Oclusão da veia central da retina

Neto, Carlos Augusto Moreira; Augusto, Gilberto Antonio Tesser

doi:10.17545/eOftalmo/2021.0014

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Revisão Narrativa de Literatura

Oclusão da veia central da retina

Carlos Augusto Moreira Neto; Gilberto Antonio Tesser Augusto

DOI: 10.17545/eOftalmo/2021.0014

ABSTRACT

Central retinal vein occlusion is the blockage of retinal blood circulation owing to obstruction of the central retinal vein. Depending to the degree of occlusion and retinal ischemia, it is classified into ischemic and non-ischemic forms. Central retinal vein occlusion leads to the development of important vascular alterations, increased inflammatory factors, and retinal edema. Diagnosis is made by ophthalmoscopy findings and complementary examinations. The clinical presentation varies from insidious painless unilateral vision loss to abrupt and profound vision loss. Neovascular glaucoma is the most severe complication, and macular edema is the most common complication. Treatment includes the identification and correction of systemic vascular risk factors. Intravitreal injections of antiangiogenics and corticosteroids can help improve final visual acuity. In this review article, we describe the main clinical and therapeutic aspects of central retinal vein occlusion.

Keywords: Central retinal vein; Retinal vein occlusion; VEGF; Intravitreal injections; Macular edema.

RESUMO

A Oclusão da Veia Central da Retina é o bloqueio da circulação sanguínea retiniana por obstrução da veia central da retina. Subdivide-se em isquêmica e não isquêmica de acordo com o grau de oclusão e de isquemia retiniana. O evento obstrutivo proporciona o desenvolvimento de alterações vasculares importantes, aumento de fatores inflamatórios e edema retiniano. O diagnóstico é feito pelos achados oftalmoscópicos e exames complementares. A apresentação clínica é variável, desde perda visual unilateral indolor insidiosa até perda abrupta e profunda da visão. Glaucoma neovascular é a complicação mais severa. A complicação mais comum é o edema macular. O tratamento inclui identificação e correção dos fatores de risco vasculares sistêmicos. O uso de injeções intravítreas de antiangiogênicos e corticoides pode auxiliar na melhora da acuidade visual final. Neste artigo de revisão descreveremos os principais aspectos clínicos e terapêuticos da oclusão venosa central retiniana.

Palavras-chave: Veia central da retina; Oclusão da veia retiniana; VEGF; Injeções intravítreas; Edema macular.

INTRODUCTION

Central retinal vein occlusion (CRVO) occurs due to blockage of retinal blood circulation resulting from obstruction of the central retinal vein, and consequently of its branches, in the region of the cribriform plate or in a location immediately posterior to it¹.

Retinal vein occlusion (RVO) is the second leading cause of vascular blindness, surpassed only by diabetic retinopathy. In 2008, it was estimated that approximately 16.4 million adults had some type of RVO, and 2.5 million were affected by CRVO².

The worldwide prevalence of CRVO is approximately 0.08%, with a similar distribution among different ethnicities and sexes. Its risk increases with increasing age². However, one study reported that Black people were 58% more likely to develop CRVO than White people³.

The best predictor of RVO development is prior episodes in the contralateral eye. The risk of contralateral involvement in individuals with CRVO is approximately 1% per year⁴.

Cardiovascular risk factors such as atherosclerosis, hypertension, and diabetes are commonly associated with all types of RVOs. However, vein occlusions can also be secondary to other processes, such as inflammation, vasospasm, or compression⁵.

CRVO is correlated with glaucoma, sleep apnea, thrombophilia, and homocystinuria⁶. A study demonstrated that smoking, alcoholism, hyperopia, and pseudophakia increased the risk of RVO⁷.

Blood hyperviscosity, which is observed in myeloproliferative disorders, may also be associated with CRVO. Inflammatory conditions that cause systemic vasculitis (Behçet’s disease, lupus, polyarteritis nodosa) and hypercoagulation states (hyperhomocysteinemia, antiphospholipid syndrome, deficiency of proteins C or S or antithrombin III) have also been described as risk factors for RVO, particularly in young patients, although this is rare^8,9.

The incidence of CRVO increases with age, and most affected individuals are aged ≥50 years¹⁰. CRVO in young adults is uncommon and only 10%-15% of patients are aged <40 years¹¹.

METHODS

This is a narrative literature review of studies retrieved from electronic databases (PubMed/MEDLINE, Google Scholar, and SCIELO) using the descriptors “central retinal vein,” “retinal vein occlusion,” “VEGF,” and “macular edema.” These terms were used in Portuguese and English, individually and in combination. The authors selected the articles considered most important, and their information was extracted to compose the textual base and describe the most relevant aspects of CRVO.

Pathophysiology

The pathogenesis of CRVO is multifactorial and involves alterations in hematological factors, compression, and abnormalities in the vessel wall. The existence of an intimate anatomical relationship between the intima layers of the central artery and the central vein of the retina in the posterior region of the cribriform plate can lead to venous compression and formation of fibrin and platelet thrombi, consequently resulting in vessel obstruction¹².

RVO can cause acute endothelial cell apoptosis, pericyte damage, and increased vascular permeability. Chronic ischemia and edema appear as the final outcomes of abnormal endothelial cell turnover and retinal hypersensitivity to hypoxia¹³.

The increase in intraluminal pressure, as a consequence of the obstruction, triggers the production of inflammatory mediators, including vascular endothelial growth factor (VEGF), and compromises the internal blood–retinal barrier. This, in turn, promotes transudation of vessels, leading to optic nerve edema, intraretinal hemorrhages in the four retinal quadrants, and macular edema. When neovascularization occurs, it can result in neovascular glaucoma and vitreous hemorrhage^14,15.

Classification

CRVO can be classified into two forms: the ischemic and non-ischemic forms. Approximately 80% of patients with CRVO suffer from the non-ischemic form, which is characterized by venous stasis retinopathy and an obstruction posterior to the cribriform plate. This location could justify a milder retinopathy owing to the presence of more collateral venous channels. In ischemic CRVO, with characteristics of hemorrhagic retinopathy, venous obstruction occurs at the level of the cribriform plate or immediately posterior to it. Few collateral venous channels are present to aid in drainage, and the retina suffers from extensive ischemia due to reduced perfusion pressure. Further, in some cases the non-ischemic form can progress to the ischemic form, likely due to either reduced retinal perfusion during sleep or thrombus migration to a region closer to the cribriform plate¹⁶.

The classification of CRVO subtypes is based on fluorescein angiography (FA) findings. Non-ischemic CRVO is characterized by an ischemic area of <10 disc areas and the absence of retinal neovascularization on examination. Ischemic CRVO is characterized by retinal or iris neovascularization with a large ischemic area (>10 disc areas) and a larger number of hemorrhages^4.

This classification has been useful for use in studies. However, with the advent of widefield angiography, it is possible to better assess the large peripheral nonperfusion areas present in cases of CRVO¹⁷. It is suggested that peripheral ischemia rates of >35% are an angiographic criterion for classifying CRVO cases as ischemic CRVO¹⁸.

Signs and symptoms

Patients with CRVO should undergo a complete eye examination. Ocular symptoms at the onset of CRVO are variable, ranging from no symptoms to severe reduction in visual acuity (VA). Vision loss is usually sudden and unilateral, but it may be gradual, progressing to definitive over a period of days to weeks¹⁹.

The examiner must determine which presentation subtype of CRVO is developing. The non-ischemic form is the most common clinical presentation. In this form, unilateral and sudden vision blurring are observed, with moderate impairment of the VA (20/200 or better). On fundoscopy, the branches of the central retinal vein appear tortuous and dilated and are accompanied by “candle-flame” hemorrhages in all quadrants, but more markedly in the periphery²⁰ (Figure 1A).

Figure 1. A 66-year-old female patient with hypertension and sudden loss of visual acuity in the left eye. (A) Retinography revealed blurring of the edges of the optic disc, associated with intense engorgement and venous tortuosity, with “candle-flame” hemorrhages in the four quadrants and in the macular region. (B and C) Fluorescein angiography shows contrast uptake in the optic disc owing to papillary edema, and contrast extravasation in the central region due to macular edema. Neovascularization was not observed. (D) Optical coherence tomography (OCT) showing significant macular edema at the initial consultation. (E) OCT 30 days after the sixth intravitreal injection of anti-VEGF agents showing complete resolution of the edema.

Almost all patients with ischemic CRVO have an initial VA of 20/200 or worse, and approximately half have significant peripheral visual field involvement. Most also exhibit a relative afferent pupillary defect (RAPD), which can be a sensitive and specific indicator of ischemic CRVO⁶.

In the ischemic form, fundoscopy features are more prominent, marked by significant engorgement and tortuosity of the branches of the central retinal vein, in addition to “cotton-wool” exudates associated with extensive hemorrhages. The presence of “cotton-wool” exudates reflects infarction foci in the nerve fiber layer and neovascularization of the anterior or posterior segment in more advanced stages²¹.

Capillary congestion can result in macular and optic nerve edema. Hence, complaints may include metamorphopsia associated with reduced VA⁶.

Complementary examinations

The evaluation of patients with RVO should include a comprehensive investigation of medical history and laboratory findings to identify cardiovascular risk factors. Suggested tests include electrocardiography, protein electrophoresis, and determination of complete blood count, erythrocyte sedimentation rate, urea, electrolytes, creatinine, blood glucose, lipid profile, thyroid function, and blood pressure²².

In recent years, the hypothesis that coagulation disorders could be related to RVO has been discussed²³. Tests for coagulation disorders can be performed in selected cases, such as those involving young patients (<50 years old), bilateral venous occlusion, and history of coagulation disorders or thrombophilia²². In the case of thrombophilia, a study suggested that the investigation should focus on factor XII, factor V Leiden deficiency, homocysteinemia, antiphospholipid antibody, and deficiency of anticoagulant proteins C and S²⁴.

Ophthalmological imaging tests

Ocular investigations for CRVO usually include FA, optical coherence tomography (OCT), and, more recently, optical coherence tomography angiography (OCTA).

Fluorescein angiography (FA)

FA is a useful and objective tool for evaluating retinal circulation through the use of intravenous fluorescein contrast. Fluorescein leaks only from physiologically abnormal vessels and capillaries, and the amount of leakage depends on the severity of the occlusion²⁵.

In cases of CRVO, FA enables the analysis of poor peripheral capillary perfusion and macular ischemia and the detection of neovascularization, even distinguishing the latter from the formation of collateral circulation⁶.

In CRVO, FA demonstrates normal filling of the choroid, but there may be a variable delay in retinal vascular filling caused by venous flow congestion. In late phases, FA presents a variable pattern of uptake in the optic nerve head and retinal veins, which is associated with variable degrees of poor capillary perfusion and extravasation in the macular region¹ (Figures 1B and 1C).

FA is useful for providing information about the capillary bed of the retina (permeability or nonperfusion) and in differentiating between the ischemic and non-ischemic forms of RVO. Other findings include late extravasation in the macular area and in the filling of veins. Macular edema usually appears as hyperfluorescence in radial cystic cavities, forming a “petaloid” pattern. The presence of peripheral nonperfusion is a characteristic of ischemic RVO and is an important risk factor for neovascularization. Macular nonperfusion is correlated with a poor visual prognosis, and improving VA can be difficult, even with treatment for macular edema²⁶.

Optical coherence tomography (OCT)

OCT is a noninvasive retinal examination method that, through sectional images, enables the identification of retinal layers in near-histological detail²⁷. It is an important test to confirm and monitor the presence of macular edema⁶.

In cases of CRVO, OCT typically reveals intraretinal cysts (Figure 1D), retinal thickening, and occasionally submacular fluid. As for structural alterations, there may be a loss of the relationship between the internal and external segments of the photoreceptors and a distortion of the architecture of the nuclear and internal plexiform layers^1,27.

Optical coherence tomography angiography (OCTA)

OCTA is a recent, noninvasive imaging technique that was developed to enable the study of retinal microvessels without contrast injection. The movement of red blood cells within retinal capillaries is used as an intrinsic contrast medium to generate flow images. OCTA provides images of the capillary network of both the superficial and deep retina, with detailed visualization of the avascular zone of the fovea and the possibility of constructing a three-dimensional vascular map of retinal circulation²⁸.

OCTA demonstrates the characteristic findings of venous occlusions seen in FA, such as decreased capillary perfusion, macular edema, vascular dilation, enlarged avascular zone of the fovea, and collateral venous circulation²⁹.

Monitoring and prognosis

Ophthalmological follow-up should prevent and identify complications caused by retinal ischemia, such as neovascular glaucoma, vitreous hemorrhage, and macular edema.

In ischemic cases, follow-up should be monthly in the first semester, to monitor macular edema and identify signs of neovascularization of the anterior segment. Follow-up of the eyes with significant ischemia after the first semester should be done every 3 months for 1 year. In non-ischemic cases, a quarterly follow-up is suggested for the first 6 months. For all patients, subsequent follow-up depends on the treatment performed and the complications present, but in cases with no complications, it is usually not necessary after 2 years. Macular edema may recur for several years; hence, follow-up beyond recommendations may be necessary for long-term VA maintenance³⁰.

Initial VA is usually the most reliable factor to predict the severity and visual prognosis in eyes with CRVO²⁷.

In cases of patients with VA 20/60 or better, VA tends to remain unaltered; VA between 20/80 and 20/200 has a variable clinical course; VA worse than 20/200 is likely to show no improvement⁴.

The prognosis of ischemic CRVO is poor owing to the presence of macular ischemia and an increased risk of neovascularization. In one study, the cumulative incidence of neovascularization was 52% and neovascular glaucoma development was 34% at 9 months after ischemic CRVO³¹.

Conversion from the non-ischemic to the ischemic form usually occurs in one third of patients within 3 years³².

The main factors related to the development of neovascular glaucoma are a history of arterial hypertension, low VA, or RAPD at the onset of the condition. If VA worsens or RAPD emerges, the possibility of conversion to the ischemic form must be considered and the patient must be monitored closely³³.

TREATMENT

Interventions performed in cases of CRVO focus on occlusion sequelae, which include macular edema and retinal ischemia¹.

Current treatment options include the use of laser, surgical interventions, and intravitreal injections of corticosteroids and VEGF inhibitors³⁴.

To date, there is no consistent evidence that clinical treatments can favorably alter the natural course of CRVO. There is no evidence that the use of antiplatelet agents, anticoagulants, thrombolytic agents, or hemodilution are effective in improving VA³⁵.

The use of antiplatelet agents or systemic anticoagulants for the treatment of CRVO does not show benefits and has been associated with worse outcomes in terms of final VA, greater loss of visual field, and worsening of retinal hemorrhage³⁶.

Optimizing the control of arterial hypertension, diabetes, dyslipidemia, and intraocular pressure are important for controlling systemic risk factors for CRVO and other consequences causing damage to target organs³⁷.

Most surgical procedures require further studies and should not be routinely indicated owing to possible complications. The use of thrombolytics by injection into the ophthalmic artery has not yet demonstrated obvious efficacy. Further, other surgical techniques such as peeling of the internal limiting membrane, radial neurotomy, and decompression of the optic nerve sheath are not completely effective³⁵.

The formation of chorioretinal anastomoses using a laser has variable results (33%–88% success in VA improvement), but it remains an experimental therapy³⁸.

The development of severe vitreous hemorrhage or tractional retinal detachment can be controlled using vitrectomy techniques³⁹.

Macular edema and neovascularization

Macular edema caused by capillary fluid leakage in the central macular area is the most common cause of vision loss in patients with RVO⁴⁰.

In non-ischemic CRVO, spontaneous resolution of the macular edema has been observed over time in approximately 30% of eyes⁴¹.

The isolated use of laser in a macular grid has not shown great benefit in improving VA, even though it significantly reduces extravasation on angiography⁴².

However, studies have reported beneficial effects from the combined use of laser and intravitreal injections in improving VA in cases of CRVO, in addition to better therapeutic responses and fewer interventions⁴³.

The use of a macular grid can be considered in patients with persistent macular edema after 3-4 monthly FA-guided injections of anti-VEGF agents to determine the sites of ischemia and extravasation that could benefit from laser treatment⁴⁴.

Prophylactic panretinal photocoagulation is no longer recommended for ischemic CRVO as it does not prevent iris neovascularization. However, laser photocoagulation should be performed when neovascularization occurs in the anterior segment, the optic disc, or the retina ⁸.

When regular follow-up is impractical, prophylactic panretinal photocoagulation may be advisable³⁰.

The use of intravitreal or intracameral anti-VEGF agents can significantly aid in reducing retinal and anterior segment neovascularization⁴⁵.

In cases of established neovascular glaucoma and blindness, the goal should be pain control with the use of topical steroids and atropine. However, if there is a prognosis of preserved vision, intraocular pressure control with hypotensive eye drops or surgery should be sought⁴⁰.

Effective benefits in the management of macular edema have recently been demonstrated with the use of intravitreal injections of anti-VEGF agents (bevacizumab, ranibizumab, and aflibercept) and corticosteroids (triamcinolone and dexamethasone). Both classes of medication have important anti-inflammatory and antiproliferative mechanisms that help to reduce macular edema and neovascularization and improve VA⁴⁶.

Anti-VEGF agents

There are three anti-VEGF agents available for use: bevacizumab (off-label), ranibizumab, and aflibercept. Currently, intravitreal therapy with anti-VEGF agents is considered the first-line therapy for the treatment of macular edema associated with RVO⁴⁷.

In eyes with RVO, structural changes in the retinal venous system result in reduced blood flow, variable levels of hypoxia, and a subsequent sharp increase in intravitreal VEGF levels^48,49.

Intravitreal VEGF levels have been shown to correlate with the severity of clinical findings⁵⁰.

Ranibizumab

Ranibizumab is a recombinant humanized monoclonal antibody capable of inhibiting the biological activity of all VEGF-A isoforms. It was developed specifically for intravitreal use and is approved for the treatment of macular edema related to RVO⁵¹.

In the CRUISE and BRAVO studies, monthly 0.5 mg ranibizumab injections significantly improved visual function in patients with RVO after 6 months of follow-up (respectively, 18.3 and 14.9 ETDRS letters vs. 7.3 and 0.8 letters in the control group), in addition to improving the mean central foveal thickness (345 µm and 442 µm vs. 158 µm and 168 µm in the control group)^47,51.

Although macular edema resolution occurs in approximately half of the patients with RVO with ranibizumab treatment, in cases of CRVO, a substantial number of individuals require frequent injections, even years after the initial treatment⁵².

Aflibercept

Aflibercept is a fusion protein composed of domains of human VEGF receptors 1 and 2 fused with a segment of human IgG. It is capable of inhibiting all VEGF-A isoforms. It has a long duration and high affinity for VEGF-B and placental growth factor⁵³.

Two randomized clinical trials (GALILEO and COPERNICUS) assessed the use of intravitreal aflibercept versus sham injections for the treatment of macular edema secondary to CRVO and reported similar results. Both studies demonstrated the efficacy of aflibercept in improving the anatomical and visual outcomes of patients with macular edema associated with CRVO in the first 6 months under fixed monthly administration of aflibercept^54,55. In the GALILEO study, 60.2% and 22.1% of patients in the treatment and placebo groups, respectively, demonstrated a gain of at least 15 letters after 6 months of treatment⁵⁴.

In the COPERNICUS study, there was a gain of 15 letters in 56% of the treated eyes compared with 12% of the sham treatment eyes after 6 months of treatment. Further, there were no cases of neovascularization or photocoagulation in those treated with aflibercept. Hence, these studies not only demonstrated the benefits of treatment over natural progression but also depicted superior results with the early treatment of CRVO-related macular edema with aflibercept⁵⁵.

Bevacizumab

Bevacizumab is a humanized antibody that blocks all VEGF-A isoforms. Several studies have shown that the intravitreal injection of bevacizumab increased VA and concomitantly reduced central macular thickness^56–58.

A large multicenter retrospective study involved the treatment of 44 eyes with 1.25 mg bevacizumab every 4–8 weeks during two years of follow-up while observing for any signs of macular edema. A mean gain of 3.5 ETDRS lines in 24 months was demonstrated, and the central macular thickness was reduced from 635 µm at baseline to 364 µm at the end of the study ⁵⁹.

To date, bevacizumab has not been approved by the FDA for intraocular use owing to the lack of large randomized clinical trials and its use remains off-label⁶⁰.

Corticosteroids

Corticosteroids are able to reduce edema by stabilizing vascular permeability, reducing inflammatory mediators, and indirectly blocking VEGF actions⁴⁶.

Currently, two medications in this group are used for the treatment of macular edema associated with CRVO: intravitreal implants of dexamethasone (on-label use) and triamcinolone (off-label use)^61,62.

Both these steroids are associated with clinically significant increases in intraocular pressure and cataract progression. Triamcinolone is a cost-effective treatment for a select groups of patients, such as those with pseudophakia or preexisting cataracts who may soon require cataract surgery⁴⁶.

The SCORE–CRVO study sought to assess the improvement in macular edema associated with CRVO after intraocular application of triamcinolone at doses of 1 mg and 4 mg in comparison to a control group. A gain of ≥15 ETDRS letters was observed in 26.5% of patients who underwent intraocular application of 4 mg of triamcinolone after 12 months of follow-up, and the decrease in central macular thickness compared to baseline was greater in this group. However, the proportion of patients with central macular thickness of ≤250 µm was similar in the three groups at the end of 12 months⁶³.

The GENEVA study evaluated the use of a dexamethasone implant (Ozurdex^®) for the treatment of macular edema secondary to branch retinal vein occlusion (BRVO) and CRVO. This study demonstrated long-term effectiveness and significant improvement in VA in the groups using the medication (0.35 mg and 0.70 mg) compared to the control group⁶⁴.

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