Abstract
Vaccination represents one of the fundamentals in the fight against SARS-CoV-2. Myocarditis has been reported as a rare but possible adverse consequence of different vaccines, and its clinical presentation can range from mild symptoms to acute heart failure. We report a case of a 29-year-old man who presented with fever and retrosternal pain after receiving SARS-CoV-2 vaccine. Cardiac magnetic resonance imaging and laboratory data revealed typical findings of acute myocarditis.
Keywords: Myocarditis, Vaccination, COVID-19, MRI
Myocarditis; Vaccination; COVID-19; MRI.
1. Introduction
Informed consent of the patient was obtained for the publication of this article. A 29-year-old male presented with fever and retrosternal pain to the emergency department after he had received a SARS-CoV-2-vaccination (Vaxzevria, Astra Zeneca) three days earlier. The patient had a medical history no known chronic illnesses or allergies and had not been using any medication. Vital signs were normal (blood pressure 125/85mmHg, heart rate 75bpm, respiratory rate 16/min, SpO2 99%). ECG showed ST-elevations of the posterolateral wall and depressions of the anterior wall (Figure 1, ECG leads II, III and aVF respectively V1–V3). In the initial laboratory testing (normal values in parenthesis) hscTroponin: 363pg (<14); CK-MB: 37U/l (<25) and nt-proBNP 347 pg/ml (<125) as well as CRP: 2,2 mg/dl (<0.50) were elevated. The remaining blood values including myoglobin were normal. Coronary heart disease was ruled out by an immediate invasive cardiac catheterization on the same day. Echocardiography showed a slightly impaired left ventricular ejection fraction (44%) without segmental wall motion abnormalities while other findings including B/M mode assessment as well as Colour Doppler, pulsed- and continuous-wave Doppler ultrasound and tissue Doppler examination revealed no structural changes or further functional disorders. The patient was transferred to a high care ward and a cardiac MRI was performed on the following day.
Figure 1.
ECG on admission showing ST-elevations of the posterolateral wall and depressions of the anterior wall.
2. Findings of functional MRI
The magnetic resonance imaging (MRI) on the 5th day post Astra Zeneca vaccination was acquired as a multiparametric functional MRI using refocusing gradient echo technique “steady-state free-precession” cinematic MRI sequences (CINE) and morphologic T1 and T2-weighted (MORPHO) sequences after intra-venous application of 25 ml Dotarem in early and late contrast-enhanced phase. Motion corrected T1 and T2 mapping sequences were acquired. These sequences were used to analyze functional and volumetric information.
T1- and T2-weighted images as non-contrasted sequences and T1 after contrast agent injection. The sequences were acquired in short-axis transversal, 2-,3-,4- chamber view, as well as left ventricular outflow-tract view.
MRI-images (Figure 2A and B) showed normal morphology of atrium and ventricles as well as normal size of the left ventricular outflow tract. Physiological morphology of all valves without stenosis or insufficiency was present. Kinetic wall movement was not impaired. In T1-weighted sequences, diffuse spotty partial configurated lesions of the lateral ventricular wall were reported (Figure 2C and D). After intravenous application of contrast agent, delayed perfusion in these areas was present (late gadolinium enhancement [LGE]). Lateral ventricular wall edema was present in T2-weighted sequences. The left ventricular ejection fraction (LVEF) was reported as slightly too high with 58%, with an end-systolic volume of 96 ml and 227 ml end-diastolic. No pericardial effusion was present. No signs of tumor, thrombosis, no atherosclerosis. During the examination, the heartbeat was 55 bpm. Based on the findings florid myocarditis was diagnosed.
Figure 2.
Cardiac MRI demonstrated lateral ventricular wall edema in T2-weighted images (A, B, arrows) with corresponding LGE in T1-weighted images (C, D, arrowheads) indicating acute myocarditis. In four-chamber view (Figure 2 A and B) spotty hyper hyperintensities corresponding to the lateral ventricular edema are confirming the diagnosis. Besides from these findings, indicating myocarditis, our cardiac MRI showed no other pathologies and physiological anatomy.
3. Clinical course
After MRI, the patient was treated with antiphlogistics, ace-inhibitors and beta-blockers. PCR and serologic tests for viral infections (Including influenza viruses, human cytomegalovirus, Ebstein-Barr-Virus, adenoviridae, mykoplasma, toxoplasma gondii, borellia burgdorferi and coxiella burnettii as well as repetitive testing for SARS-CoV 2 Virus) were negative, antibodies specific to SARS-CoV 2 were not tested. Symptoms improved as cardiac enzymes and inflammation markers decreased during the further course. The patient suffered no relevant arrhythmias and was discharged after 24 h monitoring during as symptoms dissipated completely. Due to negative tests for viral infections and the spontaneous healing after few days, the vaccination represented the most likely cause. A checkup a week later showed a normal ECG and echocardiography, MRI was not repeated.
4. Discussion
Myocarditis is reported as being caused by SARS-CoV-2 but there have been a few cases reported after SARS-CoV-2 vaccination so far. Direct virus-induced cell damage to infected cardiomyocytes and T-cell-mediated cytotoxicity [1], as well as immunological processes in response to viral components of the vaccine or immunogenic adjuvants [2, 3], are suspected as a possible cause. These rare cases of myocarditis which were reported after SARS-CoV-2 vaccination mostly manifested over a short, self-limiting course without permanent impairment of cardiac function and predominantly affect young men with a mean age of 25 years [4, 5].
In this context, MRI is the diagnostic imaging modality of choice for patients with cardiac clinical symptoms, as it is non-invasive and causes no radiation exposition to young patients [6]. LGE, myocardial edema, and pericardial thickening as well as pathological findings in ECG and laboratory values confirm the diagnosis of myocarditis. In this context, the Lake Louis criteria are used to qualitatively assess cardiac MRI [7, 8]. Myocarditis is diagnosed when two of the following criteria are matched by the findings: myocardial edema in T2-WI; early Gadolinium enhancement indicating hyperemia; myocardial damage with non-ischemic morphology and corresponding LGE.
Myocarditis has been reported mainly after administration of mRNA vaccines [4, 5, 9]; only 8 cases have been reported to the German Paul Ehrlich Institute after vaccination with the adenovirus-based vector vaccine Vaxzevria (formerly known as COVID-19 vaccine AstraZeneca) with over 9 million doses of this vaccine recently administered in Germany [10]. The evaluation of foreign vaccination surveillance showed a rather negative association with the occurrence of myocarditis and vaccination with Vaxzevria or the COVID-19 vaccine Janssen [11].
From the view of pathophysiology, the literature suggests autoimmune myocarditis as the most likely cause for post-vaccination myocarditis [1, 4, 11]. This is explained by “molecular mimicry” as viral antigens are similar to the antigen-proteins on myocardial cells, thus an autoimmunological reaction causes lymphocytes, phagocytes, and granulocytes to attack the body's own cells. Secondly, a hypersensitivity reaction could have taken place after vaccination. In our case, the patient only received a single dose of vaccine, making this overshooting reaction less likely compared to patients receiving two vaccinations (BioNTech, Moderna, etc) [2, 3, 11].
So far, myocarditis hasn't been confirmed as a specific complication after vaccination with a vector vaccine against SARS-CoV-2 but should be considered if there is a temporal coincidence and no other explanation. As our experience so far with a single patient may be an exception, there should be more cases collected and analyzed to prove this correlation between COVID-19 vaccination and myocarditis.
Declarations
Author contribution statement
All authors listed have significantly contributed to the investigation, development and writing of this article.
Funding statement
This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.
Data availability statement
Data will be made available on request.
Declaration of interests statement
The authors declare no conflict of interest.
Additional information
No additional information is available for this paper.
Footnotes
This article is a part of the "Advanced Imaging in Cardiovascular Diseases" Special issue.
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Associated Data
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Data Availability Statement
Data will be made available on request.