key: cord-0918918-ee9s3x37 authors: Regmi, Pradeep Raj; Amatya, Isha; Paudel, Sharma; Kayastha, Prakash title: Pediatric Radiology in Era of COVID-19, International Consensus and What Lies Beyond Pneumonia: A Review date: 2021-11-30 journal: JNMA J Nepal Med Assoc DOI: 10.31729/jnma.7122 sha: 97fdd891f3d3f346820342d3b787e13e60c96c59 doc_id: 918918 cord_uid: ee9s3x37 Diagnostic radiology plays a crucial role in children. The pediatric population has been less studied than the adult population since the initial period of the COVID-19 pandemic to date. Realizing the potential utility of structured reporting, different guidelines and international consensus statements regarding COVID-19 in the pediatric population have been released in recent times. Different clinical and radiological manifestations in children have been evolving in this period of uncertainty and are different from the adult population in certain aspects. Apart from the involvement of lungs, a multisystemic inflammatory syndrome in children or pediatric multi systemic inflammatory syndrome is unique in children. Therefore, awareness of the recent consensus, structural uniform reporting and multi-organ involving patterns in COVID-19 can guide radiologists for a better understanding of this complex novel disease leading to early diagnosis and timely treatment of affected children. Coronavirus belongs to the family Coronaviridae and the order Nicovarales, a family that includes the virus ranging from the common cold to Severe Acute Respiratory Syndrome (SARS) and middleeast respiratory syndrome (MERS). 1, 2 The first adult case of COVID-19 was reported on 31 st December 2019 in Wuhan, China. The first recorded case outside China was on 13 th January 2020 in Thailand. 3 World Health Organization (WHO) declared COVID-19 as a pandemic disease on 11 th March, 2020. 4 Globally, there have been 164,409,804 confirmed cases of COVID-19 including 3,409,220 deaths till 20 th May 2021. 3 The first case of COVID-19 in Nepal was recorded on 13 th January 2020, in a 32-year-old man traveling from Wuhan to Kathmandu. 5 As of 20 th May, there have been 480,418 confirmed cases of COVID-19 with 5,657 deaths, reported to WHO from Nepal. 3 Infections by COVID-19 continue to increase worldwide and Nepal is facing the second wave of the pandemic. The first confirmed case in children was reported in January 2020 in Schenzen, China. 6 Children comprise 22% of the USA (United States of America) population and according to the Centers for Disease Control and Prevention (CDC), approximately 14% of all cases of COVID-19 were among children. 7, 8 Exact number of children affected with COVID-19 is not available in Nepal. However, 121 children were diagnosed with COVID-19 in the government-based COVID care centers in Kathmandu from January 2020 till August 2020. Fever was the most common symptom in 18.2% of children. Most of the pediatric population are asymptomatic (71.9%) or had the mild disease (22.3%) and 4.9% had moderate to severe symptoms. 9, 10 In the cross-sectional study of 46 North American PICUs, between March 14 and April 3, 2020, 48 children were admitted to 14 PICUs in the US and none in Canada. A total of 40 children (83%) had pre existing underlying medical conditions, 35 (73%) presented with respiratory symptoms, and 18 (38%) required invasive ventilation, and the hospital mortality rate was 4.2%. 11 Pediatric population has been less studied is compared to the adult population affected by this mysterious disease. JNMA I VOL 59 I ISSUE 243 I November 2021 The large number of people that were exposed to the wet animal market in Wuhan city were infected, most likely of zoonotic origin. Person-to-person transmission occurs primarily via direct contact or through the droplets spread by coughing or sneezing from the affected individual. 2, 3 The major route of transmission is through respiratory droplets. However, the viral RNA samples were detected in samples of gastrointestinal tracts (saliva and rectal) of children which probably indicates the possible other routes of transmission in children. [12] [13] [14] [15] In Nepal, the majority of children (83.4%) were identified as a part of contact tracing, 28.1% had an identified contact to a person with COVID-19 before their diagnosis and 20.7% had another household member diagnosed with COVID-19. 9 Other manifestation of COVID-19 in children are severe respiratory infections or multisystem inflammatory disorder (MIS-C) with overlapping features with Kawasaki disease and toxic shock syndrome. Children with more than one comorbid condition have a higher risk of having severe disease. The clinical manifestations in children are milder compared to adults. The exact cause of this difference is unknown. However, there are some hypotheses such as viral load are lower in children than adults and under-expression of the angiotensin-converting enzyme-2, the binding receptor for COVID-19 spike protein. [10] [11] [12] [13] [14] [15] Diagnostic radiology plays an even more important role in the diagnosis, treatment, monitoring, and follow-up of pediatric patients. Different guidelines and consensus have been published for imaging of children with COVID-19. However, imaging is not indicated for screening purposes or in a child with the mild disease unless a patient has risk factors for progression or develops worsening symptoms. 16 Mild disease signifies the patient with clinical symptoms such as fever, cough, mild dyspnea, and/or rhinorrhea whereas moderate to severe signifies patient with signs of more serious respiratory compromise (moderate to severe dyspnea or hypoxemia) or symptoms of cardiovascular compromise and/or pending shock (chest pain, tachycardia, hypotension, or altered mentation). In RT-PCR positive patients with comorbid status like asthma, cystic fibrosis, tuberculosis, HIV, or immune-compromised state, chest imaging is recommended as a baseline and for another possible differential diagnosis. In moderate to severe disease, in resource-limited settings (unavailable of adequate lab facilities and long turnaround time), imaging may be used in the initial phase in presumed positive cases which significantly affects patient management. Serial imaging is advised in moderate to severe disease as needed to access the response to therapy, evaluate clinical deterioration, or assess the positions of lifesupporting devices. Post recovery chest imaging is not advised for the asymptomatic mild disease. However, in asymptomatic patients with initial moderate to the severe disease having clinical concerns for long-term lung injury and prior COVID-19 patients with long-term symptoms, follow-up imaging may be done. [17] [18] [19] Chest X-Ray (CXR) is the first go-to modality in cases with moderate or severe disease. According to the American College of Radiology (ACR), imaging is not indicated in screening and in well-appearing immunecompetent children more than 3 months old who do not require hospitalization. 18 However, similar to other viral infections, imaging is considered if the child does not respond to outpatient treatment, who requires hospitalization, and who is suspected of having community-acquired pneumonia. Chest Computed Tomography (CT) can be used to answer the specific question in a child with raised D-dimer and suspicion of pulmonary embolism. Follow-up imaging might be required in a child with the progressive disease with development and evolution of pulmonary fibrosis and significant alteration in pulmonary function test in a child with post-COVID-19 pneumonia. When performing imaging in children, multiple factors like availability of RT-PCR tests, the sensitivity of early imaging, and radiation dose should be taken into consideration. Recommended structural reporting formats for CXR in children with COVID-19 are 19,20 : 1. Typical: Bilateral peripheral/subpleural groundglass opacities (GGOs)/consolidation with suggested reporting language as imaging findings commonly seen with COVID-19 pneumonia in children. Other differentials include viral or atypical pneumonia. pneumonia and includes both infectious and non-infectious etiologies. Unilateral peripheral or peripheral and central GGOs and/or consolidation. Bilateral peribronchial thickening and/or peribronchial opacities. Multifocal or diffuse GGOs and/or consolidation without specific distribution. Uncommon or not reported imaging findings and recommend consideration of another diagnosis. Unilateral segmental or lobar consolidation, central unilateral or bilateral GGOs and/or consolidation, single round consolidation (round pneumonia with or without air bronchogram), pleural effusion, and lymphadenopathy. GGOs/consolidation predominant in lower lobes. "Halo sign" in early cases i.e. subtle area of ground-glass opacities with central consolidation which later progresses to frank ground-glass opacities (progressive phase) and consolidation pattern in developed phase. Differential diagnosis includes other viral or atypical pneumonia, hypersensitivity pneumonitis, eosinophilic lung disease, and fungal infection (especially in an immune-compromised child with halo sign). Unilateral peripheral or peripheral/ central GGOs and/or consolidation. Bilateral peribronchial thickening and/or peribronchial opacities. Multifocal or diffuse GGOs and/or consolidation without specific distribution. "Crazy paving sign". Uncommon or not reported findings and recommend consideration of alternative diagnosis. Unilateral segmental or lobar consolidation, central unilateral or bilateral GGOs/ consolidation, discrete small nodules or tree-inbud opacities, lung cavitation, pleural effusion, and lymphadenopathy. No CT findings suggestive of pneumonia (Note: Chest CT may be negative in early stage) Lung ultrasound (LUS) is a useful imaging modality especially in children as it is radiation-free. It provides the bedside diagnosis of many pulmonary conditions and status of the lung in an emergency as well as pediatric intensive care units (PICU). It is highly reliable for pneumonia, pleural effusion, and pneumothorax. Because of the peripheral or subpleural predominance of COVID-19, LUS can play a vital role in the early detection of the disease. An easier process of decontamination after the procedure is an added advantage in contrast to chest CT. Transportation of critically ill children can be difficult at times which can be solved through bedside ultrasound. However, the inability to detect the central consolidation and userdependent are some of its limitations. [21] [22] [23] [24] [25] [26] A High-frequency transducer (15 MHz) is used and the intercostal spaces of the upper and lower parts of the anterior, lateral, and posterior regions of the bilateral chest are examined with a total of 12 regions. Four patterns were defined and given a score for each: 1. Normal aeration: the presence of lung sliding and artifactual horizontal A-lines (0 points), 2. Loss of lung aeration resulting from the scattered foci of bronchopneumonia or interstitial syndrome: the presence of multiple well-defined vertical B-lines extending from the pleural line or a small subpleural consolidation (1 point), 3. Loss of lung aeration resulting from alveolar-interstitial edema that corresponds to the CT imaging entity of the ground-glass: multiple confluent vertical B-lines extending from the pleural line or a small subpleural consolidation (2 points), 4. Lung consolidation characterizing extensive bronchopneumonia: the presence of a tissue structure containing hyper-echoic punctate foci representative of air bronchogram (3 points). A global LUS aeration score ranging from 0 to 36 was obtained by summing the individual scores of all the regions. The high US score was seen in moderate to severe disease which is consistent with CT findings. 21, 22 In a study done by Denina, et al, 22 LUS performed in 8 patients, paying particular attention to signs of viral pneumonia as small subpleural consolidations and/ or individual B-lines or confluent B-lines (echogenic vertical lines arising from the pleural line and moving in concert with a sliding lung, expression of an interstitial syndrome). LUS revealed subpleural consolidations in 2 children and confluent B-lines in 5 children. In 7 of 8 patients, we found a concordance with the radiologic findings, whereas in the remaining patient, an interstitial B-lines pattern was observed despite normal chest radiography. One patient with severe clinical type was repeatedly examined with LUS on alternate days, and we noted a B-lines bilateral pattern reduction a day in advance before clinical and radiographic improvement. However, largescale studies are required for its validation and need to expand evidence in point-of-care ultrasound in children. In a retrospective literature review of 39 published articles involving 850 pediatric populations (<18 years and COVID-19 RT-PCR positive), 26.5% of patients had normal CT findings and 55% had involvement of unilateral lung fields. Ground-glass opacities and consolidations were the most common CT abnormalities (61.5%). A combination of GGOs and consolidation was found in 3.7% and other findings were halo sign, interstitial opacities, bronchial wall thickening, and crazy-paving sign. 27 Another study done in Spain showed that CXRs were performed in 35 patients (80 % of admissions) and the most common indications were fever and respiratory JNMA I VOL 59 I ISSUE 243 I November 2021 symptoms. 53 % of the chest X-rays were considered normal and the classical bilateral diffuse interstitial pattern, described in adults, was only present in 22 %. All patients with pathological chest X-rays were symptomatic and reported fever (100 %) and fever tended to be longer (fever duration: 4.25 vs. 2.46 days p: 0.048) in patients with pathological radiographs. We present a specific protocol for chest imaging in pediatric COVID-19 cases. 28 Bronchial wall thickening is a common finding in children. In RT-PCR positive cases of COVID-19, Chen et. al identified ground-glass opacities were present in 42.9%, bronchial wall thickening in 28.6%, and GGOs as well as consolidations along with nodular opacities in 14.3% of cases. 29 After reviewing the imaging findings in RT-PCR positive patients (age 10 months to 18 years) from the six centers in China, CT findings were negative in 77% of the patients. Crazy paving patterns were observed in 29% of the patients and 23% had GGOs and peripheral lung consolidation. Predominant patterns of 86% of the cases were peripheral or sub-pleural. However, pleural effusion, lymphadenopathy, pulmonary nodularity, and fibrosis are absent in all cases. There was a positive correlation between increasing age and severity of the clinical and radiological manifestations. 30 Yu H, et al. performed CT on 82 RT-PCR positive children and reported unilateral pneumonia in 46% and bilateral distribution were present in 36.5% of cases. 31 Bilateral and multifocal involvement were seen in 55% of CT examinations and single lesion and single lobe involvement were detected in 27% of cases. Pure ground glass appearance was observed in 41%, ground-glass appearance and consolidation together were seen in 36% of the cases. There was significant involvement of the lower lobes and peripheral and central co-distribution of the lesions were frequently observed. There were coexistence of multiple rounded multifocal ground-glass appearance and rounded consolidation. 32 In a study performed in neonates to 16 years children with confirmed COVID-19 in a tertiary pediatric hospital in Spain, fever was the most common symptom (43.5%). 90% of CXRs showed abnormalities. Peribronchial cuffing was the most common finding (86.3%) followed by GGOs (50%). In the majority of cases, central distribution was more common than peripheral. Follow-up CXRs were also performed in children depending on clinical evolution. Most of the children (75%) were completely recovered and underwent CXRs on discharge which showed complete resolution. Unfavorable outcomes were seen in the children having bilateral diffuse opacities with peribronchial cuffing and GGOs. 33 CT findings were abnormal in 17 (71%) patients, with 5 (21%), 9 (38%), and 3 (13%) patients considered to have typical, indeterminate, and atypical findings, respectively. The most common CT patterns were multiple ground-glass opacities (58%), followed by consolidations (50%). Six patients showed the predominantly peripheral distribution of parenchymal abnormalities. A halo sign was identified in 3 patients and a perilobular pattern was identified in one of the cases with typical findings. 34 In recent times, a new syndrome associated with severe COVID infection was coined which is known as pediatric multisystem inflammatory syndrome (PMIS) or multisystem inflammatory syndrome in children (MIS-C). It is one of the peculiar characteristics in children with COVID-19. [35] [36] [37] [38] [39] MIS-C associated with COVID-19 is characterized by persistent fever associated with abdominal pain, vomiting, diarrhea, rash, conjunctivitis, and other mucocutaneous manifestations. [36] [37] [38] [39] [40] [41] [42] [43] [44] Case definitions for post-COVID-19 hyperinflammatory syndrome according to World Health Organization (WHO) 35 Similarly, case definitions given by CDC 35 include 1. An individual aged <21 years presenting with fever, laboratory evidence of inflammation, and evidence of clinically severe illness requiring hospitalization with multisystem (>2) organ involvement (cardiac, renal, respiratory, hematologic, gastrointestinal, dermatologic, or neurologic), 2. Fever >38.0°C for ≥24 hours or report of subjective fever ≥24 hours, 3. At least one of the following laboratory findings: an elevated CRP level, ESR, fibrinogen, procalcitonin, d-dimer, ferritin, lactic acid dehydrogenase, or IL-6 levels; elevated neutrophil level; reduced lymphocyte level; and low albumin level, 4. No alternative plausible diagnosis and 5. Positive for current or recent SARS-CoV-2 infection at RT-PCR assay, serology, or antigen test or COVID-19 exposure within the 4 weeks before the onset of symptoms, or 6. Additional comments state that some individuals may fulfill full or partial criteria for Kawasaki disease but should be reported if they meet the case definition for MIS-C. MIS-C should be considered in any pediatric death with evidence of SARS-CoV-2 infection. 35 There was a range of multisystem abnormalities in children. The abnormalities were 1. Cardiovascular (51%): cardiomegaly, pericardial effusion, pancarditis, myocarditis, decreased myocardial contractility, coronary artery aneurysms (20%), 2. Gastrointestinal/ hepatobiliary: Ascites, mesenteric inflammatory change, right iliac fossa lymphadenopathy (37%), bowel wall thickening in right iliac fossa (29%), splenic infarcts, gallbladder sludge, and wall thickening, 3. Respiratory: perihilar bronchial wall/interstitial thickening (34%), atelectasis (often fleeting), consolidation: perihilar or lower lobes, round pulmonary consolidations with ground-glass halo, pleural effusions (11%), 4. Central nervous system: large hemispheric infarct (one case; most likely secondary to extracorporeal membrane oxygenation). 25 In children with MIS-C associated with COVID-19, the most common thoracic imaging abnormalities were cardiomegaly, congestive heart failure, or pulmonary edema and effusions. Interestingly, in patients with COVID-19, consolidations/ GGOs were the most common abnormality. Common abdominal abnormalities were ascites, hepatomegaly, and echogenic kidneys (present in 1/3 rd of the patients due to multi-organ injury). 36 Children with MIS-C were more likely to have interstitial opacities and pleural effusions. 37 The study done by EP Fenlon et. al identified that 82% of chest radiographs in children infected with COVID-19 had some findings. Pulmonary opacities were the most common findings in children (62%), which were bilateral and diffuse. Bronchial wall thickening was present in 58%. On abdominal findings, minimal ascites was present in 54% of cases and other findings were bowel wall thickening in the right iliac fossa along with lymphadenopathy. 38 Neurological manifestations in children with COVID-19 were identified by the ASPNR PECOBIG collaborator group. The most common imaging findings were posted infectious immune-mediated acute disseminated encephalomyelitis-like changes of the brain, myelitis, and neural enhancement. Patients had splenial lesions and had myositis in children with MIS-C. Cerebrovascular complications in children were less common than in adults. Significant preexisting comorbidities were absent and most children had favorable outcomes. 39, 45 Another interesting aspect of the COVID-19 era is highlighted by Bottari G et Evidence of manifestations of COVID-19 in children continues to evolve around the world. Imaging is not recommended for screening in children with mild symptoms. Multiple factors like the availability of RT-PCR tests, the sensitivity of early imaging in children should be taken into consideration. Radiological investigations must be done with caution in children with low doses following the ALARA principle. Multisystemic inflammatory syndrome in children is a unique manifestation. Most of the multisystemic manifestations are typical in children in contrast to the adult population. International consensus and structured reporting algorithms guide the general as well as pediatric radiologists for uniform reporting around the world for this novel disease. 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