Introduction
Although the site of primary infection in severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) is the respiratory system, there is accumulating laboratory and clinical evidence that suggests that SARS-CoV-2 may have neurotropic and/or neuroinvasive properties Reference Baig, Khaleeq, Ali and Syeda1–Reference Pellegrini, Albecka and Mallery4 similar to other human coronaviruses. Reference Arabi, Harthi and Hussein5–Reference Arbour, Day, Newcombe and Talbot9 Neurological involvement associated with SARS-CoV-2 infection have been described in adults, ranging from non-specific neurologic symptoms such as myalgia, dizziness, and headache, Reference Amanat, Rezaei and Roozbeh10,Reference Mao, Jin and Wang11 to more severe neurological complications including acute encephalopathy, cerebrovascular disorder, stroke, Guillain-Barré Syndrome, and peripheral nervous system disorders. They occur in up to 82% of adult COVID-19 patients. Reference Chou, Beghi and Helbok12–Reference Correia, Feitosa and Moreira16
In children, SARS-CoV-2 infection generally follows a milder disease course acutely as compared to adults, but several case series have documented severe signs/symptoms in some children Reference Leeb, Price and Sliwa17,18 Furthermore, case series in Europe and the United States (US) have highlighted the presence of neurological complications in some children. Reference Ray, Abdel-Mannan and Sa19–Reference Garazzino, Montagnani and Donà22 Risk factors for neurological involvement in hospitalized children are not firmly established. To address this gap, we evaluated (1) neurological signs/symptoms temporally associated with SARS-CoV-2 infection in hospitalized children in a multicenter, multinational cohort, and (2) associations between neurological involvement, pre-existing comorbidities, and clinical outcomes.
Methods
Study Design and Population
This was a multinational, retrospective study of a prospectively collected cohort of consecutive patients (0–18 years of age) admitted for any medical reasons from February 1, 2020 through May 31, 2021 who had laboratory-confirmed SARS-CoV-2 infection. The study cohort comprised of hospitalized children from 15 centers: 13 tertiary hospitals that were part of the Pediatric Investigators Collaborative Network on Infections in Canada (PICNIC), and one hospital each in San José, Costa Rica, and Tehran, Iran. Study size was determined by the number of children admitted meeting study criteria during the period of the study. SARS-CoV-2 infection was confirmed by positive reverse transcription-polymerase chain reaction (RT-PCR) of any clinical specimen (nasopharyngeal swab, throat swab, nose swab, endotracheal tube aspirates) and/or positive serological testing for antibodies against SARS-CoV-2. Routine clinical evaluations and laboratory measurements were obtained as part of standard of care and were performed according to institutional protocols. Patients were managed at the discretion of the treating physicians locally.
Standard Protocol Approvals, Registrations, and Patient Consents
Ethics approval was obtained according to local ethics committee requirements.
Clinical Data Collection
Chart review and data entry were performed locally at each participating center by designated research staff. Study data were abstracted from clinical charts using standardized case report forms (available upon request) and definitions, and de-identified data were entered into an electronic data capture tool (REDCap) hosted at the University of Alberta. Reference Harris, Taylor and Minor23 Study data regarding demographics, medical history, comorbidities, clinical features, laboratory evaluations, neuroimaging (brain and spine magnetic resonance imaging (MRI)), and treatment regimen were collected.
Clinical Definitions
Children hospitalized for any medical reasons and had lab-confirmed SARS-CoV-2 infection (with or without neurological signs/symptoms) were included in this study. We defined a neurological sign/symptom as the presence of any of the following: (1) new or worsening seizures, encephalopathy (altered/decreased level of consciousness, personality/behavioral change), psychosis, ataxia, dyskinesia, muscle weakness, sensory abnormalities, bulbar symptoms (facial weakness, dysarthria, dysphagia), headache; (2) abnormal CSF WBC (>5 WBC/mm Reference Moriguchi, Harii and Goto3 ) or protein (>0.4 g/L) or (3) new/acute central nervous system MRI abnormalities. We defined encephalopathy in children 1 year of age and older as having altered level of consciousness with or without irritability/lethargy, whereas in neonates/infants younger than 1 year of age we also included irritability and/or lethargy regardless of change in consciousness given the difficulty in establishing level of consciousness in this age group. Categorization of MIS-C was made using clinical data provided by site Principal Investigators. For the purpose of data analyses in this study, children were retrospectively classified as MIS-C if they met the World Health Organization (WHO) criteria for MIS-C in relation to systemic symptoms 24 with an additional modification to include those with fever for less than 2 days if corticosteroids or intravenous immunoglobulin (IVIG) was administered prior to day 3 of fever. Children with ADEM in absence of a purely systemic syndrome prior who were given steroids were not classified as MIS-C. Cases of neurological manifestations who were hospitalized for primary reasons other than COVID-19 and had incidental SARS-CoV-2 infection were adjudicated by a blinded pediatric neurologist (EAY). Cases of neurological manifestations that had potential pathogens detected in addition to SARS-CoV-2 were adjudicated individually by site investigators and secondarily by a blinded infectious disease specialist (AB): neurological involvement in these cases was categorized as 1) most likely due to SARS-CoV-2 infection (COVID-19/MIS-C), 2) most likely due to another pathogen, or 3) indeterminate in which the role of SARS-CoV-2 is uncertain. To avoid ambiguity in evaluating the association of SARS-CoV-2 and neurological signs/symptoms, cases of neurological manifestation that were deemed to be most likely due to other pathogens or indeterminate (categories 2 and 3 above) were excluded. Neuroimaging was performed at the discretion of the attending physician. MRI data included descriptive information gleaned from clinical reports. MRI reports were reviewed by a pediatric neurologist with special expertise in neuroinflammation (EAY), and findings were classified as 1) normal; 2) acute in the context of SARS-CoV-2 (bright signal on T2 weighted imaging ± enhancement, ± diffusion restriction in the absence of alternative chronic explanations for the abnormalities); 3) non-acute, which included those that showed chronic, incidental findings (e.g. cortical dysplasia, neoplasm).
Statistical Analysis
Continuous data were presented as median (interquartile range [IQR]) and compared using non-parametric Mann–Whitney U test. Categorical data were described using counts (percentage) and compared using chi-square or Fisher’s exact test, as appropriate. Correlation analysis was performed using Spearman’s rho test. A p-value less than 0.05 was considered statistically significant. Logistic regression was used for analysis of factors associated with neurological involvement. Imputations were not done for any missing data. Due to sample size limitations, only descriptive analysis was performed in two subgroups: 1) children with MIS-C and 2) children with neurological signs/symptoms and no overt infectious symptoms. Benjamini-Hochberg false discovery rate <0.05 was used to adjust for multiple comparisons. JASP (version 0.14) was used for statistical analysis.
Data Availability
The data that support findings in this study are available upon reasonable request from the Corresponding Author. Data are not publicly available as they contain information that could comprise the privacy of patients.
Role of Funding Source
There was no funding source for this study. The Corresponding Author had full access to all the data in the study and had final responsibility for the decision to submit for publication.
Results
Study Cohort
This multicenter study included 713 hospitalized children (413 [58%] male, median 4 years of age [IQR 0.8–10.5]) with laboratory evidence of SARS-CoV-2 infection (Canada, n = 13; Costa Rica, n = 1; Iran, n = 1; Table 1). In 28 of these children, one or more other possible pathogens were detected. Sixteen of these 28 were excluded from further analysis: 13 where another pathogen was thought to be the more likely cause of neurologic signs/symptoms, and 3 because there was causal uncertainty (Supplementary Figure). In the remaining 12 cases, SARS-CoV-2 was deemed the more likely cause of neurologic signs/symptoms. Thus, the final cohort consisted of 697 children (Table 1). Patients from Canada, Costa Rica, and Iran constituted 62, 29, and 8% of the study cohort, respectively (Table 1). Patient demographics and clinical features stratified by country are summarized in Supplementary Table 1. The Canadian cohort was significantly older (6 years [IQR 1.32–13.8]) than those from Costa Rica (2.7 years [IQR 0.5–7.5] and Iran (2.1 years [IQR 0.7–5.3]; p < 0.001).
Abbreviations: ICU, intensive care unit; IL, interleukin; IVIG, intravenous immunoglobulins; MIS-C, multisystem inflammatory syndrome in children.
a Data missing for 12/697 patients.
b Oseltamivir, Kaletra, Remdesivir.
c Antibiotics for possible secondary bacterial pneumonia.
SARS-CoV-2 infection was confirmed by RT-PCR in 581/697 (83%) children and by serology assay in 77/693 (11%). Thirty-nine (5%) children tested positive by both RT-PCR and serology. One-hundred and eighty-eight (27%) children were hospitalized with primary reasons other than SARS-CoV-2 infection but had tested positive for SARS-CoV-2 on routine screening; of these, 44 did not have symptoms typical of SARS-CoV-2 infection.
Neurological Signs/Symptoms in Overall Cohort
Table 1 shows the clinical features of children with and without neurological involvement. Of the 697 hospitalized children, 147 (21%) had at least one neurological sign/symptom temporally associated with SARS-CoV-2 infection and 40 (6%) presented with 2 or more neurological signs/symptoms. The most common neurological signs/symptoms were headache (15% [103/697]), acute encephalopathy (4% [28/697]), and seizures (4% [30/697]; Table 2).
a 85 patients had headache solely as their neurological symptoms; 12 patients had headache in addition to other neurological symptoms.
b Includes 18 infants <1 year old presenting with irritability and/or lethargy regardless of LOC change.
c Includes only patients >1 year of age.
Twelve percent (85/697) of children had headache only and no other neurological involvement. We performed a subgroup analysis comparing children with headache only (n = 85) versus those with other neurological signs/symptoms (n = 62) and found that children with headache only were significantly older (9.1 years [IQR 6-14] vs 2.5 years [0.3–9.6]; p < .0001) and had increased frequency of gastrointestinal symptoms (83% vs 39%; p < 0.001) and fever during admission (74% vs 37%; p < 0.001). We also noted that more children who had headache only met MIS-C criteria as compared to those who had non-headache neurological involvement (62% vs 11%; p < 0.001). The frequency of ICU admission (33% vs 37%; p = 0.601), length of ICU (5 [IQR 4–13] vs 3.5 [IQR 2–6]; p = 0.316) and length hospital stay (6 [IQR 4–8] vs 5 [IQR 3–12.5]; p = 0.786]) for children with headache only and those who had other neurological signs/symptoms were not significantly different (Supplementary Table 2).
Acute encephalopathy/altered mental status was reported in 28/697 (4%) of children. Of these, 15/28 (53%) were infants less than one year of age, and 5/28 (18%) children met MIS-C criteria. Ten of 28 (36%) children were admitted to the ICU and 6 (including 2 infants) needed mechanical ventilation. Four of 5 children with MIS-C and acute encephalopathy/altered mental status were admitted to the ICU with one requiring mechanical ventilation.
Seizures, including status epilepticus, were reported in 29/697 (4%) of our cohort. Twelve of 29 (41%) patients with seizures had an underlying seizure disorder and two met MIS-C criteria. Thirteen (45%) of 29 patients with seizures were admitted to the ICU and 4 (14%) needed mechanical respiratory support. Of the 17 patients with seizures but who had no history of seizure disorder, 9 (53%) had at least one other neurological sign/symptom, including acute encephalopathy/altered mental status (n = 5), headache (n = 4), limb weakness (n = 3), and ataxia (n = 2; Figure 1).
In a subgroup analysis in which we excluded children who had headache as the only symptom, we found higher frequency of neurological involvement among children with an underlying seizure disorder (30% [12/40]) than those who had no history of a seizure disorder (9% [50/572]; p < 0.001). Notably, all 12 children with an underlying seizure disorder and who also had neurological involvement presented with seizures.
Five children, not included in the above categories, had other neurological involvement including polyradiculopathy (Guillain-Barré Syndrome) and cerebellar syndrome (n = 1), weakness (n = 1), abnormal movements including twitching (n = 1), motor sensory abnormality (n = 1), and ataxia (n = 1).
Neurological Signs/Symptoms in Children with MIS-C
Overall, 20% (140/697) of patients satisfied MIS-C criteria. Children with MIS-C were significantly older (median 7.2 years [IQR 4–10] vs 2.7 [IQR 0.4–11]; p < 0.001) and fewer had an underlying neurological condition (2% [5/140] vs 12% [69/557]; p = 0.002) compared to children who did not meet MIS-C criteria. Children with neurological involvement in the MIS-C cohort were less likely than those in the non-MIS-C cohort to have a history of an underlying medical condition (MIS-C 22% vs non-MIS-C 52%; p < 0.001).
Sixty of 140 children who satisfied MIS-C criteria had neurological signs/symptoms, with headache (42% [59/140]), acute encephalopathy/altered mental status/psychosis (5% [7/140]), and seizures (1% [2/140]) being the most common. Fifty-three (38%) of 140 children with MIS-C experienced headache only while seven (5%) children who met MIS-C had at least one neurological sign/symptom other than headache (Figure 1). Sixty-six (47%) children with MIS-C were admitted to the ICU, of whom 30 had neurological involvement.
When compared to children who had neurological involvement and did not satisfy criteria for MIS-C, those with MIS-C were more likely to have headache alone (MIS-C 88% [53/60] vs non-MIS-C 37% [32/87]). When headache is removed from the analysis, the association is in the opposite direction: 7/140 (5%) patients satisfying MIS-C criteria developed neurological signs/symptoms vs. 55/557 (10%) non-MIS-C.
Asymptomatic SARS-CoV-2 and Neurological Events
Of the entire study cohort, 5/697 (0.7%) had neurological signs/symptoms only with no other typical COVID-19 symptoms.
Comparisons of Patients With and Without Neurological Involvement
Table 1 summarizes the clinical characteristics of children with and without neurological involvement. When compared to children without neurological involvement, those who had any neurological signs/symptoms were significantly older (7.3 years [IQR 3–12] vs 3.3 [IQR 0.7–10.30]; p<0.001), were more likely to be febrile at the time of admission or while hospitalized (60% [86/143] vs 41% [224/542]; p < 0.001), remained febrile for longer periods (median 6 days [IQR 4–8] vs 4 days [IQR 1–7]; p < 0.001), were more likely to meet MIS-C criteria [41% [60/147] vs 14% [80/550]; p < 0.001), more frequently reported symptoms associated with MIS-C, were more likely to be admitted to the ICU (35% [51/147] vs 23% [125/550]; p = 0.003), and had longer hospital stays (median 5 days [IQR 3–9] vs 4 days [IQR 2-7]; p < 0.005; Table 1). However, it is important to note that when patients with headache as their sole neurological sign/symptom were not included in the neurological group, except for the frequency of ICU admission which remained significantly higher (37% [23/62] vs 23% [125/550]; p = 0.012), the above-described differences were no longer significant.
CSF Findings
Twenty-seven (17%) of 163 children with any neurological involvement had a lumbar puncture performed within a median of 2.5 days (IQR 2–7) from COVID-19 symptom onset (Table 3). None of the 27 CSF samples examined had detectable SARS-CoV-2 by RT-PCR. CSF analysis showed pleocytosis (>5 WBC/mm3) in 8/27 patients (lymphocyte predominance in 7/27 and neutrophil predominance in 1/27) and elevated protein in 10/27 (median 29 mg/dL [IQR 21-88 mg/dL].
Abbreviations: CSF, cerebrospinal fluid; IQR, interquartile range.
a Data was available from 27 patients with non-headache neurological signs/symptoms.
Neuroimaging
Sixteen of 73 patients with non-headache neurological involvement received MRI scans of the brain and 5 also received MRI scans of the spine. MRI abnormalities were found in 81.2% (12/16) of these children (12/16 MRI brain, 3/5 spine), of which 68.7% (10/16) had acute abnormalities. The remaining two had chronic incidental findings including a pituitary adenoma and focal cortical dysplasia.
Six of 10 MRI abnormalities in the brain that were acute in the context of SARS-CoV-2 infection demonstrated findings consistent with neuroinflammation, including patchy multifocal lesions distributed throughout the brain, brainstem, and deep gray matter, at times associated with diffusion restriction, leptomeningeal enhancement, or punctate areas of micro hemorrhage. The four other brain MRI scans with acute abnormalities included (n = 1) findings suggestive of posterior reversible encephalopathy syndrome and (n = 2) focal abnormalities including diffusion restriction in the caudate head, and possible cortical vein thrombosis (increased susceptibility in the area of a cortical vessel). All three spinal cord abnormalities were deemed acute. They included (a) (n = 1) longitudinally extensive lesion (C2-6) with associated swelling (n = 1) and (b) enhancement of the cauda equina and nerve roots (brain MRI was noted to show cerebellar lesions as well) (n = 1). Supplementary Table 3 provides information on the clinical features seen in these patients.
Treatment
Sixty-one percent (90/147) of children with any neurological involvement received immunotherapy compared to 38% (207/550; p < 0.001) of those without. Sixteen (11%) of 147 of patients with neurological involvement received immunotherapy plus antivirals (oseltamivir, lopinavir/ritonavir, remdesivir). Of the 90 patients with neurological symptoms who received immunotherapy, 18(20%) received IVIG only, 28 (31%) received corticosteroids only and 44 (49%) received IVIG in combination with corticosteroids. Additionally, 2/147 children received IL-6 blocker (Tocilizumab) and 3/147 received IL-1 receptor antagonist (Anakinra; Table 1).
Fifty-one (85%) of 60 MIS-C patients with neurological signs/symptoms received immunotherapy. Of the patients who did not satisfy MIS-C criteria, 13/32 (41%) patients with headache only received immunotherapy; 7/23 (30%) patients with acute encephalopathy with no seizures received immunotherapy; 10/27 (37%) patients with seizures received immunotherapy; 2/5 (40%) patients with demyelinating and other syndromes received immunotherapy.
Short-term Outcomes in Children with Non-headache Neurological Involvement
Data regarding neurological evaluation at hospital discharge were available for 37/62 (60%) of children with non-headache neurological signs/symptoms. Of these, 78% (29/37) reported no significant neurological deficits or had complete recovery while 22% (8/37) still had neurological deficits, with 5 children reporting residual motor deficits/limb weakness, one child continued to have increased seizures activity, and one had hypotonia (one case did not specify residual symptoms).
Factors Associated with Neurological Signs/Symptoms
We performed multivariable logistic regression analyses to identify potential factors associated with any neurological involvement. Adjusting only for age and using separate models, we found that ICU admission (OR: 1.71, 95% CI: 1.15–2.55; p = 0.008), satisfaction of MIS-C criteria (OR: 3.71, 95% CI: 2.46–5.59; p < 0.001), fever during hospitalization (OR: 2.15, 95% CI: 1.46–3.15; p < 0.001), and gastrointestinal involvement (OR: 2.31, 95% CI: 1.58–3.40; p < 0.001) were significantly associated with any neurological involvement. We further performed a subgroup logistic regression analysis that included only patients who had neurological signs/symptoms other than headache given the high prevalence of headache among older patients and among MIS-C cases which could potentially introduce bias. After adjusting for age, we found that non-headache neurological signs/symptoms were significantly associated with ICU admission (OR: 1.92, 95% CI: 1.08–3.42; p = 0.026). We also found that underlying neurological disorders (OR: 2.98, 95% CI: 1.49–5.97, p = 0.002) and history of fever prior to hospital admission (OR: 2.76, 95% CI: 1.58–4.82; p < 0.001) were significantly associated with neurological involvement other than headache.
Discussion
Approximately 21% of children hospitalized for SARS-CoV-2 infection in our study had neurological involvement. Among these, headache (15%), encephalopathy (4%), and seizures (4%) were most commonly reported, consistent with previous studies. Reference LaRovere, Riggs and Poussaint20,Reference Fink, Robertson and Wainwright25 Notably, headache constituted 70% of the patients with neurological involvement in our cohort. Subgroup analyses revealed that these patients who had headache solely as their neurological signs/symptoms were older and were more likely to meet MIS-C criteria (61% vs 11%) than children without headache, which corroborates with a recent study of 1493 children in the US who were diagnosed with SARS-CoV-2 or MIS-C. Reference Fink, Robertson and Wainwright25 where approximately 47% of children diagnosed with MIS-C and 16% children with acute SARS-CoV-2 presented with headache. The reasons for this are likely complex, and we emphasize that headache may be a symptom only with no associated abnormalities on neurological examination or associated structural abnormalities in the brain as seen on MRI. The fact that the children with MIS-C were less likely to have neurological involvement than the non-MIS-C children may point to the lower rate of underlying neurological conditions in non-MIS-C cohort (12%) vs. the MIS-C cohort (2%) and presence of underlying medical diagnoses in the children in the non-MIS-C cohort (52%) vs. the MIS-C cohort (22%; p < 0.001).
We also make specific note of a high rate (12%) of neurological comorbidities in children with non-headache neurological signs/symptoms. In addition, we found that children with any neurological involvement were more likely to have ICU admission (OR 1.71), and children with non-headache neurological signs/symptoms were more likely to have underlying neurological disorders (OR 2.98) as were those with fever prior to admission (OR 2.76). This emphasizes the complex nature of the illness trajectory of children manifesting with neurological complications.
Seizures were common in our cohort – 20% of those with neurologic involvement and about 4% of the whole cohort – similar to the numbers that some have described in children hospitalized with SARS-CoV-2 infection (0.3-8%) Reference Ray, Abdel-Mannan and Sa19,Reference LaRovere, Riggs and Poussaint20,Reference Fink, Robertson and Wainwright25–Reference Panda, Sharawat, Panda, Natarajan, Bhakat and Dawman28 and at least twice the rate of seizures in hospitalized adults (0-2%) Reference Mao, Jin and Wang11,Reference Lu, Xiong and Liu29,Reference Romero-Sánchez, Díaz-Maroto and Fernández-Díaz30 Much of this can be explained by the relatively high proportion of children with underlying neurological disorders in our cohort with neurological complications and the relatively high rate of children with underlying seizure disorders. It is possible that many children suffered from neurological complications as a result of their overall medical complexity, signaled by the presence of an underlying neurological diagnosis. As this study did not capture specifics regarding medical complexity, we are unable to comment on how many of these children fell into the category of what could be defined as medically complex.
Of note, ICU admission rates appear relatively low among patients with encephalopathy in our cohort (36%), but when only children greater than 12 months of age were included in this calculation, 61% with encephalopathy required ICU admission. We emphasize that the decision to admit to ICU is center-based and that many centers would choose to admit patients to ICU only if the child was in need of intubation or higher-level respiratory support. Furthermore, children under 12 months of age were classified as encephalopathic if they exhibited lethargy and/or irritability. This likely led to the differences noted in rates of ICU stay between infants and children with encephalopathy.
The mechanisms by which neurological complications occurred in our cohort are unknown but are likely multifactorial. It is less likely that SARS-CoV-2 played a direct role in their neurological involvement, but their susceptibility to coinfection may have been enhanced by the presence of illness due to infection with SARS-CoV-2. Reference Zheng, Chen and Wu31 As well, some of the seizures may have occurred as a non-specific response to fever or infection, as is seen frequently in the pediatric population. Finally, seven of the children had inflammatory CNS problems, similar to that which has been described elsewhere in the literature, and which are likely due to secondary immune mechanisms. We emphasized that these were not more frequently found in children with MIS-C suggesting that CNS abnormalities can occur in the absence of evidence of marked systemic inflammation.
Those manifestations, based on laboratory or MRI evidence, which were considered to be post- or para-infectious inflammatory neurological complications, were relatively infrequently seen, comprising just over 10% of the cohort with non-headache neurological complications. SARS-CoV-2 is known to gain entrance into host cells via the binding of viral spike protein to the angiotensin-converting enzyme-2 receptor that is expressed in almost all human tissues and is highly abundant in the brain. Reference Lu, Zhao and Li2,Reference Pellegrini, Albecka and Mallery4,Reference Song, Zhang and Israelow32,Reference Yan, Zhang, Li, Xia, Guo and Zhou33 However, as in our study, the presence of viral RNA and protein has only been rarely identified in the brain and cerebrospinal fluid (CSF) of patients with COVID-19. Reference Moriguchi, Harii and Goto3,Reference Xiang, Xu and Lu34,Reference Domingues, Mendes-Correa and de Moura Leite35 While reports that SARS-CoV-2 can productively infect and replicate in human neuronal cells Reference Chu, Chan and Yuen36 and in brain organoids raises the possibility of direct viral involvement of SARS-CoV-2 in the CNS, Reference Pellegrini, Albecka and Mallery4,Reference Song, Zhang and Israelow32 we emphasize that SARS-CoV-2 was not isolated in any CSF samples. At least some of these events therefore may have resulted from the immunological response to SARS-CoV-2 rather than direct viral invasion of the CNS.
Finally, in contrast to adult studies which document relatively high rates of CNS thrombotic events, only one child had a CNS thrombotic complication, and this was related to a superficial cortical vein. No children presented with stroke or sinovenous thrombosis. This is in keeping with other studies of children which report relatively low rates of CNS thrombotic complications compared to adult populations. Reference Mao, Jin and Wang11,Reference Ray, Abdel-Mannan and Sa19,Reference LaRovere, Riggs and Poussaint20,Reference Beslow, Linds and Fox37–Reference Varatharaj, Thomas and Ellul39
Importantly, abnormalities were likely to be found on neuroimaging in the small number of children who received brain and spine imaging: over 75% of the MRI scans of the brain/spine which were performed were abnormal. Most abnormalities (9/16) appeared to be acute in the context SARS-CoV-2 as described in the results, but interestingly, SARS-CoV-2 infection may have unmasked unrelated neurologic diagnoses, such as presentation with a cluster of new-onset seizures in a child with underlying cortical dysplasia.
Our study’s strengths include the comprehensive coverage of Canadian institutions, multinational collaboration, the relatively large cohort, and the presence of a detailed neurologically focused case report form. We acknowledge several limitations, however. First, the study was retrospective, posing the risk of selection bias, although it is likely that most hospitalized children with positive SARS-CoV-2 testing were captured in the participating centers due to strong surveillance measures, reporting, and frequent testing in each of the participating centers. Second, in-hospital management strategies may differ between institutions, affecting clinical outcome variables including frequency of MRI and CSF acquisition, length of hospital stay, and ICU admission. Third, the aggregate nature of data from various institutions across different countries (all of which participated in this study voluntarily) as well as small sample size restricts the generalizability of findings. Fourth, due to the nature of the data collection, we are unable draw conclusions about the etiologies of the neurological involvement, including potential neurological signs/symptoms which do not have a specific etiological tie to SARS-CoV-2, such as febrile convulsions. Fifth, the classification of encephalopathy in children younger than 1 year of age is challenging, and decision-making around classification is subjective. Sixth, as the majority of infants under one who were noted to have neurological involvement were classified as having encephalopathy, it is possible that some of these children had non-specific symptoms related to general illness rather than focal, neurological abnormalities. Lastly, it is possible that for some of the patients with coinfection, the CNS manifestations and/or abnormal imaging findings were entirely due to the coinfection.
Conclusion
We observed a relatively high rate of neurological involvement in children hospitalized with SARS-CoV-2 infection. Further studies are needed to confirm associations between these factors and neurological involvement of SARS-CoV-2 and investigate long-term neurological and cognitive outcomes in these children.
Supplementary Material
To view supplementary material for this article, please visit https://doi.org/10.1017/cjn.2022.347.
Statement of authorship
EAY conceptualized the study. EAY, MB, JR were the project administrators. EAY, CY, AB, SM, TET, RU-G, HB-C, AY-C, GI-E, AS-F, MH-M, PG, AN, BHA, AAM, RD, JB, JP, RS, MAL, SC, TD, LR, AL, MS, AR, JW, NLS, JB, RP, JL, and CF collected the data. CY and JR curated the data. EAY, CY, MB, and JR verified the data. EAY and CY analyzed the data and drafted the initial manuscript. All authors critically reviewed the manuscript for important intellectual content and approved the final manuscript as submitted.
Conflict of Interests
Unrelated to this work, E.A. Yeh has received research funding from NMSS, CMSC, CIHR, NIH, OIRM, SCN, CBMH Chase an Idea, SickKids Foundation, Rare Diseases Foundation, MS Scientific Foundation (Canada), McLaughlin Centre, Mario Battaglia Foundation. Investigator initiated research funding from Biogen. Scientific advisory: Biogen, Hoffman-LaRoche, Vielabio. Speaker honoraria: Saudi Epilepsy Society, NYU, MS-ATL; ACRS, PRIME. J. Papenburg holds a “Chercheur-boursier clinicien” career award from the Fonds de recherche du Québec – Santé and reports grants from MedImmune, grants from Sanofi Pasteur, personal fees from Seegene, grants and personal fees from AbbVie, outside the submitted work. M. Sadarangani is supported via salary awards from the BC Children’s Hospital Foundation, the Canadian Child Health Clinician Scientist Program, and Michael Smith Health Research BC. M. Sadarangani has been an investigator on projects funded by GlaxoSmithKline, Merck, Moderna, Pfizer, Sanofi Pasteur, Seqirus, Symvivo, and VBI Vaccines. All funds have been paid to his institute, and he has not received any personal payments. S. Morris is co-PI on an investigator-led study funded by Pfizer, has served on ad hoc advisory boards for Pfizer, and has received speaker fees from GlaxoSmithKline and Johnson and Johnson China, all outside of the submitted work. All other authors declare no conflict of interest.