In this issue of the Canadian Journal of Cardiology, Zuin et al. completed a systematic
review and meta-analysis to assess the risk of incident acute myocarditis (AM) in
novel Coronavirus disease 2019 (COVID-19) survivors within 1 year following their
index infection.
1
Data from 4 studies reporting cases of AM in the post-acute phase of infection (4-12
months) were identified searching MEDLINE and Scopus (up to September 1, 2022). Mean
age, sex, pre-existing co-morbid conditions including presence of hypertension, diabetes
mellitus, chronic obstructive pulmonary disease, chronic kidney disease, heart failure
and stroke, as well as length of follow-up were recorded. Each study compared their
COVID-19 recovered patients to contemporary cohorts without a confirmed COVID-19 infection.
Over 20 million patients were followed over a mean follow-up period of 9.5 months.
COVID-19 infection was identified in 1.25 million patients. During the follow-up period,
the authors report that AM occurred in 0.21 [95% CI: 0.13-0.42] of 1000 patients who
survived their COVID- 19 infection, compared to 0.09 [95% CI: 0.07-012] of 1000 control
subjects. The results show an increased risk of incident AM of HR 5.16, 95% CI: 3.87-6.89,
p<0.0001, I2=7.9% in previously infected COVID 19 patients 1 year post index infection.
Though AM has been well reported in the acute infective period and after mRNA vaccination,
this manuscript highlights the development of AM in COVID-19 recovered patients.
COVID-19 infection related myocarditis
First identified in Wuhan, China in December 2019, COVID-19 caused by severe acute
respiratory syndrome coronavirus 2 (SARS-CoV-2) leads to mild-moderate respiratory
symptoms in a majority of cases. Multiple series have documented the variety of cardiac
complications which can manifest during the acute infection phase including acute
cardiac injury seen with elevated troponins, acute coronary syndrome, heart failure
with reduced ejection fraction, pericardial effusion, and most rarely, AM. Definite
or probable AM during the acute phase of illness has been estimated to occur at a
rate of 2.4 per 1000 hospitalizations.2, 3 Early recognition is of importance given
the younger population it tends to afflict (<40 years), and the fulminant presentation
with the need for intensive care in 70% of cases. In 39% of patients, inotropic/vasopressor
support or temporary mechanical circulatory support is required
3
Prognosis is favorable in those with isolated AM, compared to those with concomitant
respiratory involvement, where mortality has been reported to be 15%.
3
It is well established that AM is a consequence of a “trigger”, which include infectious
(viral, bacterial or fungal) or an immune disturbance (autoimmunity or hypersensitivity),
leading to a cascade of secondary autoimmunity.
4
The pathophysiology in acute COVID-19 infection is likely related to both viral and
host immune factors, but the exact mechanisms are not yet clear. Proposed viral mediated
mechanisms include direct myocardial injury via angiotensin-converting enzyme 2 receptors
(ACE2), which may indirectly cause myocardial inflammation, cytokine storm mediated
by immune dysregulation and lastly, ongoing hypoxia from oxygen supply/demand mismatch.5,
6, 7, 8 Direct myocardial injury by SARS-Cov2 has been thought to occur by the virus
binding on the spike protein of the ACE2 receptor. Entry into the cell triggers decreased
myocardial ACE2 protein expression and causes macrophage infiltration and myocardial
damage.
5
In a subset of individuals, immune dysregulation occurs following COVID-19 infection,
leading to a rise in pro-inflammatory cytokines such as IL-2,6-7, tumor necrosis factor-alpha,
C-X-C motif cytokine 10 and C motif ligand 2. The rapid rise in circulating cytokines
leads to activation of T-lymphocytes that cause myocardial injury resulting in a profound
hyperinflammatory reaction. 6, 7 Though gene sequences of the SARS-CoV-2 have been
found in endomyocardial biopsy specimens, there is a paucity of data that supports
that the virus can cause direct cardiomyocyte death..
9
COVID-19 vaccine related myocarditis
With the development of mRNA vaccination targeting SARS-CoV-2, cases of AM have been
reported as a rare complication, with a reported rate of 12.6 cases per million of
second vaccine dose administered. Afflicted individuals are predominately <40 years
of age, and present with a variety of symptoms including chest pain, dyspnea or palpitations
usually within 1 week post vaccine administration.
10
The inclusion of modified mRNA within the vaccine, which serves as a delivery medium
to transport the viral spike glycoprotein of SARS-CoV-2 into cells is believed to
be the “trigger.” Despite nucleoside modifications of the mRNA which is meant to reduce
its immunogenicity, a subset of the general population with a genetic predisposition,
develops an aberrant response causing upregulation of the innate and acquired immune
system which leads to circulation of heart reactive antibodies.
11
As the clinical trajectory of those who develop COVID-19 vaccine related myocarditis
is often mild and self-limiting, 12, 13, 14, 15, 16, 17 clear guidelines from public
health authorities recommended vaccination in all age groups.
10
Incident myocarditis post COVID-19 infection
What is of interest in the meta-analysis by Zuin et al., is the development of AM
outside of the acute phase of illness or following an mRNA vaccine. As the pandemic
has evolved, it is well recognized that these two previously discussed scenarios are
quite rare. What is unclear from a mechanistic point of view is the “trigger” which
causes the immune system to become “re”-activated in the post-acute phase of illness
in incident AM. Given what is known about COVID-19 infection and the host immune response,
it could be surmised that incident AM may occur in an individual with a predisposed
immunogenetic background or a history of autoimmune disease, and a “trigger” that
reactivates the immune system and its subsequent hyperinflammatory response.
Though one could postulate that a COVID-19 vaccination may been the “trigger” for
an AM presentation post COVID recovery, two of the included studies would suggest
otherwise. Wang et al. evaluated non vaccinated patients with COVID-19 infection,
and found the rate of AM was higher than those without previous infection (HR 4.406
[2.89-6.720].
18
A second study be Xie et al. found that the incidence of AM in COVID-19 recovered
patients was higher than those without previous infection (HR 5.38 [3.8-7.6]. In order
to eliminate a potential COVID-19 vaccine exposure as a potential “trigger” for AM,
they completed two different analyses. Incident rates for AM were still higher even
when the authors censored patients at time of receiving 1st dose of any COVID-19 vaccine
(HR 5.31 [3.75-7.53], and after adjustment for vaccination as a time varying co-variate
(HR 5.34 [3.76-7.6], compared to those without previous COVID-19 infection.19.
An alternative hypothesis which has been proposed is whether incidence AM is a result
of a persistent chronic inflammatory response which results from persistent viral
load in myocardial cells.
20
As the cases of recovered COVID-19 patients rise, it has become apparent that some
patients have persistent symptoms beyond after infection onset. In some series, 20%
of patients report symptoms beyond 4 weeks and 10% have ongoing symptoms beyond 12
weeks.
21
Termed “post-COVID-19 syndrome” by the World Health Organization, ongoing cardiac,
respiratory, and neurological symptoms beyond 3 months without an alternative diagnosis,
22
has now become a common diagnosis seen in the offices of subspecialty providers. It
is not apparent if incident myocarditis is part of the “post-COVID-19 syndrome” as
suggested in one review
23
or is a consequence of a second inciting agent or “trigger” in an immune-susceptible
individual after symptom resolution. Further studies are needed to fully understand
the pathophysiology of this “rare” event, as well as the clinical outcomes in this
group of patients.
Future Directions
Along with the limitations already described within this study, one major limitation
is the lack of further clinical information about the patients who develop incident
AM. Given the unknown patient profile for this “at-risk population,” it remains challenging
to know how we best manage recovered patients. Clinicians might wonder if identification
and subsequent risk assessment can be undertaken at time of index infection. Can providers
identify these patients at risk up front and follow them more closely clinically?
If so, how? Are there clinical parameters that could predict those at higher risk?
Are their novel biomarkers which can be used? Does the risk vary with COVID-19 variant?
In those that are at higher risk, how does one monitor them, and for how long after
their infection, and how frequently? If screening is done, which diagnostic tools
should be used? The latter is of utmost importance given the lack of data that supports
routine cardiac testing post COVID-19 infection and the utility as well as cost benefit
of widespread screening in an event that is infrequent. In addition, in those deemed
to be at higher risk, are there prophylactic medications that can reduce inflammatory
burden and risk? If so, how long do they need to be given? In those who develop incident
AM, how best do we treat them asides from vasopressors/inotropes in the critical care
setting along with foundational therapy for heart function? Which immunosuppressive
therapies do we use and for how long do the need to be given?
What is expected as we move further into this pandemic is further understanding of
the projected large proportion of patients with residual cardiac symptoms, including
those with incident AM. The epidemiological findings presented in this study presents
yet another “rare” myocarditis event associated with COVID-19 infection. Prospective
registries such as CV COVID-19 Registry Investigators and AHA's COVID-19 CVD Registry
powered by Get With The Guidelines,24-25as well as case series will be valuable in
our understanding of the clinical outcomes of these patients. Perhaps, it is still
too early to sound the alarm bells.
Figure 1
Potential areas for future research in incident acute myocarditis (AM) based on stage
of illness (index illness, post recovery of acute illness and at time of AM)- figure
created using wepik.
Uncited reference
19., 24., 25..