Article
Immune-Mediated Disease Flares or New-Onset Disease in
27 Subjects Following mRNA/DNA SARS-CoV-2 Vaccination

, Gabriele De Marco 4, Hussein Mahajna 2,5, Amit Druyan 2,3, Mailam Eltity 6, Nizar Hijazi 7,
, Michal Brodavka 2,3, Yael Cohen 2,3,

Abdulla Watad 1,2,3,4
Amir Haddad 7,8, Muna Elias 7,8, Devy Zisman 7,8
Arsalan Abu-Much 10, Muhanad Abu Elhija 7,8, Charlie Bridgewood 4, Pnina Langevitz 2,3, Joanna McLorinan 11,
Nicola Luigi Bragazzi 12,13,*
, Helena Marzo-Ortega 4
Leonard Calabrese 14, Edward Vital 4, Yehuda Shoenfeld 1,2, Howard Amital 1,2,3,†

, Merav Lidar 2,3, Cassandra Calabrese 14,

and Dennis McGonagle 4,*,†

, Mohammad E. Naffaa 9

9050435

11 Department of Rheumatology, Mid Yorkshire Hospitals, West Yorkshire WF8 1PL, UK;

1 Department of Medicine ‘B, Zabludowicz Center for Autoimmune Diseases, Sheba Medical Center,

2

Tel-Hashomer 10457, Israel; watad.abdulla@gmail.com (A.W.); yehuda.shoenfeld@sheba.health.gov.il (Y.S.);
Howard.Amital@sheba.health.gov.il (H.A.)
Sackler Faculty of Medicine, Tel-Aviv University, Tel-Aviv 69978, Israel; hmahajna@gmail.com (H.M.);
Amit.Druyan@sheba.health.gov.il (A.D.); michal.brodavka@sheba.health.gov.il (M.B.);
Yael.cohen2@sheba.health.gov.il (Y.C.); Pnina.Langevitz@sheba.health.gov.il (P.L.);
Merav.Lidar@sheba.health.gov.il (M.L.)

3 Rheumatology Unit, Sheba Medical Center, Tel-Hashomer 10457, Israel
4 NIHR, Leeds Biomedical Research Centre, The Leeds Teaching Hospitals NHS Trust & Leeds Institute of

Rheumatic and Musculoskeletal Medicine, University of Leeds, Leeds LS9 7TF, UK;
G.DeMarco@leeds.ac.uk (G.D.M.); C.D.Bridgewood@leeds.ac.uk (C.B.);
h.marzo-ortega@leeds.ac.uk (H.M.-O.); E.M.J.Vital@leeds.ac.uk (E.V.)
5 Gastroenterology Department, Sheba Medical Center, Tel-Aviv 10457, Israel
6 Department of Neurology, Sheba Medical Center, Tel-Aviv 10457, Israel; mailameltity@gmail.com
7 Rheumatology Unit, Carmel Medical Center, Michal Street, Haifa 3436212, Israel; NizarHi@clalit.org.il (N.H.);

haddadamir@yahoo.com (A.H.); nelias1@bezeqint.net (M.E.); devyzisman@gmail.com (D.Z.);
Mhndhija100@gmail.com (M.A.E.)

8 Ruth and Bruce Rappaport Faculty of Medicine, Technion-Israel Institute of Technology, Haifa 3200003, Israel
9 Department of Rheumatology, Galilee Medical Center, Azrieli Faculty of Medicine, Bar-Ilan University,

Safed 22100, Israel; MohammadN@gmc.gov.il

10 Leviev Heart Center, Sheba Medical Center, Tel Hashomer, Tel Aviv 10457, Israel;

arsalanabumuch1@gmail.com

joanna.mclorinan1@nhs.net

Toronto, ON M3J 1P3, Canada

Toronto, ON M3J 1P3, Canada

12 Centre for Disease Modelling, Department of Mathematics and Statistics, York University,

13 Fields-CQAM Laboratory of Mathematics for Public Health (MfPH), York University,

14 Cleveland Clinic Foundation, 9500 Euclid Avenue, Desk A50, Cleveland, OH 44195, USA;

calabrc@ccf.org (C.C.); calabrl@ccf.org (L.C.)

* Correspondence: bragazzi@yorku.ca (N.L.B.); D.G.McGonagle@leeds.ac.uk (D.M.)
† These authors contributed equally to this study.

Abstract: Background: Infectious diseases and vaccines can occasionally cause new-onset or flare of
immune-mediated diseases (IMDs). The adjuvanticity of the available SARS-CoV-2 vaccines is based
on either TLR-7/8 or TLR-9 agonism, which is distinct from previous vaccines and is a common
pathogenic mechanism in IMDs. Methods: We evaluated IMD flares or new disease onset within
28-days of SARS-CoV-2 vaccination at five large tertiary centres in countries with early vaccination
adoption, three in Israel, one in UK, and one in USA. We assessed the pattern of disease expression
in terms of autoimmune, autoinflammatory, or mixed disease phenotype and organ system affected.
We also evaluated outcomes. Findings: 27 cases included 17 flares and 10 new onset IMDs. 23/27
received the BNT - 162b2 vaccine, 2/27 the mRNA-1273 and 2/27 the ChAdOx1 vaccines. The
mean age was 54.4 ± 19.2 years and 55% of cases were female. Among the 27 cases, 21 (78%)
had at least one underlying autoimmune/rheumatic disease prior the vaccination. Among those
patients with a flare or activation, four episodes occurred after receiving the second-dose and in
one patient they occurred both after the first and the second-dose. In those patients with a new

Citation: Watad, A.; De Marco, G.;

Mahajna, H.; Druyan, A.; Eltity, M.;

Hijazi, N.; Haddad, A.; Elias, M.;

Zisman, D.; Naffaa, M.E.; et al.

Immune-Mediated Disease Flares or

New-Onset Disease in 27 Subjects

Following mRNA/DNA SARS-CoV-2

Vaccination. Vaccines 2021, 9, 435.

https://doi.org/10.3390/vaccines

Academic Editor:

Eduardo Gomez-Casado

Received: 14 March 2021

Accepted: 23 April 2021

Published: 29 April 2021

Publisher’s Note: MDPI stays neutral

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Copyright: © 2021 by the authors.

Licensee MDPI, Basel, Switzerland.

This article is an open access article

distributed under

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conditions of the Creative Commons

Attribution (CC BY) license (https://

creativecommons.org/licenses/by/

4.0/).

Vaccines 2021, 9, 435. https://doi.org/10.3390/vaccines9050435

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, 435

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onset disease, two occurred after the second-dose and in one patient occurred both after the first
(new onset) and second-dose (flare). For either dose, IMDs occurred on average 4 days later. Of the
cases, 20/27 (75%) were mild to moderate in severity. Over 80% of cases had excellent resolution
of inflammatory features, mostly with the use of corticosteroid therapy. Other immune-mediated
conditions included idiopathic pericarditis (n = 2), neurosarcoidosis with small fiber neuropathy
(n = 1), demyelination (n = 1), and myasthenia gravis (n = 2). In 22 cases (81.5%), the insurgence
of Adverse event following immunization (AEFI)/IMD could not be explained based on the drug
received by the patient. In 23 cases (85.2%), AEFI development could not be explained based on the
underlying disease/co-morbidities. Only in one case (3.7%), the timing window of the insurgence
of the side effect was considered not compatible with the time from vaccine to flare. Interpretation:
Despite the high population exposure in the regions served by these centers, IMDs flares or onset
temporally-associated with SARS-CoV-2 vaccination appear rare. Most are moderate in severity and
responsive to therapy although some severe flares occurred. Funding: none.

Keywords: vaccine safety; COVID-19; mRNA-based vaccine; adenoviral vector-based vaccine;
immune-mediated diseases

1. Introduction

Since its initial outbreak in late December 2019, the “Severe Acute Respiratory Syndrome-
related Coronavirus type 2” (SARS-CoV-2) infection has resulted in over 3.1 million deaths and
has contributed to immeasurable additional medical and economic consequences due to the
lockdown measures designed to control the virus spread and reduce disease mortality [1]. The
strategy to end the “Coronavirus Disease 2019” (COVID-19) pandemic rests almost entirely on
the few drugs available approved by regulatory bodies, such as the United States of America
(US) Food and Drug Administration (FDA), like Remdesivir [2], and on vaccines, which,
as a result, have been developed rapidly through global collaborations and unprecedented
efforts [3,4].

While vaccinations usually represent a safe and effective tool against infectious dis-
eases, several critical steps of their development present distinct challenges. The US Centers
for Disease Control and Prevention (CDC) have identified six stages: namely, the (i) ex-
ploratory, (ii) pre-clinical, (iii) clinical development, (iv) regulatory review and approval,
(v) manufacturing, and (vi) quality control phases [5]. Consequently, achieving a safe,
effective vaccine is a time- and resource-consuming process that ordinarily takes up to
10–15 years on average to be successfully completed. Conversely, in a rapidly evolving
pandemic, such a protracted process may cost many more lives than it could save. Hence,
due to the emergency situation related to the COVID-19 pandemic, several steps of the
path to prevention have been fast-tracked. This has increased uncertainties about the long-
term efficacy and safety of vaccines [6]. This abbreviated development process, therefore,
warrants an increased scrutiny in post-marketing surveillance of biologically plausible side
effects. Among these are immune-mediated phenomena.

To date, authorized COVID-19 vaccine products and those pending approval have shown
good efficacy, excellent safety, and tolerability in randomized clinical trials (RCTs) [7–12].
Additionally, the first SARS-CoV-2 vaccine to the market—BNT162b2 (Pfizer/BioNTech)
—has seen high utilization in several jurisdictions including the United Kingdom (UK), Israel
and the USA, where vaccine roll-out commenced in early-to mid-December 2020. Although
millions of individuals have been vaccinated, there have been so far few reports of vaccine-
associated immune-mediated disease (IMD) development, with the only notable exception of
rare, potentially immune-mediated autoimmune thrombosis [13].

The role of infectious agent derived antigens, including SARS-CoV-2 [14], as an IMD
trigger, is well recognized with both natural infection or, less commonly, after vaccination.
An array of innate and adaptive immune mechanisms, including molecular mimicry, may
be responsible for these phenomena [15,16]. Adjuvants are a group of substances that drive

Vaccines 2021, 9, 435

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innate immune system pattern recognition receptor (PRR) activation. They are commonly
used in vaccines to boost immune reactivity towards target antigens [17,18]. A link between
disorders that are characterized by innate and adaptive immune system dysregulation
and exposure to an adjuvant such as aluminum, and squalene, has been reported [19–21].
These disorders, together with others, encompass a broad spectrum of reactions, which
collectively have been referred to as the “vaccine adjuvant-related syndrome”, term coined
by Gherardi in 2003 [22] and, subsequently, as the “Autoimmune/Autoinflammatory
Syndrome Induced by Adjuvants” (ASIA syndrome) [23]. However, these two syndromes
remain highly controversial entities [24,25].

The adjuvanticity of the available SARS-CoV-2 vaccines is novel and, to a large de-
gree, depends on the intrinsic adjuvanticity of vaccine messenger RNA (mRNA) or DNA
which, respectively, stimulates the innate immunity through endosolic and cytoplasmic
nucleic acid receptors such as Toll-Like Receptors (TLRs) 3, 7, 8, and 9, and components
of the inflammasome, including Retinoic acid-Inducible Gene I (RIG-I) and Melanoma
Differentiation-Associated Gene 5 (MDA5) [26,27].

Several IMDs, most notably autoimmune connective tissue diseases, may be linked
to altered nucleic acid metabolism and processing, which have been shown to stimulate
TLR-7 and TLR-9 experimentally and in humans [28,29]. However, vaccine development
programs are not generally performed on subjects with IMDs where issues such as dis-
ease activity and immunotherapy may alter the course of disease. These diseases are
too uncommon for such events to be detected in standard vaccine trial populations [30].
They affect about 3–7% of the general population with an estimated incidence of 80 per
105 person-years [30]. Moreover, vaccine safety evaluation is generally considered as a
secondary objective, with pivotal RCTs being underpowered to enable statistical analyses of
endpoints of specific side effects, including IMDs [31]. Further, some adverse events could
be hard to identify, especially those of vaccines produced utilizing new technologies [31].
During a pandemic, it is of paramount importance to provide real-time data concern-
ing vaccine safety. Exchange of information, even though preliminary, can shed light on
potential mechanisms underlying vaccine action [31] and generate hypotheses that can be
further tested by ad hoc, large epidemiological surveys. Frontline physicians and public
health-workers, who are the point of first contact in case of insurgence of an adverse event,
can play a key role in this.

There are two major ways for identifying and reporting side effects following vacci-
nation: namely, active, or passive surveillance. The former generally implies data mining
of large electronic health record systems and is able to capture more adverse events than
passive surveillance, even if most of them are usually mild. The latter system, being on a
voluntary basis, is biased towards the reporting of more severe and earlier adverse events
and can have multiple shortcomings, such as under-reporting of mild symptoms, uncon-
firmed diagnosis, and not always clear temporal links between vaccine administration and
symptoms development. Even if the system generated by passive surveillance constitutes
the backbone of the system exploited by active surveillance, only the latter can enable a
rigorous analysis and comparison of epidemiological trends (i.e., incidence/prevalence
rates) of adverse events following immunization, in terms of spatio-temporal trend and
stratifying them according to the vaccination status [31].

Given the constantly evolving situation and the uncertainty about the still ongoing

COVID-19 pandemic, it is crucial to collect data directly from frontline physicians [32].

Accordingly, we evaluated clinical networks in three countries at the vanguard of
SARS-CoV-2 vaccination programs looking for evidence of new-onset or flare of immune
disease temporally linked to vaccine administration, collecting data from collaborating
physicians, utilizing reliable, confirmed diagnosis, and including also 1-month delayed
reported symptoms.

Vaccines 2021, 9, 435

4 of 23

2. Methods

This study was reported according to the “CAse REports” (CARE) guidelines [33].
Verbal or written consent was obtained from all patients for the anonymized use of data.
Data were obtained from three countries, Israel (Sheba Medical Centre in Tel Aviv, Carmel
Hospital in Haifa, and Galilee Medical Centre in Nahariya), UK (The Leeds Teaching
Hospitals NHS Trust) and USA (Cleveland Clinic). All patient events reported occurred in
the study period December 2020 to February 2021.

We identified patients presenting with IMD, especially rheumatic diseases, including
new presentations, new disease relapses or severe disease worsening that developed shortly
after vaccination. Given that the most commonly recognized post infectious disease and
post vaccination type of arthritis, termed reactive arthritis, may be diagnosed when onset
is within one month of infection exposure, we took a cut-off of 28 days post vaccination
as relevant.

According to the World Health Organization (WHO) guidelines [34], “Adverse Events
Following Immunization” (AEFI) can be defined as any untoward, unfavorable, or un-
intended medical occurrence (ranging from indication, symptom, series of symptoms,
disease, to abnormal laboratory findings) following vaccination, not necessarily exhibiting
a consistent, causal relationship with the administration of the vaccine product. Based
on the nature of the causal association, AEFIs can be classified into: (i) vaccine product-,
(ii) vaccine quality defect-related reactions, (iii) immunization error or anxiety, and (iv)
co-incidental event. Vaccine can act either as a factor or co-factor together with underlying
predisposing conditions related to the biological or genetic make-up of the individual
and the interaction of environmental variables. AEFIs are, as such, concrete examples of
complex, multi-factorial events [35].

We evaluated the causality of the AEFI after COVID-19 vaccination based on the WHO
guidelines, which propose a comprehensive four-step analytical and algorithmic diagram-
ming process. Even though the WHO instrument has been criticized [35], currently, there
exist no valid and reliable alternatives [36]. All possible “other causes” that could explain
the insurgence of the AEFI, excluding the etiopathological role of the vaccine, were initially
considered. Notably, all patients were well controlled and reported general well-being
with pharmacological therapy prior to vaccination, with the exception of a case in which
the administration of rituximab was delayed for immunization purpose. After validating
IMD diagnosis, and excluding non-vaccination related causalities, biological plausibility
and temporal compatibility between the immunization and the occurrence of the AEFI
were assessed (Figure 1). To ensure a reliable assessment of AEFIs, a multi-disciplinary
evaluation was performed, involving different specialists, ranging from immunologists,
rheumatologists, internal medicine doctors and epidemiologists, as recommended by the
WHO guidelines. Since these guidelines and checklists concern general AEFIs and not
particular classes of adverse events after immunization, similarly to the approach outlined
in [36], we have adapted them to the specific case of IMD-like side effects (Figure 1).

Moreover, based on the type of IMD, AEFIs were categorized according to the im-
munologic disease continuum for the classification of vaccine reactions proposed by
Koenig et al. [37].

This scheme includes the following categories including “classical adaptive immune-
meditated diseases” (mainly involving B- and T-cells and primary lymphoid organs),
“innate immune-mediated diseases” (affecting cells of the innate immune system) and
“intermediate diseases” (including major histocompatibility complex (MHC) class I-related
disease), “non-immunoglobulin E (IgE)- and IgE-related hypersensitivity” and “innate
immune driven” or autoinflammatory diseases as earlier proposed [38].

Descriptive statistics were used to summarize the age, sex, history of IMD, the av-
erage of onset of symptoms, severity, therapeutics administered, and key clinical and
laboratory findings.

Vaccines 2021, 9, 435

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Figure 1. Causality assessment of “Adverse Events Following Immunization” (AEFIs) after “Coro-
navirus Disease 2019” (COVID-19) vaccination based on the World Health Organization (WHO)
guidelines, which propose a comprehensive four-step analytical and algorithmic diagramming
process (namely, evaluation and assessment of (i) the temporal association between vaccine adminis-
tration and AEFI/immune-mediated disease (IMD); (ii) a plausible time window between vaccine
administration and AEFI/IMD; (iii) other causes, such as underlying co-morbidities or drugs taken
by the patient, which could explain the insurgence of AEFI/IMD; and, (iv) strength of the causal
association, based on what is currently known from the literature).

3. Results

We identified 27 cases of IMDs (15 females, 55.6%; 12 males, 44.4%; mean age
54.44 ± 19.20 years). 21 had an autoimmune/rheumatic background. This could be further
subcategorized as autoimmune (n = 11, 52.4%), autoinflammatory (n = 4, 19.0%) and mixed
pattern (n = 6, 28.6%) disorders before COVID-19 vaccination. In six patients (22.2%), there
was no autoimmune/rheumatic background and patients presented new-onset rheumatic
and musculoskeletal (RMD) and non-RMD disorders (Table 1).

Other factors such as alternative infectious triggers, active COVID-19 infection around
vaccination, joint trauma or major surgery as triggering events were not found, although
patients were not systematically tested for SARS-CoV-2 infection unless there were typical
symptoms.

Twenty-three (85.2%), two (7.4%), and two (7.4%) received the BNT-162b2, mRNA-
1273 and ChAdOx1 vaccines, respectively. Twenty cases (74.1%) were reported in Israel,
five (18.5%) in the UK, and two (7.4%) in the USA.

Vaccines 2021, 9, 435

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Table 1. The study population basic characteristics. Abbreviations: NSAIDs: nonsteroidal anti-
inflammatory drugs.

Age (mean ± standard deviation; median)

54.44 ± 19.20; 55

Parameter

Sex
Female
Male

Pre-vaccine autoimmune/rheumatic history
None
Rheumatoid Arthritis
Behçet’s disease
Systemic lupus erythematosus (SLE)/SLE-like
Pericarditis
Others

Days from vaccine to flare/new-onset
After 1st dose
After 2nd dose

21/27 (77.8%); median 4 days [1–25 days]
8/12 (66.7%); median 4 days [1–7 days]

Value

15 (55.6%)
12 (44.4%)

6 (22.2%)
6 (22.2%)
4 (14.8%)
3 (11.1%)
2 (7.4%)
6 (22.2%)

23 (85.2%)
2 (7.4%)
2 (7.4%)

12 (44.4%)
15 (55.6%)

17 (63.0%)
10 (37.0%)

6 (22.2%)
14 (51.9%)
7 (25.9%)

21 (77.8%)
4 (14.8%)
3 (11.1%)
2 (7.4%)
1 (3.7%)
1 (3.7%)
1 (3.7%)
1 (3.7%)
7 (25.9%)
1 (3.7%)

21 (77.8%)
2 (7.4%)
2 (7.4%)
1 (3.7%)

Vaccine
BNT-162b2
mRNA-1273
ChAdOx1

2nd Vaccine
Administered
Not administered yet

Flare
New-onset

Severity
Mild
Moderate
Severe

Therapy
Glucocorticoids
Colchicine
NSAIDs
Plasma exchange
Hydroxychloroquine
Rituximab
Local steroids
Pyridostigmine
Combination of drugs
No additional treatment

Response
Rapid response
Spontaneous resolution
Slow response
Intubation

The average time between vaccination and new-onset or flare of symptoms was 4 days
(median of 4 days [1–25 days] in those who developed an IMD after the first dose and a
median of 4 days [1–7 days] in those after the second dose) with most cases occurring after
the first inoculation (77.8%). Twelve cases flared after the first vaccine dose, one case flared
after both the first and the second vaccine dose, and four cases flared only after the second
vaccine dose. Fifteen cases (55.6%) did not receive the second vaccination.

Although we did not formally collect data on well-known vaccine adverse reactions
such as fever, headaches, myalgia, and arm pain following vaccination, these features did

Vaccines 2021, 9, 435

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not appear to be severe from review of medical records. Most IMDs were mild-to-moderate
in terms of severity (n = 20, 74.1%).

In 22 cases (81.5%), the development of AEFI/IMD could not be explained based on
the drug received by the patient. In 23 cases (85.2%), AEFI development could not be
explained based on the underlying disease/co-morbidities. Only in one case (3.7%), the
timing window of the insurgence of the side effect was considered not compatible with the
time from vaccine to flare (Table 1).

3.1. RMD Cases

The individual cases are summarized in Table 2.
Overall, 20/27 cases had RMD disease. Among those, 11 patients had arthritis, 9 flares,
and 2 of new-onset, and in 8/11 patients, arthritis was the only presentation without
extra-articular features, 7 cases of arthritis were seronegative inflammatory arthritis and
3 were anti-citrullinated protein antibody positive (ACPA+), rheumatoid factor positive
(RF+) autoimmune and 1 case of mixed pattern nature (Figure 1). One case of a flare in
gout was noted with flare in this arthropathy being well reported with native SARS-CoV-2
infection during the first wave of the pandemic [39].

Four cases of Behcet’s disease (BD) flare were noted in Israel with all of these having
oral ulceration flares with one experiencing associated arthritis. None of the BD cases
experienced major internal organ flares or immunothrombotic vascular episodes with
disease limited to cutaneous and articular flares (Figure 2).

With respect to autoimmune connective tissue diseases, 3 cases of systemic lupus
erythematosus (SLE) (2 flares and one case with predominant discoid SLE clinical features
that converted to confirmed pleuropericarditis) were noted. A single case of known
dermatomyositis experienced a flare in cutaneous disease but not myositis following
vaccination (Table 2) (Figure 3B).

Three vasculitis cases, all new-onset were reported including a Henoch-Schönlein

Purpura (HSP) pattern, and 2 cases of chilblain lesions (Figure 2).

One new case of polymyalgia rheumatica (PMR) was reported and 1 case of remitting
seronegative symmetrical synovitis with pitting edema (RS3PE) (new-onset) was docu-
mented in a subject with confirmed PMR that was treated 15 years earlier. No cases of
Giant cell arteritis (GCA) were noted.

3.2. Non-RMD

The individual cases are summarized in Table 2. In our study, 7 non-RMD cases were
reported. Among these, 4 autoimmune neurological disorders were found. Two new-onset
myasthenia gravis cases occurred, both after the second dose of BNT162b2 vaccine, one
being severe. A single new-onset case of multiple sclerosis (MS) was reported after a week
after the first dose of BNT162b2 vaccine, which was clinically moderate and responded well
to therapy (Figure 4, in particular Figure 4C). One moderate flare case of neurosarcoidosis
and small fiber neuropathy that resolved spontaneously was also reported.

We observed two cases of pericarditis that we considered to be more autoinflammatory
than autoimmune (Figure 4, in particular Figure 4A,B). Notably, one case was particu-
larly suggestive of vaccine-induced inflammation as with each vaccination, pericarditis
occurred 4 days after the first dose and a flare 4 days after the second dose. Both episodes
were treated with nonsteroidal anti-inflammatory drugs (NSAIDs) and colchicine and
responded well.

An additional case of pericarditis flare was noted in an ACPA+ RF+ RA case but there
was no flare in joint disease. Miscellaneous diagnosis cases included a case of ulcerative
colitis (UC) and severe associated hypereosinophilic syndrome that flared.

Vaccines 2021, 9, 435

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Table 2. Description of patients with immune disorder flare/new-onset following SARS-CoV-2 vaccine. Abbreviations: ACEi: Angiotensin-converting enzyme inhibitor; ANA: Antinuclear
antibody; BID: Bis in die/two times daily; CBC: Complete blood count; CCP: cyclic citrullinated peptide; CRP: C-reactive protein; DM: Dermatomyositis; dsDNA: Double-stranded DNA;
ESR: Erythrocyte sedimentation rate; IgE: Immunoglobulin E; MRI: Magnetic resonance imaging; MTX: Methotrexate; NSAID: Nonsteroidal anti-inflammatory drug; PLQ: Plaquenil; RF:
Rheumatoid factor; RA: Rheumatoid arthritis; RS3PE: Remitting seronegative symmetrical synovitis with pitting oedema; SLE: Systemic lupus erythematosus; UC: Ulcerative colitis.

ID Sex Age

Pre-Vaccine
History of
Immune
Mediated
Disease +
Medication

Date 1st
Vaccine
Dose

Date
2nd
Vaccine
Dose

Days
from
Vaccine to
Flare/New-
Onset
(Number)

Immune
Mediated
Disease
Complication

Flare
(F)/New-
Onset
(N)

Severity

Relevant Lab
Tests

Therapy

Comments on
Therapy and
Response

Country

Can the
reaction
be
Explained
Based on
Drug
Received
by the
Patient?
(Yes/No)

Can the
Reaction be
Explained
Based on the
Underlying
Co-
Morbidity
of the
Patient?
(Yes/No)

Do you Feel
the Timing
of the
Side-Effect
Compatible
with the
Time from
Vaccine to
Flare?
(Yes/No)

1

F

83

Polymyalgia
rheumatica since
2005 (clinical
diagnosis)
Hypothyroidism

January
2021
BNT162b2
vaccine

Not
given
yet

7 days
(after dose
1)

2

F

42

Transient
synovitis (one
episode in 2015,
clinical
diagnosis)

January
2021
BNT162b2
vaccine

Not
given

4 days
(after dose
1)

Severe
Seronegative
Polyarthritis with
RS3PE pattern
(clinical
assessment)

Migratory
arthritis small
joints with
erythema and
hemorrhagic rash
on toes (clinical
assessment)

N

F

Severe
(articular
swelling
and sub-
stantial
limitation
of range of
motion)

Moderate
(articular
swelling
and
moderate
limitation
of range of
motion)

CRP 74mg/L;
ANA screening
(including
anti-dsDNA)
negative;
Anti-CCP
negative;
RF negative

CRP < 4 mg/L
ANA screening
(including
anti-dsDNA)
negative;
RF negative

Prednisolone
15mgs day

Rapid response
to therapy with
quick symptom
improvement

UK

Yes

No

Yes

Prednisolone
10 mgs day

UK

Yes

No

Yes

3

M

43

F

Moderate

Israel

No

Yes

Yes

February
2021
BNT162b2
vaccine

February
2021

3 (after
first dose)

Flare in
neurosarcoidosis
and neuropathy

MRI of the
spine did not
show relapse
of myelitis

No
additional
treatment

4

M

38

Pericarditis

N

Moderate

Israel

No

No

Yes

January
2021
BNT162b2
vaccine

January
2021
BNT162b2
vaccine

Onset (4
days after
1st dose)
and flare
(4 days
after 2nd
dose)

CRP 45, ESR 60.
Negative for
ANA

Treated with
NSAIDs and
colchicine.
(1st event)
and 20 mg
prednisone
(2nd event)

Rapid response
to therapy with
low grade
swelling of 4
joints without
tenderness after 1
week

Flare
spontaneously
improved after 2
weeks, the
patient received
2nd dose of
vaccine with no
additional side
effects

Rapid response
to therapy with
quick symptom
improvement

Neurosarcoidos
is and small fiber
neuropathy,
diagnosed 3
years prior to
vaccination.
treated with
infliximab for the
last 2.5 years and
asymptomatic
under treatment

Hypertension;
dyslipidemia,
and hypertrophic
cardiomyopathy,
treated with
beta-blockers,
ACEi, and
atorvastatin

Vaccines 2021, 9, 435

9 of 23

ID Sex Age

Pre-Vaccine
History of
Immune
Mediated
Disease +
Medication

Date 1st
Vaccine
Dose

Date
2nd
Vaccine
Dose

Days
from
Vaccine to
Flare/New-
Onset
(Number)

Immune
Mediated
Disease
Complication

Flare
(F)/New-
Onset
(N)

Severity

Relevant Lab
Tests

Therapy

Comments on
Therapy and
Response

Country

Can the
reaction
be
Explained
Based on
Drug
Received
by the
Patient?
(Yes/No)

Can the
Reaction be
Explained
Based on the
Underlying
Co-
Morbidity
of the
Patient?
(Yes/No)

Do you Feel
the Timing
of the
Side-Effect
Compatible
with the
Time from
Vaccine to
Flare?
(Yes/No)

Table 2. Cont.

5

M

28

January
2021
BNT162b2
vaccine

Not
given

4 days
after 1st
dose

F

Severe

IgE 41400, 9000
eosinophils,
CRP 35

Israel

No

Yes

Yes

Ulcerative Colitis
(since 10 years) +
hypere-
osinophilic
syndrome (since
5 years)
(Vedoliziumab
300 mg every 8
week and
cyclosporin 150
mg BID) well
controlled for a
year

6

M

70

No medical
history

December
2020
BNT162b2
vaccine

Not
given

3 days
after 1st
dose

7

F

45

Hypothyroidism
controlled with
Eltroxin 50 mcg
daily

December
2020
BNT162b2
vaccine

Not
given

7 after the
1st dose

Flare of hypere-
osinophilic
syndrome and
UC with
vesicular skin
rash, oral
aphthosis and
hemorrhagic
diarrhea

Polymyalgia
rheumatica;
severe stiffness
and pain in
shoulders and
hips, fever and
fatigue

Multiple sclerosis
with left leg
weakness
disequilibrium,
and lower limbs
distal numbness

1 gr of
sulomedrol
daily for 3
days, then
prednisone
60 mg/day
tapering
dose
(decrease 20
mg every 2
weeks)

Slow response,
eosinophils of
1200 after 2
weeks of therapy,
significant and
partial
improvement in
diarrhea and skin
rash, respectively.

Prednisone
dose 40 mg
once daily

Rapid response
to therapy with
quick symptom
improvement

1 g of
sulomedrol
daily for 5
days, then
prednisone
60 mg daily
with
tapering
down dose

Rapid response
to therapy with
quick symptom
improvement

CRP 175, ESR
90
Anti-CCP, RF
and ANA
negative

Normal CBC
and
biochemistry
Multiple Peri-
ventricular
white matter
changes on
MRI.
CSF-
oligoclonal
bands.

N

Severe

Israel

No

No

Yes

N

Moderate

Israel

No

No

No

Vaccines 2021, 9, 435

10 of 23

ID Sex Age

Pre-Vaccine
History of
Immune
Mediated
Disease +
Medication

Date 1st
Vaccine
Dose

Date
2nd
Vaccine
Dose

Days
from
Vaccine to
Flare/New-
Onset
(Number)

Immune
Mediated
Disease
Complication

Flare
(F)/New-
Onset
(N)

Severity

Relevant Lab
Tests

Therapy

Comments on
Therapy and
Response

Country

Can the
reaction
be
Explained
Based on
Drug
Received
by the
Patient?
(Yes/No)

Can the
Reaction be
Explained
Based on the
Underlying
Co-
Morbidity
of the
Patient?
(Yes/No)

Do you Feel
the Timing
of the
Side-Effect
Compatible
with the
Time from
Vaccine to
Flare?
(Yes/No)

8

F

66

January
2021
BNT162b2
vaccine

Not
given

2 days
after the
1st dose

F

Positive ACPA
5.4, RF 44, CRP
40, ESR 70

Rapid response
to therapy with
quick symptom
improvement.

Israel

No

No

Yes

Idiopathic
pericarditis,
anemia
normocytic
normochromic,
left
femoro-popliteal
DVT treated with
rivaroxaban 20
mg 12.2020,
spontaneous
abortion of 1st
trimester
Idiopathic
pericarditis

Table 2. Cont.

Mild
(moderate
chest pain,
no
symptoms
of heart
failure, no
limitation
of
function)

Continued
Prednisone
15 mg
prednisone.
On 19
January 2021,
dose was
increased to
30 mg and 1
mg of
colchicine.
by physician.
15 mg of
Methotrex-
ate was
started
together
with 5 mg of
folic acid

Normal CBC,
chemistry, ESR
and CRP. Mus-
culoskeletal US
without
synovitis or
tenosynovitis
(done 1/27,
symptoms had
nearly
resolved)

Pericarditis with
fever, typical
pleuritic chest
pain, elevated
inflammation
markers
No RA articular
manifestation.

Dactylitis of RT
3rd finger
Onset of R 2nd
and 3rd finger
joint pain,
stiffness and
tightness. Also
developed
painful
erythematous
macules over
palmar surface of
several fingers on
both hands

Pain chilblains
like lesions on
fingers (painful)

9

F

36

Psoriasis since
childhood, mild

December
2020
MRNA-
1273

January
2021

10 days
after 1st
dose

N

Mild

USA

No

Yes

Yes

Ibuprofen
800 mg

Rapid response
to therapy with
quick symptom
improvement.

Vaccines 2021, 9, 435

11 of 23

ID Sex Age

Pre-Vaccine
History of
Immune
Mediated
Disease +
Medication

Date 1st
Vaccine
Dose

Date
2nd
Vaccine
Dose

Days
from
Vaccine to
Flare/New-
Onset
(Number)

Immune
Mediated
Disease
Complication

Flare
(F)/New-
Onset
(N)

Severity

Relevant Lab
Tests

Therapy

Comments on
Therapy and
Response

Country

Can the
reaction
be
Explained
Based on
Drug
Received
by the
Patient?
(Yes/No)

Can the
Reaction be
Explained
Based on the
Underlying
Co-
Morbidity
of the
Patient?
(Yes/No)

Do you Feel
the Timing
of the
Side-Effect
Compatible
with the
Time from
Vaccine to
Flare?
(Yes/No)

Table 2. Cont.

Chilblains like
lesions on fingers
(painful)
Urticarial-type
lesions
(resembled
urticarial
multiforme).
10 days after first
vaccine
developed itchy
urticarial lesions
over volar aspect
of both wrists
and feet, lesions
evolved over
thighs
(symptomless)
and extensor
surfaces of both
elbows, painful
macular/nodular
lesions over
palmar surface
both hands.
Resolved in 7
days

10

F

48

Not relevant

N

Moderate

No work up

USA

No

No

Yes

January
2021
MRNA-
1273

February
2021

10 days
after 1st
dose

Hydrocortisone

0.5%

Naproxen
500 mg

Rapid response
to therapy with
quick symptom
improvement.

11

M

21

F

Moderate

No work up

Israel

No

No

Yes

Behcet’s disease
(known for 3
years) treated
with colchicine
1.5 mg daily

January
2021
BNT162b2
vaccine

Not
given

5 days
after 1st
dose

Oral aphthous
ulcers

20 mg of
prednisone
for 1 week

Rapid response
to therapy with
quick symptom
improvement

Vaccines 2021, 9, 435

12 of 23

ID Sex Age

Pre-Vaccine
History of
Immune
Mediated
Disease +
Medication

Date 1st
Vaccine
Dose

Date
2nd
Vaccine
Dose

Days
from
Vaccine to
Flare/New-
Onset
(Number)

Immune
Mediated
Disease
Complication

Flare
(F)/New-
Onset
(N)

Severity

Relevant Lab
Tests

Therapy

Comments on
Therapy and
Response

Country

Can the
reaction
be
Explained
Based on
Drug
Received
by the
Patient?
(Yes/No)

Can the
Reaction be
Explained
Based on the
Underlying
Co-
Morbidity
of the
Patient?
(Yes/No)

Do you Feel
the Timing
of the
Side-Effect
Compatible
with the
Time from
Vaccine to
Flare?
(Yes/No)

Table 2. Cont.

12

M

55

F

Moderate

No work up

Israel

No

No

Yes

Behcet’s disease
known for 20
years and well
controlled treated
with apremilast
30 mg BID. Also
CLL (known for 5
years, controlled
with no therapy)

December
2020
BNT162b2
vaccine

January
2021
BNT162b2
vaccine

7 days
after 2nd
dose

Oral aphthous
ulcers and
synovitis of small
joints
(7 days after the
second dose,
synovitis in
MCPS and PIPS
both hands, and a
few days later
ulcers on the
tongue)

Behcet’s disease
(known for 2
years) treated
with colchicine 1
mg daily

December
2020
BNT162b2
vaccine

Not
given

3 days
after 1st
dose

Oral aphthous
ulcers

RA, treated with
MTX 15 mg wk
and
Certolizumab 200
mg every other
week (on
remission for the
last 18 months).
Medical history
included
hypertension

December
2020
BNT162b2
vaccine

January
2021
BNT162b2
vaccine

7 days
after 2nd
dose

Polyarthritis of
small joints

13

M

20

F

Moderate

No work up

Israel

No

No

Yes

14

F

62

Patient with DM
treated with MTX
and PLQ 200 mg
BID

January
2021
BNT162b2
vaccine

February
2021
BNT162b2
vaccine

7 days
after 1st
dose

Skin rash similar
to the rash when
diagnosed with
DM

F

Mild

No work up

Israel

No

No

Yes

Local steroid
cream

15

F

70

F

Moderate

High CRP

NSAIDs

Israel

No

No

Yes

Colchicine
0.5 mg twice
daily and 5
mg
prednisone

Rapid response
to therapy with
quick symptom
improvement

Increased
dosage of
colchicine to
2 mg daily

Rapid response
to therapy with
quick symptom
improvement

Flare
spontaneously
improved after a
week, the patient
received 2nd
dose of vaccine
with no
additional side
effects

Rapid response
to therapy with
quick symptom
improvement

Vaccines 2021, 9, 435

13 of 23

Table 2. Cont.

ID Sex Age

Pre-Vaccine
History of
Immune
Mediated
Disease +
Medication

Date 1st
Vaccine
Dose

Date
2nd
Vaccine
Dose

Days
from
Vaccine to
Flare/New-
Onset
(Number)

Immune
Mediated
Disease
Complication

Flare
(F)/New-
Onset
(N)

Severity

Relevant Lab
Tests

Therapy

Comments on
Therapy and
Response

Country

Can the
reaction
be
Explained
Based on
Drug
Received
by the
Patient?
(Yes/No)

Can the
Reaction be
Explained
Based on the
Underlying
Co-
Morbidity
of the
Patient?
(Yes/No)

Do you Feel
the Timing
of the
Side-Effect
Compatible
with the
Time from
Vaccine to
Flare?
(Yes/No)

16

F

78

Laboratory SLE
with no clinical
manifestation

January
2021
BNT162b2
vaccine

Not
given

2 days
after 1st
dose

Fever,
erythematous
rash (generalized
acute cutaneous
lupus), purpura,
oral aphthous
ulcers and
arthritis

+ANA, high
CRP and ESR,
Skin biopsy
from purpura
was
compatible
with leukocyto-
clastic
vasculitis

Started on
Hydroxy-
chloroquine

Rapid response
to therapy with
quick symptom
improvement

N

Mild

Israel

Yes

No

Yes

17

F

50

SLE with
arthritis, mucosal
ulcers and
hemolysis (2019
EULAR/ACR
SLE criteria)

January
2021
ChAdOx1
nCoV-19
vaccine

Not
given

14

Severe hemolysis,
oral and nasal
ulceration,
arthralgia

F

Severe
(clinical as-
sessment)

Hb 53,
reticulocytes
42%, bilirubin
48, LDH 864

Slow response

UK

Yes

No

Yes

January
2021
BNT162b2
vaccine

Not
given

5 days
after 1st
dose

Pustular skin
lesions
-developed skin
lesions as a part
of Behcet’s
disease for the
first time

Behcet’s disease
(known for 10
years, included
arthritis, uveitis,
skin rash, oral
aphthosis
controlled for the
last 12 months,
treated with
colchicine and
Humira), no
other medical
history

Recurrent.
pericarditis -
treated with
colchicine in the
past

18

M

34

F

Moderate

No work up

Israel

No

No

Yes

19

M

72

1 day after
2nd dose

Myasthenia
Gravis

N

Moderate

January
2021
BNT162b2
vaccine

January
2021
BNT162b2
vaccine

EMG-
decrement of
28–46% on
facial and
shoulder
muscles

Plasma
exchange +

Prednisone
60 mg

Rapid response
to therapy with
quick symptom
improvement

Israel

No

No

Yes

High dose
glucocorti-
coids
(Pred-
nisolone 60
mg daily)
and
rituximab

Short course
of NSAIDs
and increase
of colchicine
dose

Rapid response
to therapy with
quick symptom
improvement

Vaccines 2021, 9, 435

14 of 23

Table 2. Cont.

ID Sex Age

Pre-Vaccine
History of
Immune
Mediated
Disease +
Medication

Date 1st
Vaccine
Dose

Date
2nd
Vaccine
Dose

Days
from
Vaccine to
Flare/New-
Onset
(Number)

Immune
Mediated
Disease
Complication

Flare
(F)/New-
Onset
(N)

Severity

Relevant Lab
Tests

Therapy

Comments on
Therapy and
Response

Country

Can the
reaction
be
Explained
Based on
Drug
Received
by the
Patient?
(Yes/No)

Can the
Reaction be
Explained
Based on the
Underlying
Co-
Morbidity
of the
Patient?
(Yes/No)

Do you Feel
the Timing
of the
Side-Effect
Compatible
with the
Time from
Vaccine to
Flare?
(Yes/No)

20

M

73

Not relevant

N

Severe

Israel

No

No

Yes

Dec 2020
BNT162b2
vaccine

January
2021
BNT162b2
vaccine

7 days
after 2nd
dose

21

F

68

RA
seropositive-well
controlled with
Actemra

January
2021
BNT162b2
vaccine

February
2021
BNT162b2
vaccine

3 days
after 2nd
dose

F

Severe

Israel

No

No

Yes

Myasthenia
Gravis (firstly
ocular signs then
appearance of
bulbar signs and
respiratory
symptoms)

Flare of synovitis
of small joints
CDAI = 41
compared to
CDAI = 4 in 19
January 2021

Palpable purpura,
mild abdominal
pain and
arthralgia w/o
arthritis, no renal
involvement.
Diagnosed with
Henoch
Schlonein Pupura
with
Leukocytoclastic
cutaneous
vasculitis among
skin bipsy

Plasma
Exchange,
Pyridostig-
min and
prednisone

Patient intubated
due to respiratory
symptoms

IM
Depomedrol
160 mg

Rapid response
to therapy with
quick symptom
improvement

EMG-
borderline
decrement,
markedly
pathologic
jitter

ESR=12 after
depomedrol,
CRP = 0.06
before flare,
CRP = 0.28
after flare, RF =
1782 before
flare, RF = 2300
after flare,
ANA negative
after vaccine

Skin biopsy
revealed IgA
and C3
deposits in the
vessel walls
Mild elevation
in CRP to 0.8
mg/dL, mild
elevation in
IgA to 412
mg%, mild
leucocytosis to
11.5 k/ul

22

M

53

Not relevant

January
2021
BNT162b2
vaccine

Not
given

3 days
after first
dose

N

Mild-
moderate

Dexamethasone

10 mg,
prednisone
60 mg
thereafter

Rapid response
to therapy with
quick symptom
improvement

Israel

No

No

Yes

Vaccines 2021, 9, 435

15 of 23

Table 2. Cont.

Date 1st
Vaccine
Dose

Date
2nd
Vaccine
Dose

Immune
Mediated
Disease
Complication

Flare
(F)/New-
Onset
(N)

Severity

Relevant Lab
Tests

Therapy

Comments on
Therapy and
Response

Country

ID Sex Age

23

F

80

Pre-Vaccine
History of
Immune
Mediated
Disease +
Medication

Seronegative
RA–2007
(ACR/EULAR
2010 class. Crit.)
stable on
Methotrexate
15mgs week

Gout (known for
many years) well
controlled in the
last 2 years),
hypertension and
dyslipidaemia

January
2021
BNT162b2
vaccine

Not
given

Dec 2020
BNT162b2
vaccine

January
2021
BNT162b2
vaccine

Severe Right
ankle synovitis,
severe wrist
synovitis and 5
small joint
synovitis

Monoarthritis
at Rt elbow (after
1st dose) and at
mid foot (after
2nd dose)

F

ESR 71
CRP 27

Severe
(articular
swelling
and sub-
stantial
limitation
of range of
motion)

Can the
reaction
be
Explained
Based on
Drug
Received
by the
Patient?
(Yes/No)

Can the
Reaction be
Explained
Based on the
Underlying
Co-
Morbidity
of the
Patient?
(Yes/No)

Do you Feel
the Timing
of the
Side-Effect
Compatible
with the
Time from
Vaccine to
Flare?
(Yes/No)

UK

No

No

Yes

24

M

70

F

Moderate

CRP 44 mg/L.

Israel

No

No

Yes

25

F

78

Seropositive RA
(not active and
with no therapy
for many years)

January
2021
BNT162b2
vaccine

Not
given

2 days
after first
dose

Polyarthritis
involving
shoulders, wrists,
MCPs and PIPs

F

Moderate

ANA negative,
RF 60, ESR 52,
CRP 2.1 mg/dl

Israel

No

No

Yes

Prednisolone
15 mgs day
tapering and
increase
methotrex-
ate
dose

Rapid response
to therapy with
quick symptom
improvement

Prednisone
40 mg for
7 day

Rapid response
to therapy with
quick symptom
improvement

Prednisone
20 mg daily
with
tapering
down 5 mg
every week
was
prescribed.

Joint
aspiration
and injection
of 80mg
depomedrol

Rapid response
to therapy with
quick symptom
improvement

Rapid response
to therapy with
quick symptom
improvement

26

F

27

Seronegative RA
stable on
Adalimumab
every 2 weeks

January
2021
BNT162b2
vaccine

January
2021
BNT162b2
vaccine

Monoarthritis of
Rt knee

F

Moderate

ANA negative,
RF negative,
CRP 1.3 mg/dl

Israel

No

No

Yes

Days
from
Vaccine to
Flare/New-
Onset
(Number)

25 days
flare with
progres-
sive
worsening

1 day after
first dose
and
another
flare 1 day
after the
second
dose

4 days
after
second
dose
developed
Rt knee
monoarthri-
tis

Vaccines 2021, 9, 435

16 of 23

ID Sex Age

Pre-Vaccine
History of
Immune
Mediated
Disease +
Medication

Date 1st
Vaccine
Dose

Date
2nd
Vaccine
Dose

Days
from
Vaccine to
Flare/New-
Onset
(Number)

Immune
Mediated
Disease
Complication

Flare
(F)/New-
Onset
(N)

Severity

Relevant Lab
Tests

Therapy

Comments on
Therapy and
Response

Country

Can the
reaction
be
Explained
Based on
Drug
Received
by the
Patient?
(Yes/No)

Can the
Reaction be
Explained
Based on the
Underlying
Co-
Morbidity
of the
Patient?
(Yes/No)

Do you Feel
the Timing
of the
Side-Effect
Compatible
with the
Time from
Vaccine to
Flare?
(Yes/No)

Table 2. Cont.

27

F

60

4 days

F

Mild

UK

Yes

Yes

Yes

February
2021
ChAdOx1
vaccine

Not
given
yet

Pericardial and
pleural effusions,
possible
pericarditis

Central
intermittent
pleuritic chest
pain, had
CTPA and
bedside echo.
Trop normal
CRP 17.8

Prednisone
increased
from 8mg to
15mg for 5
days,
colchicine
500 mcg BD

Rapid response
to therapy with
quick symptom
improvement

SLE (never
previously
referred to
rheumatology):
Discoid lupus
since 2001, severe
raynauds,
alopecia,
pancytopenia
(since September
2020), proteinuria
(Developed Sept
2020, diagnosed
as class IV lupus
nephritis March
2021), hypocom-
plementaemia,
ANA positive,
dsDNA,
anti-chromatin
and
anti-ribosomal
antibody
positive), 2019
EULAR/ACR
SLE criteria)
Baseline Disease
modifying
therapy:
Prednisolone
8mg OD

Vaccines 2021, 9, 435

17 of 23

Figure 2. Panel (A) (Case 2)—Florid clinical arthritis of the proximal interphalangeal joints (dotted
red circles). Concomitant, painless rash on two toe tips (orange circles). Panel (B) (Case 23)—Severe
articular swelling of the right ankle, left wrist, and the small joints of the fingers (dotted red circles).
Panel (C) (Case 9)—dactylitis of the third finger (black arrowheads) associated with chilblain lesion
of the second finger (red arrow). Panel (D) (Case 10)—chilblain-like lesions of the fingers and
palms, associated with urticarial lesions of the wrists (blue dotted square), thighs and elbows (blue
dotted arrows).

Figure 3. Cont.

Vaccines 2021, 9, 435

18 of 24

Figure 3. Panels (A,B) (Cases 11 and 12)—Oral aphthous lesions and small joints arthritis, Behçet’s

disease. Panel (C) (Case 22)—Vasculitic lesions of the skin on lower limbs and forearms. Histology

consistent with fibrinoid necrosis of small vessels. Panel (D) (Case 17)—Pustular skin lesions on the

forehead and face, Behçet’s disease.

An additional case of pericarditis flare was noted in an ACPA+ RF+ RA case but there

was no flare in joint disease. Miscellaneous diagnosis cases included a case of ulcerative

colitis (UC) and severe associated hypereosinophilic syndrome that flared.

3.3. Laboratory Findings

Among 11 cases of arthritis, only 3 were of autoimmune (RF was positive in two cases

and 1 was anti-nuclear antibody or ANA positive). ACPA was positive in only one case of

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Figure 3. Panels (A,B) (Cases 11 and 12)—Oral aphthous lesions and small joints arthritis, Behçet’s
disease. Panel (C) (Case 22)—Vasculitic lesions of the skin on lower limbs and forearms. Histology
consistent with fibrinoid necrosis of small vessels. Panel (D) (Case 17)—Pustular skin lesions on the
forehead and face, Behçet’s disease.

3.3. Laboratory Findings

Among 11 cases of arthritis, only 3 were of autoimmune (RF was positive in two cases
and 1 was anti-nuclear antibody or ANA positive). ACPA was positive in only one case of
pericarditis but with no particular manifestation. CRP and ESR were generally high. Other
laboratory tests are reported in Table 1.

Figure 4. Panel (A) (Case 4)—Parasternal, long axis view from a 2-D echocardiogram showing a small-
sized posterior pericardial effusion (white arrow). Panel (B) (Case 27)—Computerized tomography
scan demonstrating posterior pericardial effusion (white arrow) and bilateral pleural effusion (white
arrowheads). Panel (C) (Case 7)—Magnetic resonance imaging of the brain showing demyelinating
lesions in the left mesencephalic (dotted white arrow) and in the right peri-ventricular occipital white
matter (white dotted square).

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Figure 3. Panels (A,B) (Cases 11 and 12)—Oral aphthous lesions and small joints arthritis, Behçet’s

disease. Panel (C) (Case 22)—Vasculitic lesions of the skin on lower limbs and forearms. Histology

consistent with fibrinoid necrosis of small vessels. Panel (D) (Case 17)—Pustular skin lesions on the

forehead and face, Behçet’s disease.

An additional case of pericarditis flare was noted in an ACPA+ RF+ RA case but there

was no flare in joint disease. Miscellaneous diagnosis cases included a case of ulcerative

colitis (UC) and severe associated hypereosinophilic syndrome that flared.

3.3. Laboratory Findings

Among 11 cases of arthritis, only 3 were of autoimmune (RF was positive in two cases

and 1 was anti-nuclear antibody or ANA positive). ACPA was positive in only one case of

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As outlined in Tables 1 and 2, the majority of cases 21 (80.8%) received glucocorticoid
therapy. Other drugs included colchicine, NSAIDs, hydroxychloroquine, rituximab, plasma
exchange and pyridostigmine. At the time of writing no patient has severe resistant or
progressive disease with all cases showing good therapy responses.

3.4. Therapy

4. Discussion

Natural viral infection or vaccination have both been noted as potential triggering
events for inflammatory diseases for many decades [40,41]. Herein, we combined data from
three countries from large academic centers in regions where anti SARS-CoV-2 vaccination
programs rolled out with an estimate catchment population of 6–7 million subjects. We
report the nature of flares in known IMDs that generally responded well to corticosteroid
therapy. We reported less common, but notable, new-onset IMDs temporally associated
with vaccination administration, including neurological disease, which represents the main
strength of the present investigation.

Overall, these findings of new-onset disease appear rare considering the level of popu-
lation exposure in the regions covered and are likely to be close to the background incidence
of these conditions in such a large population. While we cannot estimate frequency with
precision, the level of public and medical vigilance around this new healthcare intervention
would suggest that cases were less likely to be missed compared to, for example, seasonal
influenza. Further studies would be required to compare the frequencies of IMDs after
these vaccines.

Despite being rare, the insurgence of AEFIs represents a public health concern in that,
if not dealt with rapidly and properly, they could undermine public confidence and trust
towards vaccination. COVID-19 immunization seems to be extremely a valid strategy
to contain and mitigate against the burden imposed by the pandemic and, in order to
reach herd immunity, high compliance rates are warranted. Acceptance rate towards
COVID-19 immunization is highly variable, ranging from approximately 90% to less than
55%, depending on the country, with information being disseminated and received playing
a major role in achieving optimal coverage and community immunity [42]. Therefore,
COVID-19 vaccine safety assessment is extremely crucial, especially at the beginning of
population-level implementation. Our data assist clinicians in recognizing putative flares
that are in line with our reported experience. The outcomes provide assurance to the public
that such events are rare and manageable, and to clinicians that conventional therapies such
as glucocorticoids are usually adequate—particularly important at a time where healthcare
resources are highly stretched.

Numerically, our findings show the clearest associations for the non-specific adjuvant
effects of the mRNA vaccines in triggering a host of different inflammatory disorders. It
is possible that there is increased vigilance towards, and documentation of non-arthritis
RMDs, since these are more likely to require specialist review, other investigations, or
hospital treatment. Nevertheless, the proportion of the events observed is disproportionate
to the usual frequency of these diseases. Usual prevalence would predict RA most com-
monly, followed by other inflammatory arthritis, and, then, non-arthritis RMDS. Here, we
found that almost half of the events occur as forms of non-arthritis RMDs—usually far less
frequent than inflammatory arthritis. Within inflammatory arthritis, spondyloarthropathy-
spectrum disease was more frequent than RA, again differing from the usual prevalence,
while one RA case had a usually-rare extra-articular feature. This suggests, although does
not prove, causality. Most of the reported disease were flares, which supports the idea of
the delicate balance of immune homeostasis in such cases being momentarily tipped into a
pro-inflammatory state by vaccination.

The majority of patients in our study received mRNA vaccines while only two received
DNA-based vaccine. This may simply reflect the roll-out of these vaccines rather than
a causal association with IMDs. However, of particular importance, the use of TLR-7
and TLR-9 agonistic based vaccines which stimulates immunity in different ways to the

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more TLR-4 and inflammasome based alum vaccines represents a new vaccine strategy for
human disease [43]. Most of our cases, but not all, responded very well to therapy and in
most cases second doses of vaccines were withheld.

Natural SARS-CoV-2 infection has resulted so far in over 3.1 million deaths due to
severe viral pneumonia where immune hyper-activation also contributes to mortality as
shown by the response to some patients to corticosteroids. The most well-recognized
RMD-like feature of natural SARS-CoV-2 infection is the various cutaneous vasculitis-
like feature including “COVID toes” and the Multisystem Inflammatory Syndrome in
Children (MIS-C) [44]. Of note, these manifestations are generally seen in subjects with
minimal or not lung disease pointing towards a hyperactive immune response which, while
being protective against pneumonia, can lead to collateral damage to other organ systems.
Natural infection has also been associated with case reports of vasculitis, neurological
disease including GBS and others in addition to other occasionally reported IMDs [45–47].
Herein, we report a wide variety of vaccine-associated flares or new-onset in IMDs ranging
from autoinflammatory, mixed pattern disease (BD) and autoimmune diseases rather
than an enrichment in autoimmune diseases that are linked to disordered nucleic acid
metabolism and abnormal interferon-stimulated gene signatures involving the TLR-7/9
pathways [43].

Our findings show the presence of concomitant inflammatory arthritis and usual skin
rashes in some cases. It is well established that younger subjects in particular, without
severe COVID-19, experienced chilblain and erythematous lesions of the toes which had
associated elevations in Type-I interferon in the skin contributing to a type of vasculitis.
Of note, the TLR-7 and TLR-9 stimulation afforded by these new generations of vaccines
might be expected to upregulate interferon-stimulated genes (ISGs) and contribute to
robust early innate immune responses with robust type-I IFN responses thus accounting
for the cutaneous and potentially other features. Dysregulated nucleic acid metabolism
is associated with interferonopathies and SLE and other ANA-associated phenotypes.
The frequency of such diseases is low in our series, although being similar to our rate of
ACPA-positive RA this may be considered disproportionately high. We noted one case
of discoid SLE converting into a systemic phenotype, with pleuro-pericarditis shortly
after the TLR-9 agonist containing DNA vaccine, one case of SLE that had low activity,
but where rituximab was deferred, to enhance vaccine efficacy and where patient flared
following the DNA vaccine and a third case of dermatomyositis rash flare following
an RNA vaccine. Monogenic interferonopathies are known to often include chilblains.
Reassuringly, autoimmune myositis was not documented which is noteworthy given
the intramuscular route of vaccine administration. Other relevant negatives were an
absence of Macrophage Activation Syndrome (MAS)-like patterns of disease such as Adult-
Onset Still’s Disease (AOSD) and undefined hyperinflammatory states mimicking MIS-C,
although it is acknowledged that the latter is a disease of children and young adults, none
of whom were vaccinated in the present study.

In the existing literature, only few anecdotal side-effects have been reported, including
oral, oro-facial, and allergic reactions [48–50]. Of note, cases of Bell’s palsy, and swelling of the
lips, face or tongue associated with anaphylaxis as well as flares of RA were reported [50,51]
In addition to the non-specific vaccine adjuvant properties triggered reactions as dis-
cussed above [52–55], anaphylactic reactions to BNT162b2 and mRNA-1273 based vaccines
have been reported, allegedly attributed to adjuvants, like the polyethylene glycol (PEG)
2000 present in the lipid film of the two vaccine products or the polysorbate 80 utilized as
excipient formulation in the preparation of the ChAdOx1 nCoV-19 vaccine [48–50].

In the present study, we also noted flares in BD. However, elevations in IFN levels and
especially the use of recombinant IFN-alpha may have a therapeutic role in BD, although
the mechanism of action of IFN-alpha in BD is not fully understood and there may be
pathogenic heterogeneity.

Despite its strength, our study has several limitations, that should be properly ac-
knowledged. From the design of this non-systematic accrual and reporting of IMDs in this

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early phase of the COVID-19 vaccine roll-out it is impossible to compute AEFI incidence
rate or be certain of causality, even though the number of cases, their unusual presentations
and apparent de-challenge response from the time of vaccine administration raise the possi-
bility of their relationship. Other possibilities include that some of the cases actually could
have had concomitant SARS-CoV-2 infection but the clinical picture without respiratory
symptoms does not support this. It is also possible that some cases had prior COVID-19
disease which could have contributed to immune responses and we did not test for prior
SARS-CoV-2 immunity as assessed by antibody responses. Summarizing, multiple con-
founding factors including concomitant SARS-CoV-2 infection and multiple co-morbidities
in some cases may be contributory factors to the observed symptomatology. Given the
nature of the data collection it is impossible to know how common IMD new-onset or flare
of existing IMDs are and it is possible that these findings are coincidental. Nevertheless,
some unusual features including concomitant rashes with IMDs that have been reported
with SARS-CoV-2 infection suggest a link between vaccination, at least, in some subjects.
In conclusion this is the first large series description of IMDs flares or new-onset
temporally associated with SARS-CoV-2 vaccination. The majority of cases had disease
that quickly settled with corticosteroid therapy. Larger high-quality, prospective systematic
studies are needed to address the issue of COVID-19 vaccination. Finally, we did not
come across any cases of suspected immunothrombosis although we interacted with
haematologists but it is noteworthy that 25/27 cases received mRNA vaccines.

Author Contributions: Conceptualization, A.W. and D.M.; methodology, N.L.B.; formal analysis,
N.L.B.; investigation, A.W. and D.M.; Data Collection, A.W. and D.M.; Data Collection, A.W., G.D.M.,
H.M., A.D., M.E. (Mailam Eltity), N.H., A.H., M.E. (Muna Elisa), D.Z., Y.C., A.A.-M., M.A.E., C.B.,
P.L., J.M., N.L.B., H.M.-O., M.L., C.C., L.C., E.V., Y.S., H.A., and D.M.; data curation, A.W. and D.M.;
Data Collection, A.W., G.D.M., H.M., A.D., M.E. (Mailam Eltity), N.H., A.H., M.E. (Muna Elisa),
M.E.N., M.B., D.Z., Y.C., A.A.-M., M.A.E., C.B., P.L., J.M., N.L.B., H.M.-O., M.L., C.C., L.C., E.V., Y.S.,
H.A., and D.M.; writing—original draft preparation, A.W., N.L.B., H.A., and D.M.; writing, editing
and reviewing—A.W. and D.M.; Data Collection, A.W., G.D.M., H.M., A.D., M.E. (Mailam Eltity),
N.H., A.H., M.E. (Muna Elisa), M.E.N., M.B., D.Z., Y.C., A.A.-M., M.A.E., C.B., P.L., J.M., N.L.B.,
H.M.-O., M.L., C.C., L.C., E.V., Y.S., H.A., and D.M.; supervision, A.W., H.A., and D.M.; funding
acquisition, D.M. All authors have read and agreed to the published version of the manuscript.

Funding: This research received no external funding.

Informed Consent Statement: Informed, written consent was obtained from all subjects involved in
the study.

Data Availability Statement: All data generated are contained in the present manuscript.

Acknowledgments: G.D.M., H.M.-O., E.V. and D.M. are supported by the National Institute for
Health Research (NIHR) Leeds Biomedical Research Centre (LBRC). The views expressed are those
of the authors and not necessarily those of the (UK) National Health Service (NHS), the NIHR, or the
(UK) Department of Health.

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

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