Systematic Review
Nervous and Muscular Adverse Events after COVID-19
Vaccination: A Systematic Review and Meta-Analysis of
Clinical Trials

Jiaxin Chen 1,†

, Yuangui Cai 1,†, Yicong Chen 1, Anthony P. Williams 2,3, Yifang Gao 4,* and Jinsheng Zeng 1,*

1 Department of Neurology, The First Afﬁliated Hospital, Guangdong Provincial Key Laboratory of Diagnosis

and Treatment of Major Neurological Diseases, Sun Yat-sen University, Guangzhou 510080, China;
chenjx239@mail2.sysu.edu.cn (J.C.); caiyg3@mail2.sysu.edu.cn (Y.C.); chenyc37@mail.sysu.edu.cn (Y.C.)

2 Department of Immunology, University Hospital Southampton NHS Foundation Trust,

Southampton SO16 6YD, UK; apw3@soton.ac.uk

3 Academic Unit of Cancer Sciences, Faculty of Medicine, University of Southampton and Southampton NIHR

Experimental Cancer Medicine Centre, Southampton SO16 6YD, UK

4 Organ Transplantation Center, The First Afﬁliated Hospital, Sun Yat-sen University,

Guangzhou 510080, China

* Correspondence: gaoyf26@mail.sysu.edu.cn (Y.G.); zengjsh@mail.sysu.edu.cn (J.Z.);

Tel.: +86-020-87755766 (ext. 8667) (Y.G.); +86-020-87755766 (ext. 8286) (J.Z.)
† These authors have contributed equally to this work and share ﬁrst authorship.

Abstract: Background: Nervous and muscular adverse events (NMAEs) have garnered considerable
attention after the vaccination against coronavirus disease (COVID-19). However, the incidences of
NMAEs remain unclear. We aimed to calculate the pooled event rate of NMAEs after COVID-19
vaccination. Methods: A systematic review and meta-analysis of clinical trials on the incidences
of NMAEs after COVID-19 vaccination was conducted. The PubMed, Medline, Embase, Cochrane
Library, and Chinese National Knowledge Infrastructure databases were searched from inception
to 2 June 2021. Two independent reviewers selected the study and extracted the data. Categori-
cal variables were analyzed using Pearson’s chi-square test. The pooled odds ratio (OR) with the
corresponding 95% conﬁdence intervals (CIs) were estimated and generated with random or ﬁxed
effects models. The protocol of the present study was registered on PROSPERO (CRD42021240450).
Results: In 15 phase 1/2 trials, NMAEs occurred in 29.2% vs. 21.6% (p < 0.001) vaccinated partic-
ipants and controls. Headache and myalgia accounted for 98.2% and 97.7%, and their incidences
were 16.4% vs. 13.9% (OR = 1.97, 95% CI = 1.28–3.06, p = 0.002) and 16.0% vs. 7.9% (OR = 3.31,
95% CI = 2.05–5.35, p < 0.001) in the vaccine and control groups, respectively. Headache and myalgia
were more frequent in the newly licensed vaccines (OR = 1.97, 95% CI = 1.28–3.06, p = 0.02 and
OR = 3.31, 95% CI = 2.05–5.35, p < 0.001) and younger adults (OR = 1.40, 95% CI = 1.12–1.75, p = 0.003
and OR = 1.54, 95% CI = 1.20–1.96, p < 0.001). In four open-label trials, the incidences of headache,
myalgia, and unsolicited NMAEs were 38.7%, 27.4%, and 1.5%. Following vaccination in phase
3 trials, headache and myalgia were still common with a rate of 29.5% and 19.2%, although the
unsolicited NMAEs with incidence rates of ≤ 0.7% were not different from the control group in each
study. Conclusions: Following the vaccination, NMAEs are common of which headache and myalgia
comprised a considerable measure, although life-threatening unsolicited events are rare. NMAEs
should be continuously monitored during the ongoing global COVID-19 vaccination program.

Keywords: COVID-19; vaccine; adverse events; nervous system; muscular system

1. Introduction

As of 4 August 2021, over 199 million confirmed cases of coronavirus disease (COVID-19)
have been reported, of which more than 4.2 million have resulted in death [1]. As the
virus pandemic continues, mutations occur and resist the vaccine based on the prototype

Citation: Chen, J.; Cai, Y.; Chen, Y.;

Williams, A.P.; Gao, Y.; Zeng, J.

Nervous and Muscular Adverse

Events after COVID-19 Vaccination:

A Systematic Review and

Meta-Analysis of Clinical Trials.

Vaccines 2021, 9, 939. https://

doi.org/10.3390/vaccines9080939

Academic Editors:

Ralph J. DiClemente

and Ralph A. Tripp

Received: 14 July 2021

Accepted: 19 August 2021

Published: 23 August 2021

Publisher’s Note: MDPI stays neutral

with regard to jurisdictional claims in

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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, 939. https://doi.org/10.3390/vaccines9080939

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, 939

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isolate. Despite vaccination, breakthrough infections have been observed [2]. A safe and
effective vaccine against COVID-19 is a constructive medical strategy to protect suscep-
tible populations, slow the spread, and restore normal social order. The willingness of
the public to receive the COVID-19 vaccine has been surveyed and over 50% of partici-
pants either had a neutral attitude or questioned the safety of the vaccines [3–5]. With
vaccine development gaining momentum, adverse events of vaccinations have attracted
considerable attention. The commonly reported nervous and muscular adverse events
(NMAEs), including headache and myalgia, and occasional cases of Bell’s palsy, myelitis,
and cerebral venous thrombosis (CVT) after vaccination have caused some skepticism
and panic, even suspension of vaccination [6–10]. Moreover, according to the European
Database of suspected adverse drug reaction reports, NMAEs ranked in top and resulted
in relatively high mortality in four experimental vaccines [11]. However, the incidences
and state of NMAEs remain unclear. Therefore, NMAEs after vaccination must be summa-
rized and analyzed to reduce panic and expand the acceptance and coverage of vaccines,
especially since the threatening delta mutations of the virus have been observed in some
countries [12,13]. Herein, we present a systematic review and meta-analysis of the clinical
trials on the COVID-19 vaccine to evaluate the incidence of NMAEs after vaccination.

2. Materials and Methods

The guidelines of the Preferred Reporting Items for Systematic Reviews and Meta-
Analysis guidelines were followed. The review was registered with PROSPERO (CRD42021
240450) and reported according to PRISMA guidelines. The study protocol is available online.

2.1. Searches Strategy

A systematic search of the PubMed, Medline, Embase, Cochrane Library, and Chinese
National Knowledge Infrastructure databases was performed from the inception to 2 June
2021 using the Medical Subject Headings and the terms “COVID-19”; “vaccine”; “clinical
trials”. There were no language restrictions. Additionally, the ofﬁcial websites of the
vaccine developers were also searched.

2.2. Study Selection Criteria

The title and abstract of the identiﬁed publications were screened, and any potentially
eligible articles were retrieved for a full-text review. The inclusion criteria were (1) in terms
of population, individuals enrolled in the clinical trials of COVID-19 vaccine (including the
vaccine and control groups); (2) study designs were controlled clinical trials; (3) outcomes
were the safety of COVID-19 vaccines and the incidence of NMAEs after vaccination. The
exclusion criteria were (1) reviews, systematic reviews, meta-analysis, editorial, news,
conference proceedings, protocols, articles on diagnoses or drug treatments and (2) articles
focused on immunogenicity or efﬁcacy without complete data on adverse events. Two
reviewers (J.C. and Y. Cai) independently performed the study selection, and disagreements
were resolved through discussion or according to the judgment of a third reviewer (Y. Chen).
In the case of multiple reports from the same data set, the most recent or comprehensive
report was selected.

2.3. Data Extraction

For each included clinical trial, data on the study and patient characteristics were
extracted independently and in duplicate (J.C. and Y. Cai) using a standardized data
extraction sheet; afterward, the results were cross-checked. Discrepancies were resolved
by consensus or with the judgment of a third reviewer (Y. Chen). The extracted study and
patient characteristics included the publication dates, countries, vaccination platforms,
population, participants’ age, sample sizes, vaccines doses, placebo/control, and research
stages. The inactivated vaccine was classiﬁed as traditional vaccine, recombinant protein
vaccine, replication-incompetent vectors vaccine, and mRNA vaccine as newly licensed
vaccines [14]. According to the regulation on adverse events, NMAEs would be divided

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into the solicited and unsolicited ones [15,16]. The solicited NMAEs were listed in the
trial protocol and documented by diary card to ensure they were informed, while the
unsolicited NMAEs were unforeseeable and reported on participants’ own initiative. The
primary outcome was the incidences of NMAEs after COVID-19 vaccination, including
the solicited and unsolicited ones. Except for annotation, the numbers of NMAEs were
person-time, and a person who experienced vaccination twice would be recorded as 2 in
this study.

2.4. Quality Assessment

The study quality assessment was performed according to the validated scale for
randomized controlled trials recommended by Cochrane [17]. For each clinical trial, two
of the reviewers (J.C. and Y. Cai) assigned independent scores of high, low, or unclear
to each of the following domains: sequence generation, allocation concealment, blinding
of participants, blinding of outcome assessments, incomplete outcome data, selective
reporting, and other biases. Discrepancies in the quality assessments were resolved by
consensus or by a third reviewer (Y. Chen). We included all the eligible clinical trials,
regardless of their assessed quality.

2.5. Statistical Analysis

NMAEs after COVID-19 vaccination were analyzed using Pearson’s chi-square test
for categorical variables with SPSS 23.0 (SPSS Inc., Chicago, IL, USA). In the meta-analysis,
for each of the included studies, the differences in the frequencies of NMAEs with vaccine
versus control or baseline were pooled, stratiﬁed across the studies, and analyzed using
random-effects or ﬁxed-effects models with inverse variance weighting. Random-effects
models were used when the I2 statistics were used to estimate the proportion of variation
attributable to between-study heterogeneity of >50% or p < 0.1. Fixed-effects models were
used when the I2 was <50% or p > 0.5. The pooled effects on NMAEs were presented
as odds ratios (ORs) with corresponding 95% conﬁdence intervals (CIs). The statistical
analyses were performed using Review Manager (version 5.2; Copenhagen: The Nordic
Cochrane Centre, The Cochrane Collaboration, 2012). Publication bias was visualized by
funnel plots and measured by the Begg–Mazumdar rank correlation and the Egger bias
test conducted using STATA (version 11.2, StataCorp, College Station, TX 77845, USA).

3. Results

We identiﬁed 1613 studies from the databases and manual searches (Figure 1). After
the exclusion of 712 duplicates, 901 articles were reviewed based on their titles and abstracts,
of which 848 articles were excluded based on the article type (reviews, systematic reviews,
editorials, news, protocol and conference proceeding), and topic (symptom, diagnosis,
drug, or others). A total of 53 full-text articles were assessed for eligibility, of which
30 were excluded.
In total, 23 studies did not report the complete and clear data of
NMAEs, and the other 7 studies were the pre-prints or the data subsets to some newer
and more comprehensive studies. Finally, 23 articles met the inclusion criteria and were
included in the systematic review and meta-analysis [18–40]. The baseline characteristics
of the 23 included studies are summarized in Table 1. Overall, 15 randomized, blinded,
controlled phase 1/2 clinical trials revealed a low risk of bias (Figure S1) and enrolled in the
systematic review and meta-analysis [18–32]. Four open-label, without placebo-controlled
phase 1/2 trials and four phase 3 clinical trials were only included in the systematic
review [33–40]. The solicited and unsolicited NMAEs were clearly illustrated and can be
extracted from all included studies.

All reported NMAEs occurred within the period under the safety observation; most
were 7 days, and others were 14 or 28 days. The incidence of NMAEs was 29.2% in the
vaccine group and 21.6% in the control (p < 0.001) in a total of 15 randomized, blinded,
controlled clinical trials (Table S1). The I2 was 92% in the total NMAEs of 15 studies, and
meta-analysis could not be performed.

Vaccines 2021, 9, 939

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However, both headache and myalgia accounted for 98.2% and 97.7%, while the
remaining others, including dizziness, drowsiness, hypoesthesia, etc., only accounted for
1.8% and 2.3% in the vaccine and control groups, respectively. As the solicited adverse
reaction of the safety set, headache and myalgia had more detailed information recorded
and low published bias for meta-analysis, although the I2 was 79% and 68%, respectively
(Figure S2). The incidences of headache and myalgia were 16.4% vs. 13.9% (OR = 1.97, 95%
CI = 1.28–3.06, p = 0.002) and 16.0% vs. 7.9% (OR = 3.31, 95% CI = 2.05–5.35, p < 0.001) in
vaccine and control groups, respectively (Figure 2). In the subgroup analysis (Figure 3),
the newly licensed vaccines had more headache and myalgia, compared with the con-
trol groups (OR = 2.58, 95% CI = 1.72–3.87, p < 0.001 and OR = 4.58, 95% CI = 3.71–5.64,
p < 0.001, respectively), while the inactivated vaccines had no differences. Differences in the
incidences of headache and myalgia were signiﬁcant neither between the ﬁrst and second
vaccination doses nor between the high, moderate, and low doses (all p > 0.05). However,
headache and myalgia were more frequent in younger adults than in the older participants
(OR = 1.40, 95% CI = 1.12–1.75, p = 0.003 and OR = 1.54, 95% CI = 1.20–1.96, p < 0.001,
respectively). After excluding the extra high-dose group, headache and myalgia were signif-
icantly different between the younger and older (OR = 1.29, 95% CI = 1.01–1.65, p = 0.04 and
OR = 1.55, 95% CI = 1.21–1.99, p < 0.001, respectively). In a study by Folegatti [24], headache
and myalgia were not signiﬁcantly different with or without prophylactic paracetamol, in
either the vaccine or the control groups (Table S2).

Figure 1. PRISMA ﬂowchart describing systematic literature search and study selection. Data of
some vaccines published in the developer’s ofﬁcial websites or pre-print were duplicated with the
published articles. The included phase 3 clinical trials partly contained data of phase 1 and/or 2.
CNKI = Chinese National Knowledge Infrastructure databases.

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4 of 18 

Figure 1. PRISMA flowchart describing systematic literature search and study selection. Data of 

some vaccines published in the developer's official websites or pre-print were duplicated with the 

published articles. The included phase 3 clinical trials partly contained data of phase 1 and/or 2. 

CNKI = Chinese National Knowledge Infrastructure databases. 

 

 

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Table 1. Baseline characteristics of the included clinical trials of COVID-19 vaccines.

Vaccine Platform

Sample Size of Study

Dosage of Vaccine

Control

Current Status of Clinical Trial

5 × 1010 viral particles/mL

1 or 2

MenACWY vaccine

Suspended in some regions

Xia 2020 [18]

Inactivated vaccine

Xia 2020(2) [19]

Inactivated vaccine

Phase 1: 96, Phase2: 224

Randomized, blinded, controlled phase 1/2 clinical trials

Author/
Year of Published

Wu 2021 [20] and
Zhang 2021 [21]
Raches 2021 [22] and
Raches 2021(2) [23]

Folegatti 2020 [24]

Zhu 2020 [25]

Keech 2020 [26]
Richmond 2021 [27]
Chappell 2021 [28]

Yang 2021 [29]

Chu 2021 [30]

Walsh 2020 [31]

Mulligan 2020 [32]

Logunov 2020 [33]

Zhu 2020(2) [34]

Jackson 2020 [35] and
Anderson 2020 [36]

Kaabi 2021 [37]

Voysey 2020 [38]

Logunov 2021 [39]

Baden 2020 [40]

Inactivated vaccine

Inactivated vaccine

Replication-incompetent
vectors vaccine
Replication-incompetent
vectors vaccine
Recombinant protein vaccine
Recombinant protein vaccine
Recombinant protein vaccine

mRNA vaccine

mRNA vaccine

mRNA vaccine

Replication-incompetent
vectors vaccine
Replication-incompetent
vectors vaccine

mRNA vaccine

Inactivated vaccine
Replication-incompetent
vectors vaccine
Replication-incompetent
vectors vaccine
mRNA vaccine

Phase 1: 96,
Phase 2: 448

18~59:744
≥60: 422

375

1077

508

131
151
120

600

195

45

76

108

85

40,411

23,843

21,977

30,420

Recombinant protein vaccine

Phase 1: 50, Phase2: 900

2 µg, 4 µg, 8 µg

2.5 µg, 5 µg, 10 µg

1.5 µg, 3 µg, 6 µg

3 µg, 6 µg

1 × 1011 or 5 × 1010 viral
particles/mL
5 µg, 25 µg
3 µg, 9 µg, 30 µg
5 µg, 15 µg, 45 µg

25 µg, 50 µg

50 µg, 100 µg

10 µg, 20 µg, 30 µg, 100 µg

10 µg, 30 µg, 100 µg

Vac 0.5 mL,
Vac-Lyo 1.0 mL
5 × 1011 or 1 × 1011 or
5 × 1010 viral particles/mL

Open-label phase 1/2 clinical trials

Age of Subjects
(Year)

18~80

18~59

18~59,
≥60

18~55

18~55

≥18

18~59
18~54, 55~75
18~55

18~59

18~55, ≥55
18~55,
65~85
18~55

18~60

18~60

≥18

≥18

≥18

≥18

Number of
Vaccination

1 or 2

2 or 3

1 or 2
2
1 or 2

2 or 3

1 or 2

1 or 2

1 or 2

2

2

1

2

1

2

2

2

2

2

18~55, 56~70, ≥71

25 µg, 100 µg, 250 µg

No, open-label

Phase 3 ongoing

Phase 3 clinical trials *

5 µg, 4 µg
(3.5–6.5) × 1010 or
2.2 × 1010 viral particles/mL

0.5 mL

100 µg

Alum adjuvant and saline

Ongoing

MenACWY vaccine

Suspended in some regions

Vaccine buffer

Saline

Ongoing

Ongoing

*: All studies included the data of phase 3 clinical trials, partly contained data of phase 1/2. MenACWY vaccine = meningococcal group A, C, W, and Y conjugate vaccine.

Saline containing aluminium
hydroxide
Aluminum hydroxide (alum)
adjuvant
Aluminium hydroxide
diluent solution
Sterile solution and
adjuvants

Phase 3 ongoing

Phase 3 ongoing

Phase 3 ongoing

Phase 2 ongoing

Vaccine excipients

Phase 3 ongoing

Saline
Saline
Saline
Aluminium hydroxide in
buffer
Saline

Saline

Saline

Phase 3 in preparation
Phase 2 ongoing
Phase 2 ongoing

Phase 3 ongoing

Phase 3 ongoing

Phase 3 ongoing

Phase 3 ongoing

No, open-label

Phase 3 ongoing

No, open-label

Phase 3 ongoing

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Figure 2. Forest plot analysis of the incidence of headache (a) and myalgia (b) on the vaccine and control groups. An odd
ratio of >1 is indicative of a higher incidence of headache and myalgia in the vaccine group, compared to the control group.
A Mante–Haenszel variance random-effects model (M–H, random) was employed to estimate effects between vaccine and
control groups. I2 statistic, 95% conﬁdence interval (CI), and point estimates are displayed and diamond is presented the
pooled effect.Forest plot analysis of the incidence of headache (a) and myalgia (b) on the vaccine and control groups. An
odd ratio of >1 is indicative of a higher incidence of headache and myalgia in the vaccine group, compared to the control
group. A Mante–Haenszel variance random-effects model (M–H, random) was employed to estimate effects between
vaccine and control groups. I2 statistic, 95% conﬁdence interval (CI), and point estimates are displayed and diamond is
presented the pooled effect.

Vaccines 2021, 9, x FOR PEER REVIEW 

 

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All reported NMAEs occurred within the period under the safety observation; most 

were 7 days, and others were 14 or 28 days. The incidence of NMAEs was 29.2% in the 

vaccine group and 21.6% in the control (p < 0.001) in a total of 15 randomized, blinded, 

controlled clinical trials (Table S1). The I2 was 92% in the total NMAEs of 15 studies, and 

meta-analysis could not be performed. 

However, both headache and myalgia accounted for 98.2% and 97.7%, while the re-

maining  others, including dizziness,  drowsiness,  hypoesthesia, etc.,  only accounted  for 

1.8% and 2.3% in the vaccine and control groups, respectively. As the solicited adverse 

reaction of the safety set, headache and myalgia had more detailed information recorded 

and low published bias for meta-analysis, although the I2 was 79% and 68%, respectively 

(Figure S2). The incidences of headache and myalgia were 16.4% vs. 13.9% (OR = 1.97, 95% 

CI = 1.28–3.06, p = 0.002) and 16.0% vs. 7.9% (OR = 3.31, 95% CI = 2.05–5.35, p < 0.001) in 

vaccine and control groups, respectively (Figure 2). In the subgroup analysis (Figure 3), 

the newly licensed vaccines had more headache and myalgia, compared with the control 

groups (OR = 2.58, 95% CI = 1.72–3.87, p < 0.001 and OR = 4.58, 95%CI = 3.71–5.64, P < 0.001, 
respectively), while the inactivated vaccines had no differences. Differences in the inci-
dences  of  headache  and  myalgia  were  significant  neither  between  the  first  and  second 
vaccination doses nor between the high, moderate, and low doses (all p > 0.05). However, 
headache and myalgia were more frequent in younger adults than in the  older partici-
pants (OR = 1.40, 95% CI = 1.12–1.75, p = 0.003 and OR = 1.54, 95% CI = 1.20–1.96, p < 0.001, 
respectively). After excluding the extra high-dose group, headache and myalgia were sig-
nificantly different between the younger and older (OR = 1.29, 95% CI = 1.01–1.65, p = 0.04 
and OR = 1.55, 95% CI = 1.21–1.99, p < 0.001, respectively). In a study by Folegatti [24], 
headache and myalgia were not significantly different with or without prophylactic para-
cetamol, in either the vaccine or the control groups (Table S2). 

(a) 

 

 

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(b) 

 

Figure 2. Forest plot analysis of the incidence of headache (a) and myalgia (b) on the vaccine and control groups. An odd 

ratio of >1 is indicative of a higher incidence of headache and myalgia in the vaccine group, compared to the control group. 

A Mante–Haenszel variance random-effects model (M–H, random) was employed to estimate effects between vaccine and 

control groups. I2 statistic, 95% confidence interval (CI), and point estimates are displayed and diamond is presented the 

pooled effect. 

(a1) 

 

 

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Figure 3. Cont.

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8  of  18 

(b) 

 

Figure 2. Forest plot analysis of the incidence of headache (a) and myalgia (b) on the vaccine and control groups. An odd 
ratio of >1 is indicative of a higher incidence of headache and myalgia in the vaccine group, compared to the control group. 
A Mante–Haenszel variance random-effects model (M–H, random) was employed to estimate effects between vaccine and 
control groups. I2 statistic, 95% confidence interval (CI), and point estimates are displayed and diamond is presented the 
pooled effect. 

(a1) 

 

 

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9  of  18 

(b1) 

(a2) 

(b2) 

 

 

 

 

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Figure 3. Cont.

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9  of  18 

(b1) 

(a2) 

(b2) 

 

 

 

 

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Figure 3. Cont.

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(a3) 

(b3) 

(a4) 

 

 

 

 

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Figure 3. Subgroup analysis of headache and myalgia. Vaccine platform on headache (a1) and myalgia (b1); vaccine dose
on headache (a2) and myalgia (b2); the 1st and 2nd vaccination on headache (a3) and myalgia (b3); age of participant on
headache (a4) and myalgia (b4); age of participant (adjusted) on headache (a5) and myalgia (b5). Traditional vaccine is
inactivated vaccine, and the newly licensed vaccines include replication-incompetent vectors vaccine, recombinant protein
vaccine, and mRNA vaccine. An odd ratio of >1 is indicative of a higher incidence of headache and myalgia in the vaccine
group, compared to the control group. A Mantel–Haenszel variance random-effects model (M–H, random) was employed
to estimate effects between vaccine and control groups. I2 statistic, 95% conﬁdence interval (CI), and point estimates are
displayed and diamond is presented the pooled effect.

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(b4) 

(a5) 

(b5) 

 

 

 

Figure 3. Subgroup analysis of headache and myalgia. Vaccine platform on headache (a1) and myalgia (b1); vaccine dose 

on headache (a2) and myalgia (b2); the 1st and 2nd vaccination on headache (a3) and myalgia (b3); age of participant on 

headache (a4) and myalgia (b4); age of participant (adjusted) on headache (a5) and myalgia (b5). Traditional vaccine is 

inactivated vaccine, and the newly licensed vaccines include replication-incompetent vectors vaccine, recombinant protein 

vaccine, and mRNA vaccine. An odd ratio of >1 is indicative of a higher incidence of headache and myalgia in the vaccine 

group, compared to the control group. A Mantel–Haenszel variance random-effects model (M–H, random) was employed 

to estimate effects between vaccine and control groups. I2statistic, 95% confidence interval (CI), and point estimates are 

displayed and diamond is presented the pooled effect. 

 

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In four open-label, without placebo-controlled clinical trials, the incidences of headache,
myalgia, and other NMAEs were 38.7%, 27.4%, and 1.5%, respectively (Table S3) [33–36].
In the four phase 3 clinical trials, the person-times of NMAEs were reported, while
the vaccination times in participants were disarranged [37–40]. The incidences of headache
and myalgia were 29.5% vs. 21.0% (p < 0.001) and 19.2% vs. 8.4% (p < 0.001) in the vaccine
and control groups, respectively (Table S4). In the study by Baden [40], headache and
myalgia were more common after the second vaccination and younger adults than those
after the ﬁrst vaccination and in older groups (all p < 0.05, Table S5). In addition, this study
showed the duration of solicited adverse reactions after vaccination. In the vaccine group,
headache and myalgia lasted (2.1 ± 2.2) days and (2.3 ± 3.2) days after the ﬁrst vaccination,
and (2.3 ± 2.9) days and (2.1 ± 3.1) days after the second dosage, respectively.

The highest incidence of unsolicited NMAEs after COVID-19 vaccination was 0.7%,
and all of them were not signiﬁcantly different from the controls in phase 3 clinical trials
(all p > 0.05, Table 2). In the inactivated vaccine, cranial nerve lesions mainly manifested
as dysphagia, accounted for 97.3% of all the unsolicited NMAEs [37]. In one study of the
replication-incompetent vectors vaccines, sensory disorders were 68.2% of the unsolicited
NMAEs. In two cases of transverse myelitis, one was considered possibly related to the
vaccine, the other was considered potentially related at ﬁrst, then determined to be unlikely
related to the vaccine [38]. In the other study of replication-incompetent vectors vaccines,
the cranial nerve lesions including taste disorders, visual impairments, and noises in the
ears, were reported after the second vaccination dose [39]. In the study of the mRNA
vaccine, three of the four Bell’s palsy occurred in the vaccine group over 28 days after
vaccination, which is not listed in Table 2 [40].

Vaccines 2021, 9, 939

12 of 17

Table 2. Other nervous and muscular adverse events after COVID-19 vaccination in phase 3 clinical trials.

Inactivated Vaccine

Replication-Incompetent Vectors Vaccine

Kaabi 2021 [37]

Voysey 2020 [38]

Logunov 2021 [39]

Vaccine

WIV04
n = 13,464

HB02
n = 13,471

Control
n = 13,453

Vaccine
n = 12,021

Control
n = 11,724

Vaccine

Control

At Least
One Dose
n = 16,427

Two Dose
n = 9258

At Least
One Dose
n = 5435

Two Dose
n = 3038

Systemic neurological
symptoms *

Confusional state,
drowsiness

Seizure/tonic convulsion
Cranial nerve lesions †
Cerebrovascular events ‡
Spinal cord events §
Motor disorder ¶

Sensory disorder ||

Neuralgia, neuritis

Muscle spasms/
facial spasm

Autonomic nerve
dysfunction **

0

NA

NA

51

NA

0

NA

NA

NA

NA

NA

1

NA

NA

58

NA

2

NA

NA

NA

NA

NA

0

NA

NA

62

NA

0

NA

NA

NA

NA

NA

NA

NA

9

6

2

4

1

4

1

1

10

NA

NA

10

4

2

3

1

0

0

60

63

NA

NA

NA

NA

NA

NA

1

3

0

1

1

NA

1

6

NA

NA

NA

NA

1

NA

NA

1

NA

NA

NA

NA

NA

NA

0

2

1

0

0

NA

0

1

NA

NA

NA

NA

1

NA

NA

0

mRNA Vaccine

Baden 2020 [40]

Vaccine
n = 15,185

Control
n = 15,166

14

19

NA

NA

2

0

5

3

2

0

0

NA

NA

0

2

1

3

0

2

1

NA

NA

Total, No. (%)

51 (0.4)

61 (0.5)

62 (0.5)

88 (0.7)

93 (0.8)

6 (<0.1)

9 (<0.1)

3 (<0.1)

2 (<0.1)

26 (0.2)

28 (0.2)

* Included migraine, dizziness, vertigo, syncope, presyncope, muscle weakness, pathological changes in nervous system. † Included facial paralysis, Bell’s palsy, visual impairment, blindness transient, noise
in ears, metallic taste, dysphagia. ‡ Included ischemic stroke, hemorrhagic stroke, cerebrovascular accident, embolic stroke, subarachnoid hemorrhage, transient ischemic attack, cerebral circulation failure,
vertebrobasilar insufﬁciency, vascular encephalopathy. § Included myelitis, myelitis transverse, multiple sclerosis attacks, clinically isolated syndrome, acute disseminated encephalomyelitis. ¶ Included
monoparesis, hemiparesis, gait disturbance, vestibular ataxia, fall. || Included paresthesia, sensory disturbance, sensory loss, hyperesthesia, hypoesthesia, dysesthesia. ** Included anal incontinence, disorder of
autonomic nerve system. NA = not available. No. = number.

Vaccines 2021, 9, 939

13 of 17

4. Discussion

Although the emergency use authorization for some COVID-19 vaccines has been
approved by the government and World Health Organization, NMAEs after vaccination
have yet been comprehensively discussed. In the present study, we found that NMAEs
occurred in 29.2% of the vaccinated participants in phase 1/2 clinical trials, with headache
and myalgia being the most common and more frequent in the newly licensed vaccines and
younger adults. In each phase 3 clinical study, headache and myalgia were still common,
although the unsolicited NMAEs with incidence rates of ≤0.7% were not signiﬁcantly
different from the controls. These results indicate that following the COVID-19 vacci-
nation, NMAEs, especially headache and myalgia, were common, although the severe
life-threatening ones were rare.

Subgroup analysis demonstrated that the incidences of headache and myalgia were
more common in the newly licensed vaccines than those in the controls but not in the
inactivated vaccine, which means that inactivated vaccine may have favorable safety
and tolerability [41–44]. The previous studies suggest that RNA-based vaccines had
higher side effects in reactogenicity. The adenovirus-vectored vaccines are associated with
increased diarrhea and arthralgia. Inactivated vaccines had fewer side effects, which may
be associated with the mechanism, the mature technology, the alum-adjuvanted, or other
factors [42,45]. However, this has resulted from the limited data of phase 1/2 clinical trials
and a high level of heterogeneity between the studies. The data from the ongoing phase
3 trials deserve expectation.

Generally, the dosage is closely related to adverse reactions. However, in the current
study, the incidences of headache and myalgia had no differences between the high, mod-
erate dose and low dose, or between the ﬁrst and second vaccination doses. No signiﬁcant
correlation between the dose and adverse events occurrence was found, consistent with the
previous literature about COVID-19 vaccines [43,46]. Different vaccines have varied doses.
The number of active ingredients contained in each milliliter vaccine should be used as the
basis for comparing doses between different vaccines but not the total volume including
various adjuvant [44]. A lack of standardized dosage grading means cross-comparison
of safety, and the dose is limited. Additionally, different trials had different periods for
observation of the safety, most of which were 7 days, and others were 14 or 28 days.
Therefore, the dose-related safety required more accurate vaccine dosage and restricted
follow-up time.

Another related factor of safety that deserves attention is the age of the participant.
Here, the included participants of COVID-19 vaccines were healthy adults above 18 years
of age. However, the majority of clinical trials did not cover population > 60 years of age
that is particularly at risk for illness and death from COVID-19 [47,48]. We found that the
incidences of headache and myalgia were signiﬁcantly higher in younger adults than in
older. Previous studies observed that binding-antibody levels in those above 70 years of age
were low after COVID-19 vaccination [31,49]. This may indicate that the immune responses
in the older population are relatively lower, and age-related immunosenescence may
account for the low incidence of adverse events [6,7,50]. Although we did not analyze the
binding-antibody levels after vaccination, these results suggest that the older individuals
vulnerable to COVID-19 are not at risk of available vaccination.

Since few studies have reported the detailed date, the onset and lasting time of
headache and myalgia after vaccination cannot be concluded. Safety data on COVID-19
vaccines need to be disclosed further to implement the appropriate measures quickly.

The neurotropism of the coronavirus and its systematic or focal neurological complica-
tions, including headache, cranial nerve lesions (anosmia and dysgeusia), stroke, myelitis,
etc., have been well recognized [51,52]. Additionally, the spike protein, the receptor-binding
domain, and other structural proteins have become the antigenic target for COVID-19
vaccines, which have an essential role in inducing speciﬁc immune responses [14]. In the
four phase 3 clinical trials, headache and myalgia still ranked in the top of NMAEs and
could not be prevented by paracetamol, but most of them were relieved spontaneously

Vaccines 2021, 9, 939

14 of 17

without treatment. However, other NMAEs were low and had no statistical differences
between the vaccine and control groups. Although 17 cases of cerebrovascular events were
recorded, no deﬁnite CVT was reported. Recently, CVT following COVID-19 vaccination
has been a topic of concern in two mRNA vaccines and one replication-incompetent vec-
tor vaccine [9,10,53,54]. The events occurred more in women under 60 years of age with
headaches initially after vaccination, similar to the other typical CVT [9,10,53,54]. Therefore,
severe and persistent headaches after vaccination could be the initial and unique symptom
of CVT and should be considered and continuously monitored during the ongoing global
COVID-19 vaccination program [10,55].

Several limitations are inherent to this study. As with all systematic reviews and
meta-analyses, the potential for publication bias exists. Additionally, there was a high level
of heterogeneity between the studies and a lack of more detailed information and control
groups in some trials. Such unmeasured confounding variables may have inﬂuenced our
results. The related data update quickly and have a possibility of omission. Moreover,
the follow-up time of phase 1/2 clinical trials was not long enough, and their phase 3
trials are still ongoing. Despite these limitations, in this systemic review and meta-analysis,
we calculated and analyzed the pooled event rate of NMAEs in the COVID-19 vaccines,
providing a theoretical basis and recommendations for subsequent development and
clinical applications.

Supplementary Materials: The following are available online at https://www.mdpi.com/article/10.3
390/vaccines9080939/s1. Figure S1: Risk-of-bias graph and risk-of-bias summary of the included
studies, Figure S2: Funnel diagram, Begg–Mazumdar rank correlation, and Egger’s bias test of
publication bias of headache and myalgia, Table S1: Nervous and muscular adverse events in phase
1/2 randomized, blinded, and controlled clinical trial after COVID-19 vaccination, Table S2: The
incidences of headache and myalgia with or without prophylactic paracetamol, Table S3: Nervous
and muscular adverse events in phase 1/2 open-label clinical trial of COVID-19 vaccination, Table S4:
Headache and myalgia in phase 3 clinical trial of COVID-19 vaccination, Table S5: Headache and
myalgia subgroup in study of Baden 2020.

Author Contributions: J.Z. and Y.G. had full access to all the data in the study and takes responsibility
for the integrity of the data and the accuracy of the data analysis. Study concept and design, J.Z. and
Y.G.; acquisition, analysis, or interpretation of data, J.C., Y.C. (Yuangui Cai) and Y.C. (Yicong Chen);
drafting of the manuscript, J.C. and Y.C. (Yuangui Cai); critical revision of the manuscript for
important intellectual content, J.Z, Y.G. and A.P.W.; statistical analysis: J.C. and Y.C. (Yuangui Cai);
administrative, technical, or material support, J.Z. and Y.G.; study supervision, J.Z., Y.G. and A.P.W.
All authors have contributed signiﬁcantly, and are in agreement with the content of the manuscript.
All authors have read and agreed to the published version of the manuscript.

Funding: This research received no external funding.

Institutional Review Board Statement: Not applicable.

Informed Consent Statement: Not applicable.

Data Availability Statement: The datasets used and analyzed during the current study are available
from the corresponding author on reasonable request.

Acknowledgments: We express our gratitude to the Guangdong Provincial Key Laboratory of
Diagnosis and Treatment of Major Neurological Diseases (2020B1212060017), Guangdong Provincial
Clinical Research Center for Neurological Diseases (2020B1111170002), Southern China International
Cooperation Base for Early Intervention and Functional Rehabilitation of Neurological Diseases
(2020A0505020004), Guangzhou Clinical Research and Translational Center for Major Neurological
Diseases (201604020010), Guangdong Provincial Engineering Center for Major Neurological Disease
Treatment, Guangdong Provincial Translational Medicine Innovation Platform for Diagnosis and
Treatment of Major Neurological Disease.

Conﬂicts of Interest: The authors declare no conﬂict of interest.

Vaccines 2021, 9, 939

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