Pathology of the Brain and the Eye in Severe Acute Respiratory Syndrome Coronavirus-2-Infected Patients: A Review

Background: Patients with severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) may present or eventually develop central nervous system and ophthalmic signs and symptoms. Varying reports have emerged regarding isolation of viral RNA from these tissue sites, as well as largely autopsy-based histopathologic descriptions of the brain and the eye in patients with COVID-19. Evidence acquisition: A primary literature search was performed in literature databases such as PubMed, Google Scholar, and Cochrane Library. Keywords were used alone and in combination including the following: SARS CoV-2, COVID-19, eye, brain, central nervous system, histopathology, autopsy, ocular pathology, aqueous, tears, vitreous, neuropathology, and encephalitis. Results: The reported ophthalmic pathologic and neuropathologic findings in patients with SARS-CoV-2 are varied and inconclusive regarding the role of direct viral infection vs secondary pathology. The authors own experience with autopsy neuropathology in COVID-19 patients is also described. There is a particular paucity of data regarding the histopathology of the eye. However, it is likely that the ocular surface is a potential site for inoculation and the tears a source of spread of viral particles. Conclusions: Additional large postmortem studies are needed to clarify the role of SARS-CoV in the ophthalmic and neuropathologic manifestations of COVID-19.

Disease of the Year: COVID-19 Section Editors: Bart Chwalisz, MD Marc J. Dinkin, MD Pathology of the Brain and the Eye in Severe Acute Respiratory Syndrome Coronavirus-2–Infected Patients: A Review Samantha N. Champion, MD, Imani M. Williams, MBS, Maria Martinez Lage, MD, Anna M. Stagner, MD Background: Patients with severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) may present or eventually develop central nervous system and ophthalmic signs and symptoms. Varying reports have emerged regarding isolation of viral RNA from these tissue sites, as well as largely autopsy-based histopathologic descriptions of the brain and the eye in patients with COVID-19. Evidence Acquisition: A primary literature search was performed in literature databases such as PubMed, Google Scholar, and Cochrane Library. Keywords were used alone and in combination including the following: SARS CoV-2, COVID-19, eye, brain, central nervous system, histopathology, autopsy, ocular pathology, aqueous, tears, vitreous, neuropathology, and encephalitis. Results: The reported ophthalmic pathologic and neuropathologic findings in patients with SARS-CoV-2 are varied and inconclusive regarding the role of direct viral infection vs secondary pathology. The authors own experience with autopsy neuropathology in COVID-19 patients is also described. There is a particular paucity of data regarding the histopathology of the eye. However, it is likely that the ocular surface is a potential site for inoculation and the tears a source of spread of viral particles. C.S. Kubik Laboratory for Neuropathology (SNC, MML), Massachusetts General Hospital, Boston, Massachusetts; David G. Cogan Ophthalmic Pathology Laboratory (IMW, AMS), Massachusetts Eye and Ear Infirmary, Boston, Massachusetts; and Department of Pathology (SNC, MML, AMS), Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts. The authors report no conflicts of interest. S. N. Champion and I. M. Williams contributed equally to the manuscript. Address correspondence to Anna M. Stagner, MD, MEE Ophthalmic Pathology, 243 Charles Street, Room 328, Boston, MA 02114; E-mail: astagner@mgh.harvard.edu. Champion et al: J Neuro-Ophthalmol 2021; 41: 285-292 Conclusions: Additional large postmortem studies are needed to clarify the role of SARS-CoV in the ophthalmic and neuropathologic manifestations of COVID-19. Journal of Neuro-Ophthalmology 2021;41:285–292 doi: 10.1097/WNO.0000000000001275 © 2021 by North American Neuro-Ophthalmology Society BACKGROUND I t has been over a year since the novel, highly transmissible severe acute respiratory syndrome coronavirus-2 (SARSCoV-2) was discovered in Wuhan, China, leading to the disease state termed Coronavirus Disease 2019 (COVID19) (1). Previous severe coronavirus diseases were caused by the SARS-CoV of 2002 and the Middle East respiratory syndrome coronavirus, described in 2012 (1,2). Patients infected with SARS-CoV-2 range from asymptomatic to critically ill with symptoms spanning mild pneumonia to respiratory failure, shock, and multiorgan system dysfunction (2). Since its discovery, frequent and varied neurologic manifestations have been associated with SARS-CoV-2 infection, with increasing reports of neurologic and psychiatric symptoms (3,4). In addition to the common, early presenting signs of loss of taste and smell, patients with SARS-CoV-2 have developed headaches, nausea, vomiting, changes in consciousness, encephalopathy, and acute cerebrovascular disease (3,5–8). It has yet to be determined whether these neurologic manifestations are due to direct invasion of SARS-CoV-2 into the central nervous system (CNS) or an indirect mechanism, and there are several proposed hypotheses. SARS-CoV-2 infection may also present with ophthalmic manifestations in rare cases (9), with ocular symptomatology occurring in 5% (10) to 32% (9) of patients during the course of illness. 285 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. Disease of the Year: COVID-19 In this review, we examine the current literature regarding the mechanism of SARS-CoV-2 infection of and entry into the eye and brain, as well its associated neuro and ophthalmic pathologic findings. Included are relevant clinical microbiologic, surgical, and autopsy pathology studies. Severe acute Respiratory Syndrome Coronavirus-2 and the Brain: Central Nervous System Infection A transcerebral route of SARS-CoV-2 viral entry may occur through the olfactory mucosa and bulb. Increased MRI signal in the olfactory cortex associated with involvement by infection has been documented (11,12). A proposed mechanism is that, similar to other coronaviruses, the virus could be internalized in nerve terminals, transported retrogradely and trans-synaptically spread to the CNS (11,13). SARSCoV-2’s main docking receptor is angiotensin 1–converting enzyme 2 (ACE2) and requires transmembrane protease serine 2 (TMPRSS2) for proteolytic processing of the spike protein to enter cells (11,14). Although expression of TMPRSS2 and ACE2 has been detected in the nasal mucosa, these proteins were only present in the sustentacular cells, and not in neurons (11,15). Another alternative is that the infection causes inflammation within the olfactory mucosa leading to anosmia. It is also possible that the virus is transported to the CNS by the cerebrospinal fluid (CSF) without breaking the blood–brain barrier (BBB) (16,17). However, there are conflicting reported CSF results. Some studies have identified SARS-CoV-2 RNA in the CSF (3,11,16,18–20), but only in modest amounts (11,16,18,19), whereas others did not detect viral genomic material in CSF samples using polymerase chain reaction (PCR)-based tests (11,21,22). Alternatively, SARS-CoV-2 could breach the BBB to infect the CNS. In addition to being an enzyme, ACE2 is also a functional surface receptor and can be used by SARSCoV-2 to enter host cells. ACE2 is highly expressed in many cells, including endothelium, cardiac, renal, pulmonary, and blood cells. It is also involved in the renin– angiotensin–aldosterone system (RAAS). SARS-CoV-2 could therefore cause disease by activating RAAS, especially in patients with other comorbidities such as diabetes mellitus, hypertension, and vascular disease (16,23). Comorbidities are present in many patients infected with CoVID-19, and the comorbidities alone could potentially increase the permeability of the BBB (11,24). Paniz-Mondolfi et al report a patient with Parkinson disease and COVID-19 in which viral particles were found by electron microscopy in the frontal lobe microvessels and neurons (11,25). A study by Kantonen et al of a COVID-19–positive patient with Parkinson disease, obesity, diabetes, and hypertension showed hypoxic/ischemic neuronal damage, white matter lesions, microhemorrhages, and enlarged perivascular spaces, but no evidence of SARS-CoV-2 in the brain at 286 autopsy (11,26). Conversely, Zubair et al demonstrated neurons with entrapped viral particles by electron microscopy (27). One proposed mechanism of viral involvement of the CNS is through cellular transport across the endothelium by interacting with ACE2 on the vessels and subsequently neurons and glia (16,27). Another mechanism, known as the “Trojan-horse mechanism,” is that by infecting leukocytes, viral particles could that then cross the BBB (16,28). This could be exacerbated by COVID-19–related systemic inflammation that may increase the permeability of the BBB (16,29). A potential last mechanism could be entrance through the median eminence capillaries and tanycytes of the hypothalamus which also express ACE2 and TMPRSS2 (11,30). Finally, another hypothesis of CNS involvement postulates indirect systemic factors as the cause of brain injury. There are reports of autoimmune encephalitis in patients with COVID-19 where patients have excessive antigendriven immune responses (3,31). Patients with SARS have been shown to produce autoantibodies against the coronavirus spike protein that react with endothelial and epithelial cells, which results in cytotoxicity (3,32). These antibodies can then induce immune reactions against endothelial cell antigens in cerebral vessels or neurons, resulting in autoimmune encephalitis and edema (3). Some patients with COVID-19 develop encephalopathy and encephalitis. Although altered mental status is rare overall in hospitalized CoVID-19 patients, most critically ill patients experience altered mental status (6,11,33). It is unknown if these alterations in mental status are due to encephalopathy related to the systemic illness or caused directly by SARS-CoV-2 (11). A few cases of CoVID-19 patients with encephalitis have been reported (11,18,19,34– 36). As mentioned above, 2 of these reports described identification of SARS-CoV-2 in the CSF, albeit in modest amounts (11,18,19). Efe et al discussed a case where the diagnosis of temporal lobe encephalitis was confirmed on biopsy material, showing hypoxic neuronal damage and perivascular lymphocytic infiltrates; however, the assessment of SARS-CoV-2 in tissue was not reported (11,34). Cerebrovascular disease, including ischemic strokes, is found in a subset of patients with COVID-19 (1%–3% of hospitalized patients and up to 6% of critically ill patients with COVID-19) (6,11,37,38). An early report by Oxley et al documents embolic strokes in young, otherwise healthy patients with COVID-19 (11,39). However, later reports demonstrate that patients with embolic strokes are usually older and have numerous other vascular comorbidities (11,40). Although it is possible that SARS-CoV-2 may contribute to a vascular event, similar to other infections that alter systemic inflammatory conditions and coagulability, it is uncertain whether the strokes are caused directly by the infection or if they are related to the patient’s comorbidities while they happen to be CoVID-19 positive at the time (11,41). Champion et al: J Neuro-Ophthalmol 2021; 41: 285-292 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. Disease of the Year: COVID-19 Finally, postinfectious syndromes associated with COVID-19 have been increasingly documented in recent months. As discussed above, infection with SARS-CoV-2 can cause a dysregulated immune response. This immune system alteration may cause delayed and extended effects on the peripheral and central nervous systems. There are reports of immune-mediated responses that resemble various postinfectious inflammatory conditions. For example, Parsons et al report a neuroradiologic case of acute disseminated encephalomyelitis (ADEM), and Poyiadji et al report a neuroradiologic case of acute hemorrhagic necrotizing encephalopathy (42,43). Toscano et al report several cases of Guillain–Barre syndrome in patients with recent COVID-19, but with no detectable SARS-CoV-2 in the CSF (11,21). The persistence of or development of new symptoms late in the course of a COVID-19 infection has been described as “long-COVID” or “COVID long haulers.” (16,44) These patients have symptoms .28 days after their COVID-19 diagnosis, and their symptoms vary in severity and frequency, but many describe fatigue, “brain fog,” breathlessness, dysrhythmias, and pain which last for months after they are infectious (16,44,45). This syndrome is reminiscent of the postviral illness named myalgic encephalomyelitis/chronic fatigue syndrome, which likely is due to long-term alterations caused by the immune response to an initial viral infection (16,46). Neuropathologic Autopsy Findings in Coronavirus Disease-19 Patients Review of the literature for postmortem findings in patients with COVID-19 is mostly focused on general autopsy findings, with descriptions of brain findings occurring only later on in the pandemic. This was largely due to limited access to cases and concerns regarding the safety of the autopsy staff (16). As more reports have appeared in the literature, the neuropathologic findings have varied from hypoxic/ischemic changes, edema, perivascular chronic inflammation, microthrombi, ischemic necrosis, and acute hemorrhagic infarctions (3). Many reports have demonstrated hypoxic/ischemic brain injury with neuronal damage mostly in the brain regions that are vulnerable to hypoxia (neocortex, hippocampus, and cerebellum) (3,26,34,47–54), which is likely associated with respiratory insufficiency in the context of diffuse alveolar damage and multiorgan failure, resulting in reduced blood flow and oxygen to the brain (3,49). In addition to ischemic changes, Solomon et al also demonstrated reactive Alzheimer type II astrocytes in their case series of 18 patients (49). Microvascular and macrovascular injury has also been reported in many cases. Both large and small infarcts including multiple small subcortical infarcts, areas of ischemic necrosis, and microscopic hemorrhages have been reported, particularly in patients with pre-existing vascular disease (3,48,50,51,53–57). Al-Sarraj et al reported a case of Champion et al: J Neuro-Ophthalmol 2021; 41: 285-292 hemorrhagic infarction with microthrombi with coexisting mucormycosis, believed to be a result of the patient’s decreased immune response (3). Al-Dalahmah et al described a case of cerebellar hemorrhage and acute infarcts in a 73-year-old man with COVID-19 (56). Matschke et al examined 43 patients with COVID-19 and found territorial ischemic lesions in 6 patients (43%) and 37 patients with astrogliosis in all evaluated regions (86%) (54). Reports of an inflammatory cell component have varied. Netland et al demonstrated a mild inflammatory process in experimental mice infected with SARS-CoV, suggesting neurotoxicity with minimal inflammatory cell infiltration (3,58). Other studies have also shown a minimal inflammatory T-cell response with microglial activation and occasional microglial nodules, but no overt encephalitis or vasculitis (49,53,55,59,60). All 8 cases evaluated in the series reported by Al-Sarraj et al showed few perivascular T cells and activation of microglial cells (3). Lee et al also describe microvascular injury associated with minimal perivascular inflammation, but with perivascular and perineuronal microglia and macrophages, suggestive of neuronophagia within the substantia nigra, dorsal motor nucleus of the vagus, medullary pre-Bötzinger complex and olfactory bulb, as well as hypertrophic astrocytes (60). Al-Dalahmah et al also described microglial nodules and neuronophagia involving the inferior olives and cerebellar dentate nuclei (56). Activated microglia and infiltrating T cells were present mostly in the brainstem and cerebellum with leptomeningeal T cells in 34 of the 43 patients in Matschke et al.’s study (54). Nauen et al additionally report luminal megakaryocytes in cortical capillaries present in 5 cases (52). A case reported by Stoyanov et al described an acute necrotizing encephalitis with a necrotizing olfactory bulbitis (61). Panencephalitis, meningitis, and neuronal cell damage involving the brainstem were reported by von Weyhern et al; however, these results have been disputed (62–64). Reports of CNS involvement by SARS-CoV-2 genetic material have been heterogenous. A subset of studies document the presence of SARS-CoV-2 genetic material in brain tissue detected by quantitative reverse transcriptase PCR (qRT-PCR), immunostaining, or electron microscopy (as described above) (3,25,27,47,53). For example, Matschke et al reportedly detected SARS-CoV-2 by qRT-PCR or immunostaining in the brains of 21 of their 43 patients (53%) (54). However, many other studies did not detect SARSCoV-2 genetic material in their examined central and peripheral nervous system samples.3,11,16,26,49,59 As mentioned above, Reichard et al describe one patient with hemorrhagic white matter lesions present throughout the cerebrum with associated axonal injury and macrophage infiltration, in a perivascular ADEM–like appearance. There were also microscopic areas of white matter necrosis and axonal injury and rare organizing microscopic infarcts within the cortex (48). This is an example of a postinfectious syndrome that was demonstrated at autopsy. 287 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. Disease of the Year: COVID-19 The authors of this review have evaluated brains from 20 patients with COVID-19 at autopsy. Ages at death ranged from 21 to 91 years, with 16 men and 4 women. The cohort included 11 White, 6 Hispanic or Black, and 3 patients of unknown ethnicity. Seven cases had associated neuropsychiatric diagnosis (4/20: dementia; 2/20: schizophrenia; and 1/20: bipolar disorder), and 7 patients suffered from acute encephalopathy in the context of their disease. Neuropathologic examination revealed cerebrovascular disease in most cases; arteriolar sclerosis specifically was the most frequent finding: mild in 4/20, moderate in 9/20, and moderate to severe in 3/20. Acute hypoxic ischemic injury was seen in 13/20 patients. Nine cases had subacute/remote infarctions and/or hemorrhages, 3 associated with cerebral amyloid angiopathy. Two cases showed acute microscopic ischemic lesions, and petechial hemorrhages were present in 2 cases (one case overlapped with acute ischemic lesions) (Figs. 1A, B). Periventricular inactive demyelinating lesions of uncertain origin were present in 2 cases. In addition to routine Luxol hematoxylin and eosin (LH&E) and hematoxylin and eosin (H&E) sections, 12 cases were examined in detail with immunohistochemistry for CD3, CD68, CD163, and in situ hybridization (ISH) for SARS-CoV-2 and compared with 5 age-matched control patients who died from pneumonia. Sections of the cerebellum, frontal, and temporal lobes were compared as they were the most involved by inflammatory infiltrates. Mild-to-moderate perivascular and leptomeningeal CD68/CD163-positive macrophages and activated microglia with white matter predominance were present in all cases (Fig. 1C). All cases also showed sparse to moderate perivascular and leptomeningeal CD3-positive T cells (Fig. 1D). Interestingly, the agematched controls showed a similar degree and distribution of inflammatory activation. All cases were negative for SARS-CoV-2 genomic material by ISH. Our findings are similar to those described in other reports and favor an indirect systemic inflammatory reaction and/or cytokine response with potential associated microvascular injury as the underlying mechanism for cerebral involvement in COVID-19 infection. SEVERE ACUTE RESPIRATORY SYNDROME CORONAVIRUS-2 AND THE EYE Ocular Surface: Conjunctiva, Cornea, and Tears Early in the COVID-19 pandemic, ophthalmologists in the Hubei province of China noted external ocular manifestations of some patients being treated for SARS-CoV-2 infection, including conjunctivitis with conjunctiva hyperemia, edema (chemosis), and increased tearing, in as many as 30% of patients (9). This led to hypotheses about the conjunctiva as a site of direct inoculation for infection as well as the potential for tears as a reservoir for the virus and source of viral spread (9). The literature that emerged pro288 viding evidence of SARS-CoV-2 in conjunctival secretions is mixed (65). During the initial phases of the outbreak, researchers began testing conjunctival samples from confirmed COVID-19–infected patients, likely spurred by the early detection of SARS-CoV in the tears of some patients in the early 2000s (66). SARS-CoV-2 RNA has now been identified in conjunctival swab samples and rarely in the tears (67,68) of patients with varying systemic disease severity and in those with or without ocular signs and symptoms (9,67–69). This is an important finding that suggests asymptomatic patients may shed the virus in the absence of visible ocular abnormalities (70,71). In some studies, severely to critically ill patients were more likely to have conjunctivitis (9). However, there was a low, and similar, prevalence of positive RT-PCR results from conjunctival swabs in patients with ocular symptoms and a known positive nasopharyngeal swab and those without symptoms (around 16% in both instances) (9). Overall, given the difference in detection rates from nasopharyngeal and conjunctival swabs, viral load may be low in conjunctival secretions. ACE2, the key cell surface receptor that binds the SARSCoV 2 spike protein for inoculation of the virus into human cells, and TMPRSS2, a cell surface protease that facilitates viral entry (discussed above in more detail), have been shown to be expressed on the ocular surface in conjunctival surgical specimens and enucleated autopsy globes (72). Through both Western blot analysis of corneal epithelium and immunohistochemical localization in the anterior segment, Zhou et al noted that ACE2 is localized on the ocular surface including within the epithelium of the conjunctiva and cornea, particularly within the limbal epithelial cells and the superficial squamous cells of the conjunctiva (72). TMPRSS2 also showed immunohistochemical localization throughout all the epithelial layers of the cornea and conjunctiva. Given the frequent use of corneal tissue from deceased donors for transplantation, small autopsy studies have also interrogated corneal discs or buttons from deceased patients with known SARS-CoV-2 infection for the presence of viral RNA (73). Genomic RNA was found in over half of cases, and in these cases, RNA was also found in conjunctival swabs and occasionally in aqueous or vitreous humor samples. In this study, half of all patients had detectable RNA in their conjunctival swab specimens (with or without detection in the cornea), a much higher rate than found in specimens taken from live patients. Corneal histology in this study was unremarkable, and immunohistochemistry did not detect staining for the SARS-CoV-2 spike protein. Posterior Pole Retina/vitreous Although the primary ocular manifestation of COVID-19 seems to be conjunctivitis, the ophthalmic literature also Champion et al: J Neuro-Ophthalmol 2021; 41: 285-292 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. Disease of the Year: COVID-19 FIG. 1. Pathology of ischemic lesions in a patient who died from severe COVID-19. A. Microscopic analysis of cerebellum at ·200 magnification (LH&E). Representative focus of microscopic ischemic lesion with significant loss, but not absence, of myelin. B. Microscopic analysis of splenium white matter at ·100 magnification (LH&E) showing a microscopic hemorrhagic and ischemic lesion. C. Microscopic analysis of cerebellum at ·200 magnification. CD68 immunohistochemistry stain demonstrating aggregates of macrophages associated with the ischemic lesion. D. Microscopic analysis of cerebellum at ·200 magnification. CD3 immunohistochemistry stain showing only rare CD3-positive T cells, consistent with no significant inflammation associated with the lesion. reports conflicting data on the presence of viral RNA in ocular fluids as well as clinical and pathologic data regarding the posterior pole findings (74–76). Three of 14 deceased COVID-19 patients, in a study by Casagrande et al, showed PCR evidence of SARS-CoV-2 RNA isolated from retinal biopsies obtained at autopsy. However, direct evidence of tissue localization (through immunohistochemistry or in situ hybridization) was not demonstrated or studied, and retinal histopathology was not described (77). Clinically, retinal and, particularly, retinovascular changes have been noted in SARS CoV-2–positive patients (78,79) In a study examining retinal findings in hospitalized patients with severe COVID-19, Pereira et al found that 10 of 18 patients had retinal abnormalities on dilated eye examination including flame-shaped hemorrhages in 22.2%, cotton wool spots in 16.7%, and retinal sectoral pallor in 1 patient suggestive of retinal ischemia (79). In a similar study of 12 patients with COVID-19, Marinho et al noted that all patients had hyper-reflective lesions at the level of ganglion cell and inner plexiform layers more prominent in the papillomacular bundle bilaterally on optical coherence tomography. Subtle cotton wool spots and microhemorrhages were also noted in this cohort (78). In 2 concordant studies, researchers identified cotton wool spots (80,81), retinal hemorrhages, and venous dilation as significant findings in the eyes of COVID-19 patients (80). Given that these findings are diagnostically Champion et al: J Neuro-Ophthalmol 2021; 41: 285-292 nonspecific and often found in elderly patients with common chronic systemic conditions such as hypertension and diabetes mellitus, it is unclear if these retinal findings are indicative of a thrombotic complication because of the systemic effects of COVID-19 (82,83). In addition, other cohorts of severely ill patients with COVID-19 showed no fundus abnormalities (76). Finally, a report describing the MRI findings within the globes of 127 COVID-19 patients revealed 9 patients with one or more macular nodules which appeared hyperintense on Fluid-attenuated inversion recovery sequence (10). The nature of these nodules is uncertain, but given that in other intracranial sites this type of signal may represent intracerebral artery steno-occlusion, these lesions may be related to focal ischemia within the retina (84,85). Choroid The histopathology of eyes from patients with COVID-19 has best been demonstrated in an autopsy study from Switzerland comparing 10 enucleated postmortem eyes from 5 infected patients with control eyes (86). The anterior segments and retina were histologically normal for age, with occasional mild conjunctival inflammation. However, the choriocapillaris showed congestion and endothelial swelling with focal apoptosis, not seen in control eyes. Immunohistochemical analysis of these autopsy globes revealed fibrin microthrombi in the choriocapillaris and 289 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. Disease of the Year: COVID-19 larger choroidal vessels of 8 eyes from 4 patients (86). This finding alone is nonspecific and may be caused by sepsis or serious infection; however, no microthrombi were detected in the eyes of control patients who died from conditions such as biliary sepsis and bronchopneumonia (86). Apoptotic changes and cleaved caspase 3 expression (an apoptosis executor) were also found in endothelial and inflammatory cells infiltrating the choriocapillaris of eyes from SARSCoV-2–infected patients. In addition, ACE-2 receptor expression was demonstrated in endothelial cells of the choroid, in addition to the previously described expression in the conjunctival and corneal epithelium. Histologic evidence of the more severe ocular complications that have been reported in animal models of SARS-CoV including retinitis and optic neuritis were not seen (87). CONCLUSION The documented neuropathologic findings in patients with SARS-CoV-2 are heterogeneous. Some reports support a direct cytopathic effect of SARS-CoV-2 viral material within the central nervous system, whereas others point toward a systemic cytokine reaction and/or dysregulated immune response caused by the systemic viral infection. Others highlight potential endothelial and vascular injury as the main process. More postmortem neuropathologic studies with large patient cohorts are needed to verify the neuropathologic changes and presence or absence of SARSCoV-2 genetic material within the central and peripheral nervous system. The limited literature regarding the ophthalmic manifestations of SARS CoV-2 suggests the virus may be shed in low levels through tears or conjunctival secretions with the cornea and conjunctival epithelia as potential portals for viral entry. The intraocular pathology including choroidal microthrombi as well as the clinical retinal findings, such as in the brain, may be secondary to vascular endothelial changes, as direct evidence of viral RNA within the neural retina and uvea has not been convincingly demonstrated. REFERENCES 1. Asadi-Pooya AA, Simani L. Central nervous system manifestations of COVID-19: a systematic review. J Neurol Sci. 2020;413:116832. 2. Gavriatopoulou M, Korompoki E, Fotiou D, NtanasisStathopoulos I, Psaltopoulou T, Kastritis E, Terpos E, Dimopoulos MA. Organ-specific manifestations of COVID-19 infection. Clin Exp Med. 2020;20:493–506. 3. Al-Sarraj S, Troakes C, Hanley B, Osborn M, Richardson MP, Hotopf M, Bullmore E, Everall IP. Invited Review: the spectrum of neuropathology in COVID-19. Neuropathol Appl Neurobiol. 2021;47:3–16. 4. Varatharaj A, Thomas N, Ellul MA, Davies NWS, Pollak TA, Tenorio EL, Sultan M, Easton A, Breen G, Zandi M, Coles JP, Manji H, Al-Shahi Salman R, Menon DK, Nicholson TR, Benjamin LA, Carson A, Smith C, Turner MR, Solomon T, Kneen R, Pett SL, Galea I, Thomas RH, Michael BD; CoroNerve Study Group. Neurological and neuropsychiatric complications of COVID-19 in 153 patients: a UK-wide surveillance study. Lancet Psychiatry. 2020;7:875–882. 290 5. Wang D, Hu B, Hu C, Zhu F, Liu X, Zhang J, Wang B, Xiang H, Cheng Z, Xiong Y, Zhao Y, Li Y, Wang X, Peng Z. Clinical characteristics of 138 hospitalized patients with 2019 novel Coronavirus-infected pneumonia in Wuhan, China. JAMA. 2020;323:1061–1069. 6. Mao L, Jin H, Wang M, Hu Y, Chen S, He Q, Chang J, Hong C, Zhou Y, Wang D, Miao X, Li Y, Hu B. Neurologic manifestations of hospitalized patients with coronavirus disease 2019 in Wuhan, China. JAMA Neurol. 2020;77:683–690. 7. Li Y, Li M, Wang M, Zhou Y, Chang J, Xian Y, Wang D, Mao L, Jin H, Hu B. Acute cerebrovascular disease following COVID-19: a single center, retrospective, observational study. Stroke Vasc Neurol. 2020;5:279–284. 8. Huang C, Wang Y, Li X, Ren L, Zhao J, Hu Y, Zhang L, Fan G, Xu J, Gu X, Cheng Z, Yu T, Xia J, Wei Y, Wu W, Xie X, Yin W, Li H, Liu M, Xiao Y, Gao H, Guo L, Xie J, Wang G, Jiang R, Gao Z, Jin Q, Wang J, Cao B. Clinical features of patients infected with 2019 novel coronavirus in Wuhan, China. Lancet. 2020;395:497– 506. 9. Wu P, Duan F, Luo C, Liu Q, Qu X, Liang L, Wu K. Characteristics of ocular findings of patients with coronavirus disease 2019 (COVID-19) in Hubei province, China. JAMA Ophthalmol. 2020;138:575–578. 10. Lecler A, Cotton F, Lersy F, Kremer S, Héran F; SFNR’s COVID Study Group. Ocular MRI findings in patients with severe COVID-19: a retrospective multicenter observational study. Radiology. 2021:204394. 11. Iadecola C, Anrather J, Kamel H. Effects of COVID-19 on the nervous system. Cell. 2020;183:16–27.e1. 12. Politi LS, Salsano E, Grimaldi M. Magnetic resonance imaging alteration of the brain in a patient with Coronavirus Disease 2019 (COVID-19) and anosmia. JAMA Neurol.. 2020;77:1028– 1029. 13. Dubé M, Le Coupanec A, Wong AHM, Rini JM, Desforges M, Talbot PJ. Axonal transport enables neuron-to-neuron propagation of human Coronavirus OC43. J Virol. 2018;92:e00404–18. 14. Hoffmann M, Kleine-Weber H, Schroeder S, Krüger N, Herrler T, Erichsen S, Schiergens TS, Herrler G, Wu NH, Nitsche A, Müller MA, Drosten C, Pöhlmann S. SARS-CoV-2 cell entry depends on ACE2 and TMPRSS2 and is blocked by a clinically proven protease inhibitor. Cell. 2020;181:271–280.e8. 15. Brann DH, Tsukahara T, Weinreb C, Lipovsek M, Van den Berge K, Gong B, Chance R, Macaulay IC, Chou HJ, Fletcher RB, Das D, Street K, de Bezieux HR, Choi YG, Risso D, Dudoit S, Purdom E, Mill J, Hachem RA, Matsunami H, Logan DW, Goldstein BJ, Grubb MS, Ngai J, Datta SR. Non-neuronal expression of SARS-CoV-2 entry genes in the olfactory system suggests mechanisms underlying COVID-19-associated anosmia. Sci Adv. 2020;6:eabc5801. 16. Fisicaro F, Di Napoli M, Liberto A, Fanella M, Di Stasio F, Pennisi M, Bella R, Lanza G, Mansueto G. Neurological sequelae in patients with COVID-19: a histopathological perspective. Int J Environ Res Public Health. 2021;18:1415. 17. Baig AM, Sanders EC. Potential neuroinvasive pathways of SARS-CoV-2: deciphering the spectrum of neurological deficit seen in Coronavirus Disease-2019 (COVID-19). J Med Virol. 2020;92:1845–1857. 18. Moriguchi T, Harii N, Goto J, Harada D, Sugawara H, Takamino J, Ueno M, Sakata H, Kondo K, Myose N, Nakao A, Takeda M, Haro H, Inoue O, Suzuki-Inoue K, Kubokawa K, Ogihara S, Sasaki T, Kinouchi H, Kojin H, Ito M, Onishi H, Shimizu T, Sasaki Y, Enomoto N, Ishihara H, Furuya S, Yamamoto T, Shimada S. A first case of meningitis/encephalitis associated with SARS-Coronavirus-2. Int J Infect Dis. 2020;94:55–58. 19. Huang YH, Jiang D, Huang JT. SARS-CoV-2 detected in cerebrospinal fluid by PCR in a case of COVID-19 encephalitis. Brain Behav Immun. 2020;87:149. 20. Xiang P, Xu XM, Gao LL, Wang HZ, Xiong HF, Li RH. First case of 2019 novel coronavirus disease with encephalitis. ChinaXiv. 2020:T202003.00015. 21. Toscano G, Palmerini F, Ravaglia S, Ruiz L, Invernizzi P, Cuzzoni MG, Franciotta D, Baldanti F, Daturi R, Postorino P, Champion et al: J Neuro-Ophthalmol 2021; 41: 285-292 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. Disease of the Year: COVID-19 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. Cavallini A, Micieli G. Guillain-barré syndrome associated with SARS-CoV-2. N Engl J Med. 2020;382:2574–2576. Bernard-Valnet R, Pizzarotti B, Anichini A, Demars Y, Russo E, Schmidhauser M, Cerutti-Sola J, Rossetti AO, Du Pasquier R. Two patients with acute meningoencephalitis concomitant with SARS-CoV-2 infection. Eur J Neurol. 2020;27:e43–e44. Beyerstedt S, Casaro EB, Rangel ÉB. COVID-19: angiotensin-converting enzyme 2 (ACE2) expression and tissue susceptibility to SARS-CoV-2 infection. Eur J Clin Microbiol Infect Dis. 2021:1–15 doi:10.1007/s10096-02004138-6. Erickson MA, Banks WA. Neuroimmune axes of the blood-brain barriers and blood-brain interfaces: bases for physiological regulation, disease states, and pharmacological interventions. Pharmacol Rev. 2018;70:278–314. Paniz-Mondolfi A, Bryce C, Grimes Z, Gordon RE, Reidy J, Lednicky J, Sordillo EM, Fowkes M. Central nervous system involvement by severe acute respiratory syndrome coronavirus2 (SARS-CoV-2). J Med Virol. 2020;92:699–702. Kantonen J, Mahzabin S, Mäyränpää MI, Tynninen O, Paetau A, Andersson N, Sajantila A, Vapalahti O, Carpén O, Kekäläinen E, Kantele A, Myllykangas L. Neuropathologic features of four autopsied COVID-19 patients. Brain Pathol. 2020;30:1012– 1016. Zubair AS, McAlpine LS, Gardin T, Farhadian S, Kuruvilla DE, Spudich S. Neuropathogenesis and neurologic manifestations of the Coronaviruses in the age of Coronavirus Disease 2019: a review. JAMA Neurol. 2020;77:1018–1027. Desforges M, Le Coupanec A, Brison E, Meessen-Pinard M, Talbot PJ. Neuroinvasive and neurotropic human respiratory coronaviruses: potential neurovirulent agents in humans. Adv Exp Med Biol. 2014;807:75–96. Sankowski R, Mader S, Valdés-Ferrer SI. Systemic inflammation and the brain: novel roles of genetic, molecular, and environmental cues as drivers of neurodegeneration. Front Cell Neurosci. 2015;9:28. Nampoothiri S, Sauve F, Ternier G, Fernandois D, Coelho C, Imbernon M, Deligia E, Perbet R, Florent V, Baroncini M, Pasquier F, Trottein F, Maurage C, Mattot V, Giacobini P, Rasika S, Prevotet V. The hypothalamus as a hub for SARSCoV-2 brain infection and pathogenesis. bioRxiv. 2020. doi: 10.1101/2020.06.08.139329. Dubey D, Pittock SJ, Kelly CR, McKeon A, Lopez-Chiriboga AS, Lennon VA, Gadoth A, Smith CY, Bryant SC, Klein CJ, Aksamit AJ, Toledano M, Boeve BF, Tillema JM, Flanagan EP. Autoimmune encephalitis epidemiology and a comparison to infectious encephalitis. Ann Neurol. 2018;83:166–177. Lin YS, Lin CF, Fang YT, Kuo YM, Liao PC, Yeh TM, Hwa KY, Shieh CC, Yen JH, Wang HJ, Su IJ, Lei HY. Antibody to severe acute respiratory syndrome (SARS)-associated coronavirus spike protein domain 2 cross-reacts with lung epithelial cells and causes cytotoxicity. Clin Exp Immunol. 2005;14:500–508. Helms J, Kremer S, Merdji H, Clere-Jehl R, Schenck M, Kummerlen C, Collange O, Boulay C, Fafi-Kremer S, Ohana M, Anheim M, Meziani F. Neurologic features in severe SARS-CoV2 infection. N Engl J Med. 2020;382:2268–2270. Efe IE, Aydin OU, Alabulut A, Celik O, Aydin K. COVID-19associated encephalitis mimicking glial tumor. World Neurosurg. 2020;140:46–48. Farhadian S, Glick LR, Vogels CBF, Thomas J, Chiarella J, Casanovas-Massana A, Zhou J, Odio C, Vijayakumar P, Geng B, Fournier J, Bermejo S, Fauver JR, Alpert T, Wyllie AL, Turcotte C, Steinle M, Paczkowski P, Dela Cruz C, Wilen C, Ko AI, MacKay S, Grubaugh ND, Spudich S, Barakat LA. Acute encephalopathy with elevated CSF inflammatory markers as the initial presentation of COVID-19. BMC Neurol. 2020;20:248. Pilotto A, Odolini S, Masciocchi S, Comelli A, Volonghi I, Gazzina S, Nocivelli S, Pezzini A, Focà E, Caruso A, Leonardi M, Pasolini MP, Gasparotti R, Castelli F, Ashton NJ, Blennow K, Zetterberg H, Padovani A. Steroid-responsive encephalitis in coronavirus disease 2019. Ann Neurol. 2020;88:423–427. Champion et al: J Neuro-Ophthalmol 2021; 41: 285-292 37. Merkler AE, Parikh NS, Mir S, Gupta A, Kamel H, Lin E, Lantos J, Schenck EJ, Goyal P, Bruce SS, Kahan J, Lansdale KN, LeMoss NM, Murthy SB, Stieg PE, Fink ME, Iadecola C, Segal AZ, Cusick M, Campion TR Jr, Diaz I, Zhang C, Navi BB. Risk of ischemic stroke in patients with Coronavirus Disease 2019 (COVID-19) vs patients with Influenza. JAMA Neurol. 2020;77:1–7. 38. Yaghi S, Ishida K, Torres J, Mac Grory B, Raz E, Humbert K, Henninger N, Trivedi T, Lillemoe K, Alam S, Sanger M, Kim S, Scher E, Dehkharghani S, Wachs M, Tanweer O, Volpicelli F, Bosworth B, Lord A, Frontera J. SARS-CoV-2 and stroke in a New York healthcare system. Stroke. 2020;51:2002–2011. 39. Oxley TJ, Mocco J, Majidi S, Kellner CP, Shoirah H, Singh IP, De Leacy RA, Shigematsu T, Ladner TR, Yaeger KA, Skliut M, Weinberger J, Dangayach NS, Bederson JB, Tuhrim S, Fifi JT. Large-vessel stroke as a presenting feature of Covid-19 in the young. N Engl J Med. 2020;382:e60. 40. Lodigiani C, Iapichino G, Carenzo L, Cecconi M, Ferrazzi P, Sebastian T, Kucher N, Studt JD, Sacco C, Bertuzzi A, Sandri MT, Barco S. , Humanitas COVID-19 Task Force. Venous and arterial thromboembolic complications in COVID-19 patients admitted to an academic hospital in Milan, Italy. Thromb Res. 2020;191:9–14. 41. Parikh NS, Merkler AE, Iadecola C. Inflammation, autoimmunity, infection, and stroke: epidemiology and lessons from therapeutic intervention. Stroke. 2020;51:711–718. 42. Parsons T, Banks S, Bae C, Gelber J, Alahmadi H, Tichauer M. COVID-19-associated acute disseminated encephalomyelitis (ADEM). J Neurol. 2020;267:2799–2802. 43. Poyiadji N, Shahin G, Noujaim D, Stone M, Patel S, Griffith B. COVID-19-associated acute hemorrhagic necrotizing encephalopathy: imaging features. Radiology. 2020;296:e119–e120. 44. Mendelson M, Nel J, Blumberg L, Madhi SA, Dryden M, Stevens W, Venter FWD. Long-COVID: an evolving problem with an extensive impact. S Afr Med J. 2020;111:10–12. 45. Marshall M. The lasting misery of Coronavirus long-haulers. Nature. 2020;585:339–341. 46. Wood E, Hall KH, Tate W. Role of mitochondria, oxidative stress and the response to antioxidants in myalgic encephalomyelitis/chronic fatigue syndrome: a possible approach to SARS-CoV-2 “long-haulers”? Chronic Dis Transl Med. 2021;7:14–26. 47. Ibrahim Fouad G. The neuropathological impact of COVID-19: a review. Bull Natl Res Cent. 2021;45:19. 48. Reichard RR, Kashani KB, Boire NA, Constantopoulos E, Guo Y, Lucchinetti CF. Neuropathology of COVID-19: a spectrum of vascular and acute disseminated encephalomyelitis (ADEM)like pathology. Acta Neuropathol. 2020;140:1–6. 49. Solomon IH, Normandin E, Bhattacharyya S, Mukerji SS, Keller K, Ali AS, Adams G, Hornick JL, Padera RF Jr, Sabeti P. Neuropathological features of Covid-19. N Engl J Med. 2020;383:989–992. 50. Jaunmuktane Z, Mahadeva U, Green A, Sekhawat V, Barrett NA, Childs L, Shankar-Hari M, Thom M, Jäger HR, Brandner S. Microvascular injury and hypoxic damage: emerging neuropathological signatures in COVID-19. Acta Neuropathol. 2020;140:397–400. 51. Bryce C, Grimes Z, Pujadas E, Ahuja S, Beasley MB, Albrecht R, Hernandez T, Stock A, Zhao Z, Al Rasheed M, Chen J, Li L, Wang D, Corben A, Haines K, Westra W, Umphlett M, Gordon RE, Reidy J, Petersen B, Salem F, Fiel M, El Jamal SM, Tsankova NM, Houldsworth J, Mussa Z, Liu WC, Veremis B, Sordillo E, Gitman MR, Nowak M, Brody R, Harpaz N, Merad M, Gnjatic S, Donnelly R, Seigler P, Keys C, Cameron J, Moultrie I, Washington KL, Treatman J, Sebra R, Jhang F, Firpo A, Lednicky J, Paniz-Mondolfi A, Cordon-Cardo C, Fowkes ME. Pathophysiology of SARS-CoV-2: the Mount Sinai COVID-19 autopsy experience. medRxiv. 20211–12. doi: 10.1038/ s41379-021-00793-y. 52. Nauen DW, Hooper JE, Stewart CM, Solomon IH. Assessing brain capillaries in coronavirus disease 2019. JAMA Neurol. 2021:e210225. doi: 10.1001/jamaneurol.2021.0225. 291 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. Disease of the Year: COVID-19 53. Lou JJ, Movassaghi M, Gordy D, Olson MG, Zhang T, Khurana MS, Chen Z, Perez-Rosendahl M, Thammachantha S, Singer EJ, Magaki SD, Vinters HV, Yong WH. Neuropathology of COVID-19 (neuro-COVID): clinicopathological update. Free Neuropathol. 2021;2:2. 54. Matschke J, Lütgehetmann M, Hagel C, Sperhake JP, Schröder AS, Edler C, Mushumba H, Fitzek A, Allweiss L, Dandri M, Dottermusch M, Heinemann A, Pfefferle S, Schwabenland M, Sumner Magruder D, Bonn S, Prinz M, Gerloff C, Püschel K, Krasemann S, Aepfelbacher M, Glatzel M. Neuropathology of patients with COVID-19 in Germany: a post-mortem case series. Lancet Neurol. 2020;19:919–929. 55. Remmelink M, De Mendonça R, D’Haene N, De Clercq S, Verocq C, Lebrun L, Lavis P, Racu ML, Trépant AL, Maris C, Rorive S, Goffard JC, De Witte O, Peluso L, Vincent JL, Decaestecker C, Taccone FS, Salmon I. Unspecific postmortem findings despite multiorgan viral spread in COVID-19 patients. Crit Care. 2020;24:495. 56. Al-Dalahmah O, Thakur KT, Nordvig AS, Prust ML, Roth W, Lignelli A, Uhlemann AC, Happy Miller E, Kunnath-Velayudhan S, Del Portillo A, Liu Y, Hargus G, Teich AF, Hickman RA, Tanji K, Goldman JE, Faust PL, Canoll P. Acta Neuropathol Commun. 2020;8:147. 57. Wu F, Zhao S, Yu B, Chen YM, Wang W, Song ZG, Hu Y, Tao ZW, Tian JH, Pei YY, Yuan ML, Zhang YL, Dai FH, Liu Y, Wang QM, Zheng JJ, Xu L, Holmes EC, Zhang YZ. A new coronavirus associated with human respiratory disease in China. Nature. 2020;579:265–269. 58. Netland J, Meyerholz DK, Moore S, Cassell M, Perlman S. Severe acute respiratory syndrome coronavirus infection causes neuronal death in the absence of encephalitis in mice transgenic for human ACE2. J Virol. 2008;82:7264–7275. 59. Schaller T, Hirschbühl K, Burkhardt K, Braun G, Trepel M, Märkl B, Claus R. Postmortem examination of patients with COVID-19. JAMA. 2020;323:2518–2520. 60. Lee MH, Perl DP, Nair G, Li W, Maric D, Murray H, Dodd SJ, Koretsky AP, Watts JA, Cheung V, Masliah E, Horkayne-Szakaly I, Jones R, Stram MN, Moncur J, Hefti M, Folkerth RD, Nath A. Microvascular injury in the brains of patients with Covid-19. N Engl J Med. 2021;384:481–483. 61. Stoyanov GS, Petkova L, Dzhenkov DL, Sapundzhiev NR, Todorov I. Gross and histopathology of COVID-19 with first histology report of olfactory bulb changes. Cureus. 2020;12:e11912. 62. Franca RA, Ugga L, Guadagno E, Russo D, Del Basso De Caro M. Neuroinvasive potential of SARS-CoV2 with neuroradiological and neuropathological findings: is the brain a target or a victim? Acta Pathol Microbiol Immunol Scand. 2021;129:37–54. 63. von Weyhern CH, Kaufmann I, Neff F, Kremer M. Early evidence of pronounced brain involvement in fatal COVID-19 outcomes. Lancet. 2020;395:e109. 64. Nasrallah MP, Mourelatos Z, Lee EB. Neuropathology associated with SARS-CoV-2 infection. Lancet. 2021;397:277. 65. Luís ME, Hipólito-Fernandes D, Mota C, Maleita D, Xavier C, Maio T, Cunha JP, Tavares Ferreira J. A review of neuroophthalmological manifestations of human Coronavirus infection. Eye Brain. 2020;12:129–137. 66. Loon SC, Teoh SC, Oon LL, Se-Thoe SY, Ling AE, Leo YS, Leong HN. The severe acute respiratory syndrome coronavirus in tears. Br J Ophthalmol. 2004;88:861–863. 67. Aiello F, Gallo Afflitto G, Mancino R, Li JO, Cesareo M, Giannini C, Nucci C. Coronavirus disease 2019 (SARS-CoV-2) and colonization of ocular tissues and secretions: a systematic review. Eye (Lond). 2020;34:1206–1211. 68. Xia J, Tong J, Liu M, Shen Y, Guo D. Evaluation of coronavirus in tears and conjunctival secretions of patients with SARS-CoV2 infection. J Med Virol. 2020;92:589–594. 69. Zhang X, Chen X, Chen L, Deng C, Zou X, Liu W, Yu H, Chen B, Sun X. The evidence of SARS-CoV-2 infection on ocular surface. Ocul Surf. 2020;18:360–362. 70. Ho D, Low R, Tong L, Gupta V, Veeraraghavan A, Agrawal R. COVID-19 and the ocular surface: a review of transmission and manifestations. Ocul Immunol Inflamm. 2020;28:726–734. 292 71. Liang L, Wu P. There may be virus in conjunctival secretion of patients with COVID-19. Acta Ophthalmol. 2020;98:223. 72. Zhou L, Xu Z, Castiglione GM, Soiberman US, Eberhart CG, Duh EJ. ACE2 and TMPRSS2 are expressed on the human ocular surface, suggesting susceptibility to SARS-CoV-2 infection. Ocul Surf. 2020;18:537–544. 73. Casagrande M, Fitzek A, Püschel K, Aleshcheva G, Schultheiss HP, Berneking L, Spitzer MS, Schultheiss M. Detection of SARS-CoV-2 in human retinal biopsies of deceased COVID-19 patients. Ocul Immunol Inflamm. 2020;28:721–725. 74. Bayyoud T, Iftner A, Iftner T, Bartz-Schmidt KU, Ueffing M, Schindler M, Thaler S. Absence of severe acute respiratory syndrome-coronavirus-2 RNA in ocular tissues. Am J Ophthalmol Case Rep. 2020;19:100805. 75. List W, Regitnig P, Kashofer K, Gorkiewicz G, Zacharias M, Wedrich A, Posch-Pertl L. Occurrence of SARS-CoV-2 in the intraocular milieu. Exp Eye Res. 2020;201:108273. 76. Pirraglia MP, Ceccarelli G, Cerini A, Visioli G, d’Ettorre G, Mastroianni CM, Pugliese F, Lambiase A, Gharbiya M. Retinal involvement and ocular findings in COVID-19 pneumonia patients. Sci Rep. 2020;10:17419. 77. Casagrande M, Fitzek A, Spitzer MS, Püschel K, Glatzel M, Krasemann S, Nörz D, Lütgehetmann M, Pfefferle S, Schultheiss M. Presence of SARS-CoV-2 RNA in the cornea of viremic patients with COVID-19. JAMA Ophthalmol. 2021;139:383–388. 78. Marinho PM, Marcos AAA, Romano AC, Nascimento H, Belfort R Jr. Retinal findings in patients with COVID-19. Lancet. 2020;395:1610. 79. Pereira LA, Soares LCM, Nascimento PA, Cirillo LRN, Sakuma HT, Veiga GLD, Fonseca FLA, Lima VL, AbuchamNeto JZ. Retinal findings in hospitalised patients with severe COVID-19. Br J Ophthalmol. 2020.bjophthalmol2020-317576. 80. Invernizzi A, Torre A, Parrulli S, Zicarelli F, Schiuma M, Colombo V, Giacomelli A, Cigada M, Milazzo L, Ridolfo A, Faggion I, Cordier L, Oldani M, Marini S, Villa P, Rizzardini G, Galli M, Antinori S, Staurenghi G, Meroni L. Retinal findings in patients with COVID-19: results from the SERPICO-19 study. EClinicalMedicine. 2020;27:100550. 81. Landecho MF, Yuste JR, Gándara E, Sunsundegui P, Quiroga J, Alcaide AB, García-Layana A. COVID-19 retinal microangiopathy as an in vivo biomarker of systemic vascular disease? J Intern Med. 2021;289:116–120. 82. Connors JM, Levy JH. COVID-19 and its implications for thrombosis and anticoagulation. Blood. 2020;135:2033–2040. 83. Klok FA, Kruip MJHA, van der Meer NJM, Arbous MS, Gommers DAMPJ, Kant KM, Kaptein FHJ, van Paassen J, Stals MAM, Huisman MV, Endeman H. Incidence of thrombotic complications in critically ill ICU patients with COVID-19. Thromb Res. 2020;191:145–147. 84. Gawlitza M, Gragert J, Quaschling U, Hoffmann KT. FLAIRhyperintense vessel sign, diffusion-perfusion mismatch and infarct growth in acute ischemic stroke without vascular recanalisation therapy. J Neuroradiol. 2014;41:227–233. 85. Kamran S, Bates V, Bakshi R, Wright P, Kinkel W, Miletich R. Significance of hyperintense vessels on FLAIR MRI in acute stroke. Neurology. 2000;55:265–269. 86. Reinhold A, Tzankov A, Matter M, Mihic-Probst D, Scholl HPN, Meyer P. Ocular pathology and occasionally detectable intraocular SARS-CoV-2 RNA in five fatal COVID-19 cases. Ophthalmic Res. 2021 Jan 20. doi: 10.1159/000514573. Epub ahead of print. 87. Wang Y, Detrick B, Yu ZX, Zhang J, Chesky L, Hooks JJ. The role of apoptosis within the retina of coronavirusinfected mice. Invest Ophthalmol Vis Sci. 2000;41:3011– 3018. Champion et al: J Neuro-Ophthalmol 2021; 41: 285-292 Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited.