Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-22T18:12:48.623Z Has data issue: false hasContentIssue false
  • English
  • Français

Adverse effects of COVID-19 vaccine in the paediatric population: a focus on the cardiovascular system

Published online by Cambridge University Press:  05 December 2024

Ghena Lababidi Open the ORCID record for Ghena Lababidi [Opens in a new window] ,
Hossam Lababidi ,
Fadi Bitar Open the ORCID record for Fadi Bitar [Opens in a new window]  and
Mariam Arabi Open the ORCID record for Mariam Arabi [Opens in a new window]
Ghena Lababidi
Affiliation:
Department of Pediatrics, Children’s Heart Centre, American University of Beirut, Beirut, Lebanon
Hossam Lababidi
Affiliation:
Faculty of Medicine, American University of Beirut, Beirut, Lebanon
Fadi Bitar
Affiliation:
Department of Pediatrics, Children’s Heart Centre, American University of Beirut, Beirut, Lebanon
Mariam Arabi*
Affiliation:
Department of Pediatrics, Children’s Heart Centre, American University of Beirut, Beirut, Lebanon
*
Corresponding author: Mariam Arabi; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The COVID-19 pandemic had an unprecedented impact on healthcare systems and exists globally. To control pandemic progression, COVID-19 vaccines were developed and licensed for use in the adult population in early 2021 and became available in paediatric cohorts several months later. Since then, several studies have reported adverse events and severe adverse events in the adult and paediatric cohorts. The question remains whether there exists a significant risk to paediatric COVID-19 vaccination. This study reviews the classification and presentation of severe adverse events and discusses relevant reports in the literature. An emphasis is put on cardiovascular severe adverse events and adverse events. This paper also provides current and future perspectives relative to the pandemic, its control, and the future of vaccine immunology.

Keywords

COVID-19paediatric cardiologyCOVID-19 vaccine
Type
Review
Information
Cardiology in the Young , First View , pp. 1 - 9
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

The pandemic: an overview

COVID-19, short for coronavirus disease 2019, is an infectious disease caused by a novel coronavirus known as SARS-CoV-2. Reference Zhang, Wu and Zhang1 The virus is genetically similar to SARS-CoV and MERS, which both caused pandemics in 2002–2003 and 2012, respectively. Reference Chan-Yeung and Xu2,Reference Zaki, van Boheemen, Bestebroer, Osterhaus and Fouchier3 After emerging in Wuhan, China, in 2019, the virus spread rapidly leading to a global pandemic. The virus itself is made of a spike protein (S), a membrane protein (M), and an envelope protein (E). The spike protein permits viral entry into cells and is found on the surface of the virus, such that it is responsible for the characteristic crown-like appearance of the virus. The virus is an enveloped single-stranded RNA virus and uses the abundant membrane protein for viral assembly and the envelope protein for assembly and release. The virus also contains an N (Nucleocaspid) protein that encapsulates its genetic material. Reference Walls, Park, Tortorici, Wall, McGuire and Veesler4,Reference Masters5

Because the virus is highly transmissible, and individuals can be asymptomatic carriers, containing the virus presented many challenges. Reference Liu6 Closures and quarantine were in place internationally to varying degrees between 2020 and 2022, with unprecedented impacts on the healthcare and socio-economic sectors. Reference Selden7 Studies showed that the pandemic limited access to healthcare leading to delays in disease diagnosis and scheduled intervention, Reference Wee, Sim, Conceicao, Aung, Ng and Ling8 with a disproportionate impact on low-income households. The pandemic also highlighted racial disparities in both access to healthcare and education and livelihood, Reference Price-Haywood, Burton, Fort and Seoane9 with economic hardships such as unemployment most negatively impacting low-income service and hospitality workers. Reference Makridis10 Paediatric patients were particularly negatively impacted by these effects, with highly concerning increases in anxiety and depression being noted amongst young cohorts during the pandemic. Reference Hafstad, Sætren, Wentzel-Larsen and Augusti11

Global vaccination efforts have allowed communities to shift out of quarantines and transition back into normal life, proving to be a highly effective form of COVID-19 prevention. Vaccines such as Pfizer/BioNTech (Comirnaty), AstraZeneca/AZD1222, Janssen/Ad26.COV 2.S, Sinopharm BIBP COVID-19 (Sinovac-CoronaVac) and more have permitted international travel, school re-opening, and a return of social life. Reference Polack, Thomas and Kitchin12 A summary of available adult and paediatric COVID-19 vaccines can be found in Tables 1 and 2. Though exact figures for global COVID-19 vaccine rates in the paediatric cohort are not available, they are highly suspected to comprise less than 5% of the total number of administered vaccine doses, which are 13,337,787,446 doses. Despite the overwhelming positive impact of vaccination on this transition, there remain several concerns about the efficacy and safety of these vaccines, particularly in the paediatric cohort. Vaccine hesitancy is highly attributed to the fear of severe adverse events, and since the beginning of vaccine administration, several reports and studies have been published highlighting the incidence, management, and impact of severe adverse events to COVID-19 in the paediatric cohort. Reference Smith and Marshall13

Table 1. Adverse events reported by the Food and Drug Administration, Centers for Disease Control and Prevention, and World Health Organization relative to the five most popular modalities as of March 2023:*

*All incidence rates and totals were calculated based on data up until 3 March 2023.

**The incidence rates in the tables are calculated based on the reported cases in the cohort and the total number of doses administered in the USA, not the total number of doses administered worldwide. This is for the sake of consistency as most data were obtained from the Centers for Disease Control and Prevention and Food and Drug Administration that report exclusively on US severe adverse event.

Table 2. Adverse events of paediatric COVID-19 vaccination reported by the Food and Drug Administration, Centers for Disease Control and Prevention, and World Health Organization relative to the two most popular paediatric vaccine modalities as of March 2023.24*

*All incidence rates and totals were calculated based on data up until 3 March 2023.

**The incidence rates in the tables are calculated based on the reported cases in the cohort and the total number of doses administered in the USA, not the total number of doses administered worldwide. This is for the sake of consistency as most data were obtained from the Centers for Disease Control and Prevention and Food and Drug Administration that report exclusively on US severe adverse event.

Adverse event characterisation in adults

Though definitions of adverse events differ between studies and studied populations, it is generally accepted that adverse events are unsolicited events that are reported by subjects/patients or observed by healthcare professionals and negatively impact the prognosis or current quality of life of a patient. Severe adverse events have a personified negative influence. 14 An example of a severe adverse event following COVID-19 vaccination may be as extreme as a multisystem inflammatory syndrome. Reference Nikolopoulou and Maltezou15

Because adults were vaccinated prior to paediatric vaccine authorisation, several adverse events have been described in an adult cohort. A review of the most common adverse events along with their incidence rates and management plans associated with the four most used COVID-19 vaccines can be found in Table 1. Table 1 contains data on the total reported number of administered doses and is not specific to a paediatric cohort, though the remainder of the review focuses exclusively on paediatrics.

Objective

The aim of this literature review is to summarise existing data on adverse events resultant of paediatric COVID-19 vaccination, as well as to present data on the safety of existing vaccine options. This review further summarises the outcomes of COVID-19 vaccination in paediatrics and comments on factors contributing to vaccine hesitancy. Lastly, this review highlights the impact of COVID-19 vaccination on the cardiovascular system of paediatric patients, with emphasis on cardiac-related severe adverse events and adverse events presenting in paediatric cardiac patients.

Methods

A literature search was conducted on PubMed under the COVID-19 vaccination MeSH term. “COVID-19 vaccination” and “cardiovascular” as well as their synonyms were used as keywords. The search was restricted to adverse events and patients aged 0–18 years (paediatric). The search revealed 251 articles between the end of 2020 and the beginning of 2023. A concurrent search was done on ClinicalTrials.gov to obtain data on ongoing and future trials relevant to the subject. Post-title abstract screening where inclusion criteria was a clearly stated objective to the paper and discussion of both COVID-19 vaccination in paediatric patients and adverse events, 112 articles were relevant. Papers were only referenced if written in English and published by an official public health authority (Centers for Disease Control and Prevention, World Health Organization, etc.) or in peer-reviewed journals. A diversity of works was discussed, ranging from case reports to large-scale clinical trials.

Results

mRNA vaccines

Though the focus of this review is severe adverse events, it is important to first consider side effects and adverse events of paediatric COVID-19 vaccination. Side effects tend to be routine, mild, temporary, and similar to those observed as a consequence of any routine vaccination (tetanus, Measles Mumps Rubella, etc.). Unsolicited adverse events tend to have an unclear connection to vaccine immunology and include symptoms of vertigo, arthralgias, skin or eye irritation, musculoskeletal pain, and more. Reference Alwafi, Naser and Aldhahir23 In a cohort of 6-month to 3-year-old children, the most common side effects are pain at vaccination site, swelling of lymph nodes, irritability/crying, sleepiness, and loss of appetite. 24 Pain at vaccination site is expected, as the vaccines are intramuscular, and other side effects such as lymph node swelling and loss of appetite are indicative of vaccine immunogenicity. Several studies report that amongst immunocompromised patients such as oncology patients, vaccine immunogenicity and thus routine side effect incidence rates are low. Reference Tran, Truong and Narendran25,Reference Monin, Laing and Muñoz-Ruiz26

The KidCOVE trial conducted across 79 centres in the USA and Canada revealed valuable data on the safety and immunogenicity of mRNA-1273 COVID-19 vaccine in children aged 6 months to 5 years. The study found that solicited local and systemic vaccine side effects presented at a low grade and appeared an average of 2 days after injection, persisting for an average of 2–3 additional days. Side effects were most common after the second vaccination and occurred at a higher rate in the experimental compared with the placebo group. Researchers also found that unsolicited adverse events reported an average of 28 days post-vaccination occurred at similar rates between experimental and placebo groups. Severe adverse events were also similar amongst the two study groups, with only eight severe adverse events reported in infants aged 6–23 months and 0 in children aged 2–5 years. Of the eight children experiencing severe adverse events, one experienced a fever and febrile seizure with concurrent maculopapular rash developing 2 days after the first dose administration, suggesting an incidental concomitant viral infection. Symptoms eventually resolved, and the second dose was administered with no complications. Post-vaccine COVID-19 antibody titres were similar to figures reported in similar studies of older children, adolescents, and adults. Reference Anderson, Creech and Berthaud27 Another study cited the incidence of maculopapular rash in 43 participants across three observational studies, 49% of whom received the BNT162b2 vaccine and 51% of whom received the mRNA-1273 vaccine. Reference Sun, Fathy, McMahon and Freeman28 All but one resolved within 2–3 days, with one persisting for 1 month. Several other studies reported similar results amongst this age group. Reference Muñoz, Sher and Sabharwal29 Limited information is available on adverse events of other vaccine modalities, owing to their limited of use in young cohorts.

Results are similar in older paediatric age groups. A study by Kasif et al. found that amongst the 3,732 adolescents that were randomised in a 2:1 ratio into experimental and placebo groups, only mild, non-remarkable local or systemic adverse events occurred in both groups. No incidence of death, multisystem inflammatory syndrome in children, myocarditis, or pericarditis were observed. Researchers also noted that the incidence of unsolicited adverse events was similar in participants 12–15 years of age and 16–17 years of age, indicating homogeneous findings. Reference Ali, Berman and Zhou30 In an ongoing, placebo-controlled, observer-blinded, multinational, pivotal efficacy trial of 44.165 participants aged 16 and above, the incidence of life-threatening adverse events was 0.1% in both placebo and experimental groups, and the incidence of severe adverse events was also the same (0.3%) amongst both study groups. Reference Thomas, Moreira and Kitchin31 A visual summary of the most common side effects and severe adverse events of these vaccine modalities can be found in Figure 1.

Figure 1. A visual summary of side effects and severe adverse events observed post-paediatric COVID-19 vaccination.24 ***This figure was developed using Biorender software.

Interestingly, a recent systematic review found that the frequency of events/manifestations following vaccination decreased with subsequent dosing in attenuated, viral vector and protein subunit vaccines. Adverse events (43.7% of which were cutaneous manifestations) decreased in frequency from 52 post-first dose to two after the booster dose. Additionally, almost 90% of cutaneous manifestations were of known etiology, treatable, and resolved in less than 10 days, suggesting that even in the case of adverse events safety is not significantly compromised. Reference Sadat Larijani, Doroud, Banifazl, Karami, Bavand and Ashrafian32

Other vaccines

A double-blind phase 1/2 clinical trial conducted in China revealed that amongst children aged 3–17 years old, the Sinovac vaccine showed a 26% rate of side effects (injection site pain, fever, fatigue) for one dose and 63% for a double dose. Pneumonia was the only severe adverse event recorded and affected one participant, with researchers considering it unrelated to vaccination. Reference Han, Song and Li33 Pneumonia is more correlated with exaggerated COVID-19 infection rather than COVID-19 vaccination. Reference Zheng, Wang and Feng34 Humoral responses were high in both single- and double-dose cohorts with seroconversion being 100% in both cohorts with 95% confidence intervals of 87.2–100% and 86.8–100%, respectively. Reference Han, Song and Li33

Further data on Sinovac are comparative, as the vaccine has not yet been authorised for use in paediatric cohorts. 35 Thus, reports of severe adverse events for this vaccine are limited. A study of 39 children and adults with inborn errors of immunity revealed no severe adverse event with both mRNA and Sinovac vaccines, though results suggested that three doses of each vaccine must be given to reach optimal immunogenicity comparable with that observed in non-immunocompromised persons. Reference Leung, Mu and Duque36

Limited data is available on the AZD122 vaccine. A study including more than 300 participants between the ages of 6 and 17 revealed a safety profile comparable with that observed in all other vaccine modalities. Notably, fewer adverse events (severe, unsolicited and otherwise) were observed after the second rather than the first dose of the vaccine, irrespective of the timing between the doses. Reference Li, Cappuccini and Marchevsky37

An experimental recombinant adenovirus type-5 (Ad5)–vectored COVID-19 vaccine developed in China was also assessed for adverse events in participants more than 6 years old. Results indicate the same adverse events noted for routine vaccination and other COVID-19 vaccines summarised above, with no severe or life-threatening reactions. Two other experimental vaccines (WIBP-CorV and BBV-152) are also in development with very similar safety profiles. Reference Xia, Duan and Zhang38,Reference Ella, Reddy and Jogdand39 Interestingly, fewer adverse events were reported following boost vaccination than following primary vaccination. Reference Zhu, Jin and Zhu CanSino40 Another experimental vaccine in development is the ZyCoV-D vaccine being researched in India. Khobragade et al. found that much like all other vaccines, mild side effects were observed at higher rates in experimental compared with control groups of participants aged 12 and older. However, researchers also noted that two deaths were observed in the experimental group, though causes of death were not attributed to vaccine side effects. Two doses of ZyCoV-D were also found to be 100% efficacious at preventing severe cases of COVID-19. Reference Khobragade, Bhate and Ramaiah41 Two doses of the tetanus toxoid COVID-19 vaccine FINLAY-FR-2 followed by one dose of FINLAY-FR-1A in children revealed extremely promising results. No severe adverse events were noted, and the vaccines mounted a humeral response similar to that of natural infection. Adverse events that were observed were unremarkable and solicited. Reference Puga-Gómez, Ricardo-Delgado and Rojas-Iriarte42

Vaccine combinations have also been under study. Viral vector (AstraZeneca) and attenuated (Sinopharm) vaccines were tested in combination with Postovac protein subunits by Larjiani et al. Results show that combined vaccination carries a 4.2% increased risk of adverse events compared with isolated Postovac vaccination during an 18-month follow-up period. However, results show a low number of adverse events after the 18-month period in all experimental and control groups, suggesting favourable safety profiles. Reference Sadat Larijani, Sorouri and Eybpoosh43

Severe adverse event 1: Anaphylaxis

As is the case with other novel vaccines and drugs, the risk of anaphylaxis is of interest. A nationwide observational study in the adult population found that there were 66 incidences of anaphylaxis out of 61,414,803 administered doses of various COVID-19 vaccines, corresponding to an incidence of 1.07 per 1,000,000, with most (86%) being female. Reference Toledo-Salinas, Scheffler-Mendoza and Castano-Jaramillo44 One prospective cohort study conducted in 2021 suggested a higher incidence, with nine patients out of 403 (2.2%) experiencing severe anaphylactic reactions after the administration of either the Pfizer or AstraZeneca vaccines. Having a prior history of anaphylaxis did not appear to be a risk factor, as 1.5% of enrolled patients with a prior history of anaphylactic reactions experienced a reaction with a COVID vaccine, while 3% of enrolled patients with no prior history experienced a reaction. Reference Wentrys and Stopyra45 This contrasts with the findings of a case series in which 15 out of 22 (68%) patients who were enrolled after suffering an anaphylactic reaction to a COVID-19 vaccine were found to have a prior history of such reactions. The basophil activation test was positive to PEG in the 11 patients who agreed to further testing, though PEG IgE was negative, suggesting a non-IgE-mediated aetiology. Reference Warren, Snow and Lee46 A review published in the Italian Journal of Pediatrics points out that though the risk of post-COVID-19 vaccine anaphylaxis in children is low, high-risk children, including those with prior history of anaphylaxis or reactions to other vaccines, should consult with their paediatrician before receiving a dose. Reference Novembre, Tosca and Caffarelli47

Severe adverse event 2: multisystem inflammatory syndrome in children

Multisystem inflammatory syndrome in children is a rare side effect of COVID-19 exposure, including vaccination. A 2022 study used the Vaccine Adverse Event Reporting System to determine the incidence of post-vaccination multisystem inflammatory syndrome in children in patients aged 12–20 years. It was found that 21 individuals out 21,335,331 were diagnosed with multisystem inflammatory syndrome in children, corresponding to a reporting rate of 1 in 1,000,000. Reference Yousaf, Kunkel and Abrams48 There have also been two published case reports discussing the hospital course of three paediatric patients who developed multisystem inflammatory syndrome in children shortly after vaccination, all of whom made uneventful recoveries. Reference Yalçinkaya, Öz and Polat49 The evidence in the current literature suggests that though multisystem inflammatory syndrome in children can occur post-vaccination, such events are much more common following organic COVID-19 infection, with vaccination even having a protective effect in some cases. Reference Zambrano, Newhams and Olson50

Other severe adverse events

There are a few reports of autoimmune and/or neurological disease following COVID-19 vaccination in paediatric patients, including cases of Guillain–Barre syndrome and thrombotic thrombocytopenic purpura. A case report published in the British Journal of Clinical Pharmacology details the case of a 13-year-old female that presented with bilateral weakness and was subsequently diagnosed with Guillain–Barre syndrome. The patient had received the COVID-19 vaccine 3 days ago. Reference Rohilla, Kakkar, Divyashree, Mohindra and Suri51 Another case report discussed similar findings in a 14-year-old male 1 month after COVID-19 vaccination. Both cases were treated with multiple sessions of Intravenous immunoglobulins (IVIG) followed by gradual complete resolution. Reference Malamud, Otallah, Caress and Lapid52 As is the case with multisystem inflammatory syndrome in children, it appears that Guillain–Barre syndrome is much more common after COVID-19 infection than after vaccination. Reference Aladawi, Elfil and Abu-Esheh53 As for thrombotic thrombocytopenic purpura, there are two published papers that discussed cases in paediatric patients following COVID-19 vaccination. The first describes the cases of two females, 15 and 19 years old, who developed thrombotic thrombocytopenic purpura following Pfizer COVID-19 vaccination. Reference Vorster, Kirk, Muscal, Despotovic, Cohen and Sartain54 The second paper discussed the case of a 14-year-old female who also developed thrombotic thrombocytopenic purpura after the first dose of COVID-19 vaccination. Reference Kirpalani, Garabon and Amos55 All patients were treated with plasma exchange, methyl prednisone, and immunosuppressants and subsequently improved. Reference Kirpalani, Garabon and Amos56

Cardiac severe adverse events

Several peer-reviewed articles report incidence of myocarditis following mRNA COVID-19 vaccination in a paediatric cohort. Reference Konno, Osada, Watanabe, Sakurai and Aso57Reference Minocha, Better, Singh and Hoque62 In the case of Snapiri et al, Reference Snapiri, Rosenberg Danziger and Shirman63 myocarditis was transient, and there was no data on prior COVID-19 infection or receival of a second dose of the BNT162b2 vaccine. Reference Tano, San Martin, Girgis, Martinez-Fernandez and Sanchez Vegas64 The majority of reported cases of myocarditis post mRNA vaccination have been reported in adolescents and young adults between the ages of 12 and 24 after receiving a second dose of the vaccine. Conditions have been reported to be mild and transient in most cases, with only minimal treatment required and complete recovery within a few days. Reference Kwan, Chua and Chow65 A typical presentation for a case is a 17-year-old previously healthy male presenting with chest pain and having fulfilled multisystem inflammatory syndrome in children criteria post-BNT162b2 vaccination. Reference Das, Kohli and Ramachandran66,Reference Castagnola, Mariani and Sticchi67 Diagnosis is myocarditis with a reduced ejection fraction up to 20%. Many patients do not satisfy the multisystem inflammatory syndrome in children criteria and present with myocarditis or myopericarditis nonetheless. Reference Marshall, Ferguson and Lewis68 Treatment entails admission to the ICU for around 6 days for high-flow oxygen therapy, norepinephrine infusion, steroids, intravenous immunoglobulins, and antibiotics. Several cases are self-resolving or require a simple course of nonsteroidal anti-inflammatory drugs. Reference Tano, San Martin, Girgis, Martinez-Fernandez and Sanchez Vegas69 Discharge is typically 10 days post-admission with a normalization of ejection fraction on MRI at 62%. Follow-up 8 days post-discharge typically reveals an asymptomatic patient with residual fatigue of no obvious clinical consequence. Reference Chai, Nygaard, Schmidt, Zaremba, Møller and Thorvig70

Furthermore, a study published in Nature found that 1,615 (0.004%) of 38,615,491 patients presented with myocarditis after receiving a COVID-19 vaccine shot. Of these patients, 359 (22.2%) tested positive for COVID-19, 287 (80%) of whom tested positive for COVID-19 prior to vaccination. Authors further report an association between 1–7 and 1–238 days post-COVID-19 vaccination and the incidence of myocarditis, particularly following the second dose. Reference Patone, Mei and Handunnetthi71 It is worth mentioning that this is true for a sample population aged 12 and over and is therefore not necessarily characteristic of vaccinated paediatric patients. Further studies are needed to properly characterise myocarditis post-COVID-19 vaccination in paediatric patients.

A study published in the Pediatric Infectious Diseases Journal describes a time association between adolescents aged 16–18 receiving the COVID-19 BNT162b2 vaccine and the incidence of peri-myocarditis. In six of the seven patients, symptoms proceeded the second dose, while the seventh patient showed symptoms following the first dose. The sample case displays several cardiac and laboratory findings indicating myocarditis and pericarditis, the hallmark of which is more than a 22-fold increase in troponin levels. Upon treatment with ibuprofen (dose not mentioned) and hospitalisation in the paediatric ICU, the patient recovered in 6 days and left the paediatric ICU with normal troponin levels. Reference Snapiri, Rosenberg Danziger and Shirman63 Interestingly, patients presenting with concurrent GI symptoms were subjected to more intensive care but also recovered well. Reference Woo, Kim and Yon72

The exact mechanism through which COVID-19 vaccines may trigger myocarditis and troponinemia are unknown. Suspected mechanisms include molecular mimicry between SARS-Cov-2 and self-antigens and dysregulated activation of the immune system. Several earlier studies found that myocarditis is amongst the main cardiovascular manifestations of paediatric COVID-19 infection, triggered primarily by an overwhelming immune response manifested by an elevation in the level of inflammatory markers such as IL6, C-reactive protein, and pro-calcitonin. Authors of the paper mentioned previously suggested potential inoculation with COVID-19 during the study period to explain the incidence of myocarditis, though this is not confirmed. Reference Bozkurt, Kamat and Hotez73

It is postulated that free-floating spike protein from vaccination may interact with ACE-2 receptors resulting in degradation and consequently hypertension. Thus, COVID-19 vaccination may lead to cardiac discomfort that does not manifest as myocarditis. This is especially true in young adult (aged 18–26) and adult populations compared with teenage populations (aged 12–17). Myocarditis is known to have a slight increased propensity to occur in teenagers. Likewise, myocarditis following COVID-19 vaccination is observed in paediatric populations more so than adult ones, though the incidence of cardiac symptoms post-vaccination does not follow this trend. Reference Chaichuum, Tseng and Chang74

Paediatric patients with significant comorbidities such as CHD may be at greater risk of severe adverse events with COVID-19 and possibly even following vaccination. There is very limited data on the incidence of severe adverse events following COVID-19 vaccination in paediatric patients with CHD, though some studies on adults exist. A 2022 report described the case of a 63-year-old woman with a ventricular septal defect who suffered a transient episode of ventricular tachycardia following administration of an adenoviral COVID-19 vaccine. Reference Bassareo, Mihali and Walsh75 Another study, conducted in an Italian tertiary care centre, found that 0 out of 208 adult CHD patients suffered major adverse events from the vaccine, and the number of minor adverse events was no different from the control group. Reference Fusco, Scognamiglio and Merola76 There is no available evidence to suggest that COVID-19 vaccination is more dangerous in CHD patients than others. In fact, the risk of complication following organic COVID-19 infection far outweighs the risks of vaccination in these patients. A retrospective review using the Vizient Clinical Database found that children with CHD had a 4.75 times higher risk of mortality from COVID-19. Reference Hamedi, Loftus, Traylor, Goodwin and Arce77 Another study described the hospital course of 9 children with CHD that were admitted for COVID-19. Two of the patients, both of whom had hypoplastic left heart syndrome and aortic stenosis, died. Reference Haji Esmaeil Memar, Pourakbari and Gorgi78 Other studies are more ambivalent as to whether COVID-19 infection is more dangerous in CHD patients, with the consensus being that patients in poor physiologic states may indeed have worse outcomes. Reference Sabatino, Di Salvo and Calcaterra79Reference Raj, Vyas and Yeruva82 This points to the importance of vaccination to protect from COVID-19 in these vulnerable patients.

Discussion

Weighing the evidence

Generally, in a case series report given the current state of knowledge, the rare outcome of transient myocarditis and pericarditis should not significantly alter vaccine recommendation. Reference Woo, Kim and Yon72,Reference Haaf, Kuster and Mueller86,Reference O’Leary and Maldonado87 The Centers for Disease Control and Prevention reported an incidence of approximately 12.6 cases of myocarditis per million doses. Reference Bozkurt, Kamat and Hotez73 The Advisory Committee on Immunization Practices concluded that the benefits of COVID-19 vaccination in an adolescent population outweigh the potential risk of myocarditis, thus recommending mRNA vaccination. Reference Gargano, Wallace and Hadler88 In addition, a 2022 systematic review found that the risk of myocarditis from organic COVID-19 infection was seven-fold attributable to vaccination. Reference Voleti, Reddy and Ssentongo89 This means that any risk of vaccine-related myocarditis is offset by that of organic infection, especially given the widespread nature of the virus. This is especially relevant in CHD patients, who are at an increased risk for fibrotic cardiomyopathy and lasting cardiac dysfunction after episodes of myocarditis. Reference Hamedi, Loftus, Traylor, Goodwin and Arce77 These patients are particularly in need of prompt vaccination to prevent these COVID-19 infection complications.

The risk of anaphylaxis with COVID-19 vaccines is low and is comparable with the risk of other vaccines. Reference Maltezou, Anastassopoulou, Hatziantoniou, Poland and Tsakris90 Still, patients with a history of anaphylaxis should consult with their paediatrician before receiving a dose. Reference Novembre, Tosca and Caffarelli47 Other rare complications such as Guillain–Barre syndrome and multisystem inflammatory syndrome in children appear to occur at higher rates with organic COVID-19 infection compared with vaccination. This means that COVID-19 vaccination is protective against these complications. Reference Zambrano, Newhams and Olson50,Reference Aladawi, Elfil and Abu-Esheh53,Reference Levy, Recher and Hubert91 Therefore, the benefit of vaccination, especially in vulnerable patients, outweighs the risk. Thrombotic thrombocytopenic purpura appears to be exceedingly rare post-COVID-19 vaccine, with only two published case reports documenting its occurrence, with all patients making uneventful recoveries. Reference Vorster, Kirk, Muscal, Despotovic, Cohen and Sartain54,Reference Kirpalani, Garabon and Amos55

Patients with congenital heart disease are a vulnerable population, and COVID-19 infection may place them at an increased risk of death compared with other patients. Reference Hamedi, Loftus, Traylor, Goodwin and Arce77,Reference Haji Esmaeil Memar, Pourakbari and Gorgi78 This is especially true in patients in poor physiologic states. Reference Sabatino, Di Salvo and Calcaterra79Reference Raj, Vyas and Yeruva82 However, vaccination against COVID-19 does not appear to place them at any increased risk of harm. Reference Fusco, Scognamiglio and Merola76 Current evidence therefore suggests that the benefit acquired from protection against COVID-19 and its complications outweighs the risk of side effects in these patients.

Vaccine hesitancy

Recently, social media has also been used to track and collect data on vaccine attitudes and efforts. Cuschieri et al. conducted a cross-sectional study in Malta to understand vaccine willingness, hesitancy, and unwillingness amongst adult social media users through an online questionnaire advertised linked on social media. Results indicate that amongst this cohort, vaccine hesitancy is low, though vaccine unwillingness is high, particularly with regard to receiving one or potentially more booster shots in the future. Fear of severe adverse events was the main reason participants cited for vaccine unwillingness. Reference Cuschieri, Grech and Grech92 Several similar studies cite similar results. Reference Cordina, Lauri and Lauri93Reference Alibrahim and Awad96 Social media use has also been used as both a demographic marker and a marker of social and emotional well-being of participants in surveys and questionnaires regarding the pandemic, with results indicating that the majority of surveyed individuals obtained public health information from social media regarding the pandemic and that social media use was positively correlated with vaccine hesitancy. Reference Till and Niederkrotenthaler97

Though over 90% of teenagers utilise social media, Reference C.98 studies concerning vaccine hesitancy specifically targeting a paediatric cohort through social media have not been reported. This is probably due in part to the ethical dilemmas surrounding the use of social media to influence individuals under the age of 18 Reference Terrasse, Gorin and Sisti99 and in part to physician- and health personnel-related hesitancy towards social media use. A study by Hou et al. reported a significant knowledge gap between physicians and the social media. Authors reported fear of litigation, lack of understanding, time, and fear of unprofessionalism as barriers to social media use amongst healthcare workers. Reference Haque, Khan, Sandhu and Armstrong100 During the pandemic, social media became a major source of unregulated public health information, Reference Parabhoi, Sahu, Dewey, Verma, Kumar Seth and Parabhoi101 underscoring the importance of demographically appropriate interventions to promote knowledge and combat vaccine hesitancy. Reference Kaplan and Milstein102,Reference Hou, Song and Wang103

Furthermore, while a very large number of randomised controlled trials have been conducted to assess self-reported COVID-19 vaccine symptoms in adults, Reference Kadali, Janagama, Peruru and Malayala104 similar studies in a paediatric cohort remain unfound. There are also significant gaps in the literature when it comes to COVID-19 vaccination in not only CHD patients but the paediatric cohort as a whole. Specific COVID-19 vaccine rates in children are not well reported or well characterised. There is a lack of published studies reporting post-vaccination adverse events in paediatric CHD patients and very few in adults with CHD. More large-scale studies should be done to evaluate the risk of myocarditis and other vaccine-associated cardiac complications in CHD patients. Even though current evidence points towards the benefit of COVID-19 vaccination outweighing the risk, cardiac complications of vaccination appear to be underreported in this patient population.

Conclusion

The most relevant severe adverse events following paediatric COVID-19 vaccination include anaphylaxis, multisystem inflammatory syndrome in children, and cardiac events (myocarditis and pericarditis). However, the reported incidence of these vaccine-related complications is extremely low and appears not to be significant. Thus, vaccination benefits may outweigh potential risks. The most widely studied paediatric vaccines are the mRNA vaccines that have high efficacy rates and favourable safety profiles suggesting possible slight superiority to other vaccine modalities though further studies are needed to support conclusions. Needless to say, it is important to treat complicated cases in a case-by-case manner, as vaccines have not yet been studied in all paediatric disease states. For example, cardiac complications in CHD patients are underreported and represent a gap in the literature. Further studies are needed to rationalise vaccine hesitancy such that it may be promptly addressed.

References

Zhang, T, Wu, Q, Zhang, Z. Probable pangolin origin of SARS-CoV-2 associated with the COVID-19 outbreak. Curr Biol 2020; 30: 13461351.e2.CrossRefGoogle ScholarPubMed
Chan-Yeung, M, Xu, RH. SARS: epidemiology. Respirology 2003; 8: S9S14.CrossRefGoogle ScholarPubMed
Zaki, AM, van Boheemen, S, Bestebroer, TM, Osterhaus, AD, Fouchier, RA. Isolation of a novel coronavirus from a man with pneumonia in Saudi Arabia. New Engl J Med 2012; 367:18141820.CrossRefGoogle Scholar
Walls, AC, Park, YJ, Tortorici, MA, Wall, A, McGuire, AT, Veesler, D. Structure, function, and antigenicity of the SARS-CoV-2 spike glycoprotein. Cell 2020; 183: 17351739.CrossRefGoogle ScholarPubMed
Masters, PS. The molecular biology of coronaviruses. Adv Virus Res 2020; 96: 132.Google Scholar
Liu, Y et al. Clinical and epidemiological characteristics of COVID-19 patients in Wuhan, China: a descriptive study. The Lancet Infectious Diseases 2020; 20:17.Google Scholar
Selden, TM et al. Health disparities and COVID-19: racial/ethnic and socioeconomic differences in infection and death. J Health Politics Policy Law 2020; 45: 956962.Google Scholar
Wee, LE, Sim, JXY, Conceicao, EP, Aung, MK, Ng, IM, Ling, ML. ‘Personal protective equipment protecting healthcare workers in the Chinese epicenter of COVID-19’ by Zhao et al. Clin Microbiol Infec 2020; 26: 17191721.CrossRefGoogle ScholarPubMed
Price-Haywood, EG, Burton, J, Fort, D, Seoane, L. Hospitalization and mortality among Black patients and White patients with COVID-19. New Engl J Med 2020; 382: 25342543.CrossRefGoogle ScholarPubMed
Makridis, C. COVID-19 and the unemployment crisis. J Econ Political Econ 2020; 7: 196210.Google Scholar
Hafstad, GS, Sætren, SS, Wentzel-Larsen, T, Augusti, E-M. Adolescents’ symptoms of anxiety and depression before and during the Covid-19 outbreak – a prospective population-based study of teenagers in Norway. Lancet 2021; 5: 100093.Google ScholarPubMed
Polack, FP, Thomas, SJ, Kitchin, N et al. Safety and efficacy of the BNT162b2 mRNA COVID-19 vaccine. New Engl J Med 2020; 383: 26032615.CrossRefGoogle ScholarPubMed
Smith, MJ, Marshall, GS. Navigating parental vaccine hesitancy. Pediatr Ann 2010; 39, 476482.CrossRefGoogle ScholarPubMed
Office of the Commissioner. What Is a Serious Adverse Event? U.S. Food and Drug Administration, FDA. https://www.fda.gov/safety/reporting-serious-problems-fda/what-serious-adverse-event Google Scholar
Nikolopoulou, GB, Maltezou, HC. COVID-19 in children: where do we stand? Arch Med Res 2022; 53: 18.CrossRefGoogle ScholarPubMed
Centers for Disease Control and Prevention (CDC). (2022). COVID-19 Vaccine Safety Update. https://www.cdc.gov/coronavirus/2019-ncov/vaccines/safety/vaers-summary.html.Google Scholar
World Health Organization (WHO). (2022). COVID-19 Weekly Epidemiological Update. https://www.who.int/emergencies/disease-outbreak-news/item/2022-DON305.Google Scholar
Food and Drug Administration. (2021). Janssen COVID-19 Vaccine: FDA and CDC Joint Statement on Advisory Committee Meeting. https://www.fda.gov/news-events/press-announcements/janssen-covid-19-vaccine-fda-and-cdc-joint-statement-advisory-committee-meeting.Google Scholar
World Health Organization (WHO) . (2021). COVID-19 Weekly Epidemiological Update. https://www.who.int/emergencies/disease-outbreak-news/item/2021-DON304.Google Scholar
European Medicines Agency (EMA). (2021). COVID-19 Vaccine AstraZeneca: PRAC investigating cases of thromboembolic events. https://www.ema.europa.eu/en/news/covid-19-vaccine-astrazeneca-prac-investigating-cases-thromboembolic-events.Google Scholar
World Health Organization (WHO). (2021). COVID-19 vaccines and blood clotting disorders: clarifying the scientific questions. https://www.who.int/news-room/feature-stories/detail/covid-19.Google Scholar
World Health Organization (WHO). COVID-19 Vaccine Tracker. https://covid19.trackvaccines.org/vaccines/1/.Google Scholar
Alwafi, H, Naser, AY, Aldhahir, AM et al. COVID-19 vaccination side effects among the child age group: a large cross-sectional online based survey in Saudi Arabia. Bmc Infect Dis 2022; 22: 911.CrossRefGoogle ScholarPubMed
“Possible Side Effects after Getting a COVID-19 Vaccine.” Centers for Disease Control and Prevention, Centers for Disease Control and Prevention, https://www.cdc.gov/coronavirus/2019-ncov/vaccines/expect/after.html.Google Scholar
Tran, S, Truong, TH, Narendran, A. Evaluation of COVID-19 vaccine response in patients with cancer: an interim analysis. Eur J Cancer 2021; 159: 259274.CrossRefGoogle ScholarPubMed
Monin, L, Laing, AG, Muñoz-Ruiz, M et al. Safety and immunogenicity of one versus two doses of the COVID-19 vaccine BNT162b2 for patients with cancer: interim analysis of a prospective observational study. Lancet Oncol 2021; 22: 765778.CrossRefGoogle ScholarPubMed
Anderson, EJ, Creech, CB, Berthaud, V et al. Evaluation of mRNA-1273 vaccine in children 6 Months to 5 years of age. N Engl J Med 2022; 387: 16731687.CrossRefGoogle ScholarPubMed
Sun, Q, Fathy, R, McMahon, DE, Freeman, EE. COVID-19 vaccines and the skin: the landscape of cutaneous vaccine reactions worldwide. Dermatol Clin 2021; 39: 653673.CrossRefGoogle ScholarPubMed
Muñoz, FM, Sher, LD, Sabharwal, C et al. Evaluation of BNT162b2 Covid-19 vaccine in children younger than 5 years of age. N Engl J Med 2023; 388: 621634.CrossRefGoogle ScholarPubMed
Ali, K, Berman, G, Zhou, H et al. Evaluation of mRNA-1273 SARS-CoV-2 vaccine in adolescents. New Engl J Med 2021; 385: 22412251.CrossRefGoogle ScholarPubMed
Thomas, SJ, Moreira, ED, Kitchin, N et al. Safety and efficacy of the BNT162b2 mRNA Covid-19 vaccine through 6 Months. New Engl J Med 2021; 385: 17611773.CrossRefGoogle ScholarPubMed
Sadat Larijani, M, Doroud, D, Banifazl, M, Karami, A, Bavand, A, Ashrafian, F et al. A landscape on disorders following different COVID-19 vaccination: a systematic review of Iranian case reports. Eur J Med Res 2023; 28: 542.CrossRefGoogle ScholarPubMed
Han, B, Song, Y, Li, C et al. Safety, tolerability, and immunogenicity of an inactivated SARS-CoV-2 vaccine (CoronaVac) in healthy children and adolescents: a double-blind, randomised, controlled, phase 1/2 clinical trial. Lancet Infect Dis 2021; 21 16451653.CrossRefGoogle ScholarPubMed
Zheng, Y-J, Wang, XC, Feng, LZ, et al. Expert consensus on COVID-19 vaccination in children. WJP 2021; 17: 449457.Google ScholarPubMed
Sinovac Research and Development Co., Ltd, Efficacy, Immunogenicity and Safety of COVID-19 Vaccine, Inactivated in Children and Adolescents. ClinicalTrials.gov, NCT04992260. Updated January 12, 2023. Accessed February 24, 2023.Google Scholar
Leung, D, Mu, X, Duque, JSR et al. Safety and immunogenicity of 3 doses of BNT162b2 and coronaVac in children and adults with inborn errors of immunity. Front Immunol 2022; 13: 982155.CrossRefGoogle ScholarPubMed
Li, G, Cappuccini, F, Marchevsky, NG et al. Safety and immunogenicity of the ChAdOx1 nCoV-19 (AZD1222) vaccine in children aged 6-17 years: a preliminary report of COV006, a phase 2 single-blind, randomised, controlled trial. Lancet 2022; 399: 22122225.CrossRefGoogle Scholar
Xia, S, Duan, K, Zhang, Y, et al. Safety and immunogenicity of an inactivated COVID-19 vaccine, WIBP-CorV, in healthy children: interim analysis of a randomized, double-blind, controlled, phase 1/2 trial. Front Immunol 2022; 13: 898151.CrossRefGoogle ScholarPubMed
Ella, R, Reddy, S, Jogdand, H et al. Safety and immunogenicity of an inactivated SARS-CoV-2 vaccine, BBV152: interim results from a double-blind, randomised, multicentre, phase 2 trial, and 3-month follow-up of a double-blind, randomised phase 1 trial. Lancet Infect Dis 2021; 21: 950961.CrossRefGoogle ScholarPubMed
Zhu, F, Jin, P, Zhu CanSino, T et al. Safety and immunogenicity of a recombinant adenovirus type-5-vectored coronavirus disease 2019 (COVID-19) vaccine with a homologous prime-boost regimen in healthy participants aged ≥6 years: a randomized, double-blind, placebo-controlled, phase 2b trial. Clin Infect Dis 2022; 75 (1): e783e791.CrossRefGoogle Scholar
Khobragade, A, Bhate, S, Ramaiah, V et al. Efficacy, safety, and immunogenicity of the DNA SARS-CoV-2 vaccine (ZyCoV-D): the interim efficacy results of a phase 3, randomised, double-blind, placebo-controlled study in India. Lancet 2022; 399: 13131321.CrossRefGoogle ScholarPubMed
Puga-Gómez, R, Ricardo-Delgado, Y, Rojas-Iriarte, C et al. Open-label phase I/II clinical trial of SARS-CoV-2 receptor binding domain-tetanus toxoid conjugate vaccine (FINLAY-FR-2) in combination with receptor binding domain-protein vaccine (FINLAY-FR-1A) in children. Int J Infect Dis 2023; 126: 164173.CrossRefGoogle ScholarPubMed
Sadat Larijani, M, Sorouri, R, Eybpoosh, S et al. Assessment of long-term adverse events regarding different COVID-19 vaccine regimens within an 18-month follow-up study. Pathog Dis 2023; 81.CrossRefGoogle Scholar
Toledo-Salinas, C, Scheffler-Mendoza, SC, Castano-Jaramillo, LM et al. Anaphylaxis to SARS-oV-2 vaccines in the setting of a Nationwide Passive Epidemiological Surveillance Program. J Clin Immunol 2022; 42 15931599.CrossRefGoogle ScholarPubMed
Wentrys, Ł., Stopyra, L. COVID-19 vaccination including 198 patients with history of severe anaphylactic reaction - own observations. Przegl Epidemiol 2021; 75: 315325.CrossRefGoogle ScholarPubMed
Warren, CM, Snow, TT, Lee, AS et al. Assessment of allergic and anaphylactic reactions to mRNA COVID-19 vaccines with confirmatory testing in a US Regional Health System. JAMA Netw Open 2021; 4 e2125524.CrossRefGoogle Scholar
Novembre, E, Tosca, M, Caffarelli, C et al. Management of BNT162b2 mRNA COVID-19 vaccine in children aged 5–11 years with allergies, asthma, and immunodeficiency: consensus of the Italian Society of Pediatric Allergy and Immunology (SIAIP). Ital J Pediatr 2022; 48: 76.CrossRefGoogle ScholarPubMed
Yousaf, AR, Kunkel, A, Abrams, JY et al. COVID-19 vaccine reactogenicity and vaccine attitudes among children and parents/Guardians after multisystem inflammatory syndrome in children or COVID-19 hospitalization: September 2021-May 2022. Pediatr Infect Dis J 2023; 42: 252259.Google ScholarPubMed
Yalçinkaya, R, Öz, FN, Polat, M et al. A case of multisystem inflammatory syndrome in a 12-year-old male after COVID-19 mRNA vaccine. Pediatr Infect Dis J 2022; 41: e87e89.CrossRefGoogle Scholar
Zambrano, LD, Newhams, MM, Olson, SM et al. Effectiveness of BNT162b2 (Pfizer-BioNTech) mRNA vaccination against multisystem inflammatory syndrome in children among persons aged 12-18 years - United States, July-December 2021. MMWR Morb Mortal Wkly Rep 2022; 71: 5258.CrossRefGoogle ScholarPubMed
Rohilla, R, Kakkar, AK, Divyashree, K, Mohindra, R, Suri, V. Recombinant protein subunit COVID-19 vaccine-induced Guillain-Barré Syndrome in an adolescent: a case report. Br J Clin Pharmacol 2023; 89: 556560.CrossRefGoogle Scholar
Malamud, E, Otallah, SI, Caress, JB, Lapid, DJ. Guillain-Barré Syndrome after COVID-19 vaccination in an adolescent. Pediatr Neurol 2022; 126: 910.CrossRefGoogle ScholarPubMed
Aladawi, M, Elfil, M, Abu-Esheh, B et al. Guillain Barre Syndrome as a complication of COVID-19: a systematic review. Can J Neurol Sci 2022; 49: 3848.CrossRefGoogle ScholarPubMed
Vorster, L, Kirk, SE, Muscal, E, Despotovic, JM, Cohen, CT, Sartain, SE. COVID-19 vaccine (mRNA BNT162b2) and COVID-19 infection-induced thrombotic thrombocytopenic purpura in adolescents. Pediatr Blood Cancer 2022; 69: e.29681.CrossRefGoogle ScholarPubMed
Kirpalani, A, Garabon, J, Amos, K et al. Thrombotic thrombocytopenic purpura temporally associated with BNT162b2 vaccination in an adolescent successfully treated with caplacizumab. Brit J Haematol 2022; 196: e11e14.CrossRefGoogle Scholar
Kirpalani, A, Garabon, J, Amos, K et al. Thrombotic thrombocytopenic purpura temporally associated with BNT162b2 vaccination in an adolescent successfully treated with caplacizumab. Br J Haematol 2022; 196: e11e14.CrossRefGoogle Scholar
Konno, A, Osada, Y, Watanabe, K, Sakurai, K, Aso, K. A case of coronavirus disease 2019 vaccine-related myocarditis with late gadolinium enhancement on cardiac magnetic resonance imaging persisting over acute phase. Pediatr Int 2022; 64: e15291.CrossRefGoogle ScholarPubMed
Murase, H, Zhu, Y, Sakaida, K et al. Case report: Five patients with myocarditis after mRNA COVID-19 vaccination. Front Pediatr 2022; 10: 977476.CrossRefGoogle ScholarPubMed
Schauer, J, Buddhe, S, Colyer, J et al.. Myopericarditis after the Pfizer messenger ribonucleic acid coronavirus disease vaccine in adolescents. J Pediatr 2021; 238: 317320.CrossRefGoogle ScholarPubMed
Kim, HW, Jenista, ER, Wendell, DC et al. Patients with acute myocarditis following mRNA COVID-19 vaccination. JAMA Cardiology 2021; 6: 11961201.CrossRefGoogle ScholarPubMed
McLean, K, Johnson, TJ. Myopericarditis in a previously healthy adolescent male following COVID-19 vaccination: a case report. Acad Emerg Med 2021; 28:, 918921.CrossRefGoogle Scholar
Minocha, PK, Better, D, Singh, RK, Hoque, T. Recurrence of acute myocarditis temporally associated with receipt of the mRNA coronavirus disease 2019 (COVID-19) vaccine in a male adolescent. J Pediatr 2021; 238: 321323.CrossRefGoogle Scholar
Snapiri, O, Rosenberg Danziger, C, Shirman, N et al. Transient cardiac injury in adolescents receiving the BNT162B2 mrna COVID-19 vaccine. Pediatr Infect Dis J 2021; 40: e360e363.CrossRefGoogle ScholarPubMed
Tano, E, San Martin, S, Girgis, S, Martinez-Fernandez, Y, Sanchez Vegas, C. Perimyocarditis in adolescents after fizer-BioNTech COVID-19 vaccine. J Pediatric Infect Dis Soc 2021; 10: 962966.CrossRefGoogle ScholarPubMed
Kwan, MY, Chua, GT, Chow, CB et al. mRNA COVID vaccine and myocarditis in adolescents. Hong Kong Med J 2021; 27.CrossRefGoogle Scholar
Das, BB, Kohli, U, Ramachandran, P et al. Myopericarditis after messenger RNA coronavirus disease 2019 vaccination in adolescents 12 to 18 years of age. J Pediatr 2021; 238: 2632.e1.CrossRefGoogle ScholarPubMed
Castagnola, E, Mariani, M, Sticchi, C et al. Incidence rate of MIS-C in paediatrics: a good reason to vaccinate children against SARS-CoV-2. Acta Paediatr 2022; 111: 123124.CrossRefGoogle ScholarPubMed
Marshall, M, Ferguson, ID, Lewis, P et al. Symptomatic acute myocarditis in 7 adolescents after Pfizer-BioNTech COVID-19 vaccination. Pediatrics 2021; 148: e2021052478.CrossRefGoogle ScholarPubMed
Tano, E, San Martin, S, Girgis, S, Martinez-Fernandez, Y, Sanchez Vegas, C. Perimyocarditis in adolescents after Pfizer-BioNTech COVID-19 vaccine. J Pediatric Infect Dis Soc 2021; 10: 962966.CrossRefGoogle ScholarPubMed
Chai, Q, Nygaard, U, Schmidt, RC, Zaremba, T, Møller, AM, Thorvig, CM. Multisystem inflammatory syndrome in a male adolescent after his second Pfizer-BioNTech COVID-19 vaccine. Acta Paediatr 2022; 111: 125127.CrossRefGoogle Scholar
Patone, M, Mei, XW, Handunnetthi, L et al.Risk of Myocarditis After Sequential Doses of COVID-19 Vaccine and SARS-CoV-2 Infection by Age and Sex. Circulation 2022; 146: 743754.CrossRefGoogle ScholarPubMed
Woo, W, Kim, AY, Yon, DK et al. Clinical characteristics and prognostic factors of myocarditis associated with the mRNA COVID-19 vaccine. J Med Virol. 2022; 94: 15661580.CrossRefGoogle ScholarPubMed
Bozkurt, B, Kamat, I, Hotez, PJ. Myocarditis with COVID-19 mRNA vaccines. Circulation 2021; 144: 471484.CrossRefGoogle ScholarPubMed
Chaichuum, S, Tseng, C-L, Chang, S-C et al. Assessment of cardiac adverse events following COVID-19 vaccination by speckle tracking echocardiography. Sci Rep-UK 2024; 14: 10849.CrossRefGoogle ScholarPubMed
Bassareo, PP, Mihali, K, Walsh, KP. Ventricular tachycardia triggered by the first dose of an adenoviral vector-based COVID-19 vaccine in an adult patient with congenital heart disease. Clinical Case Reports 2022; 10: e6064.CrossRefGoogle Scholar
Fusco, F, Scognamiglio, G, Merola, A et al. COVID-19 vaccination in adults with congenital heart disease: real-world data from an italian tertiary centre. Int J Cardiol Congenit Heart Dis 2021; 6: 100266.CrossRefGoogle ScholarPubMed
Hamedi, KR, Loftus, G, Traylor, L, Goodwin, R, Arce, S. Comparison of COVID-19 vaccine-associated myocarditis and viral myocarditis pathology. Nato Adv Sci Inst Se 2023; 11: 362.Google ScholarPubMed
Haji Esmaeil Memar, E, Pourakbari, B, Gorgi, M et al. COVID-19 and congenital heart disease: a case series of nine children. World J Pediatr 2021; 17: 7178.CrossRefGoogle ScholarPubMed
Sabatino, J, Di Salvo, G, Calcaterra, G et al. Adult congenital heart disease: special considerations for COVID-19 and vaccine allocation/prioritization. Int J Cardiol Congenit Heart Dis 2021; 4: 100186.CrossRefGoogle ScholarPubMed
Broberg, CS, Kovacs, AH, Sadeghi, S et al. COVID-19 in adults with congenital heart disease. J Am Coll Cardiol 2021; 77 16441655.CrossRefGoogle ScholarPubMed
Zareef, RO, Younis, NK, Bitar, F, Eid, AH, Arabi, M. COVID-19 in pediatric patients: a focus on CHD patients. Front Cardiovasc Med 2020; 7.CrossRefGoogle Scholar
Raj, K, Vyas, V, Yeruva, K et al. Mortality and complications of COVID-19 among adult congenital heart disease patients: a retrospective cohort study using the national inpatient sample database. Curr Prob Cardiol 2023; 48: 101644.CrossRefGoogle ScholarPubMed
“Covid-19 Vaccine Safety in Children and Teens.” Centers for Disease Control and Prevention, Centers for Disease Control and Prevention. https://www.cdc.gov/coronavirus/2019-ncov/vaccines/vaccine-safety-children-teens.html.Google Scholar
Deng, L, Wood, N, Danchin, M. Seizures following vaccination in children: risks, outcomes and management of subsequent revaccination. Aust J Gen Pract 2020; 49: 644649.CrossRefGoogle ScholarPubMed
Deng, L, Gidding, H, Macartney, K et al. Postvaccination febrile seizure severity and outcome. Pediatrics 2019; 143: e20182120.CrossRefGoogle ScholarPubMed
Haaf, P, Kuster, GM, Mueller, C et al. The very low risk of myocarditis and pericarditis after mRNA COVID-19 vaccination should not discourage vaccination. Swiss Med Wkly 2021; 151: w30087.CrossRefGoogle Scholar
O’Leary, ST, Maldonado, YA. Myocarditis after SARS-coV-2 vaccination: true, true, and… Related? Pediatrics 2021; 148: e2021052644.CrossRefGoogle ScholarPubMed
Gargano, JW, Wallace, M, Hadler, SC et aal. Use of mRNA COVID-19 vaccine after reports of myocarditis among vaccine recipients: update from the Advisory Committee on Immunization Practices—United States. MMWR Morb Mortal Wkly Rep 2021; 70: 977982.CrossRefGoogle Scholar
Voleti, N, Reddy, SP, Ssentongo, P. Myocarditis in SARS-CoV-2 infection vs. COVID-19 vaccination: a systematic review and meta-analysis. Front Cardiovasc Med 2022; 9.CrossRefGoogle Scholar
Maltezou, HC, Anastassopoulou, C, Hatziantoniou, S, Poland, GA, Tsakris, A. Anaphylaxis rates associated with COVID-19 vaccines are comparable to those of other vaccines. Vaccine 2022; 40: 183186.CrossRefGoogle ScholarPubMed
Levy, M, Recher, M, Hubert, et al. Multisystem inflammatory syndrome in children by COVID-19 vaccination status of adolescents in France. JAMA 2022; 327: 281283.CrossRefGoogle ScholarPubMed
Cuschieri, S, Grech, S, Grech, V. A cross-sectional study exploring the Covid-19 vaccination landscape in Malta through social media: an insight into experiences, attitudes, and perspectives. Health Sci Rep 2023; 6: e1014.CrossRefGoogle ScholarPubMed
Cordina, M, Lauri, MA, Lauri, J. Attitudes towards COVID-19 vaccination, vaccine hesitancy and intention to take the vaccine. Pharm Pract (Granada) 2021; 19: 2317.CrossRefGoogle ScholarPubMed
Shah, NN, Khursheed, SQ, Khan, Z et al. Assessing vaccine hesitancy among health-care workers in Jammu and Kashmir: a cross-sectional study. J Educ Health Promot 2022; 11: 73.CrossRefGoogle ScholarPubMed
Jang, SR, Lee, SK, Connelly, S. Understanding motivations and deterrents for COVID-19 vaccination among US working adults: a mixed method approach. Hum Vaccin Immunother 2022; 18: 2132752.CrossRefGoogle ScholarPubMed
Alibrahim, J, Awad, A. COVID-19 vaccine hesitancy among the Public in Kuwait: a cross-sectional survey. Int J Environ Res Public Health 2021; 18: 8836.CrossRefGoogle ScholarPubMed
Till, B, Niederkrotenthaler, T. Predictors of vaccine hesitancy during the COVID-19 pandemic in Austria: a population-based cross-sectional study. Wien Klin Wochenschr 2022; 134: 822827.CrossRefGoogle Scholar
C., MJ. (2019). Teens and social media: When is it too much? [Internet] Reno, NV: University of Nevada, Reno School of Medicine; [cited 2023 Feb 28]. https://med.unr.edu/news/archive/2019/coppes-teens-and-social-media.Google Scholar
Terrasse, M, Gorin, M, Sisti, D. Social media, E-health, and medical ethics. Hastings Cent Rep 2019; 49: 2433.Google ScholarPubMed
Haque, M, Khan, S, Sandhu, A, Armstrong, K. Social media and the practice of pediatric physical medicine and rehabilitation in the COVID-19 pandemic: a new era in patient-care. J Pediatr Rehabil Med 2022; 15: 413416.Google ScholarPubMed
Parabhoi, L, Sahu, RR, Dewey, RS, Verma, MK, Kumar Seth, A, Parabhoi, D. YouTube as a source of information during the covid-19 pandemic: a content analysis of youTube videos published during January to March 2020. Bmc Med Inform Decis 2021; 21: 255.CrossRefGoogle ScholarPubMed
Kaplan, RM, Milstein, A. Influence of a COVID-19 vaccine’s effectiveness and safety profile on vaccination acceptance. Proc Natl Acad Sci U S A 2021; 118.CrossRefGoogle Scholar
Hou, Z, Song, K, Wang, K et al. Childhood COVID-19 vaccine acceptance and preference from caregivers and healthcare workers in China: a survey experiment. Prev Med 2022; 161: 107138.CrossRefGoogle Scholar
Kadali, RAK, Janagama, R, Peruru, S, Malayala, SV. Side effects of BNT162b2 mRNA COVID-19 vaccine: a randomized, cross-sectional study with detailed self-reported symptoms from healthcare workers. Int J Infect Dis 2021; 106: 376381.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Adverse events reported by the Food and Drug Administration, Centers for Disease Control and Prevention, and World Health Organization relative to the five most popular modalities as of March 2023:*

Figure 1

Table 2. Adverse events of paediatric COVID-19 vaccination reported by the Food and Drug Administration, Centers for Disease Control and Prevention, and World Health Organization relative to the two most popular paediatric vaccine modalities as of March 2023.24*

Figure 2

Figure 1. A visual summary of side effects and severe adverse events observed post-paediatric COVID-19 vaccination.24***This figure was developed using Biorender software.