Human Parechovirus Meningoencephalitis: Neuroimaging in the Era of Polymerase Chain Reaction–Based Testing

Discussion

This series describes 6 infants with HPeV meningoencephalitis and characteristic MR imaging findings that rapidly yielded a diagnosis in conjunction with PCR testing of the CSF.

Distinctive supratentorial white matter and callosal diffusion abnormality on MR imaging is shared between ours and other published series.^{3,12,13,15⇓–17} Thalamic involvement and sparing of the posterior fossa structures have been reported variably but were universally present in our cases.^12,18 T1- and T2-shortening foci branching along the distribution of the deep medullary veins is consistent with examples presented by Belcastro et al¹³ and Verboon-Maciolek et al⁹ but has not been consistent across studies. Occipital white matter and cortical involvement in 2/6 cases is also dissimilar to previous descriptions and may be explained by hypoglycemia in one and transient hypoglycemia or, alternatively, a seizure-related or vascular phenomenon such as posterior reversible encephalopathy syndrome in the other.

The pathophysiology of CNS injury in HPeV infection is not well-understood. The pattern of MR imaging signal abnormality preferentially affecting the supratentorial white matter tracts in our cases could suggest neuroaxonal tropism; however, signal abnormality along the course of the deep medullary veins on T1- and T2-weighted imaging in 5/6 cases suggests perivenular invasion or venous ischemia as a potential alternative etiology. Supporting the first hypothesis, a study of patients with clinical CNS infection and stool samples positive for HPeV-3 showed faster replication in a cultured neural cell line.¹⁹ Verboon-Maciolek et al⁹ and Volpe²⁰ reported that the HPeV RNA activates toll-like receptors in microglia, resulting in the release of inflammatory substances that injure preoligodendrocytes and axons as part of an innate immune response, as well as toll-like receptors in neurons and growing axons, resulting in direct injury. Alternatively, supporting the venous ischemia hypothesis, a postmortem examination study of 2 premature neonates (33 and 34 weeks gestational age) with fatal HPeV infection by Bissel et al¹¹ demonstrated severe inflammatory changes of the periventricular white matter with macrophage infiltration and astrocytosis. While HPeV-3 RNA probes hybridized with abundant viral particles within brain meningeal cells and blood vessel walls, they did not reveal the presence of HPeV within parenchymal cells. The authors therefore hypothesized that parenchymal injury is a consequence of vascular compromise rather than direct infection. Low diffusivity of the corpus callosum may result from seizure activity and/or Wallerian degeneration, given the relative resistance of the corpus callosum to ischemic insults. Low diffusivity in the thalamus may be due to some combination of venous ischemia and seizure activity.

While the clinical and imaging characteristics of HPeV meningoencephalitis are characteristic in a neonate with sepsis and seizures, there is a differential diagnosis. Distinction from enterovirus, rotavirus, and chikungunya infection may not be possible.^21,22 In contradistinction to neonates with hypoxic-ischemic injury, neonates with HPeV infection lack a history of a sentinel event. Frontoparietal white matter–predominant low diffusivity and sparing of the basal ganglia favor HPeV encephalitis over hypoxic-ischemic injury.¹² Isolated sulfite oxide deficiency and molybdenum cofactor deficiency can present in the neonatal period; however, the basal ganglia are usually affected.

Reported long-term outcomes are variable, with limited available data, but overall suggest adverse developmental outcomes in patients with encephalitis and abnormal MR imaging findings. In a study comparing longitudinal gross motor development between infants with HPeV infection and those with no pathogen found, a statistically significant difference was noted at 6 months, but not at 24 months.²³ In a study in which 6 patients with clinically diagnosed HPeV encephalitis underwent MR imaging during both acute illness and follow-up developmental assessment at 12 months, Britton et al¹⁵ reported concern for abnormal development in all 6. Verboon-Maciolek et al⁹ found that in the 50% (5/10) of patients in their cohort who had a developmental disability, the severity of imaging abnormalities correlated with neurodevelopmental outcome. Two patients in our cohort have been noted to be clinically well at 6- to 8-week follow-up; however, long-term follow-up data are not yet available.

A few reports have described long-term imaging follow-up, with mixed results. Pariani et al²⁴ and Amarnath et al¹² had resolution of imaging abnormalities at 2-month and 1-year follow-up, respectively. In 3 patients, Verboon-Maciolek et al⁹ reported variable degrees of visible white matter injury at 3-month-to-7-year follow-up, with abnormalities ranging from mild periventricular gliosis to extensive white matter volume loss and cystic encephalomalacia. Brownell et al¹⁶ described a patient with severe white matter injury at day 3, with only mild white matter signal abnormality and callosal thinning at 1 year. On the contrary, Belcastro et al¹³ described the development of extensive cystic leukomalacia at 4-month follow-up in 1 patient. Some data suggest that preterm infants are at higher risk for severe cystic leukoencephalomalacia.^9⇓–11 One patient in our study had a 3-month follow-up MR imaging showing diffuse parenchymal volume loss (Fig 3). Further study will help to correlate the severity of clinical and imaging findings with long-term outcomes.

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Fig 3.

Axial T2-weighted image (A) and sagittal T1-weighted image (B) obtained in patient 1 approximately 3 months after acute HPeV infection show new diffuse enlargement of the extra-axial spaces and thinning of the corpus callosum, suggesting volume loss.

Current study limitations include the retrospective design and small number of cases. Viral genotyping was not performed, and this study did not determine imaging characteristics that distinguish among viral genotypes. Furthermore, imaging techniques varied. Referral to imaging may not be performed in less severe cases, biasing MR imaging requests toward patients with severe clinical presentation. An additional limitation is limited clinical and imaging follow-up, which warrants further study. Finally, findings in patients with less severe disease are currently not well-established and could also be determined by future study.

The stereotypical MR imaging appearance correlated with molecular testing in our patients yielded a specific diagnosis of HPeV meningoencephalitis, resulting in a less extensive metabolic and genetic work-up than would have been undertaken otherwise. Knowledge of the distinctive imaging findings in young infants with HPeV meningoencephalitis thus has potential for substantial cost- and time-savings.