The n e w e ng l a n d j o u r na l of m e dic i n e clinical practice Retinal-Vein Occlusion Tien Y. Wong, M.D., Ph.D., and Ingrid U. Scott, M.D., M.P.H. This Journal feature begins with a case vignette highlighting a common clinical problem. Evidence supporting various strategies is then presented, followed by a review of formal guidelines, when they exist. The article ends with the authors’ clinical recommendations. A 69-year-old man, a former smoker with a history of hypertension and hyperlipidemia, presents with acute visual loss in his right eye of 2 weeks’ duration. Examination of the eye reveals a visual acuity of 20/60 and a sectoral area of retinal hemorrhages, cotton-wool spots, and swelling in the center of the retina (macular edema). A diagnosis of right-branch retinal-vein occlusion is made. How should he be treated? The Cl inic a l Probl em Retinal-vein occlusion is a common cause of vision loss in older persons, and the second most common retinal vascular disease after diabetic retinopathy. There are two distinct types, classified according to the site of occlusion.1 In branch retinalvein occlusion, the occlusion is typically at an arteriovenous intersection (Fig. 1); in central retinal-vein occlusion, the occlusion is at or proximal to the lamina cribrosa of the optic nerve, where the central retinal vein exits the eye (Fig. 2). Retinal-vein occlusion has a prevalence of 1 to 2% in persons older than 40 years of age2,3 and affects 16 million persons worldwide.4 Branch retinal-vein occlusion is four times as common as central retinal-vein occlusion.4 In a population-based cohort study, the 10-year incidence of retinal-vein occlusion was 1.6%.5 Bilateral retinal-vein occlusion is uncommon (occurring in about 5% of cases), although in 10% of patients with retinal-vein occlusion in one eye, occlusion develops in the other eye over time.6 Both branch retinal-vein occlusion and central retinal-vein occlusion are further divided into the categories of perfused (non ischemic) and nonperfused (ischemic), each of which has implications for prognosis and treatment. From the Singapore Eye Research Institute, Singapore National Eye Centre, National University of Singapore, Singapore (T.Y.W.); the Centre for Eye Research Australia, University of Melbourne, Melbourne, VIC, Australia (T.Y.W.); and Penn State College of Medicine, Penn State Hershey Eye Center, Hershey, PA (I.U.S.). Address reprint requests to Dr. Wong at the Singapore Eye Research Institute, Singapore National Eye Centre, 11 Third Hospital Ave., Singapore 168751, Singapore, or at ophwty@nus.edu.sg. N Engl J Med 2010;363:2135-44. Copyright © 2010 Massachusetts Medical Society. Pathogenesis and Risk Factors The pathogenesis of retinal-vein occlusion is believed to follow the principles of Virchow’s triad for thrombogenesis, involving vessel damage, stasis, and hypercoagulability. Damage to the retinal-vessel wall from atherosclerosis alters rheologic properties in the adjacent vein, contributing to stasis, thrombosis, and thus occlusion. Inflammatory disease may also lead to retinal-vein occlusion by means of these mechanisms. However, evidence of hypercoagulability in patients with retinalvein occlusion is less consistent. Although individual studies have reported associations between retinal-vein occlusion and hyperhomocysteinemia,7 factor V Leiden mutation,8 deficiency in protein C or S,8 prothrombin gene mutation,9 and anticardiolipin antibodies,10,11 a meta-analysis of 26 studies suggested that only hyperhomocysteinemia and anticardiolipin antibodies have significant independent associations with retinal-vein occlusion.11 n engl j med 363;22 nejm.org november 25, 2010 An audio version of this article is available at NEJM.org 2135 The New England Journal of Medicine ownloaded from www.nejm.org at NATIONAL UNIV OF SINGAPORE-CENTRAL LIBRARY on November 25, 2010. For personal use only. No other uses without permission Copyright © 2010 Massachusetts Medical Society. All rights reserved. The n e w e ng l a n d j o u r na l A B C D of m e dic i n e Figure 1. Branch Retinal-Vein Occlusion in the Superotemporal Quadrant of the Right Eye. A fundus photograph (Panel A) shows a sectoral area of dilated veins, retinal hemorrhages (white arrows), cottonwool spots (black arrows), and retinal edema, and a fluorescein angiogram (Panel B) reveals blockage (white arrows) and leakage of dye (yellow arrows). Optical-coherence tomographic scans (horizontal scan in Panel C and vertical scan in Panel D) show retinal thickening (white arrows), as compared with normal retinal thickness (black arrow), and macular edema (yellow arrows). N→T denotes a nasal-to-temporal cut of the retinal scan, and I→S an inferiorto-superior cut. The strongest risk factor for branch retinalvein occlusion is hypertension,12-15 but associations have been reported for diabetes mellitus,13-15 dyslipidemia,15 cigarette smoking,2 and renal disease.16 For central retinal-vein occlusion, an additional ocular risk factor is glaucoma or elevated intraocular pressure, which may compromise retinal venous outflow.2 Natural History and Complications Macular edema, with or without macular nonperfusion, is the most frequent cause of vision loss in patients with retinal-vein occlusion.17-21 Vision loss may also be due to neovascularization, leading to vitreous hemorrhage, retinal detachment, or neovascular glaucoma. The natural history of branch retinal-vein occlusion is variable.22 Many patients with branch retinal-vein occlusion have a good prognosis, 2136 n engl j med 363;22 with one study showing that half have a return to 20/40 vision or better within 6 months, without treatment.23 Nevertheless, many patients continue to have poor vision in the affected eye. Among participants enrolled in the Branch Vein Occlusion Study, a randomized trial of the effects of laser treatment for branch retinal-vein occlusion, only a third of untreated eyes with macular edema and presenting vision of 20/40 or worse improved to better than 20/40 after 3 years.17 Retinal neovascularization developed in one third of untreated eyes.17 The visual prognosis is generally worse for patients with central retinal-vein occlusion, particularly when nonperfused, than in patients with branch retinal-vein occlusion.6 A systematic review suggested that neovascularization may develop in 20% of eyes and neovascular glaucoma in 60% when nonperfused central retinal-vein oc- nejm.org november 25, 2010 The New England Journal of Medicine ownloaded from www.nejm.org at NATIONAL UNIV OF SINGAPORE-CENTRAL LIBRARY on November 25, 2010. For personal use only. No other uses without permission Copyright © 2010 Massachusetts Medical Society. All rights reserved. clinical pr actice A B C D Figure 2. Nonperfused Central Retinal-Vein Occlusion in the Left Eye. A fundus photograph (Panel A) shows scattered retinal hemorrhages (white arrows), cotton-wool spots (black arrows), optic-disk edema and hyperemia, and venous dilatation and tortuosity (yellow arrow), and a fluorescein angiogram (Panel B) reveals areas of capillary nonperfusion (white arrows) and disk leakage (yellow arrow). Optical-coherence tomographic scans (horizontal scan in Panel C and vertical scan in Panel D) show marked retinal thickening (white arrows) and edema (yellow arrows). N→T denotes a nasal-to-temporal cut of the retinal scan, and I→S an inferior-tosuperior cut. clusion is present.6 In addition, in one third of eyes initially classified as having perfused central retinal-vein occlusion, the occlusion may become nonperfused within the first year.21 Visual acuity at the time of presentation is a strong indicator of the ultimate quality of the patient’s vision. In the Central Vein Occlusion Study, a randomized trial of the use of laser treatment for central retinal-vein occlusion, 65% of patients’ eyes maintained 20/40 vision or better if acuity at the time of presentation was 20/40 or better, but only 1% achieved this level if acuity was initially 20/200 or worse.19,21,24 Despite its associations with vascular risk factors, retinal-vein occlusion does not appear to be an independent risk factor for death from cardiovascular causes.25-27 In a pooled analysis of two population-based studies, retinal-vein occlusion was not independently associated with inn engl j med 363;22 creased cardiovascular mortality,27 although a post hoc analysis revealed an association among persons younger than 70 years of age. S t r ategie s a nd E v idence Diagnosis and Assessment Patients with retinal-vein occlusion typically present with sudden, unilateral, painless loss of vision. The degree of vision loss depends on the extent of retinal involvement and on macularperfusion status. Some patients with branch retinal-vein occlusion report only a peripheral visual-field defect. Retinal-vein occlusion has a characteristic appearance on fundus examination. In branch retinal-vein occlusion, there is a wedge-shaped area in which retinal vascular signs (hemorrhages, cotton-wool spots, edema, and venous nejm.org november 25, 2010 2137 The New England Journal of Medicine ownloaded from www.nejm.org at NATIONAL UNIV OF SINGAPORE-CENTRAL LIBRARY on November 25, 2010. For personal use only. No other uses without permission Copyright © 2010 Massachusetts Medical Society. All rights reserved. The n e w e ng l a n d j o u r na l dilatation and tortuosity) arise from an arteriovenous crossing, usually in the superotemporal quadrant (Fig. 1A). In central retinal-vein occlusion, extensive retinal signs, with dilated and tortuous veins, are seen in all quadrants, often along with optic-disk edema (Fig. 2A). The diagnosis of retinal-vein occlusion is usually made on the basis of the clinical examination alone. Nonperfused central retinal-vein occlusion is suggested by vision that is worse than 20/200, a relative afferent pupillary defect, and the presence of cotton-wool spots and large, confluent hemorrhages.28 Fundus fluorescein angiography (Fig. 1B and 2B) is commonly performed to assess the severity of macular edema and perfusion status. Optical-coherence tomography is a noninvasive imaging technique used to quantify macular edema and assess treatment response (Fig. 1C, 1D, 2C, and 2D). Evaluation of patients with retinal-vein occlusion should include a detailed history taking, clinical assessment, and laboratory investigations to check for the presence of cardiovascular risk factors (Table 1). Although evidence is lacking to of m e dic i n e show that treatment of hypertension and other conditions associated with cardiovascular disease can alter the visual prognosis for patients with retinal-vein occlusion, this condition should be considered end-organ damage,29 with appropriate risk-management strategies routinely instituted. Tests for coagulation abnormalities (Table 1) are commonly performed in selected patients, such as those younger than 50 years of age or those with bilateral retinal-vein occlusion, although evidence is lacking to indicate that coagulation disorders are more common in these patients. Management Until recently, laser photocoagulation was the only treatment supported by data from highquality randomized trials30-32; data are now also available from several trials assessing the use of intraocular glucocorticoids and agents inhibiting vascular endothelial growth factor (VEGF). These more recent treatment options are increasingly being used in clinical practice. (For summaries of the recommendations for the management of branch retinal-vein occlusion and central retinal- Table 1. Assessment of Cardiovascular Risk in Patients with Retinal-Vein Occlusion. History and clinical assessment Hypertension Diabetes mellitus Dyslipidemia Cardiovascular disease (e.g., stroke, coronary artery disease, peripheral artery disease) Medications (e.g., oral contraceptives, diuretics) Hypercoagulable states and hyperviscosity syndromes (e.g., leukemia, polycythemia vera) Routine investigations Complete blood count Renal function (levels of serum electrolytes, urea, creatinine) Fasting serum levels of glucose and glycated hemoglobin Fasting levels of lipids Additional investigations (consider in select cases, such as in patients who are younger than 50 years of age, who have bilateral retinal-vein occlusion, or who may have thrombophilic or coagulation disorders) Homocysteine levels Levels of functional protein C and protein S Antithrombin III levels Antiphospholipid antibodies — lupus anticoagulant, anticardiolipin antibodies Activated protein C resistance — polymerase-chain-reaction assay for factor V Leiden mutation (R506Q) Factor XII Prothrombin gene mutation (G20210A) 2138 n engl j med 363;22 nejm.org november 25, 2010 The New England Journal of Medicine ownloaded from www.nejm.org at NATIONAL UNIV OF SINGAPORE-CENTRAL LIBRARY on November 25, 2010. For personal use only. No other uses without permission Copyright © 2010 Massachusetts Medical Society. All rights reserved. clinical pr actice Table 2. Recommendations for the Management of Branch Retinal-Vein Occlusion. Intervention Guidelines Evidence* Comments Macular grid laser photocoagu- Associated with reduced macular edema and improved lation vision in patients with macular edema and visual acuity ≤20/40 A-I May not be effective in presence of macular ischemia Scatter laser photocoagulation Recommended for treatment of ischemic retina if retinal or disk neovascularization is also present A-I Intravitreal injection of tri amcinolone acetonide No more effective than macular grid laser photocoag ulation in improving visual acuity in patients with macular edema from branch retinal-vein occlusion and associated with a higher risk of adverse events A-I Intravitreal injection of ranibizumab Associated with greater improvement in visual acuity, as compared with sham injection, over 12-mo period in patients with macular edema from branch retinal-vein occlusion A-II May be administered monthly in 0.5-mg doses, depending on persistence or recurrence of macular edema Intravitreal dexamethasone implant Associated with more rapid improvement in visual acuity than sham implant in patients with macular edema from branch retinal-vein occlusion B-II May be administered in 0.7-mg doses every 6 mo, depending on persistence or recurrence of macular edema; contraindicated in patients with advanced glaucoma Hemodilution Not recommended for routine use to improve visual acuity or prevent neovascularization B-III Pars plana vitrectomy with adventitial sheathotomy Not routinely recommended to improve visual acuity or prevent neovascularization B-III Ticlopidine, troxerutin Not routinely recommended to improve visual acuity or prevent neovascularization B-III *For the ranking of the importance of the recommendation with respect to the clinical outcome, A denotes most important or critical for a good clinical outcome and B moderately important; for the strength of the evidence, I denotes strong evidence in support of the recommendation, II strong evidence in support of the recommendation but lacking in some respects (e.g., longer-term efficacy or safety uncertain), and III insufficient evidence to provide support for or against the recommendation. vein occlusion, see Tables 2 and 3, respectively. For the outcomes of trials conducted to gauge the effects of various treatments on each condition, see the Supplementary Appendix, available with the full text of this article at NEJM.org.) Branch Retinal-Vein Occlusion Laser Treatment worse than 20/40 and that in 12% of treated eyes was worse than 20/200 at 3 years. In eyes with extensive nonperfusion, scatter laser photocoagulation markedly reduced the risks of retinal neovascularization (12%, vs. 22% in controls) and vitreous hemorrhage (29% vs. 60%).18 Glucocorticoids Grid laser photocoagulation is used for the treatment of macular edema resulting from branch retinal-vein occlusion, and scatter laser photocoagulation is used for the prevention and treatment of neovascularization. In the Branch Vein Occlusion Study,17,18 which included patients with branch retinal-vein occlusion and macular edema in one or both eyes (a total of 139 eyes were studied), eyes treated with grid laser photocoagulation were almost twice as likely as untreated eyes to enable patients to read two additional lines on an eye chart at 3 years (65% vs. 37%).17 However, in some patients, poor vision persisted despite treatment; vision in 40% of treated eyes was Case series have suggested that intravitreal injection of triamcinolone acetonide may be useful for the treatment of macular edema in patients with branch retinal-vein occlusion.33 However, the use of this treatment was not supported by the Standard Care versus Corticosteroid for Retinal Vein Occlusion (SCORE) Study, a randomized trial in which 411 patients with branch retinal-vein occlusion and vision loss from macular edema were treated with intravitreal injection of preservativefree triamcinolone acetonide (1 mg or 4 mg, injected as frequently as every 4 months) or standard care (grid laser treatment of eyes without dense macular hemorrhage).34 From baseline to n engl j med 363;22 nejm.org november 25, 2010 2139 The New England Journal of Medicine ownloaded from www.nejm.org at NATIONAL UNIV OF SINGAPORE-CENTRAL LIBRARY on November 25, 2010. For personal use only. No other uses without permission Copyright © 2010 Massachusetts Medical Society. All rights reserved. The n e w e ng l a n d j o u r na l of m e dic i n e Table 3. Recommendations for the Management of Central Retinal-Vein Occlusion. Intervention Guidelines Scatter laser photocoagulation Evidence* Comments Not recommended for patients without neovascularization unless regular follow-up is not possible A-I Recommended for patients with anterior-segment neovascularization A-I Macular grid laser photo coagulation Not recommended for treatment of macular edema from central retinal-vein occlusion A-I Intravitreal injection of tri amcinolone acetonide Associated with greater improvement in visual acuity, as compared with observation, in patients with macular edema from central retinal-vein occlusion A-I May be administered every 4 mo in 1-mg doses, depending on persistence or recurrence of macular edema Intravitreal injection of rani bizumab Associated with greater improvement in visual acuity, as compared with sham injection, over 12-mo period in patients with macular edema from central retinal-vein occlusion A-II May be administered every mo in 0.5-mg doses, depending on persistence or recurrence of macular edema Intravitreal dexamethasone implant Associated with more rapid improvement in visual acuity, as compared with sham implant, in patients with macular edema from central retinal-vein occlusion B-II May be administered in 0.7-mg doses every 6 mo depending on persistence or recurrence of macular edema; contraindicated in patients with advanced glaucoma Laser-induced chorioretinal anastomosis May improve visual acuity in patients with nonperfused central retinal-vein occlusion but may be associated with significant ocular complications B-II Hemodilution May improve visual outcome in some patients if performed as inpatient procedure following a protocol with a statistically relevant clinical outcome B-II Ticlopidine, troxerutin, epo prostenol Not routinely recommended to improve visual acuity or prevent neovascularization B-III Difficult to generalize recommendation due to variations in protocols (e.g., inpatient and outpatient) and use of different agents *For the ranking of the importance of the recommendation with respect to the clinical outcome, A denotes most important or critical for a good clinical outcome and B moderately important; for the strength of the evidence, I denotes strong evidence in support of the recommendation, II strong evidence in support of the recommendation but lacking in some respects (e.g., longer-term efficacy or safety uncertain), and III insufficient evidence to provide support for or against the recommendation. 1 year, the rate of the primary outcome — the proportion of eyes with an improvement in visual acuity that enabled patients to read 15 or more additional letters (or 3 lines) on an eye chart — was similar among the three groups (27% in the group treated with the 4-mg dose of triamcinolone, 26% in the group treated with the 1-mg dose, and 29% in the control group). Adverse events — principally, elevated intraocular pressure and progression of cataracts — were more frequent in the groups treated with triamcinolone. The percentage of eyes treated with glaucoma medications was 41% in the group receiving 4 mg of triamcinolone, 8% in the group receiving 1 mg, and 2% in the control group; for cataract progression, the percentages were 35%, 25%, and 13%, respectively. An alternative glucocorticoid, dexamethasone, was evaluated in a randomized trial involving 2140 1267 patients who had vision loss owing to macular edema caused by branch retinal-vein occlusion or central retinal-vein occlusion.35 The primary end point — the time required to achieve a visual-acuity gain of 3 lines or more on an eye chart — was significantly shorter among patients receiving dexamethasone (in a dose of 0.7 mg or 0.3 mg) than among patients who received a sham injection. The proportion of eyes with this degree of improvement was also significantly higher in both dexamethasone groups than in the placebo group at 1 month and 3 months but not at the prespecified time point of 6 months. Dexamethasone showed similar benefits in preplanned subgroup analyses of branch and central retinal-vein occlusion, although details on the extent of improvement in visual acuity at 3 and 6 months were not provided. However, the proportion of eyes in n engl j med 363;22 nejm.org november 25, 2010 The New England Journal of Medicine ownloaded from www.nejm.org at NATIONAL UNIV OF SINGAPORE-CENTRAL LIBRARY on November 25, 2010. For personal use only. No other uses without permission Copyright © 2010 Massachusetts Medical Society. All rights reserved. clinical pr actice with central retinal-vein occlusion. In the Central Vein Occlusion Study, patients (155 eyes) with macular edema caused by central retinal-vein occlusion and vision of 20/50 or worse had no significant improvement in vision after 3 years of treatment with grid laser therapy, although fluorescein angiographic leakage was reduced.24 In Anti-VEGF Agents the same study, scatter laser photocoagulation Ranibizumab and bevacizumab are anti-VEGF decreased the risk of neovascular glaucoma agents that are widely used in the treatment of among patients with iris neovascularization.20 neovascular age-related macular degeneration.36,37 Patients with retinal-vein occlusion have higher Chorioretinal Venous Anastomosis vitreous VEGF levels than patients with unaffected Chorioretinal venous anastomosis, a procedure in eyes,38 and case series have suggested beneficial which a bypass for the venous obstruction is creeffects when ranibizumab or bevacizumab is used ated with the use of laser therapy, has been sugfor the treatment of retinal-vein occlusion.39-42 In gested for patients with perfused central retinalthe study of Ranibizumab for the Treatment of vein occlusion.44 In a randomized trial comparing Macular Edema following Branch Retinal Vein the use of laser-induced chorioretinal venous Occlusion (BRAVO), 397 patients who had macu- anastomosis with conventional care in 113 palar edema as a result of branch retinal-vein occlu- tients with perfused central retinal-vein occlusion were randomly assigned to receive intraocu- sion, visual acuity did not change in laser-treated lar injections of 0.3 mg or 0.5 mg of ranibizumab eyes, but in conventionally treated eyes, there was or sham injections, and both groups receiving a loss of 8 letters (nearly 2 lines) from baseline at ranibizumab had better visual outcomes than the 18 months (P = 0.03). However, laser-related neosham-injection group.43 The primary outcome, vascularization developed in 20% of laser-treated mean improvement in visual acuity (the number eyes, and vitrectomy for vitreous hemorrhage of additional lines that could be read on an eye was performed in 10%. Thus, the potential bene chart) at 6 months, was 3 lines in both ranibizu fit of chorioretinal anastomosis in perfused cenmab groups as compared with 1 additional line in tral retinal-vein occlusion must be weighed the sham-injection group. The gain of an addi- against the risk of clinically significant ocular tional 3 lines (≥15 letters) occurred at a rate of complications. 61% in the group receiving 0.5 mg of ranibizumab and 55% in the group receiving 0.3 mg, as comGlucocorticoids pared with 29% in the control group (P<0.001 for Intravitreal injection of triamcinolone was evaluboth comparisons with controls). There were no ated in the SCORE Study in 271 patients with censignificant differences in the incidence of sys- tral retinal-vein occlusion and vision loss due to temic vascular events, including stroke, among macular edema.45 At 1 year, improvement in vithe three groups. After 6 months, all patients (in- sual acuity, defined as the ability to read an adcluding controls) who had a visual acuity of 20/40 ditional 15 letters (3 lines) or more on an eye or worse or who had persistent macular edema chart, occurred in 27% of patients receiving 1 mg were eligible to receive injections of ranibizumab. of triamcinolone, 26% of those receiving 4 mg, At 12 months, the improvements in vision gained and 7% of controls (P = 0.001 for both compariby patients who had been randomly assigned to sons with controls). Rates of adverse events were one of the ranibizumab groups were maintained, similar to those among the patients with branch whereas controls who were subsequently treated retinal-vein occlusion in the SCORE Study.34 The with ranibizumab had a mean visual improve- study of intravitreal injection of dexamethasone ment of 12 letters (>2 lines) from baseline. through an implant was associated with a shorter time to achieve a gain in acuity of 15 letters Central Retinal-Vein Occlusion on an eye chart in patients with central retinalLaser Treatment vein occlusion, as well as in those with branch Grid laser photocoagulation does not help to re- retinal-vein occlusion, as discussed above.35 In store vision loss from macular edema in patients both the triamcinolone and dexamethasone studwhich elevated intraocular pressure developed was higher with dexamethasone treatment than with the sham injection (4% for both dexamethasone doses vs. 0.7%, P<0.002). Cataract rates did not differ significantly among the groups at 6 months. n engl j med 363;22 nejm.org november 25, 2010 2141 The New England Journal of Medicine ownloaded from www.nejm.org at NATIONAL UNIV OF SINGAPORE-CENTRAL LIBRARY on November 25, 2010. For personal use only. No other uses without permission Copyright © 2010 Massachusetts Medical Society. All rights reserved. The n e w e ng l a n d j o u r na l of m e dic i n e ies, elevated intraocular pressure was a significant treated for 2 years with monthly intravitreal inadverse event for patients receiving these drugs. jections of ranibizumab than among controls (7.8% vs. 4.2%, P = 0.01).49 Although an increased Anti-VEGF Agents rate of vascular events was not identified in trials Ranibizumab and bevacizumab are widely used of intraocular anti-VEGF agents, more data are in the treatment of central retinal-vein occlusion, needed to assess whether anti-VEGF treatment as well as in the treatment of branch retinal-vein increases the risk of cardiovascular events, parocclusion.41,42,46 In the Ranibizumab for the ticularly stroke, in patients with retinal-vein ocTreatment of Macular Edema after Central Reti- clusion.50 nal Vein Occlusion (CRUISE) trial, which included Data are lacking from randomized trials com392 patients with central retinal-vein occlusion paring glucocorticoids and anti-VEGF therapies and macular edema, the proportion of patients head to head and assessing the effects of various with clinically significant improvement in visual combination therapies (e.g., laser plus anti-VEGF acuity was higher in the ranibizumab groups therapy). Most trials have largely excluded pathan in the sham-injection group (46% of pa- tients with poor visual acuity and nonperfused tients receiving 0.3 mg of ranibizumab and 48% retinal-vein occlusion, and it is unclear what type of those receiving 0.5 mg vs. 17% of those under- of treatment is appropriate for these patients. going sham injection).47 Like the BRAVO trial,43 Other systemic therapies have been tried (e.g., which assessed the same ranibizumab interven- hemodilution, streptokinase, and anticoagulants tion in patients with branch retinal-vein occlu- such as troxerutin and ticlopidine), as have surgision and in those with central retinal-vein occlu- cal approaches (e.g., radial optic neurotomy, persion, the CRUISE study showed no significant formed to improve venous outflow at the optic between-group differences in the incidence of disc, and vitrectomy with arteriovenous sheathotsystemic vascular events among the patients with omy, performed to relieve venous compression at central retinal-vein occlusion, and the vision gain the arteriovenous junctions),30-32 but these treatwith ranibizumab treatment was maintained at ments have not been rigorously studied. Surgical 12 months.47 procedures are increasingly being replaced by intraocular injections, which can be given in a physician’s office. A r e a s of Uncer ta in t y Although retinal-vein occlusion is much more common in persons older than 50 years of age, it can also arise in younger persons with no identifiable risk factors.48 In younger patients, retinalvein occlusion may have a different pathogenesis, but it is not clear whether systemic coagulation abnormalities are more common in such patients. Trials of treatments with intraocular glucocorticoid and anti-VEGF agents have had relative ly short periods of follow-up. Longer-term trials are needed to determine whether visual gains will be maintained after 1 year, to establish optimal dosing regimens, and to ascertain the risks of these therapies. In some trials, treatment was delayed to allow for spontaneous improvement; thus, it is not clear how different treatments would compare if used earlier in the course of disease. In post hoc analyses of two trials addressing neovascular age-related macular degeneration,36,37 rates of nonocular hemorrhage, including cerebral hemorrhage, were higher among patients 2142 Guidel ine s from Profe ssiona l So cie t ie s The United Kingdom Royal College of Ophthalmologists has published guidelines for the management of retinal-vein occlusion,51 but these guidelines do not take into account data from recent clinical trials. C onclusions a nd R ec om mendat ions The patient described in the vignette has a superotemporal branch retinal-vein occlusion with macular edema. We recommend a thorough ocular evaluation, including the use of fundus fluorescein angiography to assess macular perfusion and leakage and optical coherence tomography to quantify macular edema. Systemic evaluation by the patient’s general physician and appropriate management of modifiable cardiovascular risk factors (e.g., hypertension and hyperlipidemia) are n engl j med 363;22 nejm.org november 25, 2010 The New England Journal of Medicine ownloaded from www.nejm.org at NATIONAL UNIV OF SINGAPORE-CENTRAL LIBRARY on November 25, 2010. For personal use only. No other uses without permission Copyright © 2010 Massachusetts Medical Society. All rights reserved. clinical pr actice indicated. We do not recommend further workup for coagulation abnormalities in this patient. We would discuss with the patient the risks and potential benefits of grid laser photocoagulation or intraocular injections of anti-VEGF agents. The advantages of using grid laser for first-line treatment of branch retinal-vein occlusion include the availability of longer-term data from clinical trials showing improvement in visual acuity, lower rates of adverse effects, and lower costs with this treatment than with antiVEGF therapy. In selected cases (e.g., dense macular hemorrhage that precludes the use of laser therapy), we would consider intraocular injection of an anti-VEGF agent for first-line treatment; References 1. Hayreh SS. Prevalent misconceptions about acute retinal vascular occlusive disorders. Prog Retin Eye Res 2005;24:493519. 2. Mitchell P, Smith W, Chang A. Prevalence and associations of retinal vein occlusion in Australia: the Blue Mountains Eye Study. Arch Ophthalmol 1996;114: 1243-7. 3. Klein R, Klein BE, Moss SE, Meuer SM. The epidemiology of retinal vein occlusion: the Beaver Dam Eye Study. Trans Am Ophthalmol Soc 2000;98:133-41. 4. Rogers S, McIntosh RL, Cheung N, et al. The prevalence of retinal vein occlusion: pooled data from population studies from the United States, Europe, Asia, and Australia. Ophthalmology 2010;117(2): 313.e1-319.e1. 5. Cugati S, Wang JJ, Rochtchina E, Mitchell P. Ten-year incidence of retinal vein occlusion in an older population: the Blue Mountains Eye Study. Arch Ophthalmol 2006;124:726-32. 6. McIntosh RL, Rogers SL, Lim L, et al. Natural history of central retinal vein occlusion: an evidence-based systematic review. Ophthalmology 2010;117(6):1113. e15-1123.e15. 7. Chua B, Kifley A, Wong TY, Mitchell P. Homocysteine and retinal vein occlusion: a population-based study. Am J Ophthalmol 2005;139:181-2. 8. Greiner K, Hafner G, Dick B, Peetz D, Prellwitz W, Pfeiffer N. Retinal vascular occlusion and deficiencies in the protein C pathway. Am J Ophthalmol 1999;128:6974. 9. Incorvaia C, Lamberti G, Parmeggiani F, et al. Idiopathic central retinal vein occlusion in a thrombophilic patient with the heterozygous 20210 G/A prothrombin ge notype. Am J Ophthalmol 1999;128:247-8. 10. Lahey JM, Tunç M, Kearney J, et al. Laboratory evaluation of hypercoagulable states in patients with central retinal vein we would inform the patient of the increased risk of arterial thromboembolic events. Treatment with a dexamethasone implant is another option, but evidence is lacking to demonstrate an improvement in visual acuity beyond 3 months. The patient should be monitored closely for signs of neovascularization (e.g., new vessels or vitreous hemorrhage), which would require scatter laser photocoagulation. Dr. Wong reports receiving consulting fees from Allergan, Novartis, and Pfizer and speaking fees and grant support from Allergan; and Dr. Scott reports receiving consulting fees from Genentech. No other potential conflict of interest relevant to this article was reported. 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