key: cord-0776354-hfvces1c
authors: Chakraborty, Debdulal; Sheth, Jay U.; Mondal, Soumen; Boral, Subhendu
title: Role of intravitreal brolucizumab with intravitreal rtPA and pneumatic displacement for submacular hemorrhage: A case series
date: 2022-02-05
journal: Am J Ophthalmol Case Rep
DOI: 10.1016/j.ajoc.2022.101390
sha: 068ae156e457cac538bf11c1bb34c50a1f28b5fc
doc_id: 776354
cord_uid: hfvces1c

PURPOSE: To evaluate the role of intravitreal injection (IVI) of brolucizumab along with intravitreal recombinant tissue plasminogen activator (rtPA) and C3F8 gas injection for large submacular hemorrhage (SMH) secondary to neovascular age-related macular degeneration (nAMD). OBSERVATIONS: This was a prospective uncontrolled non-randomized case series conducted at a single site. Three patients with fresh SMH (≤4 days) secondary to nAMD underwent triple therapy with IVI brolucizumab + intravitreal rtPA (50 μg in 0.1 mL) + 0.3 mL of 100% C3F8 gas injection. Post-injection, a face-down position was advised for 5 days with periodic follow-up visits. All three patients had complete resolution of SMH at the end of 4 weeks with a notable improvement in the best-corrected visual acuity (BCVA). No optical coherence tomographic (OCT) biomarkers of disease activity were noted at the end of 12 weeks in the first and the third case and 4 weeks in the second case respectively. There were no ocular or systemic side effects reported in any of the cases. CONCLUSIONS AND IMPORTANCE: Intravitreal brolucizumab administered along with intravitreal rtPA and C3F8 gas injection was found to be efficacious and safe for the management of large SMH secondary to nAMD. Complete displacement of SMH with excellent structural and functional outcomes can be seen with triple therapy.

Submacular hemorrhage (SMH) is a grave visual threatening complication of neovascular age-related macular degeneration (nAMD) and polypoidal choroidal vasculopathy (PCV). 1 If untreated, the accumulated blood can cause irreversible damage to the retinal pigment epithelial (RPE) and neurosensory retina (NSR), particularly the photoreceptor layer. 2, 3 Although intravitreal anti-vascular endothelial growth factor (anti-VEGF) injections remain the gold standard for the management of this choroidal neovascularization (CNV), the therapeutic results of anti-VEGF monotherapy are suboptimal in the presence of large SMH. 4 The primary goal of treating SMH is to displace the blood away from the fovea and treat the underlying etiology. 5 Although there are no established protocols for the management of SMH secondary to nAMD, a variety of therapeutic strategies have been employed. These include a combination of modalities such as intravitreal gas injection, intravitreal or subretinal recombinant tissue plasminogen activator (rtPA), anti-VEGF injection, and pars plana vitrectomy (PPV). 6 Amongst the various anti-VEGF agents currently available, bevacizumab (AVASTIN, Genentech, Inc.,), ranibizumab (Lucentis®; Genentech, S. San Francisco, CA/Roche, Basel, Switzerland), and aflibercept (Eylea®, Regeneron, Tarrytown, NY) have been successfully employed for the management of SMH. 7, 8 Brolucizumab (Beovu®; Novartis, Basel, Switzerland), the most recent anti-VEGF agent, received the US Food and Drug Administration (FDA) approval for nAMD in 2019. 9 In India, the drug is marketed as Pagenax® (Novartis India Ltd, Mumbai, India). 9 Although the HAWK and HARRIER trials have demonstrated the efficacy of intravitreal injection (IVI) of brolucizumab in nAMD, 10 a thorough PUBMED/MED-LINE search revealed that its role in the management of SMH remains unreported.

Here, we describe the efficacy of IVI brolucizumab in combination with intravitreal rtPA and gas injection in three eyes with fresh (≤4 days) large SMH secondary to nAMD. Patients having the longest diameter of the SMH > 4-disc diopters (DD) and a thickness of >100 μm on the spectral-domain optical coherence tomography (SD-OCT) were advised the triple therapy. This retrospective chart analysis was conducted in accordance with the tenets of the Declaration of Helsinki and was approved by the Institutional Review Board and the Ethical Committee of Disha Eye Hospitals in Kolkata, India. Written informed consent was obtained from each patient. All available anti-VEGF medicines were offered to the eligible patients, who freely opted for IVI brolucizumab (6 mg in 0.05 mL). All procedures were performed in a sterile operating room. Povidone-iodine 5% was applied to the periocular region. Initially, the patients received an intravitreal injection of rtPA (50 μg in 0.1 mL) and were given a supine position for 45 minutes for better penetration of the drug. Subsequently, IVI brolucizumab was administered along with 0.3 mL of 100% C3F8 gas, followed by an anterior chamber (AC) paracentesis. Post-operatively, a face-down position was advised for 5 days along with topical moxifloxacin 0.5% for one week. Oral acetazolamide (250 mg) was given in cases with raised intraocular pressure (IOP). The patients were followed up on the second and the fifth day after injection, and subsequently at weeks 2, and 4, and every 4 weekly thereafter, respectively. Best-corrected visual acuity (BCVA) assessment using the Snellen's visual acuity chart, intraocular pressure (IOP) measurement by Goldmann applanation tonometer, anterior segment evaluation using slit-lamp biomicroscopy and fundus examination with both slit-lamp biomicroscopy (+90D lens) and indirect ophthalmoscopy (+20D lens), SD-OCT and color fundus photograph (CFP) were taken at baseline and all subsequent visits. The occurrence of any ocular or systemic adverse event due to IVI brolucizumab or procedure-related were noted too. All patients were planned to receive three monthly loading doses of IVI Brolucizumab followed by pro-renata [PRN] regimen.

A 67-year-old female with a history of nAMD in the left eye (OS) developed sudden onset of decreased vision in OS for 3 days. She had undergone 3 intravitreal anti-VEGF injections (2 IVI Ranibizumab, 1 IVI Aflibercept) one year ago following which she was lost to follow-up due to the COVID-19 pandemic. Her OS BCVA was 20/400. Fundus examination of the left eye showed the presence of a massive SMH extending beyond the arcades ( Fig. 1 a, b ) which were confirmed on SD-OCT (Fig. 2  a) . She underwent IVI brolucizumab + rtPA + C3F8 gas injection in OS and was advised prone position for 5 days. The SMH gradually disappeared over the course of one month ( Fig. 1 c-f) with the BCVA improving upto 20/80. The SD-OCT at two weeks showed significant improvement of retinal the architecture, with some subretinal fluid (SRF) and fibrovascular pigment epithelial detachments (FVPED) (Fig. 2  b) . The SD-OCT at one month showed flattening of the FVPED and no SRF or intra retinal fluid (IRF) (Fig. 2 c) . The patient was advised to undergo further IVI brolucizumab injections, but she declined to do so due to financial constraints. Over the next 12 weeks, the BCVA was maintained at 20/80 with an absence of any disease activity (Figs. 1 g, h and 2d). At all visits, the intraocular pressure (IOP) was normal, with no serious side effects.

A 62-year-old male with treatment-naïve nAMD in OS and dry AMD in the right eye (OD) presented with sudden onset of visual loss in OS for 2 days. His BCVA was 20/20 in OD and 20/800 in OS. Fundus evaluation and SD-OCT showed the presence of large SMH (Figs. 3 a and 4 a) in the OS. We performed IVI brolucizumab + rtPA + C3F8 gas injection and advised prone position for 5 days. Over one month, the SMH gradually decreased (Fig. 3 b) with the BCVA improving to 20/250. The SD-OCT illustrated multiple FVPEDs along with an absence of any fluid (Fig. 4  b) . Further IVI brolucizumab injections were recommended to the patient, but he declined due to economic constraints. Subsequently, his BCVA gradually improved to 20/200 at two months and 20/120 at three months respectively. The patient continues to be under close observation with an absence of any SMH (Fig. 3 c) and OCT biomarker of disease activity at 8 and 12 weeks (Fig. 4 c, d) . No serious adverse events were noted at any of the visits.

An 86-year-old male presented with decreased vision OS for 4 days. He had an active treatment-naïve nAMD with SMH in OS (Fig. 5 a, b) and a scarred nAMD in OD. His BCVA was 20/800 in OD and 20/120 in OS. The SD-OCT revealed the presence of a large FVPED along with sub retinal hyperreflective membrane (SHRM) (Fig. 6 a) in the OS. For the OS SMH, the patient underwent IVI brolucizumab + rtPA + C3F8 gas injection. The patient responded considerably well and showed considerable reduction of SMH at 4 weeks (Fig. 5 c, d) , with improvement in BCVA to 20/60. The presence of SHRM and residual SRF was noted on SD-OCT (Fig. 6 b) for which the patient underwent a second dose of IVI brolucizumab at 1 month. One month later, there was a complete resolution of SMH (Fig. 5 e, f) , SD OCT revealed a shallow PED (Fig. 6 c) , with improvement in BCVA to 20/40. Third dose of IVI (a, b) . Two weeks after treatment with intravitreal injection (IVI) brolucizumab + intravitreal recombinant tissue plasminogen activator (rtPA) + 0.3 cc C3F8 gas injection, there was considerable reduction in SMH with presence of residual C3F8 gas bubble (c, d). At one month, trace residual SMH was present (e, f) which completely resolved by the end of three months (g, h).

Brolucizumab was administered and the patient is yet to follow-up. At all visits, there were no safety concerns with the brolucizumab injection. The patient is scheduled for follow-up.

The purpose of our case series was to evaluate the role of IVI brolucizumab in conjunction with rtPA and C3F8 gas in the management of SMH secondary to nAMD. Our results corroborate the efficacy of this newer anti-VEGF agent in the resolution of SMH with tomographic inactivation of the disease. Additionally, in our study, we observed no ocular or systemic adverse effects.

SMH is an infrequent, but visually devastating complication associated with nAMD. 1,2 If left untreated, it can cause significant visual disability. In the Submacular Surgery Trial (SST), 60% and 70% of the patients in the observational arm had a visual acuity of 3/60 or worse at the end of 3 months and 24 months respectively. 11 Since the introduction of anti-VEGF agents, the management of nAMD has transformed dramatically. Anti-VEGF monotherapy not only makes the disease quiescent, but also helps address smaller macular bleeds. However, for large SMH, additional pneumatic displacement of the blood from the subfoveal location is warranted for optimal visual outcomes. 5 This can be achieved by a combination of intravitreal rtPA along with gas injection and post-procedure positioning to iron out the bleed. Stanescu-Segall D et al. 5 performed a literature review on various treatment modalities for SMH. In their combined analysis of 5 studies, the rate of effective displacement of SMH was 76% (62/81 eyes) with an overall improvement in vision across the board. 5 Furthermore, triple therapy with an anti-VEGF agent, rtPA, and gas resulted in a significant improvement in visual acuity (≥20/100) in 58 patients with baseline visual acuity of ≤20/200. 5 The timing of this combination treatment plays a major role in final visual outcomes. Hattenbach LO et al. 12 have demonstrated that the best visual outcomes are obtained when patients are treated during the early phase of the hemorrhage (<or = 14 days). Earlier treatment by pneumatic displacement, within the first four days of the bleed, was also shown to achieve the best visual outcomes by Sobolewska B et al. 13 In our series too, all the three patients were treated within the first 4 days of bleed, which enabled us to achieve good anatomical and visual outcomes. Amongst the various anti-VEGF agents available, bevacizumab and ranibizumab have been commonly used as a component of triple therapy for SMH. 5, 7, 8 Klettner A 14 have shown that when combined with plasmin, aflibercept is cleaved by rtPA, and its ability to bind VEGF is diminished. Due to this reason, it is not a preferred agent in the form of triple therapy for large SMH. The newer agent brolucizumab is a single-chain humanized antibody fragment that is only 26 kDa in weight. 9 Brolucizumab's effective molar dose is 22-fold more than ranibizumab and 12-fold greater than aflibercept due to its low molecular weight, which is 1/4th that of aflibercept and 1/1.8th that of ranibizumab. 9 With lower molecular weight and a higher molar dose, the brolucizumab molecule should theoretically penetrate the retina tissue more effectively. Consecutively, there is putatively a greater therapeutic role of this agent when compared to the other anti-VEGF molecule. With this backdrop, all three patients in our series were offered therapy with the brolucizumab molecule in combination with rtPA and C3F8 injection. Although we achieved good therapeutic outcomes in our cases, we propose further electrophoretic studies to evaluate the compatibility of the brolucizumab molecule with rtPA in the presence of plasmin.

Episodes of intraocular inflammation (IOI) have been reported with IVI brolucizumab, with a reported incidence of around 4% in the HAWK and HARRIER studies. 10 In the post-marketing surveillance, the incidence of Retinal vasculitis +/retinal vascular occlusion was 15.1 per 10, After the triple therapy, there was complete resolution of SMH with a dry macula and presence of fibrovascular pigment epithelial detachments at months 1 (b), 2 (c) and 3 (d) respectively. 000 injections (till October 9, 2021). 15 Correspondingly, our group recently reported the first Indian real-world data (BRAILLE Study) regarding the safety and efficacy of IVI brolucizumab in nAMD eyes. 16 We noted a significant improvement in BCVA and central subfield thickness (CST) over a mean follow-up of 7.3 ± 2.2 (range 5-30) weeks. 16 Interestingly, no episodes of IOIs were observed after 126 injections in our BRAILLE study. 16 Since the data primarily consisted of Indian eyes, the authors emphasized the importance of further research into the impact of race and genetics in predisposing to/protecting against brolucizumab-related IOIs. 16 In the current series too, we did not observe any ocular or systemic adverse events. Nonetheless, our series was too small with a short follow-up period, and hence insufficiently powered for safety analysis.

The relatively small number of cases and the short follow-up period are two of the study's major limitations. Additionally, we do not have the electrophoretic data to evaluate the molecular interaction of brolucizumab with rtPA and plasmin. Further long-term studies with a larger sample size along with a focus on evaluating the biological activity of the brolucizumab molecule in the presence of other pharmacological agents such as rtPA are warranted.

This is the first reported series of IVI brolucizumab therapy along with rtPA and gas injection in the successful management of large SMH secondary to nAMD. Triple therapy with brolucizumab helps in the displacement of the SMH along with good visual outcomes. Further studies are warranted to validate our results and assess the long-term anatomical and visual outcomes of this combination treatment.

Written informed consent was obtained from patients for publication of these case reports and any accompanying images.

No funding or grant support. 5 . Case 3 -Optos fundus and autofluorescence image demonstrating the large sub-macular hemorrhage (SMH) at baseline (a). One month post-triple therapy (intravitreal injection (IVI) brolucizumab + intravitreal recombinant tissue plasminogen activator [rtPA] + 0.3 cc C3F8 gas injection), the SMH had considerably reduced (b) which subsequently completely resolved by two months (c) after IVI brolucizumab was repeated.

All authors attest that they meet the current ICMJE criteria for Authorship.

The following authors have no financial disclosures: DC, JS, SM, SB. subretinal fluid (SRF) at baseline (a). One month after undergoing triple therapy, the IRF completely resolved along with an improvement in SHRM and SRF as seen on SD-OCT (b). After the second dose of IVI brolucizumab was administered, the SRF and the SHRM completely resolved with a significant reduction in the height of FVPED at two months (c).

Pathophysiology and management of subretinal hemorrhage

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