key: cord-0779456-s0x06z42 authors: Kovalev, Dmitri; Thottempudi, Neeharika; Ahmed, Adil; Shanina, Elena title: New-onset Neuromyelitis Optica Spectrum Disorder in a Patient with COVID-19 and Chronic Hepatitis B Co-infection date: 2022-01-11 journal: Neuroimmunology Reports DOI: 10.1016/j.nerep.2022.100063 sha: 4b4fc1c60d15e3985e89ae2be3ec93499da5783e doc_id: 779456 cord_uid: s0x06z42 Background Neurological autoimmune disorders are often triggered by bacterial and viral infections, with growing evidence supporting coronavirus disease 2019 (COVID-19) infection precipitation of these disorders. COVID-19 is already implicated in causing discrete para-infectious neurological syndromes: acute disseminated encephalomyelitis (ADEM), transverse myelitis, neuromyelitis optica spectrum disorders (NMOSD), Guillain-Barré syndrome (GBS), and is also associated with encephalopathy, acute cerebrovascular disease, neuromuscular disorders, and seizures. Case Presentation We describe a case of a 43-year-old Asian woman with chronic Hepatitis B (HBV) co-infected acutely with COVID-19, presenting with urinary retention, bilateral blindness, thoracic sensory level, and quadriparesis. Extensive workup narrowed down her diagnosis as seronegative NMOSD. She had complete resolution of symptoms after treatment with concurrent plasma exchange (PLEX), high dose corticosteroids, and emtricitabine-tenofovir. Follow-up visit showed no seroconversion at 6 months and no relapses. Conclusions Our literature review highlights the likely link between COVID-19 infection and the development of neurologic autoimmune diseases. Our literature review supports a virus-triggered immune-mediated process rather than neuro-invasion. Many viral illnesses have been linked to the development of NMOSD and anti-AQP4 antibody-related myelitis. Additionally, there is limited literature linking chronic HBV infection with the development of optic neuritis and speculation thatcross-reactivity between HBsAg and myelin antigens may lead to the development of demyelinating diseases in the CNS and PNS. We observed remarkable clinical improvement after treatment with alternating days of IV methylprednisolone and therapeutic PLEX. The pathogen causing the outbreak of coronavirus disease 2019 (COVID-19) is termed "severe acute respiratory syndrome coronavirus 2" (SARS-CoV-2) and has been implicated in causing many para-infectious neurological syndromes: acute disseminated encephalomyelitis (ADEM), transverse myelitis, neuromyelitis optica spectrum disorders (NMOSD) and Guillain-Barré syndrome (GBS) (1) . In a recent systematic review, patients with COVID-19 were found to have various patterns of brain and spinal cord demyelination resembling autoimmune neurologic disorders. (2) The pathophysiology of COVID-19 neurological involvement is not clearly established. There is abundant skepticism of the view that COVID-19 directly enters the CNS by retrograde axonal transport mechanisms of the olfactory nerve or other cranial nerves. (3, 4) Substantial evidence suggests COVID-19 causes a "cytokine storm" with proinflammatory cytokines, including IL-1β, IL-2, IL-4, IL-6, IL-8, IL-10, TNF-α, and IFN-γ that may cross the blood-brain barrier. (2) In this manner, the innate immunity mediators of the CNS such as macrophages, microglia, and astrocytes can be affected. Outside the CNS, hyperactivation of proinflammatory T cells, lymphopenia, decreased activity of regulatory T cells may also lead to antibody-mediated damage to the CNS and PNS. Currently, there is insufficient evidence to demonstrate a strong association between chronic Hepatitis B (HBV) infection and the development of NMOSD. Based on our literature review, COVID-19 is highly immunogenic and is the most likely trigger for demyelination seen in our patient. A previously healthy 43-year-old Vietnamese woman presented to the hospital with one week of urinary retention and progressive severe bilateral vision loss. Review of systems was otherwise unremarkable. She denied recent infections, travel, or trauma. On admission, she required catheterization for urinary retention, and her visual acuity was reduced to finger counting, with bilateral loss of color vision. The fundoscopic exam showed mild bilateral disc edema. Otherwise, her cognitive, cranial nerve, motor, cerebellar and sensory examinations were initially normal. She tested positive for nasopharyngeal RAPID PCR for COVID as part of our hospital protocol and expressed positive serum IgM and IgG SARS-CoV-2 antibodies. However, she continued to be afebrile, free of respiratory symptoms or signs of infection. Her neurological deficits rapidly progressed in the following 2 days. Her cognition remained intact with no encephalopathy, cranial nerves were normal except for complete vision loss in both eyes, including loss of light perception, pain with extraocular eye movements. She developed bilateral lower extremity and truncal sensory loss moving up to T4-5 to pinprick and temperature as well as quadriplegia with 0/5 strength in lower extremities on the MRC scale, 1/5 strength in upper extremities, areflexia throughout. Initial cervical spine MRI was unremarkable. Brain MRI showed a large tumefactive, contrastenhancing lesion in the right temporal lobe and multiple small T2 hyperintensities with enhancement in the frontal, parietal, cerebellar regions, all suggestive of demyelination. Considering rapid neurological decline, MRI cervical spine was repeated 2 days later demonstrating cord edema and longitudinally extensive T2 hyperintensities throughout the cervical and thoracic cord with patchy enhancement. Additionally, MRI of the orbits showed enhancement of the bilateral optic nerve sheath complexes indicative of optic perineuritis. (Fig 1) . Diagnostic lumbar puncture showed mild CSF pleocytosis with 27 WBC's, protein of 49 mg/dL, glucose of 46 mg/dL. We did not check for SARS-CoV-2 in the CSF. Oligoclonal bands were absent. Aquaporin-4 receptor (AQP4) and Myelin Oligodendrocyte Glycoprotein (MOG) antibodies were both negative, tested by indirect fluorescent antibody assay utilizing full-length transfected cell lines. Additional tests for viral meningitis/encephalitis panel, West Nile virus, Brucellosis, Tuberculosis, Neurosyphilis, Lyme disease were negative. Laboratory results revealed a normal blood count and liver enzymes, with unremarkable serologies, including ANA, histone antibodies, SSA, SSB, RF. She was also negative for HIV, Hepatitis A and C. Nerve conduction studies (NCS) of the upper and lower extremities were normal, including F-waves. Our patient was an asymptomatic chronic Hepatitis B carrier with the following serology: Hepatitis B surface (HBs) antigen positive, HBs antibody negative, Hepatitis B core (HBc) antibody positive (unspecified if IgM or IgG), Hepatitis B envelope (HBe) antigen negative and HBe antibody positive. She denied recent travel, history of intravenous drug use, tattoos, unprotected sexual intercourse. There was no transaminitis and no laboratory evidence of liver dysfunction throughout the admission. Initially, we found a low detectable, non-quantifiable level of HBV on quantitative assay by NAAT. Due to our plan to treat her with high-dose steroids, she was at increased risk for HBV reactivation, therefore we started antiviral therapy with tenofovir & emtricitabine (Truvada) to prevent an HBV flare. She continued to have normal liver enzymes and repeat testing for HBe antigen was negative. On 4-month follow-up, quantitative HBV assay by NAAT increased to 1311 IU/ml with no other lab abnormalities. Based on clinical and neuroimaging findings of bilateral optic neuritis, longitudinally extensive transverse myelitis, atypical supratentorial and infratentorial demyelinating lesions, she was diagnosed with double seronegative NMOSD. She was treated with concurrent therapeutic plasma exchange (PLEX) and intravenous 1g methylprednisolone on alternating days for a total of 5 sessions each. At the same time, antiviral therapy with tenofovir & emtricitabine was initiated to prevent Hepatitis B reactivation. Upon completion of treatment, her strength in the upper extremities normalized to 5/5 and in the lower extremities improved to 4/5. Color vision returned and visual acuity improved to 20/30. She still had mild residual sensory changes in the distal legs and required self-catheterization for remaining urinary retention. She was discharged home on an oral prednisone taper. After one month, her urinary retention resolved, her strength improved, and she returned to full-time work without limitations. At the 6-month follow-up, her exam showed intermittent bilateral lower extremity paresthesias and generally brisk reflexes. She did not show seroconversion on repeat testing of serum AQP4 and MOG antibodies via cell assays. Repeat MRI showed resolution of the spinal cord and optic nerves lesions, having only a small residual T2 hyperintensity in the right temporal lobe without enhancement. Our patient fulfilled MRI requirements for NMO on repeat imaging with posterior optic nerve T1-weighted gadolinium enhancing lesions extending over more than one-half the optic nerve length and involving the optic chiasm, intramedullary lesion extending over ≥3 contiguous segments in the spinal cord, (5) demyelinating white matter lesions, although negative for AQP4 antibodies on initial and follow-up testing. It is known that Hepatitis B vaccinations are not causally associated with the development of MS or optic neuritis. (6) Despite one study of 10 patients with chronic HBV and seropositive NMOSD hypothesizing a cross-reactivity between HBsAg and myelin proteins, we believe there is currently insufficient evidence to suggest that chronic HBV increases the risk for developing a demyelinating disorder. (7) COVID-19 is far more likely to be an immunological trigger to developing autoimmune neurological disorders. A few case reports have suggested the potential for COVID-19 to reactivate HHV-6, HHV-7, and EBV. (8, 9, 10) The risk of HBV reactivation in the setting of COVID-19 co-infection is low; however, this risk is increased with rituximab, high-dose corticosteroids, anthracyclines, and potent TNF-alfa inhibitors. (11) In one study, 3 patients with chronic HBV have seen a re-activation after infection with COVID-19. (12) Two of these reactivations were thought to be secondary to high dose methylprednisolone, with one unexplained. It is recommended to trend HBV-DNA quantitatively and to use antivirals such as Entecavir or Tenofovir before immunosuppressive treatment in COVID-19 patients with chronic hepatitis B. We performed a PubMed and Google scholar database search using keywords COVID-19, NMOSD, ADEM, myelitis, optic neuritis, from December 2020 to May 2021. We found 23 case reports of COVID-19 associated optic neuritis and myelitis (see "Table 1" in appendix). Most patients had no significant past medical history, with ages ranging 15 -70 years old: 12 male (52.2%), 11 female (47.8%). Myelitis was the predominant finding present in 86.9% (20/23) of cases. The average time from COVID-19 infection to neurological symptoms was between 2-14 days. One patient had only clinical evidence of myelitis, MRI spine was negative. (13) Various treatment regimens were tried: IV steroids, PLEX, IV steroids alternating with PLEX, or intravenous immunoglobulin (IVIG) followed by steroids. IV steroids alone were the most effective treatment. Out of 16 patients tested, 3 were positive for AQP4 antibody and had longitudinally extensive transverse myelitis (LETM). MOG antibody was positive in 2 patients, both with bilateral optic neuritis. There were 2 reported cases of myelitis with coexistent acute motor axonal neuropathy (axonal GBS variant); one had positive anti-GD1B antibody in serum. (14, 15) Although the results of nerve conduction studies in our patient were normal, it is important to rule out co-existing acute peripheral nerve involvement which would alter management. From our literature review, CSF PCR for COVID-19 was obtained in 13 patients out of 23 and all of them tested negative. This supports the theory of immune-mediated mechanisms rather than direct neuro-invasion of the virus. Although long-term outcomes in COVID-19 associated demyelinating disorders are unknown, early recognition of these disorders and prompt treatment is critical for reducing morbidity. Table 1 abbreviations: "BL" bilateral, "LETM" longitudinally extensive transverse myelitis, "PLEX" plasma exchange, "+" positive, "-" negative. None. Neurologic complications of COVID-19 Association of CNS demyelination and COVID-19 infection: an updated systematic review Covert Pathways to the Cranial Cavity: Could These Be Potential Routes of SARS-CoV-2 to the Brain? 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