The risk of acute myocarditis associated with COVID-19 mRNA vaccination has garnered intense (social) media attention. However, myocarditis after COVID-19 mRNA vaccination is rare and usually resolves within days or weeks. Moreover, the risks of hospitalization and death associated with COVID-19 are greater than the risk associated with COVID-19 vaccination. Therefore, COVID-19 vaccination should be recommended in adolescents and adults.
Acute myocarditis most commonly results from a viral infection1, including infection with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the virus that causes coronavirus disease 2019 (COVID-19). Although rare, acute myocarditis can also occur after vaccination, such as with the vaccine against smallpox or, as seen more recently, the vaccines against COVID-19, in particular those based on mRNA technology (Pfizer-BioNTech BNT162b2 and Moderna mRNA-1273). The risks of acute myocarditis associated with SARS-CoV-2 infection and after COVID-19 mRNA vaccination have garnered intense social media attention. A consistent point in these heated arguments is that the risks of hospitalization and death associated with COVID-19 are greater than the risks linked with the vaccine. Furthermore, COVID-19 vaccination reduces the relative risk of myocarditis and arrhythmia manifold, and myocarditis related to COVID-19 mRNA vaccination occurs mostly in young adults and is mild in most cases. Therefore, given that post-mRNA-vaccine myocarditis is rare and usually resolves within a few days or weeks, COVID-19 vaccination should be recommended in adolescent and adult populations.
In patients with severe myocarditis, the diagnosis is often established by heart biopsy. In patients with mild myocarditis, the diagnosis is based on compatible clinical findings and confirmed by elevated levels of blood markers or an electrocardiogram (ECG) indicative of cardiac injury, with presence of new abnormalities on echocardiography or cardiac MRI. When non-histological criteria are used, the cause of myocarditis is usually not proven1. Before the emergence of COVID-19, the estimated global incidence of acute myocarditis was 1–10 cases per 100,000 people per year1 (Table 1). Similarly, the overall incidence of COVID-19 mRNA-vaccine-related myocarditis seems to be low, estimated as 0.3–5.0 cases per 100,000 vaccinated people in case-series studies from the USA and Israel2,3,4,5 (see the Supplementary information for the full list of published reports on myocarditis and pericarditis after COVID-19 vaccination). The highest incidence of myocarditis occurred after the second vaccination and mostly in young men (83 of 117 patients were aged ≤30 years and only 15 of 117 patients were women)3. Most of the cases arose within the first week, typically 3–4 days after the vaccination. In myocarditis unrelated to COVID-19 or COVID-19 vaccination, >80% of patients will spontaneously recover, although those hospitalized for myocarditis have an approximately 4–5% risk of death or heart transplantation in the first year after diagnosis6. In COVID-19 mRNA-vaccine-associated myocarditis, up to 90% of patients will functionally recover, usually after a chest pain syndrome (see Supplementary information). To date, at least 13 deaths owing to COVID-19 mRNA-vaccine-associated myocarditis have been reported (>99% survival) (see Supplementary information), but numbers are difficult to estimate because of the lack of evidence for a causal relationship.
By contrast, the incidence of COVID-19-associated cardiac injury or myocarditis is estimated to be 100 times higher (1,000–1,400 per 100,000 people with COVID-19) than that of COVID-19 mRNA-vaccine-related myocarditis7. Moreover, in contrast to the overall mild presentation and good outcome of vaccine-associated myocarditis, COVID-19 is associated with a major risk of cardiovascular complications8. Among patients with COVID-19, 10% of outpatients and 40% of hospitalized patients have clinically significant myocardial injury, mostly in the absence of a myocardial infarction8. Advanced age and pre-existing comorbidities (obesity, diabetes mellitus, hypertension or renal dysfunction) are the main predisposing factors for cardiovascular complications in patients with COVID-19. Sepsis and shock, hypoxia and haemodynamic instability owing to severe COVID-19 pneumonia and its complications, and direct COVID-19-mediated microvascular injury and thrombosis can all cause myocardial damage (assessed by the presence of increased troponin levels in the plasma), ECG changes, heart failure and arrhythmias8.
Myocarditis that results from enterovirus or human herpesvirus (HHV4 and HHV6) infection is generally more severe with younger age and male sex. This type of myocarditis can be associated with an immune–genetic background that increases the likelihood of developing acute myocarditis after viral injury, such as genetic variants in genes encoding HLA factors and, in a minority of patients, genetic variants in genes encoding desmosomal, cytoskeletal or sarcomeric proteins1. The generation of autoantibodies and hormone-related factors contribute to the sex-specific differences observed in both COVID-19 mRNA-vaccination-related myocarditis and in non-COVID-19 viral myocarditis. Publications in the past year describe similar factors predisposing to acute myocarditis after COVID-19 mRNA vaccination9.
mRNA vaccines against COVID-19 contain nucleoside-modified mRNA that encodes the viral spike glycoprotein of SARS-CoV-2 and is encapsulated in lipid nanoparticles, but do not contain live virus or DNA. The viral spike protein, once produced in the cell after mRNA-vaccine entry, induces an adaptive immune response to identify and destroy viruses that express the spike protein. Vaccine-induced spike-protein IgG antibodies prevent the attachment of SARS-CoV-2 to the host cell (which occurs via spike-protein binding to the angiotensin-converting enzyme 2 receptor) and thereby neutralize the virus. The three main mechanisms by which COVID-19 mRNA vaccines might induce hyperimmunity9 are mRNA immune reactivity, antibodies to SARS-CoV-2 spike glycoproteins cross-reacting with myocardial contractile proteins, and hormonal differences. All of these mechanisms can be influenced by immune–genetic background, age and sex.
The immune system might detect the mRNA in the vaccine as an antigen, resulting in the activation of pro-inflammatory cascades and immunological pathways in the heart. Although nucleoside modifications of mRNA reduce their innate immunogenicity, the immune response to mRNA might still drive the activation of an aberrant innate and acquired immune response, which can explain the stronger immune response seen with mRNA vaccines than with other types of COVID-19 vaccine. However, this hypothesis is not supported by the lack of immune-related adverse effects in other organs in which the mRNA vaccine is being uptaken. Molecular mimicry between the spike protein of SARS-CoV-2 and cardiac self-antigens is another possible mechanism. Antibodies directed to SARS-CoV-2 spike glycoproteins might cross-react with structurally similar human protein sequences, including myocardial α-myosin heavy chain9. These autoantibodies might be innocent bystanders resulting from myocardial inflammation and injury, or might reflect a certain immune–genetic background that predisposes to developing hyperimmunity and myocarditis upon any trigger. Finally, given the increased incidence among male patients, differences in hormone signalling might be involved in the pathophysiology of COVID-19 mRNA-vaccination-related myocarditis. Testosterone can inhibit anti-inflammatory immune cells and promote a more aggressive T helper 1 cell-type immune response1. By contrast, oestrogen has inhibitory effects on pro-inflammatory T cells, resulting in a decrease in cell-mediated immune responses1.
Vaccinations: the way to go!
As in ‘common’ viral myocarditis, myocarditis associated with COVID-19 mRNA vaccination mainly occurs in young adults within 1 week of viral antigen-induced immune activation, but can sometimes occur in vaccine recipients with immune and genetic susceptibility to myocarditis. The risk ratio of myocarditis in a large study from Israel was 3.24 in the first 42 days after the first dose of the Pfizer-BioNTech mRNA vaccine2. By contrast, the risk ratio of myocarditis associated with COVID-19 was estimated to be 18.28 (ref.2). Importantly, most of the patients admitted to hospital with post-mRNA-vaccine myocarditis survived and recovered cardiac function within 1–5 weeks after an initial hospitalization of 3–5 days2,3,4,5. In addition, the higher proactive surveillance and public awareness in vaccinated people owing to intense media attention, and the reporting of unrelated myocarditis cases weeks to months after vaccination, might have resulted in an overestimation bias of this surplus risk compared with more passively collected historical data.
“the benefit–risk assessment for COVID-19 (mRNA) vaccination underscores a very strong favourable balance for all age and sex groups”
Despite these rare cases of self-limited myocarditis, the benefit–risk assessment for COVID-19 (mRNA) vaccination underscores a very strong favourable balance for all age and sex groups. Vaccines against COVID-19 have proved to be highly effective at preventing symptomatic disease in clinical trials and real-world reports. Vaccination flattens the epidemiology curve and strongly reduces the risk of COVID-19-related hospitalization, intensive care admission and death in both young and elderly individuals10. COVID-19 vaccination also reduces the risk of COVID-19-associated acute kidney injury, arrhythmia and thrombosis10. Moreover, with COVID-19 vaccination, the risk of myocardial injury and myocarditis strongly decreases in the general population, with a minor 1–5-fold increased risk of mild myocarditis in young adults. Therefore, COVID-19 vaccination has an extremely favourable risk ratio for myocardial injury and should be recommended in adolescent and adult populations.
“with COVID-19 vaccination, the risk of myocardial injury and myocarditis decreases 1,000-fold in the general population”
Heymans, S., Eriksson, U., Lehtonen, J. & Cooper, L. T. Jr. The quest for new approaches in myocarditis and inflammatory cardiomyopathy. J. Am. Coll. Cardiol. 68, 2348–2364 (2016).
Witberg, G. et al. Myocarditis after Covid-19 vaccination in a large health care organization. N. Engl. J. Med. https://doi.org/10.1056/NEJMoa2110737 (2021).
Mevorach, D. et al. Myocarditis after BNT162b2 mRNA vaccine against Covid-19 in Israel. N. Engl. J. Med. https://doi.org/10.1056/NEJMoa2109730 (2021).
Klein, N. P. et al. Surveillance for adverse events after COVID-19 mRNA vaccination. JAMA 326, 1390–1399 (2021).
Montgomery, J. et al. Myocarditis following immunization with mRNA COVID-19 vaccines in members of the US Military. JAMA Cardiol. 6, 1202–1206 (2021).
Greulich, S. et al. Predictors of mortality in patients with biopsy-proven viral myocarditis: 10-year outcome data. J. Am. Heart Assoc. 9, e015351 (2020).
Maiese, A. et al. Myocardial pathology in COVID-19-associated cardiac injury: a systematic review. Diagnostics 11, 1647 (2021).
Aikawa, T., Takagi, H., Ishikawa, K. & Kuno, T. Myocardial injury characterized by elevated cardiac troponin and in-hospital mortality of COVID-19: an insight from a meta-analysis. J. Med. Virol. 93, 51–55 (2021).
Vojdani, A. & Kharrazian, D. Potential antigenic cross-reactivity between SARS-CoV-2 and human tissue with a possible link to an increase in autoimmune diseases. Clin. Immunol. 217, 108480 (2020).
Baden, L. R. et al. Efficacy and safety of the mRNA-1273 SARS-CoV-2 vaccine. N. Engl. J. Med. 384, 403–416 (2021).
S.H. is an independent consultant to AstraZeneca and CSL Behring for advice on preclinical development in heart failure. L.T.C. declares no competing interests.
About this article
Cite this article
Heymans, S., Cooper, L.T. Myocarditis after COVID-19 mRNA vaccination: clinical observations and potential mechanisms. Nat Rev Cardiol 19, 75–77 (2022). https://doi.org/10.1038/s41569-021-00662-w
This article is cited by
A 1-year analysis of adverse events following COVID-19 vaccination in Lebanon: a retrospective study
Journal of Pharmaceutical Policy and Practice (2023)
Diagnostics of messenger ribonucleic acid (mRNA) severe acute respiratory syndrome-corona virus‑2 (SARS-CoV‑2) vaccination-associated myocarditis—A systematic review
Pediatric Nephrology (2023)
Clinical Research in Cardiology (2023)
Current Treatment Options in Cardiovascular Medicine (2023)