MOGAD: Diagnosis & Clinical Features

Myelin oligodendrocyte glycoprotein antibody-associated disease (MOGAD) is a distinct antibody-mediated CNS demyelinating disorder that differs from both multiple sclerosis (MS) and aquaporin-4 antibody-positive neuromyelitis optica spectrum disorder (AQP4-NMOSD) in pathophysiology, clinical features, treatment response, and prognosis. MOGAD was formally defined as a separate disease entity with the publication of the 2023 International MOGAD Panel diagnostic criteria, establishing standardized requirements for antibody testing, clinical phenotypes, and supporting features.

Bottom Line

  • Pathophysiology: MOG-IgG causes reversible demyelination with preservation of astrocytes (unlike AQP4-NMOSD astrocytopathy); less efficient complement activation than AQP4-IgG
  • Demographics: Equal sex ratio in adults (unlike MS and AQP4-NMOSD); bimodal age distribution with peaks in childhood and 30–50 years
  • Core phenotypes: Optic neuritis (most common), myelitis, ADEM, brainstem syndrome, cerebral cortical encephalitis, and cerebral monofocal/polyfocal deficits
  • Diagnosis: Requires MOG-IgG positivity by cell-based assay (CBA only — other assays not accepted) plus ≥1 core clinical manifestation; clear positivity vs. low-positive titers have different supporting requirements
  • Disease course: ~50% monophasic, ~50% relapsing; generally better recovery than AQP4-NMOSD
  • MRI features: Perineural optic sheath enhancement, longitudinal ON lesions, conus involvement, cortical lesions with meningeal enhancement, ill-defined brain lesions

Pathophysiology

MOG is a glycoprotein expressed exclusively on the outermost surface of myelin sheaths in the CNS, making it accessible to circulating antibodies. Key pathophysiologic features of MOGAD include:

  • Reversible demyelination: Pathology shows demyelination with relative preservation of astrocytes and axons, in stark contrast to the astrocyte-destructive pathology of AQP4-NMOSD
  • Less efficient complement activation: MOG-IgG activates complement less efficiently than AQP4-IgG, which may partly explain the generally better outcomes in MOGAD
  • T-cell-mediated component: Perivenous pattern of demyelination with prominent inflammatory infiltrates suggests a combined antibody- and cell-mediated process
  • Lesion resolution: MRI lesions in MOGAD frequently resolve or significantly decrease over time, reflecting the potentially reversible nature of the underlying pathology

Epidemiology

Feature MOGAD AQP4-NMOSD MS
Sex ratio (F:M) ~1:1 (adults) ~9:1 ~3:1
Peak age of onset Bimodal: childhood & 30–50y 30–50 years 20–40 years
Pediatric prevalence Common (especially ADEM) Rare ~5% of cases
Racial/ethnic predilection All backgrounds Non-White predominance Northern European predominance

Core Clinical Phenotypes

Optic Neuritis

Optic neuritis is the most common manifestation of MOGAD, with several distinguishing features compared to MS and AQP4-NMOSD:

  • Bilateral simultaneous involvement is common (unusual in MS)
  • Anterior optic nerve predilection with prominent optic disc edema (compared to posterior/chiasmal predilection in AQP4-NMOSD)
  • Longitudinally extensive involvement — optic nerve lesions extending >50% of nerve length on MRI
  • Perineural optic sheath enhancement on MRI — a highly characteristic finding
  • Prodromal headache may precede visual symptoms
  • Generally good visual recovery, though recurrent attacks can lead to cumulative visual loss

Myelitis

  • Longitudinally extensive transverse myelitis (LETM) is common, as in AQP4-NMOSD
  • Central cord/H-sign pattern on axial MRI (grey matter predominant)
  • Conus medullaris involvement — relatively specific for MOGAD among CNS demyelinating diseases
  • Generally better motor recovery than AQP4-NMOSD
  • Lesions frequently resolve or significantly shrink on follow-up MRI

Acute Disseminated Encephalomyelitis (ADEM)

  • Defined as acute polyfocal neurologic deficits with encephalopathy accompanied by multifocal T2 lesions on MRI
  • Most common MOGAD presentation in children
  • Ill-defined, large, often bilateral white matter lesions, frequently involving deep grey matter structures
  • MOG-IgG is detected in approximately 30–50% of pediatric ADEM cases

Brainstem and Cerebellar Syndromes

  • Ill-defined T2 hyperintensities involving the pons, middle cerebellar peduncle, or medulla
  • Can present with cranial neuropathies, vertigo, ataxia, or diplopia
  • Area postrema syndrome (intractable nausea/vomiting/hiccups) is less common than in AQP4-NMOSD but can occur

Cerebral Cortical Encephalitis

A relatively unique MOGAD phenotype characterized by:

  • MRI evidence of FLAIR cortical hyperintensity often with enhancement of the overlying meninges
  • Accompanied by cerebral irritability: encephalopathy, headache, focal deficits, and seizures
  • Seizures are part of the diagnostic definition and are uncommon in MS and AQP4-NMOSD
  • Can be confused with autoimmune encephalitis, infectious meningitis, or CNS vasculitis

Cerebral Monofocal or Polyfocal Deficits

  • Similar to ADEM but without encephalopathy
  • Multiple ill-defined T2 hyperintense lesions in supratentorial and often infratentorial white matter
  • Deep grey matter involvement may be seen

MRI Features

Location MOGAD Features Key Distinguishing Points
Optic nerve Longitudinally extensive (>50% nerve length), perineural sheath enhancement, optic disc edema, bilateral Anterior predilection (vs. posterior/chiasmal in AQP4-NMOSD); sheath enhancement is relatively specific
Spinal cord LETM, central cord/H-sign, conus involvement, lesion resolution over time Conus lesions favor MOGAD; lesions often resolve (unlike AQP4-NMOSD where atrophy develops)
Brain Ill-defined T2 lesions, deep grey matter involvement, cortical lesions with leptomeningeal enhancement Lesions do NOT resemble typical MS plaques; cortical involvement with meningeal enhancement is characteristic
Brainstem Ill-defined T2 hyperintensity in pons, middle cerebellar peduncle, medulla Distinguished from the pencil-thin ependymal enhancement of AQP4-NMOSD

MRI Lesion Evolution in MOGAD

A hallmark of MOGAD is the tendency for MRI lesions to resolve or substantially decrease on follow-up imaging, which contrasts with both MS (where lesions persist and may develop as T1 black holes) and AQP4-NMOSD (where lesion resolution is accompanied by significant tissue atrophy). This MRI behavior reflects the relatively reversible, demyelinating pathology of MOGAD. Persistent or worsening lesions over time should prompt reconsideration of the diagnosis.

Diagnostic Criteria (2023 International MOGAD Panel)

The diagnosis of MOGAD requires fulfillment of three criteria (A, B, and C):

Criterion A: Core Clinical Manifestation

At least one of the following six core phenotypes:

  1. Acute or subacute optic neuritis
  2. Acute or subacute myelitis
  3. ADEM (acute polyfocal deficits with encephalopathy + multifocal MRI lesions)
  4. Cerebral monofocal or polyfocal deficits without encephalopathy
  5. Acute or subacute brainstem or cerebellar deficits
  6. Cerebral cortical encephalitis with seizures

Criterion B: MOG-IgG Positivity by Cell-Based Assay

Only cell-based assays are accepted for MOGAD diagnosis (unlike AQP4-NMOSD, where other assays can be used with caution). The criteria distinguish two levels of positivity:

MOG-IgG Level Definition Additional Requirements
Clear positivity ≥2 doubling dilutions above assay cutoff (live CBA) or titer ≥1:100 (fixed CBA) No additional supporting features required
Low positivity Low-range positivity (live CBA) or titer 1:10–1:100 (fixed CBA), OR unknown/not reported titer, OR isolated CSF positivity Requires: (1) negative AQP4-IgG AND (2) ≥1 supporting clinical or MRI feature

False Positivity Risk

  • Low-positive MOG-IgG titers carry a significant risk of false positivity — hence the requirement for supporting features
  • ELISA and other non-CBA assays are not accepted for MOGAD diagnosis due to unacceptable false-positive rates
  • In borderline cases, repeat testing with a more accurate assay (e.g., live vs. fixed CBA) is advised
  • Consultation with a demyelinating disease specialist is recommended when in doubt

Supporting Clinical and MRI Features

Required when MOG-IgG positivity is low or uncertain:

Phenotype Supporting Features
Optic neuritis Bilateral simultaneous involvement; >50% nerve length on MRI; perineural optic sheath enhancement; optic disc edema
Myelitis Longitudinally extensive spinal cord lesion; central cord/H-sign; conus lesion
Brain/brainstem syndrome Multiple ill-defined T2 lesions in supra/infratentorial white matter; deep grey matter involvement; ill-defined pons/MCP/medulla lesions; cortical lesion with leptomeningeal enhancement

Criterion C: Exclusion of Alternative Diagnoses

Common red flags that should prompt reconsideration include:

  • Progressive disease course (primary or secondary progressive) — consider MS, sarcoidosis, metabolic or genetic etiologies
  • Hyperacute onset (<4 hours) — consider stroke or ischemic etiologies
  • Typical MS lesion morphology on brain MRI (ovoid periventricular, Dawson fingers, ring/open-ring enhancement)
  • CSF-restricted oligoclonal bands — consider MS or sarcoidosis
  • Development of new asymptomatic lesions over time — favors MS
  • Lack of lesion resolution over time (uncommon in MOGAD)
  • Lack of response to corticosteroids and PLEX

Disease Course and Prognosis

Feature Detail
Monophasic course ~50% of patients; single attack with no recurrence
Relapsing course ~50% of patients; predominantly optic neuritis relapses
Progressive course Not a recognized feature of MOGAD; its presence should prompt reconsideration of diagnosis
Recovery Generally better than AQP4-NMOSD; complete or near-complete recovery is common
MOG-IgG seroconversion Conversion to seronegative status reduces future relapse risk; serial monitoring informative
Disability drivers Visual impairment from recurrent ON; motor deficits from severe myelitis attacks

CSF Findings in MOGAD

  • CSF pleocytosis is common (often higher cell counts than MS)
  • Oligoclonal bands are typically absent (<20% positive) — their presence should raise suspicion for MS
  • Elevated protein is common during acute attacks
  • Neutrophilic predominance may be seen acutely (unlike the lymphocytic predominance typical of MS)

Differentiation from MS and AQP4-NMOSD

Feature MOGAD AQP4-NMOSD MS
Antibody MOG-IgG AQP4-IgG None specific
Pathology Demyelination, astrocytes preserved Astrocytopathy Demyelination, axonal loss
OCBs Usually absent Usually absent Present ~90%
ON pattern Anterior, bilateral, sheath enhancement Posterior/chiasmal Retrobulbar, unilateral
Myelitis LETM, conus, H-sign LETM, bright spotty lesions Short, peripheral lesions
Brain lesions Ill-defined, cortical, resolve Periependymal, cloud-like Ovoid, periventricular, persistent
Course 50% monophasic, no progression >90% relapsing, no progression Relapsing then progressive
Recovery Generally good Often poor Variable

References

  1. Sechi E. Neuromyelitis optica spectrum disorder and myelin oligodendrocyte glycoprotein antibody-associated disease. Continuum (Minneap Minn). 2024;30(4):1057-1090.
  2. Banwell B, Bennett JL, Marignier R, et al. Diagnosis of myelin oligodendrocyte glycoprotein antibody-associated disease: International MOGAD Panel proposed criteria. Lancet Neurol. 2023;22(3):268-282.
  3. Sechi E, Cacciaguerra L, Chen JJ, et al. Myelin oligodendrocyte glycoprotein antibody-associated disease (MOGAD): a review of clinical and MRI features, diagnosis, and management. Front Neurol. 2022;13:885218.
  4. Höftberger R, Guo Y, Flanagan EP. The pathology of central nervous system inflammatory demyelinating disease accompanying myelin oligodendrocyte glycoprotein autoantibody. Acta Neuropathol. 2020;139(5):875-892.
  5. Takai Y, Misu T, Kaneko K. Myelin oligodendrocyte glycoprotein antibody-associated disease: an immunopathological study. Brain. 2020;143(5):1431-1446.
  6. Valencia-Sanchez C, Guo Y, Krecke KN, et al. Cerebral cortical encephalitis in myelin oligodendrocyte glycoprotein antibody-associated disease. Ann Neurol. 2023;93(2):297-302.