Abstract
Purpose
Following the first wave of the COVID-19 pandemic in early 2020, the easing of strict measures to reduce its spread has led to a resurgence of cases in many countries at both the national and local level. This article addresses how guidance for ophthalmologists on managing patients with retinal disease receiving intravitreal injections of anti-vascular endothelial growth factor (VEGF) during the pandemic should be adapted to the local epidemic pressure, with more or less stringent measures implemented according to the ebb and flow of the pandemic.
Methods
The Vision Academy’s membership of international retinal disease experts analyzed guidance for anti-VEGF intravitreal injections during the COVID-19 pandemic and graded the recommendations according to three levels of increasing epidemic pressure. The revised recommendations were discussed, refined, and voted on by the 14-member Vision Academy Steering Committee for consensus.
Results
Protocols to minimize the exposure of patients and healthcare staff to COVID-19, including use of personal protective equipment, physical distancing, and hygiene measures, should be routinely implemented and intensified according to local infection rates and pressure on the hospital/clinic or healthcare system. In areas with many COVID-19-positive clusters, additional measures including pre-screening of patients, postponement of non-urgent appointments, and simplification of complex intravitreal anti-VEGF regimens should be considered. Treatment prioritization for those at greatest risk of irreversible vision loss should be implemented in areas where COVID-19 cases are increasing exponentially and healthcare resources are strained.
Conclusion
Consistency in monitoring of local infection rates and adjustment of clinical practice accordingly will be required as we move forward through the COVID-19 era. Ophthalmologists must continue to carefully weigh the risk–benefits to minimize the exposure of patients and healthcare staff to COVID-19, ensure that patients receive sight-saving treatment, and avoid the potential long-term impact of prolonged treatment postponement.
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Introduction
Following the rapid spread of the novel coronavirus SARS-CoV-2 across the world in early 2020, the ophthalmic community had to quickly adjust clinical practice in response to high infection rates, mounting pressure on healthcare systems, and implementation of restrictions or “lockdowns” that precluded many patients from attending appointments.
As we navigate through the current phase of the pandemic, where infection rates are once again accelerating in many countries and vary largely between regions, ophthalmologists must be prepared to respond quickly to the changing epidemic pressure in their local area to ensure that patients receive sight-saving ophthalmic care, while still ensuring the safety of patients and staff.
The Vision Academy previously published guidance for managing patients receiving anti-vascular endothelial growth factor (VEGF) injections during the acute phase of the COVID-19 pandemic [1]. As we adjust to the “new normal” of ophthalmic care in the era of COVID-19, we consider how this guidance should be implemented according to the local epidemic pressure. This article provides practical guidance for the management of patients receiving anti-VEGF injections while the threat of COVID-19 remains, and describes how measures should be escalated when infection rates rise and healthcare resources become stretched, to ensure prioritization of treatment for those with the greatest medical need. Conversely, this article also indicates how measures can be de-escalated when the epidemic pressure decreases.
Methods
The Vision Academy is an international group of more than 90 retinal physicians who work together to share existing skills and knowledge, and provide collective recommendations on clinical challenges in areas where there is a lack of conclusive evidence in the literature [2].
Vision Academy guidance for anti-VEGF intravitreal injections during the COVID-19 pandemic was first published online in April 2020 [1], during the first “wave” of the pandemic. This guidance was reviewed during the Vision Academy Annual Meeting in August 2020, where members were asked to validate and decide which recommendations should be implemented at three levels of local epidemic pressure. Following contributions from the membership, the revised recommendations were analyzed, refined, and voted on by the 14-member Vision Academy Steering Committee for consensus.
Guiding principles
Ensuring the safety of healthcare staff and patients should be a key consideration in all decision-making, and practices should be reviewed regularly to account for changing local epidemic pressure. Vigilance in identifying suspect cases of COVID-19 remains essential, with symptoms including dry cough, fever, and fatigue, or less commonly, loss of taste or smell, headache, muscle pain, sore throat, conjunctivitis, dyspnea, nasal congestion, skin rash, or diarrhea [3]. Patients receiving intravitreal injections of anti-VEGF are often elderly and/or diabetic, both of which are characteristics associated with a high risk of COVID-19 complications and hospitalization [4, 5]. While it is important to minimize the exposure of vulnerable patients to avoidable risk, prevention of irreversible vision loss through continuation of care should be practiced wherever possible.
Although our previous guidance [1] discussed the potential for short-term deprioritization of certain cases of diabetic macular edema (DME) and branch retinal vein occlusion (BRVO) due to a reduced likelihood for irreversible vision loss [6, 7], it is important to consider that many patients with DME and BRVO will have already had their treatment postponed during the initial wave of the COVID-19 pandemic, and it is possible that further deferral of treatment may lead to permanent visual changes.
Overall, patients receiving intravitreal injections require clear communication and advice to ensure they feel supported and reassured that their vision remains a key priority. Extensive considerations can be found in previously published guidance [1]. A summary of the recommendations is shown in Table 1.
Low epidemic pressure situations
The effective reproduction number, Rt, is the expected number of new infections generated at time t by each infectious case, in a population where some individuals may no longer be susceptible [15, 16]. Rt has been widely used to monitor the spread of COVID-19, with achieving Rt < 1 being a key goal to prevent the exponential spread of infection [16,17,18,19]. When considering the following recommendations, low epidemic pressure indicates situations where Rt is significantly < 1 but herd immunity through mass vaccination has not yet been achieved. In such situations, some physical distancing measures are likely to be in place, but these would constitute the “new normal” until a suitable vaccine or treatment becomes available. Recommendations for situations of low epidemic pressure are also valid in situations with a higher alert level.
General considerations
COVID-19 remains a threat even in areas where the infection rate is low, and vigilance must be practiced irrespective of the current situation to help prevent escalation of the infection rate. It is essential that safety and hygiene practices are implemented consistently throughout the patient journey to prevent the cycle of transmission (Table 1) [20].
Prioritizing patients according to medical need
Even in situations of low epidemic pressure, ophthalmology clinics may be unable to run at full capacity due to physical distancing measures. If prioritization of patients is required, steps should be taken to ensure the patient is fully informed and that legal, regulatory, and future capacity considerations are appropriately assessed (Table 1). If necessary, treatment visits should be prioritized over monitoring visits, with self-monitoring procedures implemented where possible (Table 1) [21].
Postponing appointments for patients with confirmed or suspected COVID-19 is strongly recommended in all cases, with the exception of emergency intervention to prevent severe vision loss.
Measures to triage and support patients, and inform them of important safety practices such as use of masks and physical distancing [9,10,11] have been discussed previously [1]. In addition to these measures, it may be beneficial to provide a “Dear Patient” letter to all patients that reiterates the importance of attending appointments and offers advice on what to do should they be unable to attend [8].
Reducing exposure during the patient visit
Specific considerations to reduce the exposure of patients and staff to COVID-19, including use of personal protective equipment (PPE), physical distancing, and other measures to reduce exposure in waiting rooms, have previously been described at length [1] and are summarized in Table 1. Importantly, use of masks and physical distancing are strongly encouraged due to their association with a reduced risk of infection in those exposed to COVID-19-positive individuals [9]. Risk reduction appears to be strongest with N95 or equivalent masks; both N95 and surgical masks may offer better protection from infection than single-layer masks. Physical distancing of at least 1 m is associated with a significant reduction in risk of infection, which may be further reduced by distancing by 2 m, and should be implemented wherever feasible [9].
Reducing exposure during the patient examination
In addition to stringent hygiene measures, use of PPE, and physical distancing between staff and patients where appropriate, patient examinations should be kept as brief as possible (Table 1). Use of plastic/plexiglass shields affixed to slit lamps and optical coherence tomography may offer further protection during these examinations, in addition to the use of masks. Given the potential risk of contamination, taping the upper edges of the face mask during intravitreal injection procedures should be considered to prevent air jets from radiating towards the eyes [22].
High epidemic pressure situations
High epidemic pressure indicates situations where the Rt is ~ 1 and/or there are many clusters of COVID-19-positive people present in the community. The following considerations are applicable for situations where the risk of contracting COVID-19 is high but hospital resources are not yet strained. Recommendations for situations of high epidemic pressure are also valid in situations with a higher alert level, where the Rt rises above 1 and hospital resources are strained, resulting in the need for patient prioritization.
Prioritizing patients according to medical need
In situations where there is a high presence of COVID-19 in the community, additional safety measures should be implemented, such as pre-screening patients by phone to determine whether they have symptoms consistent with COVID-19 or have been recently exposed to the virus (Table 1).
High epidemic pressure may result in the need for postponement of non-urgent appointments, guidance for which has been previously published [1]. Patients with certain conditions may be at greater risk of vision deterioration or permanent vision loss with treatment delay and should have their treatment maintained (Table 1). Previous studies have suggested that, in the short term, DME and BRVO cases may be less likely to suffer irreversible vision loss [6, 7], which may make certain patients suitable candidates for treatment delay. However, as these patients may have already had their treatment postponed > 6 months during the initial wave of the COVID-19 pandemic, further deferral could lead to permanent visual changes and therefore these patients should have their treatment maintained wherever possible.
Reducing exposure during the patient examination
In addition to the recommended guidance for low epidemic pressure situations (Table 1), it may be appropriate during high epidemic pressure to limit the use of optical coherence tomography examinations and special instruments (Table 1), unless they are deemed critical for the management of a particular patient.
Treatment regimen considerations
Simplification of treatment regimens and avoidance of regimen changes that require frequent monitoring are recommended as additional measures to reduce exposure and free up healthcare resources during periods of high epidemic pressure. Guidance on suggested approaches to minimize the need for monitoring is provided in Table 1.
Due to the increased likelihood that patients will be unable to attend regular appointments during the pandemic, panretinal photocoagulation may be a preferable treatment choice for patients with severe proliferative diabetic retinopathy to reduce the potential risk of developing tractional retinal detachment.
It is important to reassure patients who are switched to a fixed-dose regimen as a result of the pandemic of the validity and efficacy of using this approach to deliver their anti-VEGF therapy [7, 13, 14].
Extreme epidemic pressure situations
Extreme epidemic pressure indicates situations where the Rt is significantly > 1 and hospital resources are likely to be under significant pressure. In such circumstances, where the spread of COVID-19 is accelerating rapidly, it is likely that lockdown measures are implemented within the local area or country. The following recommendations are only for consideration in instances of extreme epidemic pressure and where the risk–benefits have been carefully weighed.
Prioritizing patients according to medical need
Where the risk of infection is high and hospital resources are strained, consider postponing non-urgent appointments where there is capacity to reschedule within ≤ 4–6 months (Table 1).
Additional measures, including implementation of telemedicine consultations, referral of patients to non-hospital-based settings, or offering home care, should be considered where possible to reduce footfall at hospitals and limit the risk of exposure of vulnerable patients to COVID-19. Telemedicine consultations are encouraged for patients who have been deprioritized to enable visual function monitoring until they are able to attend an in-person appointment, which should ideally be within ≤ 4–6 months (Table 1).
Reducing exposure during the patient examination
In situations of extreme epidemic pressure, it may be acceptable to avoid full visual acuity testing of every patient in order to reduce the examination time and any potential exposure. Use of a near-reading chart or performance of a brief visual acuity test may be sufficient to flag any visual changes that require further investigation (Table 1).
Conclusion
Management strategies for ophthalmic care of patients with retinal disease while COVID-19 remains a threat should be reassessed at regular intervals and adjusted in response to local infection rates and the availability of healthcare resources. The long-term impact of the delays or cancellations of ophthalmology appointments during the initial wave of the COVID-19 pandemic is still to be determined. As long as local infection rates remain low, ophthalmologists should aim to practice at as close to normal operating levels as possible, to limit the risk of irreversible vision loss while ensuring that adequate safety protocols, including PPE and physical distancing, are in place.
In areas where there are many COVID-19-positive clusters or where the number of cases is increasing exponentially, measures to ensure the safety of patients and staff, and the sustainability of healthcare resources, should be intensified as appropriate. In such situations, complex intravitreal anti-VEGF treatment regimens requiring frequent monitoring and dose adjustment should be simplified, and treatment should be prioritized for those at greatest risk of irreversible vision loss.
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Acknowledgements
Writing and editorial assistance was provided by Hollie Robinson, PhD of Complete HealthVizion, Ltd., McCann Health Medical Communications.
Funding
The above assistance was funded by Bayer Consumer Care AG, Pharmaceuticals, Basel, Switzerland.
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This article does not contain any studies with human participants or animals performed by any of the authors. Therefore, informed consent was not required for this analysis.
Conflict of interest
Jean-François Korobelnik is a consultant for Allergan, Bayer, Kanghong, Novartis, and Roche.
Anat Loewenstein is a consultant for Allergan, Bayer, Kanghong, Novartis, Roche, ForSight Labs, and Notal Vision.
Bora Eldem is a consultant for Bayer, Novartis, Allergan, and Roche.
Antonia M. Joussen has received research grants from Novartis and Bayer and is a consultant for Allergan, Bayer, Novartis, and Roche.
Adrian Koh is a consultant and advisor for Bayer, Novartis, Allergan, Carl Zeiss, Heidelberg, and Topcon.
George N. Lambrou is an employee of Bayer AG Pharmaceuticals.
Paolo Lanzetta is a consultant for Allergan, Bayer, CenterVue, Novartis, and Roche.
Xiaoxin Li is a consultant/advisor for Bayer and has received research funding from Bayer.
Monica Lövestam-Adrian has received research grants from Novartis and Bayer and is a consultant for Bayer, Novartis, Allergan, and Santen.
Rafael Navarro has received consultancy fees from Allergan and Bayer.
Annabelle A. Okada has received research grants from Alcon Pharma, Bayer Yakuhin, Mitsubishi Tanabe Pharma, Novartis Pharma, and Santen, and personal fees from AbbVie Japan, Alcon Pharma, Allergan Japan, Astellas Japan, Bayer Healthcare AG, Bayer Yakuhin, Biocon Biologics, Chugai, Daiichi-Sankyo, Mitsubishi Tanabe Pharma, Novartis Pharma, Otsuka, Senju, and Santen.
Ian Pearce has received consultancy/travel/speaker fees from Allergan, Bayer, Novartis, and Roche.
Francisco J. Rodríguez is a consultant/member of the speaker bureau for Bayer, Novartis, and Allergan.
David T. Wong has received grants/research support from Bayer, Novartis, and Roche, consulting fees from Alcon, Allergan, Bausch Health, Bayer, Novartis, Topcon, and Zeiss, and has minor equity in Arctic DX.
Lihteh Wu is a consultant/member of the speaker bureau for Bayer and Quantel Medical.
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Korobelnik, JF., Loewenstein, A., Eldem, B. et al. Anti-VEGF intravitreal injections in the era of COVID-19: responding to different levels of epidemic pressure. Graefes Arch Clin Exp Ophthalmol 259, 567–574 (2021). https://doi.org/10.1007/s00417-021-05097-0
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DOI: https://doi.org/10.1007/s00417-021-05097-0