Introduction
Transverse myelitis (TM) is an inflammatory and immune-mediated demyelinating pathology with an acute or subacute onset and sensory, motor, and autonomic spinal dysfunction. TM might be partial, complete, longitudinally extensive, or central1-4.
TM is infrequent in the pediatric population, with an estimated annual incidence of 1-4 cases/1,000,000 patients. It is more frequent in male patients during the pre-pubertal stage, while female patients have a predilection in the pubertal and adult stages. Presentation in children has both clinical and prognostic significance since it has been reported that children have a better prognosis with complete recovery at 2-year follow-up compared with adults. However, the latter might be age-related since younger patients have been reported to have the worst outcomes related to brain immaturity. The main differences in TM between children and adults include an initial presentation with back pain and fever in the pediatric population and a higher prevalence of sphincter dysfunction in adults5-8.
Pathogenesis is diverse, and several factors have been related to its development, such as infectious, vascular, and autoimmune diseases3. Neurological impairment has increased since the onset of the COVID-19 pandemic, and neurological manifestations of the disease have been frequently reported, demonstrating its neurotropic capability. Mechanisms that explain the latter remain unclear9.
Neurological involvement in COVID-19 has been reported as hyposmia/anosmia, dysgeusia/ageusia, headache, and other severe presentations such as stroke, meningitis, acute disseminated encephalitis, myasthenia gravis, Guillain-Barre syndrome, and acute TM10.
COVID-19-related TM pathophysiology has been described as developing an immune response directed against the infectious agent that may target the central and peripheral nervous system, potentially, leading to neurological damage. Fuerthermore, it has been suggested that severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) can enter human cells through angiotensin-converting enzyme 2 (ACE2) receptors, which are also found on the membranes of spinal cord neurons11.
Acute TM presents with neurological manifestations depending on the affected medullary level. Motor impairment includes bilateral limb weakness or bilateral paraplegia, which may present with flaccidity or spasticity, while sensory involvement is represented as pain, dysesthesia, and paresthesia. The affected medullary level might be identified in 60% of cases10,12,13,14. Autonomic dysfunction presents as urinary retention, incontinence, constipation, and sexual dysfunction15,16.
Regarding TM treatment, multiple courses of steroids, immunoglobulin, and plasma exchange have improved motor function. To date, no treatment specifically targeting COVID-19 infection has been described17.
This report aims to present an acute inflammatory-mediated medullary disease in a pediatric patient in the context of a SARS-CoV-2 infection, in whom a broader diagnostic protocol discarded alternative etiologies, contributing to pediatric literature due to the low incidence of neurological impairment after COVID-19 infection. TM following COVID-19 infection in Mexico has been reported only in adult patients. This is the first report of this condition in a pediatric patient in the country18.
Clinical case
A 15-year-old previously healthy male patient, with a complete immunization scheme for his age and a single dose of Pfizer-BioNTech vaccine (BNT162b2), administered 3 months before the disease onset, presented with upper respiratory symptomatology that partially improved with symptomatic ambulatory medication. Twenty-four hours later, he presented to the emergency room after experiencing thoracic oppressive pain at rest, radiating to both shoulders and bilateral palmar hypoesthesia. He further developed ascending symmetric paraparesis, which rapidly progressed to paraplegia and urinary incontinence.
During the neurological examination, upper cognitive function and cranial nerves were normal, with no signs of meningeal irritation. Sensory involvement affecting the T3 medullary level was documented. Deep tendon reflexes in upper limbs were reported as 2/4 and 0/4 in lower limbs on the Daniels scale, with non-pathologic Babinski reflex.
Forty-eight hours after admission, he developed a loss of ventilatory automatism that required advanced ventilatory support.
General laboratory tests were taken upon admission, with no pathological findings other than a positive SARS-CoV-2 real-time polymerase chain reaction by nasal swab. Head and spine computed tomography showed no alterations. Brain and spine magnetic resonance imaging (MRI) showed a hyperintense longitudinally extensive lesion from medullary levels C4 to T4 in the T2/STIR modality with discrete heterogeneous enhancement after the administration of contrast, with edema affecting the entire medullary cord in some regions and involvement of the gray matter at different levels, including anterior and posterior horns, mainly affecting the C7 medullary level, compatible with TM (Fig. 1).
A diagnostic protocol for demyelinating disease was performed, including cerebrospinal fluid (CSF) analysis, which showed a protein level of 51.9 mg/dL, a CSF glucose level of 61 mg/dL, and no pleocytosis. A viral panel with negative results for enterovirus, herpesvirus, and cytomegalovirus (CMV) in multiplex modality was also obtained. Mycobacterium tuberculosis complex, a highly prevalent pathogen in our setting, was discarded.
Myelin basic protein (MBP) and aquaporin-4 antibodies were requested, with a positive result for MBP. The CSF oligoclonal banding test was reported as negative. Cerebral and spinal angiography discarded a vascular malformation.
Methylprednisolone pulses of 1 g/day were initiated in the context of a demyelinating pathology. Due to the diseases refractoriness, plasma exchange was initiated 72 h after hospitalization, completing five sessions.
The patient presented with a complex neurological impairment that required neurological and pulmonary rehabilitation, as well as the placement of a gastrostomy tube and tracheostomy cannula.
He was discharged after 2 months of hospital stay, with complete improvement of upper limb mobility and residual paraplegia in lower limbs, with fine and gross sensitivity affected. At present, he is dependent on a urinary catheter due to urinary incontinence.
Discussion
Defining TM etiology might be challenging, and it is not uncommon for an infectious disease to precede TM cases. Herpes simplex virus 2, Varicella zoster virus, Epstein-Barr virus, CMV, flavivirus, and enterovirus, all of which were discarded in our patient, have been related to the pathology. Moreover, only SARS-CoV-2 infection was confirmed. The exact pathophysiology of TM remains unknown, while four mechanisms have been proposed to develop the disease: the direct effect, molecular mimicry, microbe superantigen-mediated inflammation, and the humoral response19-21.
SARS-CoV-2 has a great neurotropic and neuroinvasive capacity related to its affinity for ACE2, which is present not only in respiratory system cells but also in neurons and glial cells7.
Higher levels of Interleukin 6, a pro-inflammatory cytokine, lead to greater production of acute phase reactants, like C-reactive protein and fibrinogen, which were elevated in our patient20,21.
The presence of MBP antibodies in our patient demonstrates a genetic and immunologic host predisposition22.
Neurological deficits due to SARS-CoV-2 have been increasingly reported, and their relation must be suspected when other causes have been discarded. The latency period has yet to be established since reports vary from 15 h to 5-day post-respiratory disease to 10-day to 6-week post-COVID-19 confirmation19-23.
Our patient presented with a complete acute medullary syndrome, typical of TM, due to its immune-mediated mechanism, which meets the criteria of the TM Consortium Working Group1.
Symptom progression tends to be rapidly progressive, with a nadir between 4 h and 21 days. It is vital to discard an extra-axial compression etiology24,25.
We describe imaging results consistent with TM on MRI, including a hyperintense lesion in T2/STIR modality, longitudinally extensive, well-defined, and homogeneous from C4 to T4 medullary levels26.
The differential diagnosis includes Guillain-Barre syndrome, which also presents in its acute form with weakness and areflexia. However, a defined sensory level and urinary retention allow differentiation from TM26. The differential diagnosis should also include myelin oligodendrocyte glycoprotein antibody-associated disease, although no radiological findings in the optic nerve or visual impairment were reported27.
High doses of methylprednisolone have been described as a first-line treatment for TM. Plasmapheresis has been described as an appropriate therapeutic approach in severe or steroid-refractory cases, as our patient received five sessions of this therapy25.
Close observation of children with COVID-19 should be considered if any neurological involvement is present due to the gravity and risk of sequelae.
Conclusion
COVID-19 is an infrequent cause of Transverse Myelitis and should be suspected when other etiologies have been carried out. Due to the gravity and sequelae risk, close observation of children with COVID-19 should be considered if any neurological involvement is present. MRI plays a crucial role in differential diagnosis with other neuropathies and should not be delayed.