Spectrum of Myelitis in Systemic Lupus Erythematosus: Experience from a Single Tertiary Care Centre over 25 Years

Background: Inflammatory myelitis rarely occurs in Systemic Lupus Erythematosus (SLE). Methods: Medical records from a tertiary care centre in India (1989–2018) were reviewed to identify patients with myelitis in SLE and their clinical characteristics and outcomes were compared with two matching comparators drawn from adjacent hospital registration numbers in the SLE database. Results: Ten patients had myelitis from a cohort of 1768 patients with SLE. Myelitis was the first manifestation of lupus in 7 (70%). Cervicothoracic cord was most frequent site of involvement. ANA was negative at onset in 2 cases. One of 4 was positive for Anti-Aquaporin 4 antibody. Four had relapsing disease (16 events) with a median time to relapse of 0.65 years (0.3– 7 years). All cases received steroid sparing agents over the follow-up duration (78.5 patient years). Lupus nephritis (20% vs. 75%, p=0.004) and haematologic manifestations (0 vs. 25%, p=0.02) were less common. Higher frequency of anti-Ro antibodies was noted in the group with myelitis (p=0.05). Conclusion: Myelitis can be a presenting feature of SLE with lupus nephritis and hematologic involvement being rare. Relapses are common that mandate long-term immunosuppression.


Neuropsychiatric involvement in Systemic Lupus
Erythematosus (NPSLE) is a major cause of morbidity and mortality. Of the 19 distinct syndromes described under NPSLE, one is myelopathy. 1,2 Cord involvement can be attributed to demyelination, thrombosis and vasculitis specifically in SLE in addition to infective and compressive caus-es. Demyelinating syndromes (DS) in SLE have been previously attempted to be classified into Neuromyelitis Optica (NMO), Neuromyelitis Optica spectrum disorder (NMOSD), DS predominantly involving the brain, DS predominantly involving the brainstem and Clinically Isolated Syndrome (CIS). 3 The rare nature of demyelinating cord disease (<1%) along with its heterogeneity 4 has precluded a clear understating of the pathogenesis, prevalence, and clinical course in the setting of SLE. Consensus on management assumes an important role due to its potentially devastating nature, with adverse effects on the quality of life. 4,5 Data from this part of the world is lacking with respect to this regard and thus, we conducted a retrospective chart review of a large cohort of SLE with a focus on the prevalence, clinical features, and laboratory profile of myelitis in SLE and compared those with patients without myelitis.

METHODS
A retrospective chart review was conducted to screen the records of patients with Connective tissue disease (CTD) were screened to identify SLE (SLICC criteria, Figure 1). 6 Among cases with NPSLE, 1 myelitis were identified by the Transverse Myelitis Working Group criteria. 7 Their demographic details, clinical profile, laboratory markers (haemogram, clinical chemistry, cerebrospinal fluid profile, autoantibodies, inflammatory markers and complements), imaging, treatment history and outcomes were recorded till the last hospital visit. A waiver of consent was taken from the Institutional review board for retrospective review of records. Nephritis was defined as nephrotic range proteinuria or proteinuria >500mg/24 hours with active sediments with or without renal biopsy. Hematologic manifestation was defined as presence of leukopenia (<4000/cmm) and/or thrombocytopenia (<100000/cmm) and/or autoimmune haemolytic anaemia (haemolytic anaemia with Coombs positivity
Other features of SLE were seen in half of the cases at presentation (Supplementary Table 1) and notably, haematological involvement in none. ANA was negative at presentation in two, and later turned positive at 2 and 5 years respectively. Anti-Ro antibody, anti-Sm/RNP and elevated anti-dsDNA were seen in 4, 4 and 5 respectively. Four had positive antiphospholipid antibodies. NMO-IgG was tested in 4 and found positive in 1 (25%). In comparison with other patients of SLE without myelitis, Ro positivity was higher in those with myelitis (p=0.05,

Features of lupus
Features of active disease at the time of myelitis Organ system involvement due to lupus at any point in time

Myelitis in lupus was prone to relapses
Sixteen episodes of relapse occurred in 4 of the 10 (40%) women over 78.5 patient-years, with a median time to relapse of 0.65 (0.3-7) years. Relapses were constituted by myelitis, 9 ON, 6 and 1 with features of both simultaneously. High dose glucocorticoids and cyclophosphamide (CYC) were the choice of treatment in the majority with Rituximab preferred in those with relapsing disease (Supplementary Table 2). Of the 8 patients on follow up, 90% had no to minimal disability at their last follow up. The one suffering from significant disability had multiple relapses when treated with steroid monotherapy and there was a considerable delay in initiating definitive steroid sparing drug (Supplementary Table 2).

DISCUSSION
Myelitis seldom occurs in SLE although is 1000 times more common than the general population. 12 We found a prevalence of 0.56% in 1768 patients of lupus similar to other recent studies. 13 They had presentations with motor, sensory and/or bladder bowel involvement in varying combinations with most common site of involvement being the cervicothoracic cord. A significant proportion (40%) had a relapsing course reiterating the importance of maintenance immunosuppression.
Myelitis can be the first manifestation of SLE as seen in 7 patients (70%) in our case series, even before disease manifests elsewhere which was also observed in other series. 14 These patients were significantly less likely to have nephritis and haematologic manifestations making the diagnosis particularly challenging. 14 Since patient with such features are likely to present to the neurologist it is important to suspect and rule out underlying autoimmune disease. At times autoantibody positivity can be the only sign of underlying SLE which may evolve into clinical lupus with time as seen in 2 of our patients. It is pertinent to note that in this series, ANA was negative at the outset in 2 cases and the autoantibody positivity evolved with time. It is now well known that autoimmunity precedes clinical disease. Cohorts of pre-lupus have very well described the evolution of autoantibodies from anti-Ro to anti-ds DNA and later anti-Sm due to epitope spreading. Along with clinical features, the antibody profile can also evolve with time. Thus, it is important to observe these individuals over time, as manifestations of another organ involvement may appear later. Anti Ro antibody was more commonly seen in those with myelitis as seen in other cohorts. 15 Antiphospholipid antibody is also commonly reported in patients with myelitis (40% in our series) and it may be associated with LM, however none of them had other clinical features of antiphospholipid antibody syndrome. 4 CSF analysis revealed elevated protein in 5 of 9 and lymphocytosis in 2 of 9. CSF in NMOSD is characterized by lymphocytic pleocytosis, however, it was not observed in our cohort. Prevalence of CSF pleocytosis varies TITLE widely in NMOSD, ranging from 14 to 79 percent. 16,17 In addition, CSF changes are dynamic and often related to disease activity. False negatives for CSF pleocytosis can also result from very early CSF examination, erroneous sample handling or delayed processing. Probably, one of these could be the reason for the discrepancy. Further, we found that 5 (50%) of our patients could be classified into NMOSD. 10 NMOSD overlap can occur in patients with other autoimmune diseases, the most common being SLE. Data on myelitis in the setting of other rheumatic disorders has been detailed in Supplementary  Table 3. 13,18,19 The other series shows female preponderance, although patients were younger in our series. LM was seen in most cases, but ON was higher in the case series from Tianjin. This could be due to routine Visual Analogue Potential testing in that cohort. Petri et al. have classified cord involvement into white matter and gray matter disease. 4 It is important to note that although all cases improved with high dose glucocorticoids, a large proportion relapsed on follow-up, highlighting the need for steroid sparing immunosuppressants. 14 Myelitis is treated by various drugs and regimens with an induction and maintenance phase. Induction can be done with pulse methylprednisolone (1000mg intravenously for 3-5 days); however, if the initial response is inadequate then plasmapheresis may be considered. 20 25 Thus, RTX is emerging as first line steroid sparing agent in NMO. 23 It seems likely that it would work as well in NMO-SD too. Monthly CD 27 monitoring can identify short term responders to RTX as described by Ciron et al. in recommendations for the use of Rituximab in NMOSD. 26 Recent reports suggest successful use of Eculizumab (monoclonal antibody against C5a) and Inebilizumab (previously known as MEDI-551), a CD19 monoclonal antibody in NMOSD. 27,28 This case series fills important lacunae in existent knowledge of myelitis in the setting of lupus, and offers novel insights for the rheumatologist and neurologist alike. It also suggests that evolution of disease and autoantibody profile could vary, and a high index of suspicion for lupus adds greatly to diagnosis and successful therapy. The study has the disadvantages inherent to any retrospective analysis. Further, anti-aquaporin antibody was not tested in all cases. Also, cases were recruited from the rheumatology department, and possibly cases presenting to neurology department could have been missed. Thus, demyelinating syndromes can be the first manifestation of lupus. Although NMOSD is the most common form, CIS can also be seen in setting of lupus. Lupus nephritis and hematologic manifestations are less common, and ANA can be negative in lupus with myelitis making the diagnosis challenging at times. The disease should be aggressively treated with cyclophosphamide or rituximab followed by maintenance immunosuppression to prevent disability.