neovascularization membrane on the optic nerve and retina, electrocoagulation of the vessel stump and sufficient retinal photocoagulation. (Chin J Ocul Fundus Dis,238-240)
Objective To observe the expression of vascular endothelial growth factor (VEGF) in aqueous humor and vitreous body in eyes with proliferative vitreo-retinal diseases, and to investigate the role of VEGF plays in the pathoge nesis of proliferative vitreo-retinal diseases. Methods The concentration of VEGF in aqueous humor and vitreous body in eyes with proliferative vitreoretinopathy (PVR), retinal vein occlusion (RVO), proliferative diabetic retinopathy (PDR), and neovascular glaucoma (NVG) were measured by double antibodies sandwich enzyme-linked immunosorbent assay (ELISA). Results The concentration of VEGF in aqueous humor and vitreous body in eyes with PVR, RVO, PDR and NVG were obviously higher than that in the control group (Plt;0.05), respectively. Among all of the diseases, the concentration of VEGF in aqueous humor and vitreous body decreased orderly in NVG, PDR, RVO and PVR (Plt;0.05). The concentration of VEGF in vitreous body in eyes with PVR, RVO, PDR and in the control group were much higher than that in aqueous humor in corresponding groups (Plt;0.05). There was a negative correlation between the disease history and content of VEGF in aqueous humor and vitreous body in patients with PVR (r=-0.819, -0.823;Plt;0.05). The disease history positi vely correlated with the concentration of VEGF in aqueous humor and vitreous body in patients with RVO (r=0.913, 0.929;Plt;0.05), and the time of vitreous hemorrhage positively correlated with the concentration of VEGF in aqueous humor and vitreous body in patients with PDR (r=0.905, 0.920;Plt;0.05). Conclusion The concentration of VEGF in aqueous humor and vitreous body in patients with proliferative vitreo-retinal diseases significantly increases, and VEGF may play an important role in the pathoge nesis of proliferative vitreo-retinal diseases. (Chin J Ocul Fundus Dis, 2006, 22: 313-316)