In-Depth Evaluation of a Case of Presumed Myocarditis After the Second Dose of COVID-19 mRNA Vaccine

Initial Presentation

A 52-year-old man presented to the emergency department ≈90 min after the onset of substernal chest pain. Three days before presentation, he received his second dose of mRNA-1273 (Moderna) vaccine for coronavirus disease 2019 (COVID-19), and the next day had a severe reaction that he described as being the “worst he had ever felt.” He had subjective high fevers, shaking chills, myalgias, and a headache. These symptoms largely resolved by the third day after vaccination except for a positional headache that was unusual for him. On the morning of hospitalization, he walked 3 to 4 miles and felt fine. Later that day, while in a meeting, he developed persistent midsternal chest discomfort without radiation, prompting him to seek evaluation in a university hospital emergency department. The pain subsided spontaneously after approximately 3 hours. He had no associated dyspnea, palpitations, dizziness, fever, chills, or myalgia.

The patient had a past medical history of hypertension, hypercholesterolemia, obstructive sleep apnea treated with an oral appliance, and minor elevations in liver function tests attributed to possible hepatic steatosis. A recent screening coronary artery calcium scan demonstrated coronary artery calcium at the 81st percentile for age and sex. The patient had no previous history of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection. His medications included aspirin 81 mg, simvastatin 40 mg, ezetimibe 10 mg, and lisinopril 10 mg daily, and he took no supplements. He drank alcohol socially and denied use of tobacco and all recreational drugs.

On physical examination, the following vital signs were recorded: oral temperature 36.8°C, pulse 73/min, blood pressure 124/76, and respiratory rate 18/min, and his oxygen saturation was 100% on room air. Pulmonary and cardiac examinations were normal without a pericardial friction rub. The remainder of his physical examination was normal.

In the emergency department, his initial ECG showed sinus rhythm with left axis deviation and incomplete right bundle-branch block without ST or T wave changes (Figure 1A). His initial high-sensitivity cardiac troponin I was 2768 ng/L. Point-of-care echocardiogram showed normal left ventricular function and volumes, and no wall motion abnormalities. Urgent coronary angiography showed mild nonobstructive coronary artery disease with no stenoses or visible thrombus and no evidence of coronary embolism or dissection (Figure 1B and 1C).

His initial laboratory panel revealed normal white blood cells 6.3 × 10⁹/L (76% polymorphonuclear leukocytes, 14% lymphocytes, 9% monocytes, 0.5% eosinophils, and 0.2% basophils), hemoglobin 14.9 g/L, and platelets 207 × 10⁹/L. Chemistries were remarkable for glucose of 172 mg/dL, but creatinine 0.87 mg/dL and alanine aminotransferase 58 U/L were consistent with his baseline. High-sensitivity cardiac troponin I peaked at 6770 ng/L at 7 hours after admission and remained elevated (551 ng/L) even after 4 days. In contrast, high-sensitivity cardiac troponin T and creatine kinase-MB biomarkers showed modest elevation (Table 1). C-reactive protein, erythrocyte sedimentation rate, and D-dimer were elevated in the first sample taken at the time of admission but resolved to near normal levels within 1 to 2 days. Antinuclear antibodies were negative.

Additional Clinical Testing

A repeat echocardiogram performed on hospital day 2 revealed a normal ejection fraction without wall motion abnormalities and no valvular or pericardial abnormalities. Contrast-enhanced cardiac magnetic resonance imaging (MRI) with parametric mapping was performed on a 1.5T MRI scanner (Siemens Healthineers) on hospital day 3. Delayed contrast-enhanced phase-sensitive images showed midmyocardial and subepicardial linear and nodular late gadolinium enhancement in the inferoseptal, inferolateral, anterolateral, and apical walls. The left ventricle showed mild dilatation and “low normal” left ventricular ejection fraction at 54%. The right ventricular ejection fraction was normal at 58%. Parametric mapping showed elevated T1 relaxation time and relative inhomogeneity and focal elevation of the T2 relaxation values (Figure 2). In addition, wall motion abnormalities with mild hypokinesis of the lateral and inferior apical walls were noted. These findings were consistent with myocarditis on the basis of the modified Lake Louise criteria.¹

Hospital Course

The chest discomfort in the patient had fully resolved within 3 hours after onset and did not recur. He reported feeling normal throughout the remainder of his 4-day hospital stay. Endomyocardial biopsy was not performed because of his resolution of symptoms, preserved left ventricular ejection fraction, and the absence of any hemodynamic or arrhythmic complications. The patient was treated with low-dose lisinopril and carvedilol, but no immunosuppressive or anti-inflammatory medications. At the time of discharge, the patient remained asymptomatic, and his high-sensitivity cardiac troponin T levels had fallen to 138 ng/L. His NT-proBNP (N-terminal pro-B-type natriuretic peptide) at discharge was <27 pg/mL.

Postdischarge Course

The patient has had no recurrent symptoms in >3 months since hospital discharge. Given the presumptive diagnosis of myocarditis, exercise has been restricted, and he has remained on β-blocker and angiotensin-converting enzyme inhibitor medications. Repeat high-sensitivity cardiac troponin I was 10 ng/L 4 days after discharge and undetectable (<5 ng/L) 2 weeks after discharge. Serial cardiac MRIs have been performed showing a gradual reduction in left ventricular volumes and reduction in the degree of late gadolinium enhancement abnormalities, with normalization of T1 relaxation time and decrease in the T2 relaxation time (Table 2).

Exploratory Studies to Investigate Potential Pathological Mechanisms

Myopericarditis has been reported to the US national passive Vaccine Safety Surveillance System (VAERS) as a rare adverse event after vaccinations, with most reports associated with smallpox vaccination.² However, at the time of the patient’s presentation, there were no reported cases of myocarditis caused by COVID-19 vaccination.

To explore potential mechanisms of myocardial injury in temporal association with vaccination in the present case, written informed consent was obtained for additional in-depth analysis of viral, cytokine, and autoimmune panels and subsequent research publication of the case. Samples from the patient of interest were compared with excess, remnant blood specimens that were available in the laboratory after routine clinical testing. Samples from the case of interest (CI) were collected on days 1 to 4 after symptom onset (CI_S1–S4) and were compared with 4 groups: naive unvaccinated (N_UV; n=8), unvaccinated patients hospitalized with COVID-19 (n=10), naive vaccinated (N_V; n=10), and age-matched controls receiving Moderna vaccine (N_M, n=2). N_V and N_M groups were tested ≈?2 weeks after receiving their second vaccine dose. The studies were performed as part of a biorepository protocol approved by the University of Texas Southwestern Institutional Review Board, and waiver of Institutional Review Board consent was obtained to use the remnant blood specimens. Detailed methods are provided in the Methods in the Data Supplement.

Results of Exploratory Studies

Antibody response to viral antigens and SARS-CoV-2 nucleocapsid and spike proteins serum immunoglobulin (Ig) G antibodies against 18 different viral antigens and SARS-CoV-2 serology testing were measured using a custom developed proteome array and US Food and Drug Administration–approved standard assays, respectively, using the methods described in the Methods in the Data Supplement. These studies confirmed the absence of previous COVID-19 infection (negative reactivity for SARS-CoV-2 nucleocapsid IgG) (Figures 3 and 4). As expected, a clear immune response to the vaccine (SARS-CoV-2 spike as a component) was observed in the case of interest 5 and 6 days after the second dose of Moderna vaccine, which corresponds with the third and fourth day after symptom onset in the case of interest (CI_S3 and CI_S4) (Figure 3). Comparison of the strength of vaccine-induced immune responses in the case of interest at the measured sampling period CI_S2 and CI_S4 with either N_V or N_M did not reveal abnormally elevated SARS-CoV-2 spike IgG or SARS-CoV-2 spike IgM levels (Figure 4). Low IgG serology reactivity was noted in the case patient samples (CI_S1–S4) for the other viral antigens, including cytomegalovirus, Epstein-Barr virus, influenza A, and respiratory syncytial virus compared with vaccinated control samples (Figure 3). It is interesting that, although anti-spike antibody levels were higher than the manufacturer-recommended positive threshold, the SARS spike protein antibody levels were either lower or just comparable in the case compared with N_V (Figure 4). This may be partly explained by a difference in the timing of blood sampling after immunization among the vaccinated controls (2 weeks) versus case patient (5–6 days) for assessing antibody response. Concurrent clinical evaluation for known infectious causes of acute myocarditis, including multiple SARS-CoV-2 nasopharyngeal polymerase chain reaction tests and Food and Drug Administration–approved multiplex respiratory viral polymerase chain reaction panels and serologies, were all negative with 2 exceptions. An IgG antibody for Mycoplasma pneumoniae was positive but IgM antibody was negative, consistent with previous exposure and not acute infection. In addition, an IgG titer of 1:320 was reported for coxsackie B virus 4, but IgM antibody titers were negative. However, convalescent serum antibody testing 3 weeks later revealed a titer of 1:160, consistent with remote and not acute or recent infection.

Discussion

This case describes a 52-year-old previously healthy man who presented with an acute myocarditis-like illness 3 days after the administration of the second dose of Moderna’s COVID-19 vaccine. Although endomyocardial biopsy was not performed, the clinical and cardiac MRI features were consistent with myocarditis, as was the resolution of symptoms and gradual improvement in cardiac MRI findings. The case does not prove a causal association between the vaccine and the observed myocarditis-like syndrome. However, ischemic injury and other potential causes of acute myocardial injury were excluded, as were other potential infectious causes of myocarditis, and there was no evidence of systemic autoimmune disease.

The US Centers for Disease Control and Prevention have received reports of possible cases of vaccine-associated myocarditis through the VAERS reporting system, and anecdotal cases have been recently been reported in the lay media. Moreover, 2 case series in this issue of Circulation report similar presentations of myocarditis-like illness 2 to 4 days after COVID-19 vaccination.^29,30 However, the link between COVID-19 vaccination and myocarditis remains circumstantial, and a mechanism has not been established. This case represents one of the first reports of possible mRNA-based COVID-19 vaccine–associated myocarditis reported in the medical literature, with in-depth clinical and translational investigation and comparison with different control groups.

Although multiple cytokines and autoantibodies with plausible links to myocarditis or cardiac pathogenesis appeared to differ in the case patient compared with controls, a specific signature was not identified. There was an increase in numbers of a specific subset of NK cells and increased expression of several autoantibodies compared with controls. T helper 17 cells–related IL-17–enriched immune signature has been implicated in the development of myocarditis and its associated transition of fibrosis to heart failure.³¹ It is interesting that such upregulation of IL-17 levels was not observed in our patient. The lack of evidence for upregulation of this cytokine, combined with the increased NK cell numbers observed in the case patient, could suggest a distinct vaccine-associated immunophenotype with a high likelihood for rapid recovery. However, it is not clear whether the observed differences reflect a potential (causal) pathological immune response or rather appropriate healing responses to myocardial inflammation. These differences may also be chance findings, given the exploratory nature of our investigations and large numbers of tests performed in few patients. Additional studies in larger numbers of individuals are needed to explore potential mechanisms, including prospective studies with biospecimen collection before and after vaccination.

Clinicians should be aware that myocarditis may be present in patients exhibiting cardiac signs and symptoms 2 to 4 days after COVID-19 vaccination. However, we emphasize that this report of a rare potential vaccine-related adverse event does not change the highly favorable risk/benefit of COVID-19 vaccination, including in patients with underlying heart disease or cardiomyopathy. Additional surveillance of such adverse events after COVID-19 vaccination will help to identify whether there are subgroups who are at higher risk for this vaccine-related effect, and if so, whether additional precautions are necessary.

Acknowledgments

The authors thank the Abbott Diagnostics Division in Illinois for providing SARS-CoV-2–specific antibody test kits for clinical research.

Sources of Funding

Dr Muthukumar has received grant support from Abbott and Roche Diagnostics. The autoantibody assay was funded through the Alfred W. Harris, MD, Professorship in Cardiology awarded to Dr Mammen. Dr de Lemos has received grant support from Abbott Diagnostics and Roche Diagnostics.

Disclosures

Dr de Lemos has received consulting income from Siemens Health Care Diagnostics, Ortho Clinical Diagnostics, and Quidel, Inc. The other authors report no conflicts.

Supplemental Materials

Expanded Methods

Supplementary Material