Article
Shedding the Light on Post-Vaccine Myocarditis and
Pericarditis in COVID-19 and Non-COVID-19
Vaccine Recipients

Rima Hajjo 1,2,3,*, Dima A. Sabbah 1

, Sanaa K. Bardaweel 4

and Alexander Tropsha 2

1 Department of Pharmacy, Faculty of Pharmacy, Al-Zaytoonah University of Jordan, Amman 11733, Jordan;

2

dima.sabbah@zuj.edu.jo
Laboratory for Molecular Modeling, Division of Chemical Biology and Medicinal Chemistry, Eshelman
School of Pharmacy, The University of North Carlina at Chapel Hill, Chapel Hill, NC 27515, USA;
alex_tropsha@unc.edu

3 National Center for Epidemics and Communicable Disease Control, Amman 11942, Jordan
4 Department of Pharmaceutical Sciences, School of Pharmacy, University of Jordan, Amman 11942, Jordan;

s.bardaweel@ju.edu.jo

* Correspondence: r.hajjo@zuj.edu.jo

Abstract: Myocarditis and pericarditis have been linked recently to COVID-19 vaccines without
exploring the underlying mechanisms, or compared to cardiac adverse events post-non-COVID-
19 vaccines. We introduce an informatics approach to study post-vaccine adverse events on the
systems biology level to aid the prioritization of effective preventive measures and mechanism-based
pharmacotherapy by integrating the analysis of adverse event reports from the Vaccine Adverse
Event Reporting System (VAERS) with systems biology methods. Our results indicated that post-
vaccine myocarditis and pericarditis were associated most frequently with mRNA COVID-19 vaccines
followed by live or live-attenuated non-COVID-19 vaccines such as smallpox and anthrax vaccines.
The frequencies of cardiac adverse events were affected by vaccine, vaccine type, vaccine dose, sex,
and age of the vaccinated individuals. Systems biology results suggested a central role of interferon-
gamma (INF-gamma) in the biological processes leading to cardiac adverse events, by impacting
MAPK and JAK-STAT signaling pathways. We suggest that increasing the time interval between
vaccine doses minimizes the risks of developing inflammatory adverse reactions. We also propose
glucocorticoids as preferred treatments based on system biology evidence. Our informatics workflow
provides an invaluable tool to study post-vaccine adverse events on the systems biology level to
suggest effective mechanism-based pharmacotherapy and/or suitable preventive measures.

Keywords: COVID-19; myocarditis; pericarditis; SARS-CoV-2; systems biology; vaccine; VAERS

Citation: Hajjo, R.; Sabbah, D.A.;

Bardaweel, S.K.; Tropsha, A.

Shedding the Light on Post-Vaccine

Myocarditis and Pericarditis in

COVID-19 and Non-COVID-19

Vaccine Recipients. Vaccines 2021, 9,

1186. https://doi.org/10.3390/

vaccines9101186

Academic Editors: Soo-Hong Lee,

Jagathesh Chandra Rajendran,

Hansoo Park and K.S Jaganathan

Received: 22 September 2021

Accepted: 13 October 2021

Published: 15 October 2021

Publisher’s Note: MDPI stays neutral

with regard to jurisdictional claims in

published maps and institutional affil-

iations.

1. Introduction

Since the identification of SARS-CoV-2 virus in 2019 and the emergence of Coron-
avirus disease of 2019 (COVID-19) as a global pandemic, there has been an upsurge of
vaccine research and development worldwide with several vaccines that completed the
clinical evaluation phases and were authorized for COVID-19 [1,2]. The theoretical and
technological strategies used to develop the currently approved vaccines are diverse al-
lowing for their preferential use in distinct groups of the human population [3]. However,
owing to COVID-19 vaccines’ rapid development and the innovation of the implemented
technologies, it is reasonable to expect that some issues or problems, such as unexpected
side effects, associated with the use of a new vaccine against a new disease may arise and
would need to be addressed.

Adverse reactions to vaccines are usually trivial. The Vaccine Adverse Event Report-
ing System (VAERS) database provides information on reports of adverse effects after

Copyright: © 2021 by the authors.

Licensee MDPI, Basel, Switzerland.

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Vaccines 2021, 9, 1186. https://doi.org/10.3390/vaccines9101186

https://www.mdpi.com/journal/vaccines

(cid:1)(cid:2)(cid:3)(cid:1)(cid:4)(cid:5)(cid:6)(cid:7)(cid:8)(cid:1)
(cid:1)(cid:2)(cid:3)(cid:4)(cid:5)(cid:6)(cid:7)

Vaccines 2021, 9, 1186

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vaccination with vaccines approved for use in the United States. Recently, several worri-
some reports have been released on the development of acute myocarditis after COVID-19
vaccination [4,5].

The Advisory Committee on Immunization Practices (ACIP) at the U.S. Centers for
Disease Control and Prevention (CDC) has released a statement on May 17, saying that a few
young vaccine recipients, predominantly male adolescents and young adults, developed a
condition known as myocarditis, which is defined as the inflammatory processes of the
muscular walls of the heart (myocardium) which result in injury to the cardiac muscle
cells (myocytes), according to MeSH Descriptor Data 2021 [6]. Manifestations range from
subclinical to sudden death. Myocarditis can reduce the heart’s ability to function or cause
arrhythmia CDC [7,8]. Currently, there are increasing numbers of adverse even reports of
post-COVID-19 myocarditis and pericarditis [9]. Pericarditis is inflammation of the fibro-
serous sac surrounding the heart (pericardium) from various origins, such as infection,
neoplasm, autoimmune process, injuries, or drug-induced according to MeSH Descriptor
Data 2021 [10]. Pericarditis usually leads to pericardial effusion or constrictive pericarditis.
Myocarditis and pericarditis symptoms can range from asymptomatic, to chest pain
with little or no overt cardiac damage, to acute and severe cardiac dysfunction associated
high mortality if untreated [11]. These conditions has been frequently linked to common
viral infections and less often to hypersensitivity related to drug reactions in the human
body [12]. Thus far, the CDC did not find a causal link between myocarditis and COVID-19
vaccines [8].

Herein, we introduce an informatics workflow to study vaccine adverse events on the
systems biology level. We also shed the light on post-vaccine myocarditis and pericarditis
by providing answers to the following key questions: What COVID-19 vaccines were
linked to myocarditis and/or pericarditis? What sex and age group were mostly affected?
Are these adverse events affected by the vaccine dose? Are post-vaccine myocarditis
and pericarditis common post-non-COVID-19 vaccines? Finally, we attempt to provide
a mechanistic insight for post-vaccine myocarditis and pericarditis by deriving testable
hypotheses backed by evidence derived from systems biology analyses.

2. Materials and Methods
2.1. Dataset

Raw data files were downloaded in comma-separated value (CSV) files from the CDC
website [13]. CDC WONDER online search tool was used to mine the VAERS [14]. We
downloaded the 2021 VAERS public data set, which contained vaccine side reaction reports
since 1990, and consisted of three separate data files: (1) VAERS data, (2) VAERS symptoms,
and (3) VAERS vaccine.

2.2. Databases
2.2.1. VAERS

VAERS [14] was established in 1990, as a national early warning system to detect
possible safety problems in U.S. licensed vaccines. It serves as is a post-marketing safety
surveillance program, collecting information about adverse events (possible side effects)
that occur after the administration of U.S. licensed vaccines. VAERS is co-managed by
the U.S. Centers for Disease Control and Prevention (CDC) and the U.S. Food and Drug
Administration (FDA). The VAERS data are updated weekly, and includes reports from
1990 onwards.

2.2.2. MetaCoreTM

MetaCoreTM version 20.3 build 70,200 [15] from Clarivate Analytics is a database of
manually composed ontologies mapped to canonical pathways and networks. We used
this database for purposes of enrichment analysis in pathway maps. Pathway maps in
MetaCoreTM are defined as subsets of functionally connected genes to describe a specific
cellular process in a specific cellular context. Herein, the enrichment analysis is performed

Vaccines 2021, 9, 1186

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by examining the intersection between a gene list of myocarditis biomarkers extracted from
MetaCoreTM, and the prebuilt pathway maps in MetaCoreTM using the hypergeometric
mean, which takes into account the number of objects in your dataset, the number of objects
in the intersecting map and the number of objects in the entire database. This assessment
returns a p-value that tells us the likelihood that the intersection between the gene signature
and a particular map is obtained purely by chance. We set the p-value threshold at 0.05;
rejecting all hypotheses/pathway maps that have enrichment p-values higher than 0.05.

2.3. Integrative Informatics Workflow

We developed an informatics workflow (Figure 1), based on the methods developed
by Hajjo et al. [16–19], to interrogate the network pharmacology of myocarditis/pericarditis
to derive a testable mechanistic hypothesis that could explain post-vaccine cardiac adverse
events. First, we started by searching VAERS using the following VAERS indexing terms
for events: “myocarditis” and “pericarditis”. All reports were grouped according to age,
sex, vaccine type, vaccine dose and event category. Cases missing patient age, sex, or type
of vaccine were kept in the raw data files and labeled as “unknown”. All raw data files are
deposited at the dataset repository. The identified sex, age groups and vaccine types and
doses were used as input search terms for our informatics approach to derive a testable
hypothesis regarding post-vaccine myocarditis.

Figure 1. Workflow for mining post-vaccine adverse events (part 1) and understanding the underlying biology (part 2).
Part 1 is a VAERS module to mine post-vaccine adverse events. The module starts by mining the VAERS database for
post-vaccine adverse events then filtering by myocarditis and pericarditis adverse events, vaccine type, sex and age of the
vaccinated individuals. Part 2 is a MetaCoreTM module to mine biological pathways associated with myocarditis and viral
infection processes. This module starts by filtering Myocarditis pathway maps in MetaCoreTM followed by extracting all
myocarditis biomarkers in addition to viral infection biomarkers and then using these biomarkers to conduct enrichment
analysis for pathway maps in MetaCoreTM. The identified pathway maps from the enrichment analysis plus pathway
maps linked to myocarditis via any individual biomarkers (i.e., initial 143 pathway maps), were filtered based on FDR
values and map ontologies to accept common pathway maps that have the smallest FDR values. *Biomarkers according to
MetaCoreTM database.

Vaccines 2021, 9, x   

 

3  of  15 

MetaCoreTM are defined as subsets of functionally connected genes to describe a specific 

cellular process in a specific cellular context. Herein, the enrichment analysis is performed 

by  examining  the  intersection  between  a  gene  list  of  myocarditis  biomarkers  extracted 

from MetaCoreTM, and the prebuilt pathway maps in MetaCoreTM using the hypergeomet-

ric mean, which takes into account the number of objects in your dataset, the number of 

objects in the intersecting map and the number of objects in the entire database. This as-

sessment returns a p-value that tells us the likelihood that the intersection between the 
gene  signature  and  a  particular  map  is  obtained  purely  by  chance.  We  set  the  p-value 
threshold at 0.05; rejecting all hypotheses/pathway maps that have enrichment p-values 
higher than 0.05. 

2.3. Integrative Informatics Workflow 

We developed an informatics workflow (Figure 1), based on the methods developed 
by Hajjo et al. [16–19], to interrogate the network pharmacology of myocarditis/pericardi-
tis to derive a testable mechanistic hypothesis that could explain post-vaccine cardiac ad-
verse events. First, we started by searching VAERS using the following VAERS indexing 
terms for events: “myocarditis” and “pericarditis”. All reports were grouped according to 
age, sex, vaccine type, vaccine dose and event category. Cases missing patient age, sex, or 
type of vaccine were kept in the raw data files and labeled as “unknown”. All raw data 
files are deposited at the dataset repository. The identified sex, age groups and vaccine 
types and doses were used as input search terms for our informatics approach to derive a 
testable hypothesis regarding post-vaccine myocarditis.   

Figure 1. Workflow for mining post-vaccine adverse events (part 1) and understanding the underlying biology (part 2). 

Part 1 is a VAERS module to mine post-vaccine adverse events. The module starts by mining the VAERS database for 

post-vaccine adverse events then filtering by myocarditis and pericarditis adverse events, vaccine type, sex and age of the 

vaccinated individuals. Part 2 is a MetaCoreTM module to mine biological pathways associated with myocarditis and viral 

infection processes. This module starts by filtering Myocarditis pathway maps in MetaCoreTM followed by extracting all 

myocarditis biomarkers in addition to viral infection biomarkers and then using these biomarkers to conduct enrichment 

analysis for pathway maps in MetaCoreTM. The identified pathway maps from the enrichment analysis plus pathway maps 

linked to myocarditis via any individual biomarkers (i.e., initial 143 pathway maps), were filtered based on FDR values 

and map ontologies to accept common pathway maps that have the smallest FDR values. *Biomarkers according to Met-

 

aCoreTM database.   

 

 

 

Vaccines 2021, 9, 1186

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3. Results

Our search in VAERS databases indicated that myocarditis and pericarditis adverse
events were not unique to COVID-19 vaccines; they were also reported after receiving
smallpox, anthrax, typhoid, hepatitis B, influenza, and other vaccines to a smaller extent.
However, myocarditis and pericarditis events were more prevalent after receiving mRNA
COVID-19 vaccines than any other vaccine. This could be partly due to potentially smaller
population sizes receiving the identified non-COVID-19 vaccines, or it may be due to other
reasons. To understand this better, we applied a two-step informatics workflow (Figure 1)
which helped in answering important questions regarding the most affected age groups,
the most affected sex, the frequency of these adverse events after each vaccine dose, and
biological mechanisms leading to myocarditis and pericarditis.

3.1. Post-COVID-19 Vaccine Myocarditis and Pericarditis Adverse Events
3.1.1. Age Differences

We searched VAERS for myocarditis and pericarditis adverse events by COVID-19
vaccine and age group of the affected people. Our search resulted in 1579 myocarditis
events and 1063 pericarditis events. The prevalence of myocarditis and pericarditis events
in different age groups indicated that these two cardiac adverse events were predominant
in young adults 18–29 years old. Myocarditis events were also prevalent in children 6–17
years old followed by adults 30–39 years old for myocarditis (Figure 2a). Pericarditis events
were prevalent in adults 30–39 years old followed by children 6–17 years old (Figure 2b).

Figure 2. Reported post–COVID–19 vaccine myocarditis (a) and pericarditis (b) adverse events by
age group and vaccine type. The x–axis shows the number of myocarditis side events after receiving
COVID–19 vaccine. The y–axis shows the age groups of vaccine recipients. The bars were colored
according to the vaccine received. VAERS reports were processed as of 2 September 2021.

Vaccines 2021, 9, x   

 

4  of  15 

3. Results 

Our search in VAERS databases indicated that myocarditis and pericarditis adverse 

events  were  not  unique  to  COVID-19  vaccines;  they  were  also  reported  after  receiving 

smallpox, anthrax, typhoid, hepatitis B, influenza, and other vaccines to a smaller extent. 

However, myocarditis and pericarditis events were more prevalent after receiving mRNA 

COVID-19 vaccines than any other vaccine. This could be partly due to potentially smaller 

population  sizes  receiving  the  identified  non-COVID-19  vaccines,  or  it  may  be  due  to 

other  reasons.  To  understand  this  better,  we  applied  a  two-step  informatics  workflow 

(Figure 1) which helped in answering important questions regarding the most affected 

age groups, the most affected sex, the frequency of these adverse events after each vaccine 

dose, and biological mechanisms leading to myocarditis and pericarditis. 

3.1. Post-COVID-19 Vaccine Myocarditis and Pericarditis Adverse Events 

3.1.1. Age Differences 

We searched VAERS for myocarditis and pericarditis adverse events by COVID-19 
vaccine  and  age  group  of  the  affected  people.  Our  search  resulted  in  1579  myocarditis 
events and 1063 pericarditis events. The prevalence of myocarditis and pericarditis events 
in different age groups indicated that these two cardiac adverse events were predominant 
in young adults 18–29 years old. Myocarditis events were also prevalent in children 6–17 
years  old  followed  by  adults  30–39  years  old  for  myocarditis  (Figure  2a).  Pericarditis 
events were prevalent in adults 30–39 years old followed by children 6–17 years old (Fig-
ure 2b). 

Figure 2. Reported post–COVID–19 vaccine myocarditis (a) and pericarditis (b) adverse events by 

age group and vaccine type. The x–axis shows the number of myocarditis side events after receiving 

COVID–19 vaccine. The y–axis shows the age groups of vaccine recipients. The bars were colored 

according to the vaccine received. VAERS reports were processed as of 2 September 2021. 

 

 

Vaccines 2021, 9, 1186

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3.1.2. Sex Differences

Our results showed large sex differences in the frequency of myocarditis and peri-
carditis adverse events occurring after receiving COVID-19 vaccines. The percentages of
myocarditis and pericarditis adverse events in male subjects were 77% and 65% subse-
quently, in comparison to 22% myocarditis and 34% pericarditis adverse events in females
(Figure 3a).

Figure 3. The number post-COVID-19 myocarditis and pericarditis adverse events by sex (a) and the
administered vaccine dose (b). The x-axes show the adverse event counts for each COVID-19 vaccine
shown on the y-axes. Considering VAERS reports processed as of 2 September 2021.

3.1.3. Vaccine Dose Differences

Post-vaccine adverse events generally happen within six weeks of receiving a vaccine
dose, and they could be more intense after booster doses, according to the U.S. Centers for
Disease Control and Prevention (CDC) [20]. For this reason, the FDA requires each of the
authorized COVID-19 vaccines to be studied for at least eight weeks after the final vaccine
dose [20]. Currently, the majority of people around the world have taken either one or two
vaccine doses. Our results showed that myocarditis and pericarditis events were more
common after the second doses of Moderna and Pfizer/BIONTECH COVID-19 vaccines
(Figure 3b).

3.1.4. Outcome Differences

To assess the severity of post-COVID-19 vaccine myocarditis and pericarditis events,
we analyzed these adverse events by adverse event category. The VAERS database di-
vided adverse events into multiple categories that range in severity from office visit to
death (Supplementary Figure S1). These categories in order of increasing severity are
office visit, emergency room, existing hospitalization prolonged, hospitalized, congenital
anomaly/birth defect, permeant disability, life threatening, and death. Our results indicate
that deaths remained fairly rare in comparison with hospitalizations and emergency room

Vaccines 2021, 9, x   

 

5  of  15 

3.1.2. Sex Differences 

Our results showed large sex differences in the frequency of myocarditis and peri-
carditis adverse events occurring after receiving COVID-19 vaccines. The percentages of 
myocarditis and pericarditis adverse events in male subjects were 77% and 65% subse-
quently, in comparison to 22% myocarditis and 34% pericarditis adverse events in females 
(Figure 3a). 

 

Figure 3. The number post-COVID-19 myocarditis and pericarditis adverse events by sex (a) and 

the administered vaccine dose (b). The x-axes show the adverse event counts for each COVID-19 

vaccine shown on the y-axes. Considering VAERS reports processed as of 2 September 2021. 

3.1.3. Vaccine Dose Differences 

Post-vaccine adverse events generally happen within six weeks of receiving a vaccine 

dose, and they could be more intense after booster doses, according to the U.S. Centers 

for Disease Control and Prevention (CDC) [20]. For this reason, the FDA requires each of 

the  authorized  COVID-19 vaccines  to  be  studied for  at  least  eight  weeks  after the  final 

vaccine dose [20]. Currently, the majority of people around the world have taken either 

one  or  two  vaccine  doses.  Our  results showed  that myocarditis and  pericarditis  events 

were more common after the second doses of Moderna and Pfizer/BIONTECH COVID-

19 vaccines (Figure 3b).   

3.1.4. Outcome Differences 

To assess the severity of post-COVID-19 vaccine myocarditis and pericarditis events, 

we  analyzed these adverse  events  by adverse  event  category.  The VAERS  database  di-

vided adverse events into multiple categories that range in severity from office visit to 

death (Supplementary Figure S1). These categories in order of increasing severity are of-

fice  visit,  emergency  room,  existing  hospitalization  prolonged,  hospitalized,  congenital 

 

Vaccines 2021, 9, 1186

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admissions. This confirms that these conditions are curable with proper treatment, and
when they are diagnosed correctly.

3.2. Comparing Myocarditis and Pericarditis Events Occurring after Receiving COVID-19 versus
Non-COVID-19 Vaccines

To check whether myocarditis and pericarditis events were unique to COVID-19
vaccines, or whether they were more serious after receiving a COVID-19 vaccine, we
searched the VAERS database for all post-vaccine myocarditis and pericarditis events.
Our results identified 1927 reported post-vaccine myocarditis events (348 events post
non-COVID-19 and 1579 events post-COVID-19 vaccines), and 1438 pericarditis adverse
events (375 events post non-COVID-19 and 1063 events post-COVID-19 vaccines) that
were more common in young male adults (Figure 4a,b) indicating that myocarditis and
pericarditis adverse events are not unique to COVID-19 vaccines, and can occur after
receiving non-COVID-19 vaccines. However, the incidences of myocarditis and pericarditis
were much higher after COVID-19 vaccines, and this could be partly due to the relatively
larger number of people who received the COVID-19 vaccines.

Figure 4. A comparison for post-vaccine myocarditis and pericarditis side effects between COVID-19 and Non-COVID-19 vaccines
based on the age (a) and sex (b) of affected people. The x-axis in (a) shows the different age groups of vaccine recipients reporting
adverse events for both COVID-19 and non-COVID-19 vaccines, and the y-axis shows the adverse even counts. Reports with
unknown age records are not shown in (a). Considering VAERS reports processed as of 2 September 2021.

Vaccines 2021, 9, x   

 

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anomaly/birth defect, permeant disability, life threatening, and death. Our results indicate 

that deaths remained fairly rare in comparison with hospitalizations and emergency room 

admissions. This confirms that these conditions are curable with proper treatment, and 

when they are diagnosed correctly. 

3.2. Comparing Myocarditis and Pericarditis Events Occurring after Receiving COVID-

19 Versus Non-COVID-19 Vaccines 

To check whether myocarditis and pericarditis events were unique to COVID-19 vac-

cines, or whether they were more serious after receiving a COVID-19 vaccine, we searched 

the VAERS database for all post-vaccine myocarditis and pericarditis events. Our results 

identified 1927 reported post-vaccine myocarditis events (348 events post non-COVID-19 

and  1579  events  post-COVID-19  vaccines),  and  1438  pericarditis  adverse  events  (375 
events  post  non-COVID-19  and  1063  events  post-COVID-19  vaccines)  that  were  more 
common in young male adults (Figure 4a,b) indicating that myocarditis and pericarditis 
adverse events are not unique to COVID-19 vaccines, and can occur after receiving non-
COVID-19 vaccines. However, the incidences of myocarditis and pericarditis were much 
higher after COVID-19 vaccines, and this could be partly due to the relatively larger num-
ber of people who received the COVID-19 vaccines. 

Figure 4. A comparison for post-vaccine myocarditis and pericarditis side effects between COVID-19 and Non-COVID-19 

vaccines based on the age (a) and sex (b) of affected people. The x-axis in (a) shows the different age groups of vaccine 

 

 

Vaccines 2021, 9, 1186

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Analyzing the distribution of myocarditis and pericarditis adverse events among different
age groups indicated that these events were more predominant in young adults 18–29 years
old, followed by adults 30–39 and children 7–16 years old (Figure 4a). We also found that these
adverse events were more prevalent in males (%) than females (%) (Figure 4b).

The top 10 vaccines associated with myocarditis and pericarditis are listed in Table 1.
Myocarditis and pericarditis were more frequently reported after receiving the COVID-19
followed by smallpox and anthrax vaccines. It should be noted that smallpox, anthrax and
typhoid vaccines are all live vaccines, and are only recommended in the United States to
small vulnerable groups of the population in certain research jobs and travel situations
according to CDC’s guidelines [21].

Table 1. The counts and percentages of reported myocarditis and pericarditis adverse events associated
with top 10 vaccine types ranked based on the number of events reported as of 2 September 2021.

Myocarditis Adverse Events

Rank

Vaccine Type

Vaccine Type
Code *

Events
Reported

10

1
2
3
4
5

6

7

8

9

1
2
3

4

5
6
7

8

9

10

Pericarditis Adverse Events

Rank

Vaccine Type

Vaccine Type
Code

Events
Reported

COVID-19 VACCINE
SMALLPOX VACCINE
ANTHRAX VACCINE
TYPHOID VACCINE
HEPATITIS B VACCINE
INFLUENZA VIRUS
VACCINE, TRIVALENT
(INJECTED)
HAEMOPHILUS B
CONJUGATE VACCINE
INFLUENZA VIRUS
VACCINE, NO BRAND NAME
HEPATITIS A
VARIVAX-VARICELLA VIRUS
LIVE

COVID-19 VACCINE
SMALLPOX VACCINE
ANTHRAX VACCINE
INFLUENZA VIRUS
VACCINE, TRIVALENT
(INJECTED)
TYPHOID VACCINE
ZOSTER VACCINE
HEPATITIS B VACCINE
INFLUENZA VIRUS
VACCINE, NO BRAND NAME
INFLUENZA VIRUS
VACCINE, TRIVALENT
(INTRANASAL SPRAY)
HUMAN PAPILLOMAVIRUS
(TYPES 6, 11, 16, 18)
RECOMBINANT VACCINE

FLU3(SEASONAL)

FLUX(SEASONAL)

COVID19
SMALL
ANTH
TYP
HEP

HIBV

HEPA

VARCEL

COVID19
SMALL
ANTH

TYP
VARZOS
HEP

FLU3(SEASONAL)

FLUX(SEASONAL)

FLUN3(SEASONAL)

12

1579
223
63
29
26

20

18

18

16

16

1063
200
63

35

33
29
20

19

Percent

87.19%
12.31%
3.48%
1.60%
1.44%

1.10%

0.99%

0.99%

0.88%

0.88%

Percent

79.15%
14.89%
4.69%

2.61%

2.46%
2.16%
1.49%

1.41%

0.89%

HPV4

10

0.74%

* According to the VAERS databases.

3.3. Identifying Causal Gene Associations with Myocarditis and Pericarditis

To understand the underlying biology of post-vaccine myocarditis and pericarditis, we
applied a systems biology approach which starts by searching MetaCoreTM for myocarditis
and pericarditis pathway maps to extract plausible high confidence mechanistic insight.

Vaccines 2021, 9, 1186

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In these searches we mined MetaCoreTM for genes and gene products on the DNA, RNA,
and/or protein levels. We identified 41 biomarker genes for myocarditis which included the
following higher confidence myocarditis biomarkers: (1) TNC (tenascin C) [22], (2) RNASE3
(ribonuclease A family member 3) [13] and (3) CD44 (Indian blood group antigen) [23].
Lab experiments found elevated protein levels (i.e., gene products) of these three genes in
myocarditis [7,22]. We could not identify any causal gene associations with pericarditis,
and there were not any MetaCoreTM pathway maps linked to pericarditis. Hence, this
analysis will focus primarily on understanding myocarditis adverse events.

We used two methods to link these 41 myocarditis biomarkers to pathway maps that
can provide better mechanistic insight about the underlying biology. First, we mined 143
MetaCoreTM pathway maps that were linked to myocarditis biomarkers through at least
one biomarker. Then we filtered these 143 maps based on map ontologies that had the
following terms: “Virus”, “Viral”, “Antiviral”, and “Vaccine”. As a result, we identified
two pathway maps that were related to antiviral actions: (1) Immune response map for
the antiviral actions of interferons, and (2) immune response map for the role of PKR in
stress-induced antiviral cell response. Filtering genes on each map based on established
links to myocarditis highlighted the role of IFN-gamma as an important signaling molecule
that turns on cardiac inflammation pathways. Example maps are shown in Supplementary
Figures S2 and S3 (Supporting Information).

We also filtered the initial list of 41 myocarditis biomarkers, shown in Supplementary
Table S1 (Supporting Information), by keeping overlapping biomarkers for myocarditis and
antiviral action based on MetaCoreTM biomarker data; this filtering resulted in 19 biomark-
ers shown in Supplementary Table S2 (Supporting Information). Next, we performed
enrichment analysis in MetaCoreTM to identify overrepresented pathways with FDR ≤
0.05. We identified 282 pathways maps overrepresented for the 41-biomarker list, and 188
pathway maps for the 19-biomarker list. We identified three immune response pathway
maps among top 10 most enriched pathways by the 19-biomarker list. All three maps
were related to interferon-gamma signaling: (1) Immune response map for IFN-gamma
signaling via MAPK (FDR = 3.661 × 10−4), (2) Immune response map for the induction of
the antigen presentation machinery by IFN-gamma (FDR = 3.800 × 10−4), and (3) Immune
response map for IFN-gamma signaling via PI3K and NF-kB (FDR = 4.269 × 10−4).

We also mined all pathway maps that had in their description the term “Myocarditis”
and identified three pathway maps: (1) Immune response IFN-gamma signaling via MAPK,
(2) Immune response IL-23 signaling pathway, and (3) A COVID-19 map for SARS-CoV-2
effects on infected tissues (Figure 5). Focusing on Immune response IFN-gamma signaling
via MAPK that has been predicted by two different approaches that increased the confi-
dence in this pathway map, highlighted two key biomarkers for myocarditis and antiviral
immune processes: IFN-gamma and TNF-alpha.

This result signifies the role of IFN-gamma signaling in post-vaccine inflammatory adverse
events that may affect many organs including the heart. IFN-gamma signaling is an immune
effector for various vaccines, and it is not unique for COVID-19 vaccines [24–26]. The type of
the vaccine exerts a direct influence on the type of immune effectors and magnitude of mounted
immune response that mediate protective efficacy of vaccines [27]. In fact, inflammatory
cytokines have been proposed recently to mediate post-vaccine allergic reactions [28].

IFN-gamma has been generally associated with the promotion of TH1 immune re-
sponse [29,30] which is strongly triggered in response to live vaccines versus ‘non-live’
vaccines [31]. In this regard, mRNA vaccines seem to emulate the effects of live vaccines
which makes sense because viral mRNA triggers the activation of the innate immune sys-
tem through multiple pathogen-associated signals. In fact, stronger TH1 responses imply
higher intensity of innate responses and more prolonged antigen persistence generally
which results in higher antibody (Ab) responses to live versus ‘non-live’ vaccines [27].

This situation is very similar to that occurring after a natural infection where dendritic
cells (DCs) are activated at multiple sites, migrate toward the corresponding draining lymph

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nodes, and launch multiple foci of T- and B-cell activation. This sequence provides a second
explanation of the generally higher immunogenicity of live versus “non-live” vaccines.

Figure 5. Immune response IFN-gamma signaling via MAPK and/or JAK/Stat pathways. B: binding; IE: influence on
expression; TR: transcription regulation; red arrows for inhibition, green arrows for activation, gray arrows for unspecified
action, violet text boxes for normal process, pink text boxes for pathological processes, blue text boxes for notes, starred
network objects refer to groups or complex processes, pink hexagons indicate whether a network object is a biomarker
for cardiomyopathies, and green hexagons indicate whether the network object is expressed in cardiovascular tissues, red
thermometers indicate that the network object is a biomarker for myocarditis.

For pericarditis, we identified PRG4 gene (proteoglycan 4) as the only gene associated
with pericarditis according to MetaCore methods and data in the biomedical literature.

Vaccines 2021, 9, x   

 

9  of  15 

Figure 5. Immune response IFN-gamma signaling via MAPK and/or JAK/Stat pathways. B: binding; IE: influence on ex-

pression; TR: transcription regulation; red arrows for inhibition, green arrows for activation, gray arrows for unspecified 

action, violet text boxes for normal process, pink text boxes for pathological processes, blue text boxes for notes, starred 

network objects refer to groups or complex processes, pink hexagons indicate whether a network object is a biomarker for 

cardiomyopathies, and green hexagons indicate whether the network object is expressed in cardiovascular tissues, red 

thermometers indicate that the network object is a biomarker for myocarditis. 

 

This result signifies the role of IFN-gamma signaling in post-vaccine inflammatory 

adverse events that may affect many organs including the heart. IFN-gamma signaling is 

an immune effector for various vaccines, and it is not unique for COVID-19 vaccines [24–

26]. The type of the vaccine exerts a direct influence on the type of immune effectors and 

magnitude of mounted immune response that mediate protective efficacy of vaccines [27]. 

 

Vaccines 2021, 9, 1186

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This association between PRG4 and pericarditis is based on a mutational study indicating
that mutations in PRG4 gene on chromosome 1 result in camptodactyly arthropathy-coxa
vara-pericarditis syndrome [32]. To check if there are any direct links between PRG4 and
IFN-gamma, we attempted to build a “direct interactions” network but no links were
identified. Therefore, the “auto expand” algorithm was used to derive sub-networks
around PGR4 and IFN-gamma. Then, the derived sub-networks keep expanding until
they intersect. The resulting larger network (Supplementary Figure S4) highlighted a link
between PGR4 and IFN-gamma via TCF/LEF protein group including LEF1 (lymphoid
enhancer binding factor 1), TCF7 (Transcription factor 7) also known as TCF1 (T-cell-
specific transcription factor 1) and TCF7L2 (transcription factor 7 like 2) also known as
TCF4 (T-cell-specific transcription factor 4).

4. Discussion

In an effort to understand post-vaccine myocarditis and pericarditis side effects that
have been linked to mRNA vaccines lately, according to a statement from the CDC [13], we
applied an informatics workflow to mine the VAERS database for post-vaccine myocarditis,
followed by a systems biology analysis that relied on mining specialized chemogenomics
databases for genes, proteins and chemicals that are linked to myocarditis. There were
three COVID-19 vaccines included in VAERS database (i.e., vaccines approved by the U.S.
FDA) including Pfizer/BioNTech, Moderna and Janssen. These vaccines were prepared
by two technologies: (1) mRNA encoding the SAR-CoV-2 spike (S) protein encapsulated
in lipid nanoparticle such as the two vaccines by Pfizer/BioNTech and Moderna, and (2)
adenovirus (AdV) vectors encoding the S protein such as Janssen’s vaccine. The different
vaccine preparations enter dendritic cells (DCs) at site of injection or within lymph nodes,
resulting in production of S protein [33].

Our results indicated that post-COVID-19 vaccine myocarditis and pericarditis adverse
events were more prevalent in young males 18-29 years old. Actually, a recent opinion [34]
in the journal Pediatric Reports raised concerns about mRNA vaccines for adolescents, and
questioned why cardiac adverse events have higher incidence in male adolescents after
receiving the second dose of the vaccine and what mechanisms are contributing to these
adverse events. Our data also showed that the number of myocarditis and pericarditis
adverse events was higher for Pfizer/BioNTech vaccine followed by Moderna’s and then
Janssen’s (based on the available data described herein). However, it should be noted that
the Pfizer/BioNTech and Moderna vaccines were more widely administered in the United
States than Janssen’s. Therefore, we cannot conclude based on the data described here in
that myocarditis was more frequent after receiving mRNA vaccines.

We also found evidence in the biomedical literature documenting cardiac side effects
after receiving smallpox and anthrax vaccines [4,35–42]. There is also clinical evidence
for developing myocarditis in 59% smallpox and 23% anthrax vaccinated individuals [4].
In fact, vaccinated individuals from Europe and Australia reported more post smallpox
vaccine cardiac complications suggesting that the vaccine strains or preparations used
there might been more immunologically reactive in comparison to the vaccine strains
used in the United States which is knowns as the New York City Board of Health (NY-
CBOH) strain [43]. Other clinical studies found evidence for post-vaccine myocarditis after
receiving typhoid [44] and hepatitis B vaccines [45].

Our systems biology results highlighted central signaling roles for IFN-gamma and
TNF-alpha in both myocarditis and viral disease maps. Finally, combing the knowledge
from searching both VAERS and MetaCoreTM enabled the exploration of age and sex
differences of post-vaccine myocarditis. We found evidence in the biomedical literature
indicating gender and age differences in many immunological factors. The sex differences
in the levels of proinflammatory cytokines, including TNF-alpha and IFN-gamma, increase
at puberty and then wane later in life suggesting hormonal effects. This goes in concert
with our findings about the prevalence of post-vaccine myocarditis in the age group in
adolescents and young adults (Figures 2, 3a and 4). Furthermore, Aomatsu et al. reported

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on the gender differences in in TNF-alpha production in human neutrophils stimulated
by lipopolysaccharide (LPS) or IFN-gamma plus LPS [46]. It was suggested that the lower
sensitivity of female neutrophils to LPS and IFN-gamma, was due to the anti-inflammatory
effects of estradiol on vascular endothelial cells and monocytes/macrophages [46]. How-
ever, for immune response factors the sex difference remains constant from birth to old age
(for example higher numbers of CD4+ T cells and higher rations of CD4/CD8 T have been
reported in females at all age groups) [46].

To fathom post-vaccine myocarditis, it is important to understand that post-vaccine
side effects (e.g., injection site pain, fever, chills, swelling fatigue, headache, muscle pain,
joints pain, and others) [14,47] are caused by the secondary enhancement of the inflam-
matory response which often results from short-term changes to innate cells such as
macrophages through ‘trained immunity’ [48], and/or from the activation of memory
T cells and B cells generated from the initial injection [33]. There is also evidence that
systemic vaccine side effects can be augmented with the second vaccine doses [49] due
to an amplified release of type 1 interferon which plays a central role in amplifying T-cell
memory and B-cell differentiation and survival. This implies that post-vaccine inflamma-
tion after receiving booster doses, can further promote the generation and perpetuation of
long-term immunological memory [33,50,51].

We found evidence that IFN-gamma is also key component of the host defense to
viral infection [52–55] that is also elicited in response to viral vaccines [56]. MRNA and
viral vector vaccines trigger spike protein synthesis inside human cells which can then
be presented on cell surfaces to cytotoxic T cells by the major histocompatibility complex
(MHC) MHC class I and MHC class II molecules, leading to virus-specific recognition and
killing of infected or vaccinated cells. Interferons alpha, beta and gamma are required to
induce MHC class I expression, while MHC class II transactivator factor (CIITA) is the
master regulator of MHC class II expression and it is efficiently induced by IFN-gamma.
However, most cell types do not express basal CIITA, and its expression is induced by
IFN-gamma [57,58]. In myocarditis, T lymphocytes (T cells), have been reported to home
the myocardium and to acutely reduce left ventricular (LV) function and this has been
associated with increased levels of circulating cytokines, such as TNF-α which led to the
prioritization of proinflammatory cytokines as markers of myocarditis and heart failure.
It is also known that antigen presentation by endothelial cells may initiate rapid and
localized ‘memory’ immune responses in peripheral tissues. Antigens displayed on major
histocompatibility complex (MHC) molecules on the surface of endothelial cells can then
be recognized by T-cell receptors on circulating effector memory T cells triggering both
trans-endothelial migration and activation [59].

Type I interferons are key drivers for the antiviral state in non-immune cells and
they orchestrate antiviral immune responses through: (i) the inhibition of viral replication
in infected cells during the innate stage of the immune response; (ii) the activation and
enhancement of antigen presentation in the “early induced” immune response, and (iii)
the generation of the adaptive immune response through direct and indirect actions on
T and B cells that constitute the memory response (reviewed in References [50,60]). TH1
response, which triggers IFN-gamma expression that in turn activates CTLs and NK cells.
From a homeostatic point of view, prolonged effector function of these cells may lead to
excessive cytotoxicity and other detrimental effects resulting in host tissue damage [50,61].
Additional support for the identified role of IFN-gamma in myocarditis came from a recent
Nature publication by Arunachalam et al. [62] confirming that Pfizer/BioNTech mRNA
vaccine induced a heightened innate immune response after secondary immunization
relative to primary immunization implicating the overexpression of IFN-gamma in driving
innate and antiviral responses after the booster.

It should be noted that this study has a few limitations. First, while VAERS is a
valuable source for monitoring vaccine adverse effects, reports from VAERS alone may not
be conclusive to establish a causal relationship between an adverse event and a vaccine use.
Due to the voluntary nature of VAERS reports, the information provided about an adverse

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effect can be imperfect, imprecise, coincidental, or unconfirmed, limiting the scientific use
of such reports [14]. Though the CDC and FDA usually follow up on all serious adverse
event reports to obtain additional medical, laboratory, death certificates, and/or autopsy
records, nonetheless changes in information based on further investigations of serious
adverse events may not be reflected on VAERS public data. Secondly, bioinformatics
techniques relying on gene expression, pathway over-representation and network biology
have the following limitations and biases that we reviewed by Hajjo and Tropsha else-
where [17]. While we were finalizing this manuscript, we learned that the CDC is planning
an ‘emergency meeting’ on rare post-COVID-19 vaccine heart inflammation [63].

Based on research findings presented here, we suggest that increasing the time interval
between the first and second vaccines doses could potentially reduce or eliminate myocardi-
tis adverse events by reducing the chances of unfavorable synergism on interferon-gamma
secretion resulting from the successive waves of primary responses. We also prioritize the
use of glucocorticoids (e.g., dexamethasone) for post-COVID-19 vaccine myocarditis for the
following reasons: (1) glucocorticoids has been used successfully for the treatment of acute
and chronic myocarditis, including viral myocarditis [27,63–69], (2) glucocorticoids lead to
the inhibition of IFN-gamma by regulating STAT1 expression [19], (3) dexamethasone is
one of the drugs that reduces COVID-19 mortality.

5. Conclusions

Our study suggests that myocarditis adverse events are linked to vaccine type
(i.e., COVID or non-COVID), technology (e.g., mRNA or inactivated), age and sex of
the vaccinated individuals. Based on VAERS data, post-vaccine myocarditis was most
frequently reported for live vaccines (e.g., smallpox, anthrax and some typhoid vaccines),
or vaccines that behave like live vaccines such as mRNA and possibly viral vector vaccines
(e.g., COVID-19 vaccines) versus inactivated vaccines. The suggested mechanism of post-
vaccine-myocarditis involves IFN-gamma signaling and TH1 immune responses following
vaccination, which can be modulated by increasing the time interval between first vaccine
doses and following boaster doses, or by the use of glucorticoids. Herein we applied
a systems biology informatics approach for studying post-vaccine myocarditis adverse
events which resulted in testable hypotheses explaining the biological mechanisms leading
to these events and led the prioritization of pharmaceutical and non-pharmaceutical miti-
gation strategies. This approach can be applied for conducting similar analyses involving
other side effects or other vaccines, hence, our workflow stands ready for following up on
any alarming report from the CDC.

Supplementary Materials: The following are available online at https://www.mdpi.com/article/10
.3390/vaccines9101186/s1, Table S1: List of myocarditis biomarkers, Table S2: The list of common
biomarkers for myocarditis and virus infection, Figure S1: The distribution of post-COVID-19 vaccine
myocarditis and pericarditis adverse events by category, Figure S2: Immune response map for the role
of PKR in stress-induced antiviral cell response, Figure S3: Immune response map for the antiviral
actions of Interferons, Figure S4: Network connecting IFN-gamma with PRG4.

Author Contributions: R.H. generated the idea, collected and mined the VAERS data, performed
formal data analysis and prepared results in figures and tables, wrote first manuscript draft. D.A.S.
and S.K.B. participated in scientific discussions, participated in manuscript writing and collecting
supporting evidence from the biomedical literature. A.T. participated in scientific discussions, edited
the first draft and made suggestions to improve the first draft. All authors have read and agreed to
the published version of the manuscript.

Funding: R.H. and D.A.S. acknowledge support from the Deanship of Scientific Research at Al-
Zaytoonah University of Jordan (Grant number 2020-2019/17/03).

Institutional Review Board Statement: No human subjects are involved. All adverse event data
were publicly available from VAERS.

Data Availability Statement: Biomarkers data used in this study are available at Vaccines online. All
VAERS raw data files are available on GitHub (https://github.com/rhajjo/Myocarditis-Pericarditis).

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Conflicts of Interest: The authors declare no conflict of interest.

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