International  Journal  of
Environmental Research
and Public Health
Article
Side-Effects following Oxford/AstraZeneca COVID-19 Vaccine
in Tororo District, Eastern Uganda: A Cross-Sectional Study
Jagire Onyango 1, David Mukunya 1,2,*, Agnes Napyo 1, Ritah Nantale 3, Brian T. Makoko 1,
Joseph K. B. Matovu 1,4, Benon Wanume 1, David Okia 1, Francis Okello 1, Sam Okware 5,
Peter Olupot-Olupot 1,6 and Yovani Lubaale 1
1 Department of Community and Public Health, Busitema University, Mbale P.O. Box 236, Uganda
2 Department of Research, Nikao Medical Center, Kampala P.O. Box 10005, Uganda
3 Department of Nursing, Busitema University, Mbale P.O. Box 236, Uganda
4 Department of Disease Control and Environmental Health, Makerere University School of Public Health,
Kampala P.O. Box 7072, Uganda
5 Department of Research, Uganda National Health Research Organizations, Kampala P.O. Box 465, Uganda
6 Department of Research, Mbale Clinical Research Institute, Mbale P.O. Box 1966, Uganda
* Correspondence: dmukunya@fhs.busitema.ac.ug
Abstract: Effective, safe and proven vaccines would be the most effective strategy against the
COVID-19 pandemic but have faced rollout challenges partly due to fear of potential side-effects.
We assessed the prevalence, profiles, and predictors of Oxford/AstraZeneca vaccine side-effects
in Tororo district of Eastern Uganda. We conducted telephone interviews with 2204 participants
between October 2021 and January 2022. Multivariable logistic regression was conducted to assess
Citation: Onyango, J.; Mukunya, D.; factors associated with Oxford/AstraZeneca vaccine side-effects using Stata version 15.0. A total of
Napyo, A.; Nantale, R.; Makoko, B.T.;
603/2204 (27.4%) of the participants experienced one or more side-effects (local, systemic, allergic,
Matovu, J.K.B.; Wanume, B.; Okia, D.;
and other side-effects). Of these, 253/603 (42.0%) experienced local side-effects, 449/603 (74.5%)
Okello, F.; Okware, S.; et al.
Side-Effects following experienced systemic side-effects, 11/603 (1.8%) experienced allergic reactions, and 166/603 (27.5%)
Oxford/AstraZeneca COVID-19 experienced other side-effects. Ten participants declined to receive the second dose because of
Vaccine in Tororo District, Eastern side-effects they had experienced after the first dose. Previous infection with COVID-19 (adjusted
Uganda: A Cross-Sectional Study. Int. odds ratio (AOR): 4.3, 95% confidence interval (95% CI): 2.7–7.0), being female (AOR: 1.3, 95% CI:
J. Environ. Res. Public Health 2022, 19, 1.1–1.6) and being a security officer (AOR: 0.4, 95% CI: 0.2–0.6) were associated with side-effects to the
15303. https://doi.org/10.3390/ Oxford/AstraZeneca vaccine. We recommend campaigns to disseminate correct information about
ijerph192215303 potential side-effects of the Oxford/AstraZeneca vaccine and strengthen surveillance for adverse
Academic Editors: Jon Øyvind events following vaccination.
Odland and Elisabeth Darj
Keywords: side-effects; COVID-19; Oxford/AstraZeneca vaccine; Uganda
Received: 13 October 2022
Accepted: 15 November 2022
Published: 19 November 2022
Publisher’s Note: MDPI stays neutral 1. Introduction
with regard to jurisdictional claims in Globally, countries are grappling with low coronavirus disease 2019 (COVID-19)
published maps and institutional affil- vaccine acceptance, even though vaccines are known to save lives [1]. The hesitancy
iations. is partly caused by the fear of vaccine side-effects [2]. Furthermore, the hasty manner
with which vaccines under emergency authorization, such as the COVID-19 vaccines, are
approved resulted in unease among some members of the scientific community. The World
Health Organization (WHO) estimates that immunization programs worldwide prevent
Copyright: © 2022 by the authors.
Licensee MDPI, Basel, Switzerland. 2–3 million deaths from vaccine-preventable diseases every year [3], and are not only cost-
This article is an open access article effective but an essential element of preventative healthcare. Vaccines work with our body’s
distributed under the terms and natural defenses to build protection against diseases in a process called immunization.
conditions of the Creative Commons A study conducted in the United Kingdom compared infection rates among a subset of
Attribution (CC BY) license (https:// vaccinated individuals reported a significant buildup of immunity after 12 days following
creativecommons.org/licenses/by/ vaccination with Oxford/AstraZeneca [4]. This interaction and other aspects of vaccines
4.0/). may cause untoward experiences such as swelling, pain, redness at the injection site, fever,
Int. J. Environ. Res. Public Health 2022, 19, 15303. https://doi.org/10.3390/ijerph192215303 https://www.mdpi.com/journal/ijerph
Int. J. Environ. Res. Public Health 2022, 19, 15303 2 of 10
headache, dizziness, joint pain, fainting, nausea, vomiting, diarrhea, and a rash among the
vaccine recipients.
Vaccines are also critical to the prevention and control of infectious disease outbreaks;
therefore, an effective, safe, proven and widely acceptable COVID-19 vaccine would be a
great tool for controlling the pandemic [5]. Immunization is one of the most cost-effective
health investments with proven strategies that make it accessible to even the most hard-
to-reach and vulnerable populations [6]. However, not only does a vaccine need to be
safe and effective, it also must be accepted by those at greatest risk of harm from the
disease [7]. COVID-19 vaccine acceptance by a large proportion of the population would
also offer protection to the other people who remain unimmunized, a phenomenon called
herd immunity. Reported serious side-effects, inconsistent information, conspiracy theories,
and geopolitics seem to be the drivers of poor acceptance at this level.
Uganda initially acquired about 900,000 doses of Oxford/AstraZeneca vaccine (Cov-
ishield), manufactured by the serum institute of India, and embarked on the vaccination
campaign in earnest. However, low vaccine acceptance and hesitancy in Uganda are
common [8]. This could be attributed to fear of potential risks that can be encountered, pri-
marily where a vaccine has not been well evaluated [8]. As of 30 April 2021, the vaccination
coverage in Uganda was at 330,077/990,000 of the available doses, representing about 33%
achievements for the country (MOH press statement on COVID-19 updates). However, by
the same date, the Tororo district had posted well over 85.9% utilization, with 6865 doses
of the available 8000 dispensed, showing a fairly good acceptance. A study conducted
in Western Uganda concluded that government needs to prioritize vaccine acceptance
strategies, especially among the risky groups in the community, to ensure a successful
vaccination process [8]. The same study found that the level of vaccine acceptance (53.6%)
and risk perception (46.7%) was relatively average in Western Uganda. High-risk groups
such as health workers are targeted with this vaccine to ensure stability in the system
in case an overwhelming epidemic threatens to derail service delivery. The surveillance
system in place may not be relied upon to provide conclusive data on adverse events fol-
lowing immunization. Anecdotal evidence suggests that there have been varying untoward
experiences with the vaccine that need to be investigated. In this study, we determined the
prevalence, profiles, and predictors of Oxford/AstraZeneca vaccine side-effects among the
vaccine recipients in the Tororo district of Eastern Uganda.
2. Materials and Methods
2.1. Study Design
This was a cross-sectional analytical study, on prevalence and predictors of Ox-
ford/AstraZeneca vaccine side-effects among vaccine recipients in Tororo district com-
munity members, using quantitative methods. The population-based survey used secondary
data extracted from COVID-19 vaccination registers and a telephone questionnaire interview.
2.2. Study Setting
The study was conducted in the Tororo district of Eastern Uganda, targeting all five
vaccination sites allocated COVID-19 vaccination materials, for the initial phase of vacci-
nation in Tororo district. Tororo district comprises 17 rural sub-counties, 2 town councils,
and 2 municipal divisions. The district has a population of 597,500, with 291,300 males and
306,200 females [9]. The COVID-19 vaccination sites included: Tororo General Hospital,
the three Health Center (HC) IVs (Mukuju, Mulanda, and Nagongera), and Osukuru HCIII.
Uganda’s primary health care system is structured along the local government setup. The
HCIII is a sub-county facility that offers all the services offered in HCII, plus maternity
services, including facility delivery of expectant mothers. The staffing includes a midwife,
a health assistant, and a records person. It is headed by a senior clinical officer, assisted by
a clinical officer. The HCIV is a county facility that offers similar services as HCIII services
and also serves as a referral facility for the lower units in the county, as well as providing
emergency obstetric care, including cesarean sections. It is headed by a senior medical
Int. J. Environ. Res. Public Health 2022, 19, 15303 3 of 10
officer, assisted by a medical officer, a senior nursing officer, and a midwife. Allocation
was guided by the initial registration of health workers and the available teachers, per the
district registry records at the District Education Office. The vaccination exercise was under
the direct supervision of immunization focal persons that mobilized and supervised teams
of nurses, midwives, and data clerks, who put the vaccination and data entry into the
registers. The health officer in charge of these facilities was responsible for doing overall
supervision of the exercise, among other programs. The exercise was initially facility-based,
but later involved targeted outreaches for organized entities, such as schools and factories.
2.3. Study Population
All the COVID-19 vaccine adult recipients, as listed in the COVID-19 vaccination
registers of the five participating sites, with complete information in Tororo district, were
eligible for this study. We excluded vaccine acceptors with hearing impairment, those
without functional telephone contacts, those unable to sustain a telephone interview, and
those that did not provide informed consent.
2.4. Sample Size
We enrolled all eligible participants, totaling 2204 between October 2021 and January
2022. This yielded a high (0.6% to 2.1%) absolute precision (half width of the 95% confidence
interval) for side-effect prevalence estimates ranging from 2% to 50%.
2.5. Data Extraction
Personal profile data were derived from a review of the COVID-19 vaccination registers
as secondary data sources, namely participants’ ID, client name, sex, and telephone contact,
except for additional information that was included in the questionnaire. We used a
data extraction tool to generate this data, as it was already collected in the COVID-19
vaccine registers.
2.6. Data Collection Methods
The cross-sectional observational study used telephone interviews for data collection.
Training of research assistants ensured that they were familiar with the tool and could use
it to collect quality data. Trained research assistants conducted questionnaire interviews
with those with functional telephone contacts. They gathered data on side effects, related
information (such as the previous infection with COVID-19), and other additional sociode-
mographic data. All the 2204 participants included in this study had functional telephone
contacts. For those who died, we interviewed their caregivers or next of kin, as they were
the ones who picked up the calls.
2.7. Measurement of Variables
The outcome variable was a side effect, following vaccination with AstraZeneca. It
was defined as any untoward feeling experienced by a person, after being vaccinated. A
question was asked, “Did you experience any of these listed side effects or untoward feel-
ings after receiving the AstraZeneca vaccine?” The list included local side-effects, defined
as: pain at the injection site, redness, swelling of lymph nodes, and local swelling; systemic
side effects, defined as: tiredness, headache, nausea, diarrhea, vomiting, breathlessness,
fainting, fever, muscle pains, joint pains, and chills; allergic side-effects, defined as: rash,
skin burning, and red welts on face and lips; and other side effects.
The exposure variables included potential factors associated with Oxford/AstraZeneca
vaccine side-effects. These were adopted from literature and included sociodemographic
factors such as age, sex, education, religion, marital status, occupation, and residence.
Others were individual participant characteristics such as vaccination status, previous
infection with COVID-19, comorbidities, and healthcare-seeking behavior.
Int. J. Environ. Res. Public Health 2022, 19, 15303 4 of 10
2.8. Statistical Analysis
First, we conducted exploratory data analyses to check the cleanliness of the data. We
then summarized categorical data as proportions and continuous data using measures of
central tendency [mean (SD), median (IQR)]. We conducted multivariable logistic regression
to determine the factors associated with Oxford/AstraZeneca vaccine side-effects. Factors
known to be associated with Oxford/AstraZeneca vaccine side-effects from the literature
(for example, age, sex), and factors from the bi-variable analysis with a p-value less than
0.2 (occupation, education level, marital status) were included in the multivariable analysis.
We used Stata version 15.0 for analysis.
3. Results
3.1. Participant Characteristics
A total of 2204 participants were recruited, of whom 68.7% (1515/2204) were less than
50 years old. The majority, 59.4% (1310/2204), were male. In terms of education, more than
half, 57.4% (1264/2204), had tertiary education. Concerning religion, the majority (88.7%)
were Christians. Most of the participants, 86.2% (1900/2204), were married. In terms
of occupation, the majority of the population were teachers, 23.2% (512/2203), followed
by health workers at 17.1% (377/2203), and security at 8.7% (191/2203). Three-point
four percent (75/2204) of the population had been infected with COVID-19 before the
vaccination exercise. The details are in Table 1 below.
Table 1. Characteristics of study participants.
Characteristic, n = 2204 Frequency (n) Percentage
Age
<50 1515 68.7
>50 689 31.3
Sex
Male 1310 59.4
Female 894 40.6
Education level (n = 2203)
Primary 398 18.1
Secondary 541 24.5
Tertiary 1264 57.4
Religion (n = 2203)
Christian 1953 88.7
Moslem 206 9.3
Hindu 44 2.0
Marital status
Single 304 13.8
Married 1900 86.2
Occupation (n = 2203)
Teacher 512 23.2
Health worker 377 17.1
Security 191 8.7
Others * 1123 51.0
Previous COVID–19
Infection
Yes 75 3.4
No 2129 96.6
* Others included: business people, farmers, drivers, students.
3.2. Prevalence of Side-Effects to Oxford/AstraZeneca Vaccine in Tororo District
A total of 603 out of 2204 experienced side-effects, representing (27.4%) (Figure 1). Of
those who experienced side-effects, 253/603 (42.0%) experienced local side-effects, 449/603
(74.5%) experienced systemic side-effects, 13/603 (2.2%) had allergic reactions, and 171/603
(28.4%) reported other side-effects. Other side-effects included loss of libido, changes in
appetite, body weakness, cough, and flu.
Int. J. Environ. Res. Public Health 2022, 19, 15303 5 of 10
Only 424/603 participants had responses to when side-effects occurred. Of these,
268/424 (63.2%) of the participants experienced side-effects after the first dose, 44/424
Int. J. Environ. Res. P
 (u1b0lic.4 H%eal)the 2x0p22e, 1r9i,e xn FcOeRd PsEiEdR eR-EeVfIfEeWct s after the second dose, and 112/424 (26.4%) experien5c eofd 11 
side-effects after both doses. Ten participants did not receive the second dose of the
vaccine because of the side-effects they experienced after the first dose. Among those that
experienced side effectsY
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3.3. Side-Effe3c.t2P. Prorefivlaelence of Side-Effects to Oxford/AstraZeneca Vaccine in Tororo District 
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reported fevcehr.anOgtehse irn saipdpee-teitfefe, cbtosdayr we esahkonwesns, icnouFgighu, arnesd 1flua.n d 2 below:
Int. J. Environ. Res. Public Health 2022, 19, x FOR PEER REVIEW 6 of 11 
 
 
Figure 1. LocaFligsuidree -1e. fLfeocctasl sfiodlelo-ewffeinctgs vfoallcocwininagti ovnacwcinitahtioOnx wfoitrhd O/Axfsotrrda/ZAestnraeZcae.neca. 
Only 424/603 participants had responses to when side-effects occurred. Of these, 
268/424 (63.2%) of the participants experienced side-effects after the first dose, 44/424 
(10.4%) experienced side-effects after the second dose, and 112/424 (26.4%) experienced 
side-effects after both doses. Ten participants did not receive the second dose of the vac-
cine because of the side-effects they experienced after the first dose. Among those that 
experienced side effects after both doses of the vaccine, 74/112 (66.1%) were reported to 
have been affected more in terms of the severity of symptoms by the first dose. 
3.3. Side-Effect Profile 
For local side-effects, the majority 247/253 (97.6%) reported pain at the injection site, 
16/253 (6.3%) swelling at the injection site, 3/253 (1.2%), swollen armpit lymph nodes, and 
1/253 (0.4%) had redness at the injection site. For systemic side-effects, most, 218/449 
(48.5%), experienced headache, 203/449 (45.2%) had tiredness, and 134/449 (29.8%) re-
ported fever. Other side-effects are shown in Figures 1 and 2 below: 
 
Figure 2. SysFteigmuirce s2i.d Sey-setfefmecict ssifdoel-leofwfecintsg fovlalocwciinnagt vioancciwnaitthionO wxfiothr dO/xAfosrdtr/aAZsternaeZcean.eca. 
 
3.4. Health Care Seeking Following Oxford/AstraZeneca Vaccine Side-Effects 
Almost half of the participants, 269/424 (63.4%) did not seek any health care after 
experiencing side-effects. However, a total of 64/424 (15.1%) of the participants sought 
medical attention in a health facility. These probably represented those with serious-side 
effects, as a visit to a health facility may be a proxy indicator for a serious medical condi-
tion. Among those who visited a health facility, 34 out of 64 visited a private facility (Ta-
ble 2). 
Table 2. Health care seeking following AstraZeneca side-effects. 
Place of Seeking Care (n = 424) Frequency (n) Percentage (%) 
Did not seek health care 269 63.4 
Consulted CHW 21 5.0 
Consulted traditional healer 3 0.7 
Visited health center 18 4.3 
Visited hospital 12 2.8 
Visited private clinic 34 8.0 
Self-medication 72 17.0 
Other * 2 0.5 
* other used home remedies, taking juice and a lot of fluids. 
3.5. Medications Following Oxford/AstraZeneca Side-Effects 
A total of 156 respondents reported the use of medications following Ox-
ford/AstraZeneca side-effects. Most of the respondents, 96/156 (61.5%), used paracetamol 
following COVID-19 vaccination side-effects. Other medications used are in Table 3. 
Table 3. Medications following Oxford/AstraZeneca vaccine side-effects. 
Medication (n = 156) Frequency (n) Percentage (%) 
Herbs 5 3.2 
Paracetamol 96 61.5 
Diclofenac 33 21.2 
 
Int. J. Environ. Res. Public Health 2022, 19, 15303 6 of 10
3.4. Health Care Seeking following Oxford/AstraZeneca Vaccine Side-Effects
Almost half of the participants, 269/424 (63.4%) did not seek any health care after
experiencing side-effects. However, a total of 64/424 (15.1%) of the participants sought
medical attention in a health facility. These probably represented those with serious-side
effects, as a visit to a health facility may be a proxy indicator for a serious medical condition.
Among those who visited a health facility, 34 out of 64 visited a private facility (Table 2).
Table 2. Health care seeking following AstraZeneca side-effects.
Place of Seeking Care (n = 424) Frequency (n) Percentage (%)
Did not seek health care 269 63.4
Consulted CHW 21 5.0
Consulted traditional healer 3 0.7
Visited health center 18 4.3
Visited hospital 12 2.8
Visited private clinic 34 8.0
Self-medication 72 17.0
Other * 2 0.5
* other used home remedies, taking juice and a lot of fluids.
3.5. Medications following Oxford/AstraZeneca Side-Effects
A total of 156 respondents reported the use of medications following Oxford/AstraZeneca
side-effects. Most of the respondents, 96/156 (61.5%), used paracetamol following COVID-
19 vaccination side-effects. Other medications used are in Table 3.
Table 3. Medications following Oxford/AstraZeneca vaccine side-effects.
Medication (n = 156) Frequency (n) Percentage (%)
Herbs 5 3.2
Paracetamol 96 61.5
Diclofenac 33 21.2
Amoxicillin 11 7.1
Azithromycin 3 1.9
Chloroquine 2 1.3
Ciprofloxacin 6 3.9
Vitamin C 4 2.6
Dexamethasone 13 8.3
Others * 10 6.4
Don’t know 18 11.5
* others included: metronidazole, prednisolone, artesunate, artemether–lumefantrine, fluids.
3.6. Deaths following Oxford/AstraZeneca Vaccination
Of the participants, 7/424 died after COVID-19 side-effects (Table 4). The causes of
death were probably not directly related to the side-effects as shown in the table below.
Information about the death was obtained via telephone interview. However, it was not
possible to infer an association between death and the side-effect of Oxford/AstraZeneca.
Table 4. Deaths following receipt of Oxford/AstraZeneca vaccine.
Participant Cause of Death Period from the Date of the
Second Dose of the Vaccine
1 Diabetes complication Three weeks
2 Hypertension/stroke Three weeks
3 Accident Two weeks
4 Malaria One month
5 Sudden death Three months
6 Accident Five months
7 Tuberculosis Two months
Int. J. Environ. Res. Public Health 2022, 19, 15303 7 of 10
3.7. Factors Associated with Experiencing Side-Effects to Oxford/AstraZeneca Vaccine
Previous infection with COVID-19 (adjusted odds ratio (AOR): 4.3, 95% confidence
interval (95% CI): 2.7–7.0, p < 0.001) and being female (AOR: 1.3, 95% CI: 1.1–1.6, p = 0.004)
were positively associated with experiencing side-effects of the AstraZeneca COVID-19
vaccine. Being a security officer (AOR: 0.4, 95% CI: 0.2–0.6, p < 0.001) was negatively
associated with experiencing side-effects of the COVID-19 AstraZeneca vaccine. Par-
ticipants previously infected with COVID-19 were 4.3 times more likely to experience
Oxford/AstraZeneca vaccine side-effects than those who weren’t. Females were 1.3 times
more likely to experience side-effects than males. Security officers were 0.4 times less likely
to experience side-effects of the Oxford/AstraZeneca vaccine compared to participants of
different occupations. Table 5 shows the factors associated with experiencing side-effects to
Oxford/AstraZeneca vaccine.
Table 5. Factors associated with experiencing side-effects of Oxford/AstraZeneca vaccine.
Characteristic Had Side
Effects COR 95% CI p-Value AOR 95% CI p-Value
Age
<50 415 (68.8) 1 1
≥50 188 (31.2) 1.0 0.8–1.2 0.958 1.0 0.8–1.2 0.942
Sex
Male 322 (53.4) 1 1
Female 281 (46.6) 1.4 1.2–1.7 <0.001 1.3 1.1–1.6 0.004 *
Marital status
Single 85 (14.1) 1 1
Married 518 (85.9) 1.0 0.7–1.3 0.800 0.9 0.7–1.2 0.595
Previous COVID-19 infection
No 557 (92.4) 1 1
Yes 46 (7.6) 4.5 2.8–7.2 <0.001 4.3 2.7–7.0 <0.001 *
Education level
Primary 114 (18.9)
Secondary 160 (26.5) 1.0 0.8–1.4 0.756 1.1 0.8–1.5 0.423
Tertiary 329 (54.6) 0.9 0.7–1.1 0.304 0.8 0.6–1.1 0.163
Occupation
Teacher 151 (25.04) 1 1
Health
worker 110 (18.2) 0.9 0.7–1.2 0.549 0.9 0.7–1.2 0.561
Security 27 (4.5) 0.4 0.3–0.6 <0.001 0.4 0.2–0.6 <0.001 *
Others 315 (52.2) 1.0 0.7–1.3 0.919 0.8 0.6–1.1 0.152
COR—crude odds ratio; CI—confidence interval; AOR—adjusted odds ratio; * statistically significant at a
p-value < 0.05.
4. Discussion
In this study, we investigated the side-effects and associated factors following COVID-19
vaccination with the Oxford/AstraZeneca vaccine among priority populations comprising
health workers, teachers, security personnel, the elderly above fifty, and all adults between
18 and 50 with underlying conditions. This was a COVID-19 vaccine-naïve population,
as they were the first beneficiaries of this service in the phased approach the government
undertook to vaccinate its eligible citizens. In our study, 27.4% of the participants expe-
rienced one or more side-effects. Studies conducted elsewhere reported higher findings,
Int. J. Environ. Res. Public Health 2022, 19, 15303 8 of 10
as compared to our findings. For instance, a study carried out in Saudi Arabia reported
a 68.5% prevalence of side-effects [10]. Another study carried out in Jordan on a vaccine
naïve population but comparing AstraZeneca with Pfizer and Sino pharm, reported an
89.9% prevalence of side-effects [11]. The same study revealed that more side-effects were
significantly associated with the Oxford/AstraZeneca vaccine than other vaccines. Addi-
tionally, a study conducted among health workers in Ethiopia reported a 91.3% prevalence
of AstraZeneca COVID-19 vaccine side-effects [12]. The differences could be explained
by differences in populations, as some of them could present differing thresholds for
discomfort, as well as the nocebo effect in that, some populations could be more averse
to rumors and misinformation. The nocebo effect can modulate the outcome of a given
therapy negatively [13]. In this case, it could be induction or worsening of side-effects of
the Oxford/AstraZeneca vaccine.
We found that being female was positively linked to experiencing side-effects. This is
contrary to a study conducted in Ethiopia on health workers that found no association [14].
However, similarly, a cross-sectional survey among recipients of the COVID-19 vaccine in
the general population in Saudi Arabia reported a higher prevalence of side-effects among
women than men, after either dose [15]. We cannot rule out the nocebo effect in explaining
gender relations, as some people could have experienced side-effects out of expectation.
This is emphasized in a report by Winfried Rief of the JAMA health forum, that states that
the very fear of side effects can amplify or induce side-effects [16].
The strong relation between side-effects with previous COVID-19 infection could be
a result of a primed body with natural immunity, developing from a previous infection
reacting more aggressively to the vaccine [17]. Similarly, a prospective observational study
conducted in the United Kingdom showed such a strong linkage between a previous
COVID-19 infection and side-effect experience, a 1.6 times higher likelihood of side-effects
in those with the previous infection [4]. A significant association between side-effects
following the previous infection was quite apparent, suggesting the possibility of the
vaccine landing on a primed immune system that probably overreacted [17].
A small number (15.1%) of the participants who had side-effects sought medical care
from a health facility. We can take these as those with serious side-effects, as a visit to
the health facility could be a proxy indicator for a serious condition in our setting. This
was way above the 2% serious side-effects reported by a study in the United States [18].
The difference could be accounted for by a difference in the definition of serious side-
effects. However, a study conducted in England concluded that there aren’t enough data to
conclude serious adverse events following COVID-19 vaccination, as not enough clinical
trials and long-term follow-up have been performed [19].
Among those that experienced side-effects after both doses of the vaccine, 76/112
(67.9%) were reported to have been affected more by the first dose. Similar results were
reported by a study in Poland of participants being affected more by the first dose of the
vaccine [20].
Security personnel had a statistically significant protective relationship. Perhaps the
hardened nature due to their training and work makes them less likely to report minor
events as side-effects. However, these are generally fit people but also “macho” in nature
by training, and possibly are more inclined towards not reporting minor events.
Our study provides evidence of mild symptoms, as most of the side-effects were man-
aged conservatively (did nothing), followed by self-medication, using mainly paracetamol
tablets. This is in agreement with a study conducted in Ethiopia amongst health workers
that reported that 64% of the people who experienced side-effects used paracetamol as
a remedy [14]. Up to 18/424 (4.2%) of those who experienced side-effects had ongoing
symptoms at the time of the study, on average six months later. Seven participants died
from causes that may not necessarily have been related to the vaccine; two from accidents,
one from TB, malaria, stroke, hypertension, and diabetes mellitus, respectively, on average
3 months post-vaccination. Ten participants couldn’t proceed to receive the second dose
because of the side-effects.
Int. J. Environ. Res. Public Health 2022, 19, 15303 9 of 10
Study Limitations
This population-based survey used telephone interviews to gather quantitative data
using a structured questionnaire. We proposed to reach an estimated 7834 people who had
received the Oxford/AstraZeneca vaccine from the first 8000 doses released to Tororo as of
July 2021. Of the over 7834 targeted population, only 5750 were deemed to have complete
data to be contacted, and of these, only 2204 were reached. Some telephone contacts were
not available or unreachable. Some contacts were duplicated in the register. This could
have also resulted in information bias, as the participants who could not be accessed could
have reported side-effects.
The retrospective nature of our study paused a risk of recall limitations, as this study
took place more than six months after the vaccination exercise. Furthermore, COVID-19
considerations have impacted some practical aspects of this study.
5. Conclusions
Following vaccination with the Oxford/AstraZeneca vaccine, participants reported
side-effects that were majorly local and systemic. Most of the side-effects were mild and
self-limiting. Being female and having had a previous COVID-19 infection were positively
linked to experiencing side-effects after vaccination with the Oxford/AstraZeneca vaccine,
while being security personnel was negatively associated with experiencing side-effects
after vaccination with the Oxford/AstraZeneca vaccine. We recommend campaigns to
disseminate correct information about potential side-effects of the Oxford/AstraZeneca
vaccine, and to strengthen surveillance for adverse events following vaccination.
Author Contributions: J.O., D.M., A.N., R.N., B.T.M. and Y.L. conceived, designed, analyzed the
data, and prepared the first draft of the manuscript. J.K.B.M., B.W., D.O., F.O., S.O. and P.O.-O. were
instrumental in data analysis, interpretation of the data, and drafting of the final manuscript. All
authors have read and agreed to the published version of the manuscript.
Funding: This research received no external funding. The Norwegian Research School of Global
Health funded the article processing charges for this manuscript. D.M. is an alumnus of the school.
Institutional Review Board Statement: The study was conducted in conformity with the principles
of the declarations of Helsinki. We obtained ethical approval from the Review and Ethics Committee
(REC) of Mbale Regional Referral Hospital, REC approval number MRRH-2021-91.
Informed Consent Statement: Informed consent was sought on the phone from individual partici-
pants at the beginning of the interview. For confidentiality, the names of participants were removed
from the extracted data set, and only serial numbers alongside the telephone contacts were availed to
research assistants.
Data Availability Statement: The datasets used and/or analyzed during the current study are
available from the corresponding author.
Acknowledgments: We acknowledge Tororo district health team for making the COVID-19 vaccina-
tion register data available for this study. We thank our dear research assistants for their outstanding
work during data collection. Our special regards also go to the study participants, who took the time
to take part in the study.
Conflicts of Interest: The authors declare no conflict of interest.
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