key: cord-0747394-ezj56d1d
authors: Elilarasi, S.; Poovazhagi, V.; Kumaravel, G.; Srividya, V. Gomathy; Solomon, J. Ritchie Sharon
title: Pediatric Inflammatory Multisystem Syndrome Temporally Associated with SARS-CoV-2
date: 2021-11-24
journal: Indian J Pediatr
DOI: 10.1007/s12098-021-03954-8
sha: 4b00c3ec97734ac5b2e9fe65d905631a04620777
doc_id: 747394
cord_uid: ezj56d1d

OBJECTIVES: To know the clinical presentation and outcome of children with pediatric inflammatory multisystem syndrome temporally associated with SARS-CoV- 2 (PIMS-TS) at a pediatric tertiary care center in Chennai. METHODS: Clinical and biochemical parameters of 65 children with PIMS-TS treated between July and October 2020 were studied. All children had their COVID RT-PCR and IgG COVID antibodies tests done. RESULTS: Mean age of the study group was 5.65 ± 3.68 y. Fever with red eyes, rash, vomiting, abdominal pain, and shock were common presenting features. Sixty percent of the study group had Kawasaki/incomplete Kawasaki features. Sixty-seven percent of the study group had coronary dilatation, 41% presented with shock, and 25% had left ventricular dysfunction. Coronary aneurysms were documented in 58% of the study group (z score more than 2.5). Respiratory presentation with pneumonia was seen in 10%. Four children presented with acute abdomen. Acute kidney injury, acute liver failure, hemolysis, pancytopenia, macrophage activation syndrome, encephalopathy, and multiorgan dysfunction syndrome (MODS) were other features. Forty-three percent required noninvasive oxygen support and 15.4% required mechanical ventilation. Intravenous immunoglobulin (73.8%) and methylprednisolone (49.8%) were used for therapy. Mortality in the study was 6%, which was due to MODS. CONCLUSIONS: Acute febrile illness with mucocutaneous and gastrointestinal manifestations should have PIMS-TS as a possible differential diagnosis and needs evaluation with inflammatory markers and SARS-CoV-2 antibodies.

Since the pandemic of coronavirus disease 2019 (COVID- 19) , many countries around the world have reported their data but data from India have been limited. Initial reports suggested that children were spared from severe disease [1] . However, currently there are increasing reports of pediatric multisystem inflammatory syndrome temporally associated with SARS-CoV-2 (PIMS-TS) also called the multisystem inflammatory syndrome in children and adolescents temporally related to COVID-19 and the multisystem inflammatory syndrome in children (MIS-C) [2, 3] . PIMS-TS is a spectrum of disease with phenotypes including Kawasaki disease, toxic shock syndrome, and macrophage activation syndrome [4, 5] . The authors describe their experience of treating children with PIMS-TS from a pediatric tertiary care center in South India.

This was a descriptive study undertaken at the pediatric tertiary care center at Chennai and all children with PIMS-TS admitted to the hospital between July and October 2020 were included. Their medical and laboratory data were analyzed and the symptomatology and outcome were reported. The criteria for diagnosis was based on Royal College of Pediatrics and Child Health, United Kingdom for PIMS-TS [2] . Inclusion criteria included child presenting with:

• Persistent fever > 38.5 °C • Laboratory evidence of inflammation (ex: neutrophilia, elevated CRP, lymphopenia) • Single or multiorgan dysfunction Exclusion of alternative causes. SARS-CoV-2 testing can be positive or negative.

The primary aim of this study was to identify the different phenotypes of PIMS-TS spectrum and its outcome. Children were included after caregiver's informed consent. Data on demographics, clinical presentation, laboratory, and radiological investigation, ECG, ECHO, and management and outcome were collected. Vital parameters like heart rate, respiratory rate, and blood pressure were analyzed as per standard definitions [6] . Echocardiogram was done by a pediatric cardiologist using GE VIVID S6 ultrasound machine with phased array cardiac transducer. Coronary abnormalities were categorized as normal if z score was < 2, dilatation, if between 2 and 2.5, mild aneurysm if between 2.5 and 5, moderate if between 5 and 10, and severe if > 10 [7] . SARS-CoV-2 IgG antibody test was performed with ICMR-approved SARS-CoV-2 IgG antibody titer assay kits as per manufacturer's instructions; and titers more than 10 AU was considered reactive. SARS-CoV-2 real-time polymerase chain reaction (RT-PCR) was done by ICMR-approved laboratory. All children were followed up till discharge from the hospital or death in case of hospital mortality. The study was undertaken after ethics approval. Statistical analysis was undertaken using the Epi Info version 7.2 stat software. Continuous variables were reported as means, medians, and range and categorical variables as frequency.

A total of 65 children were included for analysis in the study. The age group ranged from 2 mo to 12 y with a median age of 5 y, of which, 6.1% (4/65) were less than 12 mo, 44.6% (29/65) were between 1 and 5 y, and 49.23% (32/65) were between 5 and 12 y. Male to female ratio was 1.5:1. None of these children were obese. Nine (6%) children had history of contact with individuals with COVID-19 infection and 2 of them were COVID-19 RT-PCR-positive in the previous 4 wk. Two children had no history of contact or previous COVID infection or presence of antibody, but had features of coronary aneurysm. SARS-CoV-2 IgG antibodies were present in 86% (56/65).

The median duration of illness was 5 d (range 2-14 d). Of the 65 children, 27 (41.5%) presented with shock at the emergency room and 17 (26%) were hypotensive at admission to PICU. Thirty-three children required PICU care. Inotrope support was needed in 25/65 (38.5%) children. Twelve children required one inotrope, 9 required two inotropes, 3 children required three inotropes, and 1 child required four inotropes. Clinical features are summarized in Table 1 . Differential diagnosis considered at admission included acute febrile illness, dengue, scrub typhus fever, and fever with thrombocytopenia, bronchopneumonia, and acute abdomen. Highest temperature recorded was 108 ˚F with a mean of 102.58 ± 1.72 ˚F. Respiratory involvement was in the form of breathlessness, pleural effusion 12% (8/65), consolidation in 9% (6/65), and ARDS in 1 child. Nearly half of the children [54% (38/65)] required respiratory support. Twentythree needed non-rebreathing mask oxygen, 3 required highflow humidified nasal cannula oxygen (HHFNC), 2 required BIPAP, and 10 required mechanical ventilation.

Of the 65 children, 35 had received either antibiotics or antiemetics or analgesics/antipyretics before presenting to the authors' institute. Clinical presentation was predominantly acute febrile illness with mucocutaneous and gastrointestinal manifestations as shown in Table 1 . Mucocutaneous features included skin rash, edema, conjunctival congestion, cracked lips, red lips, red tongue, and peeling of skin. Gastrointestinal manifestations included, nausea, vomiting, diarrhea, and pain in abdomen. Cardiac involvement included coronary artery abnormalities (68%, 44/65), tachycardia (60%, 39/65), shock (42%, 27/65), hypotension (26%, 17/65), and left ventricular dysfunction (25%, 16/65). Coronary artery abnormalities seen were nontapering coronaries, echogenic coronaries, coronary dilatation, and coronary aneurysm with a z score > 2.5. Coronary abnormalities were seen in 44 children. Eight had dilatation (z score 2-2.5), 34 had small aneurysm (z score 2.5-5), 1 had medium aneurysm (z score 5-10), and 1 had echogenic and tram tracking of coronaries. Figure 1 shows dilated coronaries in short Other ECHO findings included pericardial effusion (49.2%), mitral regurgitation (17/65), aortic regurgitation (2/65), and tricuspid regurgitation (3/65). One child had supraventricular tachycardia. Neurological features included encephalopathy in 6% (4/65), seizures in 3% (2/65), and stroke in 1 child. One child had refractory hypertension for weeks following diagnosis and is on antihypertensives. Acute abdomen (surgical presentation) was seen in 4 children. Three of them were operated and were later diagnosed as PIMS-TS. Associated comorbid conditions included febrile seizures (3/65), children known to have reactive airway disease (3/65), and acute lymphoblastic leukemia (2/65). Hematological abnormalities included anemia (78%, 51/65), neutrophilic leucocytosis (70.7%, 46/65), lymphopenia (72.3%, 47/65), high neutrophil lymphocyte ratio more than 3 (55%, 33/65), thrombocytopenia (55%, 33/65), thrombocytosis (31.25%, 20/65), pancytopenia (29%, 19/65), and hemophagocytosis (6%, 4/65). Renal involvement with elevated urea was reported in 37% (24/65) of children. Renal complications (pRIFLE) included risk in 4 children, injury in 5, and failure in 3. Hepatic involvement included elevated SGOT (49%, 32/65), elevated SGPT (32%, 21/65), and hyperbilirubinemia (17%, 11/65), ascites in 15% (10/65), and acute liver cell failure in 7.7% (5/65). Other laboratory abnormalities included hyponatremia (84.62%, 55/65) and hypoalbuminemia (40%, 26/65). Thirty-eight children had LDH levels measured and all of them had elevated LDH and 81.6% (31/38) had anemia with elevated LDH levels.

Coinfections noted were dengue, scrub typhus, and typhoid in 1 child each, which were excluded from the study group.

Overall, the clinical phenotypes were as follows: Kawasaki phenotype [51/65, (78.4%)], toxic shock syndrome phenotype [27/65, (41%)], and HLH phenotype [6/65, (9.23%)]. Nine children (13.8%) had no specific phenotype. Multiorgan failure was seen in 7 (10.7%) children. The laboratory findings are summarized in Table 2 . Management of children with coronary dilatation was by 2 g/kg of intravenous immunoglobulin (IVIG) and aspirin with or without steroids. Children with LV dysfunction and those refractory to IVIG were on pulse methylprednisolone. Presence of myocardial dysfunction or hemodynamic compromise in the form of shock were considered as upfront indications to start on methylprednisolone along with IVIG. Therapy included IVIG and methylprednisolone in 36 children, IVIG alone in 12 children, methyl prednisolone alone in 6, dexamethasone in 3 children, tocilizumab in 4 children, and aspirin in 48 children. Overall mortality was 6% (4/65); among those who died, all 4 received IVIG and methyl prednisolone, and 1 received tocilizumab in addition. All the 4 children who died had shock, multiorgan dysfunction (MODS), encephalopathy, and macrophage activation syndrome (MAS). Three had Kawasaki-like features and 3 had acute kidney injury (AKI). High NLR ratio, AKI, MODS, shock, and HLH were identified to be associated with mortality with a p value of 0.00002, 0.008, 0.0001, 0.013, and 0.0008, respectively (Table 3 ).

PIMS-TS is a rare pediatric condition characterized by hyperinflammation and multiorgan dysfunction frequently following an infectious trigger by SARS-CoV-2. PIMS-TS was initially reported by pediatricians in UK. Subsequently, the US center for disease control and the WHO published the criteria and named it as multisystem inflammatory syndrome in children (MIS-C) and RCPCH defined it as PIMS-TS [2, 3] . This condition is typically seen 2-4 wk after an acute COVID-19 infection. However, in the present cohort, only 9 children reported history of COVID-19 infection or contact with COVID infection in the recent past. The median age group was similar to other published reports [5, 8, 9] and as described in other reports, a male preponderance was found in this study as well [10] . Data from the present study add to the evidence that a large proportion of children with PIMS-TS present with gastrointestinal manifestations [8, [11] [12] [13] [14] [15] , thus highlighting that PIMS-TS should be considered in children presenting with fever and GI symptoms. Mucocutaneous features like red eye and rashes is another common presentation similar to the studies elsewhere [16, 17] . Median duration of illness was 5 d and can range from 3-9 d [5, 18] . Lymphopenia was seen in 72% and is a common finding in PIMS-TS [12, 19] . The coronary dilatation among children with PIMS-TS varies from 8%-63% [9, 20, 21] . In contrast to the published literature from South India [6] , more than two-thirds (68%, 44/65) of the children presented with coronary abnormalities. Higher percentage of coronary involvement or the Kawasaki-like feature in this study group could be attributed to the delayed referral pattern seen during the COVID-19 pandemic. Acute abdominal pain presenting as a surgical emergency has been previously reported in children with PIMS-TS [22, 23] . Similar to this, 3 of the children in the present study were also operated for appendicitis and later diagnosed as PIMS-TS. Clinical features of PIMS-TS often overlap with the clinical presentation of other infectious diseases, especially scrub typhus fever and dengue. Hence, it is imperative to consider and exclude other causes of acute febrile illness in children in tropical countries. Presence of lymphopenia, high neutrophil -to-lymphocyte ratio, raised ESR, hyponatremia, hypoalbuminemia along with either previous history of COVID-19 or contact with COVID-19 or a positive IgG antibody status would help clinicians differentiate PIMS TS.

The limitation of this study is that COVID RT-PCR-positive children were treated in COVID-exclusive facility and could not be included. Overlap of Kawasaki disease in Kawasaki phenotype of MIS-C is possible. Likewise, being a tertiary care referral hospital, children with severe complications may have been received and mild cases of PIMS-TS could have been missed or not referred to. Being a new disease there is an urgent need for further research and long-term follow-up of these children. Future research 

Acute febrile illness with mucocutaneous and gastrointestinal manifestations should have evaluation with laboratory markers, ECHO, and SARS-CoV-2 antibodies. PIMS-TS spectrum in children includes acute febrile illness with Kawasaki-like features with or without shock, and acute abdomen. Myocardial dysfunction, shock, leucopenia, thrombocytopenia, high neutrophil-to-lymphocyte ratio, hyponatremia, and hypoalbuminemia are frequently encountered in KD phenotype PIMS-TS. Macrophage activation syndrome, encephalopathy, stroke, acute abdomen, hemolysis, and thrombotic microangiopathy are less common presentations of PIMS-TS in children. Therapy includes intravenous immunoglobulin, methylprednisolone, and immunomodulatory agents like tocilizumab. Outcome is good if recognized early and treated appropriately. High NLR ratio, AKI, MODS, shock, and HLH were identified to be associated with mortality with a p value of 0.000, 0.008, 0.0001, 0.013, 0.0008, respectively.

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The authors are thankful to Dr Aishwarya Ven-