Immune-mediated neurological syndromes in SARS-CoV-2-infected patients

A broad spectrum of neurological symptoms occurring during coronavirus disease 2019 (COVID-19) infection, such as anosmia, headache, impaired consciousness, cerebrovascular disease and skeletal muscle injury, have been promptly reported [1]. Since then, two cases of possible encephalitis and para- or post-viral immune-mediated polyneuropathies, including one case associated with the presence of anti-GD1b IgG antibodies have been described in COVID-19 patients [2‐5]. However, little is known about the immune-mediated neurological syndromes associated with severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) infection. Recent studies reported almost no evidence of CSF inflammation in severely affected COVID-19 patients [6, 7]. Only a few cases have been reported with positive SARS-CoV-2 PCR in CSF [8]. In this pilot study, we describe the neurological manifestations, serological and CSF findings of SARS-CoV-2-infected patients.

From March 23rd through April 24th 2020, consecutive COVID-19 positive patients with neurological manifestations were prospectively enrolled at Cliniques universitaires Saint-Luc (Brussels, Belgium) and affiliated hospitals (CHU UCL Namur site Godinne and Clinique Saint-Pierre Ottignies). A positive diagnosis of COVID-19 infection was established either by SARS-CoV-2 PCR assay of nasopharyngeal swabs or a positive SARS-CoV-2 IgG serology.

Patients were not included if (1) neurological presentation was isolated anosmia and/or non-severe headache (as these symptoms were considered to be not sufficiently suggestive of CNS involvement), and (2) they had a history of previous neurological or psychiatric disorders (to avoid the confounding factor of a fortuitous exacerbation). All patients underwent neurological examination. Serum anti-gangliosides antibodies (anti-GM1, anti-GM2, anti-GD1a, anti-GD1b and anti-GQ1b IgG) were initially tested in patients with suspicion of peripheral nerve involvement, and then systematically in subsequent patients with ataxia or features suggestive of brainstem involvement; only high-titer IgG (> 1/100) are reported here. Onconeuronal antibodies (anti-Tr, anti-GAD65, anti-Zic4, anti-Titin, anti-SOX1, anti-recoverin, anti-Hu, anti-Yo, anti-Ri, anti-Ma2/Ta, anti-CV2/CRMP5, anti-amphiphysin) and anti-neuronal antibodies (anti-NMDAR, anti-LGI1, anti-CASPR2, anti-GABARB1, anti-DPPX, anti-AMPAR) were tested when encephalitis was suspected. Lumbar puncture (LP) with CSF study was performed in all patients, when not contraindicated. Brain imaging and serological workup were acquired according to the clinical care needs of patients. Patients were categorized as having severe or non-severe COVID-19 infection, as previously described [1]. All patients were treated with hydroxychloroquine for 6 days according to institutional guidelines. The study was approved by the local ethics committee of each medical center and informed consent was obtained from all subjects/next-of-kin.

In agreement with the available literature, our study confirms that viral genome is frequently undetectable by PCR in the CSF of SARS-CoV-2-infected patients [1]. However, we found CSF patterns consistent with blood-CSF barrier dysfunction and meningeal inflammation, such as elevated Qalb and/or lymphocytic pleocytosis.

We observed CSF lymphocytic pleocytosis in two cases: one with anti-Caspr2-associated limbic encephalitis and the other with para-infectious polyradiculitis. Autoimmune encephalitis (such as anti-NMDAR encephalitis) can occur following herpes simplex virus infection [9]. However, the pathophysiological role of viral infections in limbic encephalitis remains controversial. Noteworthily, in our SARS-CoV-2-positive patient with anti-Caspr2-associated encephalitis, no evidence of direct CNS infection nor underlying neoplasm was present. Autoimmune encephalitis was suspected in two other patients with neuropsychiatric symptoms and/or seizure but could not be proven. Para- or post-infectious polyradiculitis have been described in COVID-19 patients, but never associated with significantly increased CSF WBCs [2, 3]. In this context, our patient’s CSF pleocytosis, surprisingly associated with the presence of anti-GD1b IgG antibodies, clinical-imaging evidence of multiple cranial nerves and cauda equina inflammation suggest an immune reaction triggered by SARS-CoV-2.

Two COVID-19 patients with unexplained coma had clinical features highly suggestive of brainstem involvement associated with flaccid tetraplegia, suggesting potential concomitant peripheral nerve involvement. In both, LP demonstrated mild blood-CSF barrier dysfunction without pleocytosis. Serum anti-GD1b IgG were detected in one patient, a finding described in patients with Bickerstaff brainstem encephalitis and COVID-19-associated Miller Fisher syndrome [3, 10].

Interestingly, three patients in our study had high-titer serum IgG antibodies targeting the GD1b ganglioside. However, clinical presentations were highly variable, including cranial neuropathy with meningo-polyradiculitis, brainstem encephalitis and delirium with akathisia, choreiform involuntary movements, raising the question of whether these are truly pathogenic in all cases. GD1b is one of the most represented gangliosides in nerve tissues, but has been less studied than its GQ1b and GM1 counterparts [10]. Anti-GD1b antibodies have been described in the clinical spectrum of Guillain–Barré syndrome, Miller Fisher syndrome and Bickerstaff brainstem encephalitis, and are associated with more severe disease and slower recovery [11, 12]. More recently, anti-GD1b IgG antibodies were reported in a COVID-19 patient with Miller Fisher syndrome [3]. How anti-ganglioside autoimmunity arises in SARS-CoV-2 infection remains unclear. Structural and molecular modelling studies suggest that SARS-CoV-2 binds to respiratory tract gangliosides through its spike protein [13]. This association between COVID-19 and anti-GD1b-mediated autoimmunity has potential therapeutic implications (i.e., corticotherapy, intravenous immunoglobulins, plasmapheresis).

Three patients in our study had acute cerebrovascular disease associated with normal CSF findings or only mild blood-CSF barrier dysfunction. Whether stroke in COVID-19 patients may be partially immune-mediated is debatable. A recent case report described the presence of antiphospholipid antibodies in a SARS-CoV-2 infected patient with multifocal ischaemic stroke, even though a possible causative role remains uncertain [14].

This study has some limitations. First, our cohort size is rather small, therefore precluding a robust evaluation of the incidence of each presented neurological syndrome and CSF findings. Furthermore, the etiopathological role of SARS-CoV-2 in the observed neurological manifestations and laboratory abnormalities cannot be assessed. It cannot be excluded that some of the observed neurological syndromes, such as encephalopathy, may have resulted at least in part from our patients’ comorbidities. Such a confounding causality could only be demonstrated by pathological analysis.

In conclusion, our data suggest that CSF lymphocytic pleocytosis and/or blood-CSF barrier dysfunction is associated with para-infectious encephalitis and polyradiculitis in SARS-CoV-2 infected patients. Anti-GD1b and anti-Caspr2 autoantibodies can be identified in certain cases, raising the question of SARS-CoV-2-induced secondary autoimmunity [15]. In clinically relevant presentations, a thorough screening for autoantibodies should be initiated, as this may lead to therapeutic implications in some patients.