Written by 11:47 pm Source News Views: 1

The impact of information sources on COVID-19 vaccine hesitancy … – BMC Public Health

Click to share the News

Advertisement
BMC Public Health volume 23, Article number: 38 (2023)
2547 Accesses
4 Citations
2 Altmetric
Metrics details
Vaccination remains the most powerful weapon against the emergence of new variants of coronavirus (COVID-19). However, false information about COVID-19 vaccines through various platforms including social media remains a major threat to global public health. This study examined the impact of information sources on COVID-19 vaccine hesitancy and resistance in sub-Saharan Africa (SSA).
A validated web-based cross-sectional study was conducted from 14 March to 16 May 2021, and was administered in both French and English to 2572 participants aged 18 years and over. Data on sociodemographic characteristics, medical and vaccination history, and the information sources (mainstream media and social media) used by the participants during the pandemic were obtained. There were three main outcomes: The vaccinated group were those who responded in the affirmation (Yes) to the question of whether they have been vaccinated against COVID-19. Those who responded ‘not sure’ or ‘no’ to the question were then asked if they were willing to be vaccinated when the vaccine became available in their home countries. The responses to this follow-up question were used to derive the second and third outcome variables of ‘vaccine hesitancy’ and ‘vaccine resistance’, respectively. A series of logistic regression analyses were used to examine the impact of information sources on the three main outcomes.
The prevalence of COVID-19 vaccine hesitancy among the participants was lowest among newspaper readers (42%) and highest among TV (72%) and social media users (73%). The prevalence of COVID-19 vaccine-resistance was also lowest among newspaper readers (37%) but highest among social media users (87%). Multivariate analyses revealed that compared to those who did not use these information sources, SSA participants who relied on the radio (aOR 0.83, 95%CI = 0.70, 0.99), TV (aOR 0.80, 95%CI = 0.65, 0.97) and social media (aOR 0.79, 95%CI = 0.65, 0.97) for information during the pandemic were less likely to be hesitant towards taking the vaccines. However, social media users (aOR 2.13, 95%CI = 1.62, 2.80), those who watched TV (aOR 1.40, 95%CI =1.08, 1.80), relied on healthcare workers (HCWs: aOR 1.32, 95%CI = 1.07, 1.63) and families/friends (aOR 1.31, 95%CI = 1.06, 1.61) for COVID-19 related information during the pandemic were more likely to resist taking the COVID vaccines in this study. Participants who relied on the newspaper for information during the pandemic were less likely to resist the vaccines (aOR 0.77, 95%CI = 0.62, 0.95) compared to non-readers of a newspaper.
We found that all six information sources except radio were strong predictors of the resistance towards COVID-19 vaccination. Further research on how these channels can be used to improve the availability of reliable healthcare information is needed. Investments in these resources will protect people and empower them to make appropriate choices about their health.
Peer Review reports
The COVID-19 pandemic has significantly impacted economic, health and living conditions on the African continent and elsewhere [1, 2]. The impact on individuals, families and communities across Africa has been unprecedented. While the global economic loss is still unfolding, it is projected to be quite huge particularly in African countries [3]. The risk of COVID-19 resurgence remains high in several African countries due to poor adherence to public health measures, mass gatherings, low testing and low vaccination rates [4]. This resurgence creates more demands on an already depleted and struggling healthcare system thereby leaving many of the citizens in a dilemma. Governments are also overburdened with balancing the provision of care regarding the presence of other viral infections and diseases that have sprung up again due to all attention being diverted to the COVID-19 pandemic as is seen in countries like the Democratic Republic of Congo (Ebola), Lassa fever in Guinea, Liberia, Kenya (Rift valley Fever), Nigeria and Sierra Leone, Republic of Guinea (Marburg virus disease), among other African countries [5,6,7,8]. Furthermore, residents have purchased and stored some medications commonly used for treating other infectious diseases causing scarcity, and rising costs due to an increase in demand [9].
Vaccination remains the most powerful weapon against the emergence of new variants [10] as well as reaching herd immunity [11]. However, compared with the rich European and North-American countries, COVID-19 vaccination remains very low among African countries with only 11% of the adult population fully vaccinated [10]. This lack of adequate and complete vaccination of the populace, among other factors, is brought about by the state of the economy in African countries. Most African countries are in the low-middle income strata. High income economies, purchase and hoard vaccines immediately or even before they are mass produced by paying pharmaceutical companies huge deposits for these vaccines before production which affects the vaccine distribution globally. This also limits effective control of the widely spreading disease, particularly among African countries and thus the emergence of various variants of the virus as seen in South Africa (omicron), Brazil (delta) and India [12]. This act of hoarding vaccines could be directly attributable to the non-achievement of disease control and its resurgence in other variants in low-middle-income countries. As such the inability to attain community immunity globally since people are still travelling, more so, with most of these countries lowering their guard on the earlier preventive measures [12].
The African continent has witnessed four waves of COVID-19 over the last 2 years and has improved its capacity to manage COVID-19 cases [10]. The supply of COVID-19 vaccines across the region has also increased with approximately 672 million doses distributed across the region, mostly facilitated by COVAX (65%) and the rest through bilateral deals (29%) and the African Union’s Vaccines Acquisition. Despite this improvement, there are concerns that the rapid spread of ‘false or misleading information’ in digital and physical environments causes confusion and risk-taking behaviours that can harm health and lead to mistrust in health authorities and undermine the public health response [13]. For instance, in Pakistan, vaccine hesitance and resistance fuelled by fear of the unknown, country of manufacture of the vaccine, religious and cultural ideologies, have made it almost impossible to reach the people [14]. Yet, despite the widespread concern about the potential impacts of misinformation on vaccination, little is known about the magnitudes of those impacts nor their differential effects across various countries in sub-Saharan Africa (SSA).
Exposure time to COVID-19-related news increased over time during the pandemic [15] and more exposures to the news have direct implications on people’s actions such that receiving timely and informative communication during a time of uncertainties promotes public cooperation [16]. Infodemic affects the hesitance and resistance to uptake of new products across the market, and it becomes worse in a pandemic as seen with the coronavirus disease and its management and supposed consequences [13]. Vaccine hesitancy (reluctance to receive vaccines) is one of the top ten threats to global health [17] and this is fuelled by health information obtained from the news media, internet and social media platforms [18,19,20,21]. Vaccine hesitancy is also high among certain population groups [22, 23] probably due to the previous medical experiment amongst these population groups [24] and poor messaging [25]. Misinformation regarding the benefits, medicinal composition, and adverse effects of vaccination, limits patient understanding and overall buy-in [18]. Although access to technology has improved during the pandemic, and the use of social media has increased [18], there are concerns about the spread of misinformation across different social networks propagated via the contemporary anti-vaccination movement, to fuel vaccine hesitancy [26, 27]. This has the potential to compromise public confidence in the COVID-19 vaccine for the prevention of the disease [28]. However, where social media platforms were used to propagate healthy messages, by nurses and doctors, a significant improvement in compliance with public health messages and subsequent COVID-19 infections has been reported [21].
Sources of vaccination information have different effects on people’s coping appraisal of COVID-19 vaccination [20]. Unlike mainstream media, social media such as Facebook, Twitter, Instagram, WhatsApp, and Pinterest allow individuals to rapidly create and share content globally without editorial oversight [29, 30]. These are complex and fluid ecosystems, in which anti-vaccination viewpoints can be amplified and represented as mainstream, and vaccine-hesitant parents can encounter compelling narratives from other parents dissuading vaccination [31]. Misinformation and unsubstantiated rumours regarding COVID-19 and potential vaccination against SARS-CoV-2 have already begun emerging on social media platforms, threatening to erode public confidence as the vaccines are rolled out in African countries [32]. Information spread through social media directly or indirectly increases hesitancy toward COVID-19 vaccination, while the opposite effect was observed for institutional websites [27]. Since social media platforms may self-select content streams, contributing to ideological isolation, owners must ensure that social media platforms provide access to accurate information on the safety and efficacy of vaccinations [29].
The uptake of COVID-19 vaccination in SSA may be impeded by the rapid spread of misinformation on social media leading to belief in false rumours about the pandemic [29], which has been associated with poor health-seeking behaviour [33, 34]. The recent mixed international messages about the efficacy of the different COVID-19 vaccines, their side effects beyond the local and systemic effects [35, 36] and the lack of clarity regarding the required dosage [37] may further reduce the confidence of African populations in the safety of the vaccines [21]. In addition, the halting of the AstraZeneca vaccine in South Africa, which showed less protection against the new variant SARS-CoV-2 that can evade key antibodies [21], may have contributed to lower people’s confidence in the vaccine efficacy. Healthcare workers are among the most trusted experts [38,39,40].
Intensive global efforts for continued physical distancing and isolation to curb the spread of new strains of SARS-CoV-2 may intensify the use of social media as individuals try to remain connected while apart [41]. In a randomized controlled trial to understand the impact of social media in the United States, researchers found that messages spread by nurses and doctors on social media led to a significant reduction in holiday travel and subsequent COVID-19 infections [21]. Therefore, identifying, understanding, and addressing how information sources affect vaccine acceptance [42], hesitancy and resistance [43] is potentially important to increase vaccine uptake.
Therefore, this study was designed to, a) determine the proportions of SSA participants that were dependent on the different sources of information (social media and mainstream media sources) for COVID-19-related information; b), profile individuals who use the mainstream media outlets (TV and radio, newspaper) to obtain COVID-19 related information by identifying the key socio-demographic, and health-related factors that are associated with the different information sources; and c), determine the sources of information about the COVID-19 pandemic among vaccine-hesitant and resistant individuals across SSA countries as well as identify the association between sources of information and vaccine hesitancy. By identifying the distinguishing characteristics, public health officials may be better able to target a sub-population at greater risk of exposure to misinformation about the COVID-19 vaccine. Findings will also offer a greater understanding of how public health officials can effectively tailor health behaviour messaging to align with the socio-demographic profiles of vaccine-hesitant or resistant individuals, while also considering their consumption of COVID-19 information and the predominant sources. In addition, the study findings will help to provide steps on how social media may be used to improve health literacy and build public trust in vaccination.
This was a cross-sectional study that recruited participants across SSA countries between March 14 and May 16, 2021. The questionnaire was initially developed and used for a similar study [44]. The questionnaire was tested for the internal validity of the items, and Cronbach’s alpha coefficient score ranged from 0.70 and 0.74, indicating satisfactory consistency [44]. The questionnaire was adapted with minor modifications to suit this study’s objective and was made available in English and French languages to allow for residents residing in the Anglophone and Francophone SSA countries to participate. This was also necessary to increase the reach of the survey, one of the past study limitations [33, 34]. Moreover, a pilot study was conducted on 10 participants who were not included in the final study and were not part of the research group to ensure clarity and understanding as well as to determine the duration of completing the questionnaire before dissemination. The final questionnaire is presented as Supplementary Table S1.
Eligible participants were adults of SSA origin, living in or outside of Africa, aged 18 years and older, who were able to provide informed consent at the time of this study. Since this was an online survey, it is possible that participants were those who had access to the internet and those who were on their respective social media platforms and used them. Participants were excluded if they were not from SSA countries, were younger than 18 years, were unable to provide informed consent, and participated in the initial pilot study. The supplementary Fig. S1 shows the distribution of the participants by their countries of origin.
Using a snowball sampling technique, participants were recruited online after the survey was created in survey monkey (SurveyMonkey Inc., San Mateo, California, USA, www.surveymonkey.com) and was administered in two languages. An e-link to the survey was disseminated via emails and posted on social media platforms (Facebook and WhatsApp). The distribution of the survey was strongly reliant on the snowballing or chain-referral approach using virtual networks to reach the population who used social media and other online formats, thus saving time and cost for data collection [45, 46]. Authors were also encouraged to share the e-link of the survey through personal emails and social network groups in their respective countries. The use of an online survey ensured that a large spectrum of prospective participants across SSA could be reached in limited time and resources.
The sample size calculation was based on a single population proportion formula by the World Health Organization (WHO) as well as previous studies [33, 34, 47]. Assuming a 20% attrition rate for a proportion of 50% of the population and using the desired precision of 2% and the 5% significance level for a two-sided test to detect statistical differences between groups at 80% power, a sample size of 2502 was considered adequate for this study aims.
The main outcomes were the three COVID-19 vaccine indicators of the participants. The vaccinated group was formed by those who responded in the affirmation (Yes) to the question of whether they have been vaccinated against COVID-19. Those who responded ‘not sure’ or ‘no’ to the question were then asked if they were willing to be vaccinated when the vaccine became available in their home countries. The responses to these follow-up questions were used to derive the second and third outcome variables of ‘vaccine hesitancy’ and ‘vaccine resistance’, respectively, similar to a previous study [48]. In this study, vaccine acceptance refers to a position ranging from passive acceptance to active demand [42], whereas hesitancy and resistance, respectively, were used to define the reluctance to receive vaccines (i.e. positions of being unsure about taking a vaccine) and being absolutely against taking a vaccine [43].
The exposure variables were derived from the question of how the participants obtained information on the COVID-19 vaccine. The participants responded ‘yes’ or ‘no’ to whether they obtained the information from the mainstream media (Radio, Television, Newspaper), Social media (such as Facebook, WhatsApp, Twitter) or healthcare workers (HCWs), or family and friends.
The questionnaire included demographic data (age group, sex, country of origin, religion, marital status, educational level, employment status, occupational status), health indicator factors (smoking status, presence of pre-existing conditions including diabetes, lung disease, heart disease, hypertension, obesity, asthma) and previous immunisations/vaccines history. These constituted the independent variables.
Analyses were performed using STATA/MP version 14 (Stata Corp, College Station, TX, USA) and categorical data are shown as counts and percentages. The proportion of participants who used each of the sources of information was conducted using cross-tabulation. The proportion of participants who used each of the sources of information was conducted using cross-tabulation. The associations between sources of information and vaccine hesitancy and resistance were determined in a series of logistic regression analyses that included sources of information as exposure variables after controlling for demographic factors, and health indicator factors. There is no unique statistical test for multicollinearity for binary logistic regression but in our analysis, we treat the binary outcome variables as a continuous variable and used the “Logit” command and then ‘collin’ command in Stata to determine multicollinearity including Variance Inflation Factors (VIF) because collinearity is driven by the characteristic of the independent variables and no the type of regression used [49] and the VIF < 4 was considered suitable [50]. The odds ratios with 95% confidence intervals (CI) were calculated to assess the adjusted odds of exposure and independence variables.
This self-administered web-based cross-sectional study was approved by the Humanities and Social Sciences Research Ethics Committee (HSSREC 00002504/2021) of the University of KwaZulu-Natal, Durban, South Africa. The study adhered to the principles of the 1967 Helsinki declaration (as modified in Fortaleza 2013) for research involving human subjects. Before the study, an explanation detailing the nature and purpose of the study was provided to all participants using an online preamble. Informed consent was obtained from the participants who were required to answer either a ‘yes’ or ‘no’ to a question on whether they were willing to voluntarily participate in the survey. The confidentiality of participant responses was assured, and anonymity was maintained. Participation in the study was voluntary without any incentive, inducement, or obligation from the researchers. To ensure that only one response per participant was included in the study, participants were instructed not to take part in the survey more than once, and during analysis, we also restricted the data by the IP address of the participants.
The socio-demographic characteristics of the 2572 participants who took part in this study are reported in Table 1. Of these participants, 1390 were males (54%), mostly educated (80% of the participants had completed a bachelor’s or higher education degree), about one-third were aged 18-28 years (929, 36.1%), and more than half of them were not married (1440, 56.0%) and resided in West African countries (1446, 56.2%). About 80% of the participants were employed in non-healthcare sectors and of health indicators, there were few smokers (177, 6.9%) and people who reported that they had a pre-existing condition (880, 34.2%).
Television and social media were the main sources of information for more than two-thirds (n = 1897 and 1879, respectively) of the participants in this study during the pandemic, while less than half relied on the newspaper (n = 1067, 41.5%) for such information (Table 1). This was consistent across regions, age groups and gender. More than half of the Central African participants reported that they sought COVID-19-related information from HCWs, whereas East African participants relied less on this source of information. Fifty-five percent of those with a pre-existing health condition and those that had previous vaccination reported that they relied on HCWs for COVID-19-related information.
The proportion of COVID-19 vaccinated, hesitant and resistant participants at the time of this study was 14.9, 17.8, and 67.3%, respectively. Figure 1 displays the proportion of participants who reported COVID-19 hesitancy and resistance, across the different media sources used by the participants during the pandemic. A total of 17% of mainstream listeners and 13% of social media users were vaccinated at the time of this study. Irrespective of the participants’ source of information during the pandemic, the proportion who resisted the vaccine was significantly higher and ranged from 37% among newspaper readers to 85% among social media users. In comparison, the proportion who were hesitant to take the vaccine ranged from 42% among newspaper readers to 73% among those who watched TV during the pandemic.
Prevalence of COVID-19 vaccination, hesitancy, resistance by information sources in sub-Saharan Africa, during the pandemic (n = 2572)
The Chi-square test found significant associations between the participants’ vaccination status and their reliance on social media (p < 0.0001), TV (p = 0.004), HCWs (p < 0.0001) and friends/families (p = 0.001) for COVID-19-related information, during the pandemic.
The full set of findings from the multinomial logistic regression analyses for the characteristics of those that relied on the various sources of information during the pandemic, after adjusting for the potential cofounders, is presented in Table 2. In this study, reliance on the mainstream media for information during the pandemic was more likely to be observed among Central and Southern African participants, whereas social media was less likely to be used for COVID-19 information retrieval in those with primary education (aORs = 0.36, 95%CI = 0.20, 0.62) and non-Christians (aORs = 0.74, 95%CI = 0.56, 0.97).
Central African participants and those who worked in health sectors were more likely to rely on HCWs for COVID-19-related information as compared to West African participants and those who worked in non-healthcare sectors, during the pandemic. Compared with males, female participants were less likely to listen to the radio, watch TV and read the newspaper but more likely to rely on friends and family (aOR = 1.23, 95%CI = 1.05, 1.45), for COVID-19-related information, during the pandemic. Current smokers were also more likely to rely on friends and family (aOR = 1.97, 95%CI = 1.26, 3.10), while those with primary or no education as well as non-Christians were less likely to rely on social media for information, during the pandemic.
The aORs and their 95%CI for factors associated with vaccine hesitancy and vaccine resistance are presented in Tables 3 and 4, respectively. After adjusting for the potential confounders, in this study, participants who listened to the radio, those who watched TV, and social media users, during the pandemic, were less likely to report COVID-19 vaccine hesitancy. As shown in Table 4, age (29-38 years), SSA region of origin (East Africa), educational level (primary education or less), religion and occupation of the participants were associated with resistance towards COVID-19 vaccination. Except for those who listened to the radio, reliance on other media sources for COVID-19-related information was significantly associated with vaccine resistance, with the strongest association found among social media users (aOR = 2.13 95%CI = 1.62, 2.80) Table 4. Also, those who watched TV and people who relied on HCWs and friends/family for COVID-19-related information were more likely to resist COVID-19 vaccination, whereas reading the newspaper reduced the likelihood of vaccine hesitancy (aOR = 0.77, 95%CI 0.62, 0.95) among the participants.
The forest plots showing the adjusted odd ratios for the association between the media sources used by the participants in SSA countries during the pandemic and vaccine hesitancy and resistance are shown in Figs. 2 and 3, respectively. Figure 2 shows that COVID-19 vaccine hesitancy was significantly associated with four of the six media sources examined in this study. Reliance on HCWs, social media and traditional sources (TV and radio) for COVID-19-related information during the pandemic reduced the odds of COVID-19 vaccine hesitancy by 27, 21, 20 and 17%, respectively.
Forest plot of association between main information sources and vaccine hesitancy and resistance among the participants in sub-Saharan Africa, during the pandemic
Forest plot of association between main information sources and vaccine resistance among the participants in sub-Saharan Africa, during the pandemic
There was a strong association between the use of social media and resistance towards COVID-19 vaccination (aOR = 2.13, 95%CI 1.62, 2.80) as seen in Fig. 3. Other factors such as watching TV and reliance on friends/families for information related to COVID-19 were also associated with COVID-19 vaccine resistance among the participants. Those who relied on the newspapers for information during the pandemic were less likely to be resistant towards taking the COVID-19 vaccines compared to those who did not (Fig. 3).
This study was undertaken to determine the role of different information sources on COVID-19 vaccine hesitancy and resistance in SSA. Consistent across age groups, gender and regions, television and Facebook, were the main sources of up-to-date information for participants in SSA during the pandemic. However, information from these sources, particularly those obtained from social media platforms, can be misleading, and as shown in the present study, social media users were twice more likely to resist the COVID-19 vaccines compared with non-users. Those who relied on the TV, HCWs, friends, and family members for their up-to-date information had a higher likelihood of vaccine resistance than their counterparts. In contrast, the odds for vaccine resistance were significantly reduced among those who reported that the newspaper was their main source of information during the pandemic.
Although the finding of a strong independent association between social media use and vaccine resistance was contrary to previous studies on smaller samples in Saudi Arabia [51, 52], this is important considering the wide utilisation of Facebook as the main source of information by many participants during the pandemic. A Facebook IQ survey revealed that more than 95 million people in SSAs access Facebook, with 97% of these doing so on handheld and mobile devices each month. Therefore, these popular sources of information (Television and Facebook) must be used to convey reliable, science-based information about COVID-19 vaccines and future pandemics to the millions of SSA people.
Smokers and females were more likely to rely on family and friends for COVID-19-related information, but less likely to rely on mainstream media (such as TV) than their male counterparts. There was a lower likelihood for non-Christians and those with lower education to rely on social media for information during the lockdown. Of the information sources, reliance on social media showed the strongest association with COVID vaccine hesitancy and resistance. After adjusting for potential covariates, information sources played a significant role in vaccine hesitancy and resistance among SSAs. Those who relied on information obtained from watching TV and family/friends were more likely to resist the COVID vaccine when compared to those who did not rely on those media sources. Listening to the radio and obtaining information from HCWs had a positive influence on intent towards vaccination because it reduced their likelihood of being resistant and hesitant towards COVID-19 vaccination. The negative influence of TV and social media use on COVID-19 vaccination reported in this study was not surprising as some emerging anti-vaccine television and social media campaigns are responsible for generating and perpetuating vaccine hesitancy and resistance. The high prevalence of inaccurate and negative information on social media regarding COVID-19 may predict a greater likelihood of negative vaccine intent in this case as well [53, 54]. In addition, social media is generally unregulated and has enabled people with anti-vaccine beliefs to generate and disseminate information freely [55]. The findings of this study are consistent with a previous study which found that, relative to social media and the internet, there was a positive association between reliance on traditional news sources and intention to uptake a COVID-19 vaccine in the United States [56]. Another previous work also highlighted the role of negative information on social media in shaping individual perceptions regarding human papillomavirus (HPV) vaccination intent [57].
Central and Southern African participants showed greater reliance on mainstream media for COVID-19-related information, particularly watching TV, and this increased their likelihood of not taking the vaccine. This finding could, in part, be related to the nature of lockdowns in different sub-Saharan countries. For instance, South Africa went into Level 5 (hard lockdown) quite early in the pandemic (March 2020), and residents were mostly confined to their homes, watching TV [58]. Reliance on social media platforms for COVID-19-related information was associated with higher educational levels, which agreed with a study from South Africa [58] which found that education-related inequalities were visible in the use of COVID-19 preventive measures in South Africa.
The finding that the participants with pre-existing medical conditions or those who had a prior history of vaccinations were more reliant on HCWs for COVID-19-related information during the pandemic suggests that HCWs are trusted to have a better understanding of COVID-19 information, and as such, they can be a source of essential care and information in future pandemics. In a previous study, participants rated health information from doctors and other health workers as highly reliable [59]. This assertion is supported by a recent study that showed that HCWs are essential front liners, working to ensure the health of older adults and those with chronic conditions or disabilities during the COVID-19 pandemic [60]. The high vaccination and low hesitancy rates reported among participants who relied on HCWs for information were consistent with a previous study, which showed that HCWs have adequate information on vaccines and have the ability and confidence to communicate such information effectively [61]. This finding supports the idea that HCWs, can positively influence the use of vaccines and have the potential to impact COVID-19 vaccination in SSA. However, recent literature has also warned of the inadequate capacity of HCWs to deal with anti-vaccine messages on social media [62].
One interesting finding of this paper is the resistant effect of information derived from HCW reported by participants. Studies among Africans have shown that HCWs themselves are resistant to the vaccine with their information being obtained from unreliable sources such as social media, friends and family [63, 64]. Safety concerns, insufficient or inaccurate information, lack of trust in the government’s capacity to manage, and personal beliefs are factors that have been reported to influence the acceptance or resistance of HCWs to the vaccine [65,66,67]. The likelihood of such health workers passing on information to the populace with content that may be tainted with their own beliefs and inaccuracies can contribute to making those who interact with them resistant to the vaccine.
Females were less likely to listen to the radio, watch TV and read newspapers but more likely to rely on friends and family, and this increased their likelihood of vaccine hesitancy. This finding may suggest that women expressed interest in COVID-19 issues with their friends and family (leaving very little room for individual proactive decision-making) while men were significantly more likely than women to get such information from the radio, TV and newspapers. The study also showed differences in behaviour, such that the less educated, non-Christians were not more reliant on social media platforms for information during the pandemic than their counterparts. For those who were more likely to be resistant (such as those who watched TV and those who relied on their families and friends for information), additional vaccine promotional efforts would be required.
Some limitations should be considered when interpreting the findings of this study. First, this was a cross-sectional study, and as such, we cannot determine causation. Second, like previous studies conducted during COVID-19 in SSA [34, 47, 68, 69], we utilized an internet-based methodology which was the only reliable means to disseminate information at the time of this study. The survey was distributed electronically using social media platforms and emails because it was difficult to physically access some participants in some places due to the protective measures still in place at the time of the study. This method of soliciting participants may have inadvertently excluded some potential participants whose opinions differed, such as those without internet access and people living in rural areas, where internet penetration remains relatively low [70]. Third, the survey was presented in English and French and thus inadvertently excluding non-English and non-French speaking countries in SSA from participating. Fourth, although the study showed satisfactory internal validity, its generalization or transferability to all SSA countries may be limited. Notwithstanding these limitations, this was the first study from the SSA region to provide insight into some of the impacts of information sources on the acceptance of COVID-19 vaccines which has been a worry to the international community. Although this topic is commonplace as reliance on online information sources is expected to happen during pandemics, no study has demonstrated the impacts of these sources of information on COVID vaccination in the way the present study did, including the use of a robust analysis to control for potential confounders during the analysis and reduce the possibility of a bias. This makes our study a unique one since it provided the first documented evidence from SSA showing the impacts of the lockdown on the behaviour of ordinary citizens.
This study provides an understanding of how the exposure of SSAs to various media sources during the pandemic, influences their attitude toward the COVID-19 vaccination program. Our focus on COVID-19 vaccine hesitancy and resistance is important because of the need to stem the pandemic by vaccinating enough people in the face of the recent rise in infections [11]. The findings are important because people’s negative attitudes toward vaccination in general, and their hesitancy or resistance to the COVID-19 vaccine, is a growing public health problem. This study provides insight into how the various media outlets commonly used by the participants living in different SSAs regions to obtain COVID-19-related information affect their attitude towards vaccine uptake. This finding underlines the importance of media exposure, suggesting that the media can be used to improve vaccine literacy across the region [71]. In addition, this study contributes to our understanding of the interplay between SSA regions and media exposure during the pandemic. For example, the study found greater reliance on the mainstream media for COVID-19-related information among those from Central and Southern Africa, which negatively influenced vaccine uptake. This insight has important practical implications by informing us about the dynamics of individuals’ attitudes and would help researchers understand the underlying factors that influence the acceptance of vaccination during a pandemic. This study will help public health and health promotion officers in various SSA countries design more effective communications and interventions.
Furthermore, the very low vaccination rate observed in this study raises the concern of vaccine nationalism with challenges of vaccine inequity in low and middle-income countries which was shown to be counterproductive during the pandemic [5, 12, 72]. High-income countries prioritized investment in the stock of vaccinations over immediate capacity building and delivery of such life-saving vaccines by healthcare systems. These lessons are important in tackling future pandemics. Although vaccinations are the only effective means of tackling viral diseases, prior studies have demonstrated that many people do not believe in their safety and effectiveness [14]. There is also the possibility that previously eradicated infections may re-emerge in some regions. People need to be educated about vaccines, their safety and their efficacy. The media can be used to boost people’s confidence in taking the vaccine [14, 73, 74].
The findings of this study suggest that healthcare organizations and governments of SSA fight misinformation by providing factual messages countries need to utilise social media platforms, television, and healthcare workers to provide reliable information to influence vaccine hesitancy and encourage uptake of the COVID-19 vaccination. Failure to access and apply reliable healthcare information, whether for the public or health workers, has always been a major cause of avoidable deaths. More research and investment are needed to improve the availability of reliable healthcare information, protect people from misinformation, and empower people with education on how to identify misinformation. The ongoing trajectory of misinformation – from vaccine hesitancy to previous infectious diseases to COVID-19 –calls for global action as the ‘infodemic’ of the next public health emergency may be worse than the current COVID infodemic.
The dataset supporting the conclusions of this article is included within the article (and its additional files). Data is also available on request from the corresponding author OUL.
Coronavirus disease
Sub–Saharan Africa
Odds ratio
Adjusted odds ratio
Confidence interval
Television
Healthcare worker
World Health Organization
Semo B-W, Frissa SM. The mental health impact of the COVID-19 pandemic: implications for sub-Saharan Africa. Psychol Res Behav Manag. 2020;13:713.
Article  Google Scholar 
Kassema JJ: COVID-19 outbreak: is it a health crisis or economic crisis or both? Case of African counties. Case of African counties (March 23, 2020) 2020.
Ataguba JE. COVID-19 pandemic, a war to be won: understanding its economic implications for Africa: Springer; 2020.
Google Scholar 
WHO. In: Boakye-Agyemang C, Oka S, editors. African countries face high risk of COVID-19 resurgence. World Health Organization Africa; 2021. https://www.afro.who.int/news/african-countries-face-high-risk-covid-19-resurgence.
Riaz MMA, Ahmad U, Mohan A, Dos Santos Costa AC, Khan H, Babar MS, et al. Global impact of vaccine nationalism during COVID-19 pandemic. Trop Med Health. 2021;49(1):101.
Article  Google Scholar 
Uwishema O, Okereke M, Onyeaka H, Hasan MM, Donatus D, Martin Z, et al. Threats and outbreaks of cholera in Africa amidst COVID-19 pandemic: a double burden on Africa’s health systems. Trop Med Health. 2021;49(1):1–5.
Article  Google Scholar 
Okonji OC, Okonji EF, Mohanan P, Babar MS, Saleem A, Khawaja UA, et al. Marburg virus disease outbreak amidst COVID-19 in the Republic of Guinea: a point of contention for the fragile health system? Clin Epidemiol Glob Health. 2022;13:100920.
Article  CAS  Google Scholar 
Hasan MM, Mohanan P, Emmanuella N, dos Santos Costa AC, Ahmad S, Mousavi SH, et al. Challenges of HIV amidst COVID-19 in Africa: can we conquer them? J Med Virol. 2022;94(1):11–3.
Article  CAS  Google Scholar 
Osuagwu UL, Nwaeze O, Ovenseri-Ogbomo G, Oloruntoba R, Ekpenyong B, Mashige KP, et al. Opinion and uptake of chloroquine for treatment of COVID-19 during the mandatory lockdown in the sub-Saharan African region. Afr J Prim Health Care Fam Med. 2021;13(1):1–8.
Article  Google Scholar 
WHO. In: Dalal M, editor. Africa on track to control COVID-19 pandemic in 2022. Brazzaville: World Health Organization regional office for Africa; 2022. https://www.afro.who.int/news/africa-track-control-covid-19-pandemic-2022. Accessed 14 July 2022.
Mellissa Q. Fauci warns “unlikely” to reach herd immunity if too many refuse vaccine: CBS News; 2020.
Google Scholar 
Rackimuthu S, Hasan MM, Bardhan M, Essar MY. COVID-19 vaccination strategies and policies in India: the need for further re-evaluation is a pressing priority. Int J Health Plann Manag. 2021.
Harvey A. Combatting health misinformation and disinformation: building an evidence base. In: COVID-19. Washington, DC: Health Affairs Forefront; 2021.
Google Scholar 
Mehmood Q, Ullah I, Hasan MM, Kazmi SK, Ahmadi A, Lucero-Prisno DE 3rd. COVID-19 vaccine hesitancy: Pakistan struggles to vaccinate its way out of the pandemic. Ther Adv Vaccines Immunother. 2022;10:25151355221077658.
Google Scholar 
Losada-Baltar A, Jiménez-Gonzalo L, Gallego-Alberto L, Pedroso-Chaparro MS, Fernandes-Pires J, Márquez-González M. “We are staying at home.” Association of self-perceptions of aging, personal and family resources, and loneliness with psychological distress during the lock-down period of COVID-19. J Gerontol B. 2021;76(2):e10–6.
Article  Google Scholar 
Hu G, Qiu W. From guidance to practice: promoting risk communication and community engagement for prevention and control of coronavirus disease (COVID-19) outbreak in China. J Evid Based Med. 2020;13(2):168–72.
Article  Google Scholar 
Scheres J, Kuszewski K. The ten threats to global health in 2018 and 2019. A welcome and informative communication of WHO to everybody. Zesz Nauk Ochr Zdr Zdr Publiczne Zarz. 2019;17(1):2–8.
Google Scholar 
Tustin JL, Crowcroft NS, Gesink D, Johnson I, Keelan J, Lachapelle B. User-driven comments on a Facebook advertisement recruiting Canadian parents in a study on immunization: content analysis. JMIR Public Health Surveill. 2018;4(3):e10090.
Article  Google Scholar 
Wilson SL, Wiysonge C. Social media and vaccine hesitancy. BMJ Glob Health. 2020;5(10):e004206.
Article  Google Scholar 
Wang P-W, Ahorsu DK, Lin C-Y, Chen I-H, Yen C-F, Kuo Y-J, et al. Motivation to have COVID-19 vaccination explained using an extended protection motivation theory among university students in China: the role of information sources. Vaccines. 2021;9(4):380.
Article  Google Scholar 
Breza E, Stanford FC, Alsan M, Alsan B, Banerjee A, Chandrasekhar AG, et al. Effects of a large-scale social media advertising campaign on holiday travel and COVID-19 infections: a cluster randomized controlled trial. Nat Med. 2021;27(9):1622–8.
Article  CAS  Google Scholar 
Razai MS, Osama T, McKechnie DGJ, Majeed A. Covid-19 vaccine hesitancy among ethnic minority groups. BMJ. 2021;372:n513.
Article  Google Scholar 
Robertson E, Reeve KS, Niedzwiedz CL, Moore J, Blake M, Green M, et al. Predictors of COVID-19 vaccine hesitancy in the UK household longitudinal study. Brain Behav Immun. 2021;94:41–50.
Article  CAS  Google Scholar 
Anderson J. America has a history of medically abusing Black people. No wonder many are wary of COVID-19 vaccines. USA Today. 2021;1. https://www.usatoday.com/story/news/2021/02/16/black-history-covid-vaccine-fears-medical-experiments/4358844001/.
Nyhan B, Reifler J, Richey S, Freed GL. Effective messages in vaccine promotion: a randomized trial. Pediatrics. 2014;133(4):e835–42.
Article  Google Scholar 
Faasse K, Chatman CJ, Martin LR. A comparison of language use in pro-and anti-vaccination comments in response to a high profile Facebook post. Vaccine. 2016;34(47):5808–14.
Article  Google Scholar 
Reno C, Maietti E, Di Valerio Z, Montalti M, Fantini MP, Gori D. Vaccine hesitancy towards COVID-19 vaccination: investigating the role of information sources through a mediation analysis. Infect Dis Rep. 2021;13(3):712–23.
Article  Google Scholar 
Al-Shamsi HO, Alhazzani W, Alhuraiji A, Coomes EA, Chemaly RF, Almuhanna M, et al. A practical approach to the management of cancer patients during the novel coronavirus disease 2019 (COVID-19) pandemic: an international collaborative group. Oncologist. 2020;25(6):e936.
Article  CAS  Google Scholar 
Puri N, Coomes EA, Haghbayan H, Gunaratne K. Social media and vaccine hesitancy: new updates for the era of COVID-19 and globalized infectious diseases. Hum Vaccin Immunother. 2020:1–8.
Meleo-Erwin Z, Basch C, MacLean SA, Scheibner C, Cadorett V. “To each his own”: discussions of vaccine decision-making in top parenting blogs. Hum Vaccines Immunother. 2017;13(8):1895–901.
Article  Google Scholar 
Daley MF, Glanz JM. Using social media to increase vaccine acceptance. Acad Pediatr. 2021;21(4):S32–3.
Article  Google Scholar 
Donovan J. Social-media companies must flatten the curve of misinformation. Nature. 2020. https://doi.org/10.1038/d41586-020-01107-z.
Osuagwu UL, Miner CA, Bhattarai D, Mashige KP, Oloruntoba R, Abu EK, et al. Misinformation about COVID-19 in sub-saharan africa: evidence from a cross-sectional survey. Health Secur. 2021;19(1):44–56.
Article  CAS  Google Scholar 
Ovenseri-Ogbomo G, Ishaya T, Osuagwu UL, Abu EK, Nwaeze O, Oloruntoba R, et al. Factors associated with the myth about 5G network during COVID-19 pandemic in sub-Saharan Africa. J Glob Health Rep. 2020;4:1–13.
Google Scholar 
Wise J. Covid-19: European countries suspend use of Oxford-AstraZeneca vaccine after reports of blood clots: British Medical Journal Publishing Group; 2021.
Google Scholar 
Shimabukuro TT, Cole M, Su JR. Reports of anaphylaxis after receipt of mRNA COVID-19 vaccines in the US—December 14, 2020-January 18, 2021. JAMA. 2021;325(11):1101–2.
Article  CAS  Google Scholar 
Wise J. Covid-19: people who have had infection might only need one dose of mRNA vaccine. BMJ. 2021;372:n308.
Article  Google Scholar 
Altman D. Why doctors and nurses can be vital vaccine messengers. Kaiser Family Foundation; 2021. https://www.kff.org/coronavirus-covid-19/perspective/why-doctors-and-nurses-can-be-vital-vaccne-messengers/.
Liz H, Ashley K, Lunna L, Audrey K, Grace S, Mollyann B. KFF COVID-19 vaccine Monitor: January 2021. In: Coronavirus: Kaiser Family Foundation (KFF); 2021.
Google Scholar 
McDonnell Nieto del Rio G. Doctors plead with Americans to take the virus surge seriously. The New York Times; https://www.nytimes.com/live/2020/11/15/world/covid-19-coronavirus#doctors-plead-with-americans-to-take-the-virus-surge-seriously. Accessed 8 June 2022.
Limaye RJ, Sauer M, Ali J, Bernstein J, Wahl B, Barnhill A, et al. Building trust while influencing online COVID-19 content in the social media world. Lancet Digit Health. 2020;2(6):e277–8.
Article  Google Scholar 
Habersaat KB, Jackson C. Understanding vaccine acceptance and demand—and ways to increase them. Bundesgesundheitsblatt-Gesundheitsforschung-Gesundheitsschutz. 2020;63(1):32–9.
Article  Google Scholar 
Larson HJ, Jarrett C, Eckersberger E, Smith DM, Paterson P. Understanding vaccine hesitancy around vaccines and vaccination from a global perspective: a systematic review of published literature, 2007–2012. Vaccine. 2014;32(19):2150–9.
Article  Google Scholar 
Biasio LR, Bonaccorsi G, Lorini C, Pecorelli S. Assessing COVID-19 vaccine literacy: a preliminary online survey. Hum Vaccin Immunother. 2021;17(5):1304–12.
Article  CAS  Google Scholar 
Johnson TP. Snowball sampling: introduction. In: Wiley StatsRef: Statistics Reference Online; 2014.
Google Scholar 
Varela C, Ruiz J, Andrés A, Roy R, Fusté A, Saldaña C. Advantages and disadvantages of using the website SurveyMonkey in a real study: psychopathological profile in people with normal-weight, overweight and obesity in a community sample. E-methodology. 2016;2016(3):77–89.
Google Scholar 
Mashige KP, Osuagwu UL, Ulagnathan S, Ekpenyong BN, Abu EK, Goson PC, et al. Economic, health and physical impacts of COVID-19 pandemic in sub-Saharan African regions: a cross sectional survey. Risk Manag Healthc Policy. 2021;14:4799.
Article  Google Scholar 
Murphy J, Vallières F, Bentall RP, Shevlin M, McBride O, Hartman TK, et al. Psychological characteristics associated with COVID-19 vaccine hesitancy and resistance in Ireland and the United Kingdom. Nat Commun. 2021;12(1):29.
Article  CAS  Google Scholar 
Abir T, Ekwudu OM, Kalimullah NA, Nur-A Yazdani DM, Al Mamun A, Basak P, et al. Dengue in Dhaka, Bangladesh: hospital-based cross-sectional KAP assessment at Dhaka north and Dhaka south city corporation area. PLoS One. 2021;16(3):e0249135.
Article  CAS  Google Scholar 
Vatcheva KP, Lee M, McCormick JB, Rahbar MH. Multicollinearity in regression analyses conducted in epidemiologic studies. Epidemiology (Sunnyvale, Calif). 2016;6(2):227.
Google Scholar 
Othman SS, Alsuwaidi A, Aseel R, Alotaibi R, Bablgoom R, Alharbi R, et al. Association between social media use and the acceptance of COVID-19 vaccination among the general population in Saudi Arabia–a cross-sectional study. BMC Public Health. 2022;22(1):1–11.
Article  Google Scholar 
Al-Regaiey KA, Alshamry WS, Alqarni RA, Albarrak MK, Alghoraiby RM, Alkadi DY, et al. Influence of social media on parents’ attitudes towards vaccine administration. Human Vaccin Immunother. 2022;18(1):1872340.
Article  Google Scholar 
Fridman I, Lucas N, Henke D, Zigler CK. Association between public knowledge about COVID-19, trust in information sources, and adherence to social distancing: cross-sectional survey. JMIR Public Health Surveill. 2020;6(3):e22060.
Article  Google Scholar 
Li HO-Y, Bailey A, Huynh D, Chan J. YouTube as a source of information on COVID-19: a pandemic of misinformation? BMJ Glob Health. 2020;5(5):e002604.
Article  Google Scholar 
Stein RA. The golden age of anti-vaccine conspiracies. Germs. 2017;7(4):168.
Article  Google Scholar 
Piltch-Loeb R, Savoia E, Goldberg B, Hughes B, Verhey T, Kayyem J, et al. Examining the effect of information channel on COVID-19 vaccine acceptance. PLoS One. 2021;16(5):e0251095.
Article  CAS  Google Scholar 
Margolis MA, Brewer NT, Shah PD, Calo WA, Gilkey MB. Stories about HPV vaccine in social media, traditional media, and conversations. Prev Med. 2019;118:251–6.
Article  Google Scholar 
Kollamparambil U, Oyenubi A. Behavioural response to the Covid-19 pandemic in South Africa. PLoS One. 2021;16(4):e0250269.
Article  CAS  Google Scholar 
Worsley A. Perceived reliability of sources of health information. Health Educ Res. 1989;4(3):367–76.
Article  Google Scholar 
Sterling MR, Tseng E, Poon A, Cho J, Avgar AC, Kern LM, et al. Experiences of home healthcare workers in New York City during the coronavirus disease 2019 pandemic: a qualitative analysis. JAMA Intern Med. 2020;180(11):1453–9.
Article  CAS  Google Scholar 
Falagas ME, Zarkadoulia E. Factors associated with suboptimal compliance to vaccinations in children in developed countries: a systematic review. Curr Med Res Opin. 2008;24(6):1719–41.
Article  Google Scholar 
Goldstein S, MacDonald NE, Guirguis S. Health communication and vaccine hesitancy. Vaccine. 2015;33(34):4212–4.
Article  Google Scholar 
Ackah M, Ameyaw L, Gazali Salifu M, Afi Asubonteng DP, Osei Yeboah C, Narkotey Annor E, et al. COVID-19 vaccine acceptance among healthcare workers in Africa: a systematic review and meta-analysis. PLoS One. 2022;17(5):e0268711.
Article  CAS  Google Scholar 
Nomhwange T, Wariri O, Nkereuwem E, Olanrewaju S, Nwosu N, Adamu U, et al. COVID-19 vaccine hesitancy amongst healthcare workers: an assessment of its magnitude and determinants during the initial phase of national vaccine deployment in Nigeria. EClinicalMedicine. 2022;50:101499.
Article  Google Scholar 
Manyaapelo T, Mokhele T, Sifunda S, Ndlovu P, Dukhi N, Sewpaul R, et al. Determinants of confidence in overall knowledge about covid-19 among healthcare workers in South Africa: results from an online survey. Front Public Health. 2021;9:614858.
Article  Google Scholar 
Steffens MS, Bullivant B, Bolsewicz K, King C, Beard F. Factors influencing COVID-19 vaccine acceptance in high income countries prior to vaccine approval and rollout: a narrative review. Int J Public Health. 2022;9.
Adane M, Ademas A, Kloos H. Knowledge, attitudes, and perceptions of COVID-19 vaccine and refusal to receive COVID-19 vaccine among healthcare workers in northeastern Ethiopia. BMC Public Health. 2022;22(1):1–14.
Article  Google Scholar 
Abir T, Osuagwu UL, Nur AYDM, Mamun AA, Kakon K, Salamah AA, et al. Internet use impact on physical health during COVID-19 lockdown in Bangladesh: a web-based cross-sectional study. Int J Environ Res Public Health. 2021;18(20):10728.
Article  CAS  Google Scholar 
Abu EK, Oloruntoba R, Osuagwu UL, Bhattarai D, Miner CA, Goson PC, et al. Risk perception of COVID-19 among sub-Sahara Africans: a web-based comparative survey of local and diaspora residents. BMC Public Health. 2021;21(1):1562.
Article  CAS  Google Scholar 
Hjort J, Poulsen J. The arrival of fast internet and employment in Africa. Am Econ Rev. 2019;109(3):1032–79.
Article  Google Scholar 
Pugliese-Garcia M, Heyerdahl LW, Mwamba C, Nkwemu S, Chilengi R, Demolis R, et al. Factors influencing vaccine acceptance and hesitancy in three informal settlements in Lusaka, Zambia. Vaccine. 2018;36(37):5617–24.
Article  Google Scholar 
Basak P, Abir T, Al Mamun A, Zainol NR, Khanam M, Haque MR, et al. A global study on the correlates of gross domestic product (GDP) and COVID-19 vaccine distribution. Vaccines. 2022;10(2):266.
Article  CAS  Google Scholar 
Lin C, Tu P, Beitsch LM. Confidence and receptivity for COVID-19 vaccines: a rapid systematic review. Vaccines (Basel). 2020;9(1):16.
Article  Google Scholar 
Sallam M, Dababseh D, Eid H, Al-Mahzoum K, Al-Haidar A, Taim D, et al. High rates of COVID-19 vaccine hesitancy and its association with conspiracy beliefs: a study in Jordan and Kuwait among other Arab countries. Vaccines. 2021;9(1):42.
Article  CAS  Google Scholar 
Download references
None.
This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.
Bathurst Rural Clinical School (BRCS), School of Medicine, Western Sydney University Bathurst, Bathurst, NSW, 2795, Australia
Uchechukwu L. Osuagwu
African Vision Research Institute, Discipline of Optometry, Westville Campus, University of KwaZulu-Natal, Durban, 3629, South Africa
Uchechukwu L. Osuagwu, Khathutshelo P. Mashige, Bernadine N. Ekpenyong & Kingsley E. Agho
Translational Health Research Institute (THRI), Western Sydney University, Campbeltown, NSW, 2560, Australia
Uchechukwu L. Osuagwu & Kingsley E. Agho
Department of Optometry, University of the Highlands and Islands, Inverness, IV2 3JH, UK
Godwin Ovenseri-Ogbomo
Department of Community Medicine, College of Health Sciences, University of Jos, Jos, 930003, Nigeria
Esther Awazzi Envuladu
Department of Optometry and Vision Science, School of Allied Health Sciences, College of Health and Allied Sciences, University of Cape Coast, Cape Coast, 00233, Ghana
Emmanuel Kwasi Abu
Department of Community Medicine, College of Health Sciences, University of Jos, Jos, 930003, Nigeria
Chundung Asabe Miner
Department of Optometry, Faculty of Health sciences, Mzuzu University, P. Bag 201 Luwinga 2,, Mzuzu, Malawi
Chikasirimobi G. Timothy
Department of Public Health, Faculty of Allied Medical Sciences, College of Medical Sciences, University of Calabar, Cross River State, Calabar, 540271, Nigeria
Bernadine N. Ekpenyong
Health Division, University of Bamenda, Bambili, P. O. Box 39, Cameroon
Raymond Langsi
Department of Optometry, Faculty of Life Sciences, University of Benin, Benin, Nigeria
Onyekachukwu M. Amiebenomo
School of Optometry and Vision Sciences, College of Biomedical Sciences, Cardiff, CF24 4HQ, UK
Onyekachukwu M. Amiebenomo
School of Management and Marketing, Curtin Business School, Curtin University, Bentley, WA, 6151, Australia
Richard Oloruntoba
Department of Psychiatry, College of Health Sciences, University of Jos, Jos, Nigeria
Piwuna Christopher Goson
Tanzania Food and Nutrition Center, P. O. Box 977, Dar es Salaam, Tanzania
Deborah Donald Charwe
Department of Computer Science, University of Jos, Jos, 930003, Nigeria
Tanko Ishaya
School of Health Sciences, Western Sydney University, Campbelltown, NSW, 2560, Australia
Kingsley E. Agho
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
All authors were involved in the conceptualization of the study; K.E.A, U.L.O., and K.P.M performed the methodology; Software, K.E.A., U.L.O.; Validation, T.I., R.O., E.E., B.N.E., O.A., K.P.M., E.K.A., M.C. and T.C.; Formal Analysis, K.E.A., and U.L.O.; Investigation, all authors; Resources, all authors; Data Curation, K.E.A., O.M.A, and U.L.O.; Writing – Original Draft Preparation, P.C.G., G.O., R.O.; E.E., U.L.O., E.A.; Writing – Review & Editing, K.P.M., G.O., O.A., E.A., K.E.A., K.P.M., R.L., D.D.C., and M.C.; Visualization, K.P.M., and K.E.A.; Supervision, K.E.A., U.L.O., T.I, B.N.E, K.P.M; Project Administration, K.E.A., U.L.O. and P.C.G.. All authors reviewed the manuscript, read and agreed to the published version of the manuscript.
Correspondence to Uchechukwu L. Osuagwu.
The study was conducted following the Declaration of Helsinki involving human subjects and was approved by the Humanities and Social Sciences Research Ethics Committee (approval #: HSSREC 00002504/2021) of the University of KwaZulu-Natal, Durban, South Africa. Informed consent was obtained from all participants involved in the study.
Not applicable.
The authors declare that they have no competing interests.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Sample of Survey Item.
Country of origin of respondents.
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data.
Reprints and Permissions
Osuagwu, U.L., Mashige, K.P., Ovenseri-Ogbomo, G. et al. The impact of information sources on COVID-19 vaccine hesitancy and resistance in sub-Saharan Africa. BMC Public Health 23, 38 (2023). https://doi.org/10.1186/s12889-022-14972-2
Download citation
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/s12889-022-14972-2
Anyone you share the following link with will be able to read this content:
Sorry, a shareable link is not currently available for this article.

Provided by the Springer Nature SharedIt content-sharing initiative
Advertisement
ISSN: 1471-2458
By using this website, you agree to our Terms and Conditions, Your US state privacy rights, Privacy statement and Cookies policy. Your privacy choices/Manage cookies we use in the preference centre.
© 2023 BioMed Central Ltd unless otherwise stated. Part of Springer Nature.

source

(Visited 1 times, 1 visits today)
Close