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. 2021 Feb 16:204394. doi: 10.1148/radiol.2021204394

Ocular MRI Findings in Patients with Severe COVID-19: A Retrospective Multicenter Observational Study

Augustin Lecler 1,, François Cotton 1, François Lersy 1, Stéphane Kremer 1, Françoise Héran 1; on behalf of the SFNR’s COVID Study Group1
PMCID: PMC7887777  PMID: 33591889

ABSTRACT

COVID-19 may affect various organs. This paper reports 9 patients (1/9 [11%] woman and 8/9 [89%] men, mean age 56 ± 13 years) with globe MRI abnormalities obtained from a multicenter cohort of 129 patients presenting with severe COVID-19 from March 4th to May 1st, 2020. 9/129 (7%) patients had one or several FLAIR-WI hyperintense nodules of the posterior pole of the globe. All patients had nodules in the macular region, 8/9 (89%) had bilateral nodules, 2/9 (22%) had nodules outside the macular region. Screening of these patients might improve the management of potentially severe ophthalmological manifestations of the virus.

See also the editorial by Kirsch.

Keywords: MRI, Orbit, COVID-19, SARS-CoV-2

INTRODUCTION

COVID-19 is a pandemic infection caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), negatively affecting various organs such as the central nervous system(1,2). COVID-19 has been reported to be associated with ophthalmological abnormalities, such as conjunctivitis, chemosis, retinopathy or optic neuritis(37). MRI orbital abnormalities have been reported but no MRI studies have been published about globe abnormalities to the best of our knowledge(810).

This paper reports a series of patients with severe COVID-19 presenting with abnormal MRI findings of the globe.

MATERIAL AND METHODS

Study design and population

This retrospective observational multicenter study was initiated by the French Society of Neuroradiology (SFNR). It included clinical and imaging data of consecutive patients presenting with severe COVID-19 who underwent brain MRI from 16 hospitals including 11 university hospitals and 5 general hospitals from March 4th to May 1st 2020. The study was approved by the ethical committee of Strasbourg University Hospital (CE-2020-37)

Clinical, ophthalmological, virological and imaging data

Clinical and ophthalmological data were extracted from the patients’ electronic medical records. Virological assessment was made with quantitative real-time RT-PCR tests for SARS-CoV-2 nucleic acid performed on nasopharyngeal or lower respiratory tract swabs and cerebrospinal fluid. Imaging studies were conducted either on 1.5- or 3-Tesla MRI.

MRI Analysis

MRI examinations were anonymized and analyzed by two neuroradiologists with 9 years (“blinded”) and 30 years (“blinded”) of experience in ophthalmological imaging.

RESULTS

Study Population

A total of 129 patients (43/129 [33%] women and 86/129 [67%] men, mean age 63 ± 14 years) was included for analysis from March 4th to May 1st 2020 (Figure 1). Among them, 9/129 (7%) patients (1/9 [11%] woman and 8/9 [89%] men, mean age 56 ± 13 years) had abnormal MRI findings of the globe consisting in the presence of one or several nodules of the posterior pole of the globe. 2/9 (22%) patients had diabetes, 6/9 (67%) were obese, 2/9 (22%) had hypertension and none of them had asthma.

Figure 1:

Flow chart. MRI=Magnetic Resonance Imaging.

Flow chart. MRI=Magnetic Resonance Imaging.

8/9 (89%) patients were hospitalized in intensive care unit (ICU) with severe COVID. All ICU patients presented with acute respiratory distress syndrome, with a median Simplified Acute Physiology Score (SAPS II) of 45 (IQR 18.5). All ICU patients were intubated on high-flow supplementary oxygen, curarized and sedated. 7/9 (78%) patients were placed in the prone position. 1/9 (11%) was placed on extracorporeal membrane oxygenation. 3/9 (33%) patients were put on dialysis. Median duration of hospitalization in ICU was of 17 (IQR 7] days.

6/9 (67%) patients underwent brain MRI due to delayed awakening despite discontinuation of sedation, 2/9 (22%) due to persisting agitation and confusion after awakening and 1/9 (11%) for agitation and hallucinations.

MRI findings

The nodules of the posterior pole of the globe were all hyperintense on FLAIR-WI, isointense on T1-WI and showed no enhancement after gadolinium injection. No abnormal susceptibility was seen on susceptibility-weighted images. All 9/9 (100%) patients had nodules in the macular region, 8/9 (89%) had bilateral nodules, 2/9 (22%) had nodules outside the macular region (figure 2).

Figure 2:

56-year-old man presenting with severe COVID-19. Diagnosis of SARS-CoV-2 infection was based on a positive quantitative real-time RT-PCR test for SARS-CoV-2 nucleic acid performed on nasopharyngeal and lower respiratory tract swabs. The patient had been hospitalized in intensive care unit for 20 days when an MRI was performed due to delayed awakening despite discontinuation of sedation. He presented with acute respiratory distress syndrome, with a median Simplified Acute Physiology Score (SAPS II) of 45. He was intubated on high-flow supplementary oxygen and placed in the prone position. A, B, 3D FLAIR-weighted MRI reformatted in the axial plane showing several hyperintense nodules of the posterior pole of the globe located in the macular region (white arrowhead) and the extramacular region (black arrowheads). Note the presence of a focal temporal retinal detachment of the left eye (arrow).

56-year-old man presenting with severe COVID-19. Diagnosis of SARS-CoV-2 infection was based on a positive quantitative real-time RT-PCR test for SARS-CoV-2 nucleic acid performed on nasopharyngeal and lower respiratory tract swabs. The patient had been hospitalized in intensive care unit for 20 days when an MRI was performed due to delayed awakening despite discontinuation of sedation. He presented with acute respiratory distress syndrome, with a median Simplified Acute Physiology Score (SAPS II) of 45. He was intubated on high-flow supplementary oxygen and placed in the prone position. A, B, 3D FLAIR-weighted MRI reformatted in the axial plane showing several hyperintense nodules of the posterior pole of the globe located in the macular region (white arrowhead) and the extramacular region (black arrowheads). Note the presence of a focal temporal retinal detachment of the left eye (arrow).

2/9 (22%) patients had diffuse extensive white matter hyperintense lesions on FLAIR-WI, with restricted diffusion, without post-contrast enhancement and disseminated multiple microhemorrhages on SWI. 2/9 (22%) had diffuse non-confluent multifocal white matter hyperintense lesions on FLAIR-WI without restricted diffusion nor post-contrast enhancement. 1/9 (11%) had multiple infarcts in the anterior cerebral artery territory. 1/9 (11%) had a frontal hematoma. 1/9 (11%) had multiple microhemorrhages of the splenium of the corpus callosum. 1/9 (11%) had leptomeningeal enhancement without parenchymal abnormalities. Brain MRI was unremarkable for 1/9 (11%) patient. 5/9 (56%) patients had bilateral fluid filling of the mastoid cells. No patient had optic nerve, optic chiasm or optic tract abnormalities.

Correlations between MRI and ophthalmological findings

3/9 (33%) patients had a fundoscopy showing no abnormality of the posterior pole. 1/9 (11%) had an OCT showing no abnormality. 1/9 (11%) had an occlusion of a central retinal artery branch on fluorescein angiography. 1/9 (11%) presented with keratitis of the left eye.

DISCUSSION

This paper reports a series of patients with severe COVID-19 presenting with abnormal MRI findings of the globe. This study showed that 7% of patients with severe COVID-19 presented with one or several nodules of the posterior pole of the globe. This rate is in line with the prevalence of 5.5% of ocular manifestations among COVID-19 patients reported in a recent meta-analysis(3). Patients affected by severe COVID-19 were reported to be more at-risk to develop ocular manifestations (4,11,12).

Nodules were mostly bilateral and were located in the macular region in all cases, in association with extra-macular nodules in 22% of the cases. These nodules were not visible in the 3 patients who underwent ophthalmological examination. This might be due to a lack of sensitivity of the clinical examination, which was difficult to perform in patients with severe COVID-19 or to the delay between the completion of the MRI examination and the ophthalmological examination.

No retinal involvement could be detected on fundoscopy in a single retrospective series of severe COVID-19 patients(13). However, viral RNA of SARS-CoV-2 has been reported to be detectable in the retina of deceased COVID-19 patients. Moreover, three recent reports showed that retinal findings, such as hemorrhages, cotton wool spots, dilated veins, or tortuous vessels, could be possibly associated with COVID-19 infection in humans(1416). Two studies displayed findings from the OCT, which is a more sensitive tool than fundoscopy(14,15). They reported hyper-reflective lesions at the level of ganglion cell and inner plexiform layers on OCT, as well as the presence of cotton wool exudates which are markers of vascular disease severity. Interestingly, these abnormalities were more prominent at the papillomacular bundle in both eyes, which was also the preferential location for the nodules visible on MRI in our study. Only one of our patients with a macular nodule underwent OCT, showing no abnormal findings.

Although the nature of these nodules remains unknown, several hypotheses might be considered since human and animal coronaviruses were reported to cause inflammation of varying ocular segments, causing retinitis, choroiditis, retinal detachment or optic neuritis in the literature(17,18). A wide variety of mechanisms have been described, such as direct infiltration of the retina and retina pigment epithelium by the virus, vasculitis, or autoimmune process, the latter mechanism being more frequent to explain retinal damages(17). The onset of an ocular microangiopathic syndrome is highly prevalent after viral infections. SARS-Cov-2 is known to target the angiotensin-converting enzyme-related carboxypeptidase (ACE2) receptor, which is largely expressed in the retina and the choroid. ACE2 is the primary enzyme of the vasoprotective axis of the renin–angiotensin system in the retina(19). Its downregulation might induce the development of retinal ischemia(15). Another possible hypothesis is a Valsalva retinopathy secondary to orbital proptosis which can occur when the ocular venous system is affected by the increased central venous pressure, leading to an inadequate ocular venous drainage. This situation can occur in patients hospitalized in intensive care units, especially those in the prone position or intubated, which was the case for almost all our patients with severe COVID-19(20,21).

In clinical practice, our study suggests that a dedicated exploration of the globes with high resolution 3D T2-WI and post-contrast fat-suppressed T1-WI MRI, as well as fundoscopy and OCT, should be considered in all patients presenting with severe COVID-19 to detect posterior pole nodules. Severe eye problems might largely go unnoticed as these patients are often treated in intensive care units for much more severe, life-threatening conditions. Our data support the need for a screening and follow-up of these patients to provide appropriate treatment and improve the management of potentially severe ophthalmological manifestations.

Our study suffers from several limitations. Firstly, it is a retrospective study with a limited number of patients and no control group. Secondly, we analyzed ocular abnormalities on brain MRI performed in patients with severe COVID infections. Dedicated ocular MRI sequences, especially high-resolution MRI sequences, were not available, preventing a precise description and understanding of ocular abnormalities. Thirdly, ophthalmological data were missing for the majority of our patients, because no systematic ophthalmological examination was performed in our patients with severe COVID-19 hospitalized in intensive care unit, thus clinical-radiological correlations were limited. Fourthly, no ocular or conjunctival sampling for detection of SARS-CoV-2 was available, thus it is impossible to assess the direct causality of the virus in our findings. We do not know whether a high viral load was linked to more severe ophthalmological findings. Fifthly, pathologic material was lacking. Finally, we lacked follow-up data to assess whether the MRI abnormalities were transient or not and their consequences on visual acuity.

CONCLUSION

This paper reports a series of patients with severe COVID-19 presenting with abnormal MRI findings of the globe. Screening of these patients might be suitable to provide appropriate treatment and improve the management of potentially severe ophthalmological manifestations.

Acknowledgments

Acknowledgement

Laura McMaster provided professional English-language medical editing of this article.

Footnotes

Abbreviations and Acronyms:

MRI
Magnetic Resonance Imaging
SARS-CoV-2
Severe Acute Respiratory Syndrome CoronaVirus 2
OCT
Optical Coherence Tomography
FLAIR
Fluid-attenuated inversion recovery
RT-PCR
Reversetranscriptase-polymerase chain reaction

Contributor Information

Augustin Lecler, Email: alecler@for.paris.

Collaborators: Helms Julie, Meziani Ferhat, Collange Olivier, Mertes Paul Michel, Fafi-Kremer Samira, Lefebvre Nicolas, Hansmann Yves, Pottecher Julien, Schenck Maleka, Schneider Francis, Bonneville Fabrice, Adam Gilles, Martin-Blondel Guillaume, Pariente Jérémie, Geeraerts Thomas, Ferré Jean-Christophe, Maamar Adel, Carsin-Nicol Béatrice, Colmar Oesterlé Hélène, Bolognini Federico, Messie Julien, Hmeydia Ghazi, Benzakoun Joseph, Oppenheim Catherine, Constans Jean-Marc, Metanbou Serge, Heintz Adrien, Bapst Blanche, Megdiche Imen Marie- Cécile, Henri Feugeas Henri Feugeas, Khalil Antoine, Gaudemer Augustin, Jager Lavinia, Nesser Patrick, Talla Mba Yannick, Hemmert Céline, Feuerstein Philippe, Sebag Nathan, Carre Sophie, Alleg Manel, Lecocq Claire, Schmitt Emmanuel, Anxionnat René, Zhu François, Comby Pierre-Olivier, Ricolfi Frederic, Thouant Pierre, Grand Sylvie, Krainik Alexandre, Forestier Géraud, de Beaurepaire Isaure, Bornet Grégoire, Lacalm Audrey, Pique Julie, Boutet Claire, Fabre Xavier, Desal Hubert, Berge Jérome, Boulouis Grégoire, Kazemi Apolline, Pyatigorskaya Nadya, Lecler Augustin, Saleme Suzana, Edjlali-Goujon Myriam, Kerleroux Basile, Brisset Jean-Christophe, Zorn Pierre-Emmanuel, Matthieu Muriel, Chenaf Samir, Savatovsky Julien, and Duron Loïc

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