Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-26T14:58:38.276Z Has data issue: false hasContentIssue false

Behavioural intention of receiving COVID-19 vaccination, social media exposures and peer discussions in China

Published online by Cambridge University Press:  23 April 2021

Sitong Luo
Affiliation:
Centre for Health Behaviours Research, JC School of Public Health and Primary Care, The Chinese University of Hong Kong, New Territory, Hong Kong SAR, China
Meiqi Xin
Affiliation:
Centre for Health Behaviours Research, JC School of Public Health and Primary Care, The Chinese University of Hong Kong, New Territory, Hong Kong SAR, China
Suhua Wang
Affiliation:
Graduate School of Baotou Medical College, Baotou Medical College, Baotou, Inner Mongolia, China
Junfeng Zhao
Affiliation:
Department of Psychology, School of Education, Henan University, Kaifeng, China
Guohua Zhang
Affiliation:
Department of Psychology, School of Psychiatry, Wenzhou Medical University, Wenzhou, China
Lijuan Li
Affiliation:
School of Public Health, Dali University, Dali, Yunnan, China
Liping Li
Affiliation:
Shantou University Medical College, Shantou, China
Joseph Tak-fai Lau*
Affiliation:
Centre for Health Behaviours Research, JC School of Public Health and Primary Care, The Chinese University of Hong Kong, New Territory, Hong Kong SAR, China
*
Author for correspondence: Joseph Tak-fai Lau, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The study aimed to investigate behavioural intentions to receive free and self-paid COVID-19 vaccinations (BICV-F and BICV-SP) among Chinese university students if the vaccine was 80% effective with rare mild side effects, to examine their associations with social media exposures and peer discussions regarding COVID-19 vaccination, and to explore the mediational role of perceived information sufficiency about COVID-19 vaccination. An online anonymous survey (N = 6922) was conducted in November 2020 in five Chinese provinces. Logistic regression and path analysis were adopted. The prevalence of BICV-F and BICV-SP were 78.1% and 57.7%. BICV-F was positively associated with the frequencies of passive social media exposure (adjusted odds ratio (AOR) = 1.32, P < 0.001), active social media interaction (AOR = 1.13, P < 0.001) and peer discussions (AOR = 1.17, P < 0.001). Indirect effects of the three factors on BICV-F via perceived information sufficiency were all significant (P < 0.001). The direct effect of active social media interaction on BICV-F was significantly negative (P < 0.001). Similar associations/mediations were observed for BICV-SP. The COVID-19 vaccination intention of Chinese university students needs improvement. Boosting social media exposures and peer discussions may raise students' perceived information sufficiency and subsequently increase their vaccination intention. Considering the potential negative effect of active social media interaction, caution is needed when using social media to promote COVID-19 vaccination.

Type
Original Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press

Introduction

Immunisation is seen as the most promising measure to end the COVID-19 pandemic [1]. Despite the remarkable progress of COVID-19 vaccine development, vaccine hesitancy has raised public health concerns [Reference Megget2]. Prior to the COVID-19 pandemic, vaccine hesitancy was listed as one of the top 10 threats to global health by the World Health Organization (WHO) given the resurgence of vaccine-preventable diseases [3]. A number of studies conducted across countries (e.g. France, Italy, U.S.A., Canada, Israel, China and Indonesia) have warned that vaccine hesitancy may undermine the success of future COVID-19 vaccination programmes, with the reported prevalence of acceptability or behavioural intention of receiving COVID-19 vaccination ranging from 57.6% to 93.3% [Reference Wang4Reference Lazarus10]. It is warranted to understand the facilitators and barriers that influence the acceptance of COVID-19 vaccines.

Social media are the major platforms for information seeking and discussion about COVID-19 [Reference Saud, Mashud and Ida11, Reference Lin12]. As previous studies have shown that online information influenced people's perceptions, attitudes and intentions regarding vaccination (e.g. HPV vaccination) [Reference Betsch13Reference Yang and Myrick15], COVID-19 vaccination-related information on social media is potentially important in shaping the public's intention to vaccinate. There is a dearth of empirical studies looking at such relationships. It is common for people to access professional information about vaccines' safety and efficacy via social media [Reference Yin16]. Correct information on vaccination may strengthen their confidence and trust of vaccines [Reference Zhang17]. For instance, previous studies on influenza and HPV vaccinations illustrated that the frequency of exposure to vaccination-related information via social media was positively associated with positive beliefs and utilisation of those vaccines [Reference Ortiz, Smith and Coyne-Beasley18, Reference Ahmed19]. However, social media sometimes convey misinformation and anti-vaccination sentiments, such as conspiracy theories, exaggerated side effects and down-graded vaccine efficacy that may increase vaccine hesitancy [Reference Johnson20, Reference Puri21]. Examples include those cases involving HPV and MMR (measles, mumps and rubella) vaccinations [Reference Ortiz, Smith and Coyne-Beasley18, Reference Wang22]. Warnings about such potential negative impacts on COVID-19 vaccination via social media have been discussed [Reference Johnson20, Reference Cornwall23]. A number of influential international health organisations have partnered with social media giants to combat COVID-19 and promote COVID-19 vaccination. For instance, some platforms (e.g. Facebook) have been directing their users to webpages of the WHO while they are seeking information about COVID-19 vaccines, so as to provide them with accurate and reliable information and remove false claims about COVID-19 vaccines that have been debunked by the WHO [24, 25].

Along with social media influences, peer discussion may affect individuals' intention to vaccinate against COVID-19, as it is another major source of information and social influences which takes place both in online and offline settings [Reference Southwell and Yzer26]. A U.S. survey reported that 38% of the general population indicated that their family members' and friends' opinions would influence their COVID-19 vaccination decisions [Reference Reiter, Pennell and Katz27]. Peer communication may contribute to the creation of social norms that may enhance the intention to vaccinate [Reference Larson28]. A qualitative Singaporean study reported that motivation regarding influenza vaccination was strengthened via communications with friends [Reference Teo29]. In contrast, peer discussion that involves negative attitudes about vaccines may diminish the intention to vaccinate [Reference Larson28]. To the best of our knowledge, no study has examined the association between the frequency of peer discussions about COVID-19 vaccines and the intention of receiving COVID-19 vaccination.

People may feel inadequately informed about the expedited COVID-19 vaccine development, whereas the perceived sufficiency of the obtained information is important for making decisions of receiving vaccination [Reference Dubé30]. Perceived sufficiency of the information related to vaccination was positively associated with influenza vaccination and negatively associated with confusion and mistrust of influenza vaccines [Reference Esteban-Vasallo31, Reference Korkmaz32]. The availability of sufficient information was also associated with a lower level of parental scepticism and hesitancy of early childhood vaccination [Reference Kaufman33]. However, sufficient information about the negative aspects of COVID-19 vaccines may deter people from vaccination. For instance, parents who rejected childhood vaccinations had searched for a large amount of information about vaccination [Reference Burton-Jeangros, Golay and Sudre34]. Moreover, perceived information sufficiency may mediate between the frequencies of social media exposures/peer discussions about COVID-19 vaccines and the intention of receiving COVID-19 vaccination, as such exposures/discussions may increase perceived sufficiency of related information, which may in turn boost or hinder the vaccination intention. No study has looked at such mediations.

A few studies have examined the intention of receiving COVID-19 vaccination among university students in Europe and Southeast Asia [Reference Grech and Gauci35Reference Baloran37]. COVID-19 vaccination among university students is important as the campus setting often involves close contacts and high vulnerability of COVID-19. It is also a good setting for health promotion, which has been used effectively in promoting HPV vaccination [Reference Gerend, Murdock and Grove38] and flu vaccination [Reference Caleb39]. COVID-19 vaccination among university students may avoid closures of campuses that may affect learning. Furthermore, university students are intensive social media users who often use social media as the main source of information seeking, sharing and exchanges [Reference Zachos, Paraskevopoulou-Kollia and Anagnostopoulos40]. It is thus warranted to investigate whether the information obtained from social media and peer discussions about COVID-19 vaccination would increase or decrease the vaccination intention among university students.

The current study investigated the prevalence and associated factors of behavioural intentions of receiving COVID-19 vaccination among Chinese university students if the vaccine was 80% effective with rare mild side effects. The factors included (1) the frequency of passive exposure to information about COVID-19 vaccination on social media, (2) the frequency of active interaction about COVID-19 vaccination on social media, (3) the frequency of peer discussions about COVID-19 vaccination and (4) the level of perceived sufficiency of the obtained information about COVID-19 vaccination for decision-making. As the aforementioned associations could both be positive or negative, the four alternate hypotheses were two-sided. In addition, a mediation hypothesis was tested, that the associations between the frequencies of passive social media exposure/active social media interaction/peer discussions and the vaccination intention would be fully or partially mediated by perceived information sufficiency about COVID-19 vaccination.

Methods

Study design

An anonymous cross-sectional survey was conducted during 1–28 November 2020 among university students in China via an online survey platform. Through personal networks, a number of academic staff of five universities in five provinces of mainland China formed a fieldwork team. The five provinces (Zhejiang in the east, Yunnan in the south-west, Guangdong in the south, Inner Mongolia in the north and Henan in the middle) represented to some extent the country's geographical and socioeconomic variations. The researchers selected 165 classes of various grades (e.g. year 1 to 4) within the faculties of arts, sciences, social sciences, economics or management, engineering and medicine or pharmacy (and others) of the five participating universities by convenience sampling. The teachers or student representatives of the selected classes helped to send an invitation message, a QR code to access the online questionnaire and three to five daily reminders of participation to all the students of the selected classes via the existing class-based WeChat groups used for class administration. WeChat has over 1 billion Chinese subscribers and involves multiple functions (e.g. messaging, sharing news/photos/documents and digital payment).

The inclusion criteria included being (a) full-time students of the selected universities and (b) able to read and write Chinese. The exclusion criterion was a self-reported experience of having received experimental COVID-19 vaccination by the time of the survey (n = 18). The questionnaire was self-administered and took about 10–15 min to complete. In the invitation message sent to the students and at the beginning of the online questionnaire, the aims, procedures and voluntary and anonymous nature of the study were clearly presented, and it was also stated that the submission of the questionnaire implied informed consent to participate in the survey. The students were thus able to make decisions of participation with a full understanding of the survey. Upon completion, the participant could join a lottery which offered eight prizes of 10–50 RMB (about 1.5–7.5 USD) and a symbolic ‘lucky money’ of 1 RMB for the half of the participants for each university. Ethical approval was obtained from the ethics committee of the corresponding author's affiliated university. The same method had been used in another previously published COVID-19 study targeting university students conducted by the same research team [Reference Xin41]. The response rate (the number of returned questionnaires divided by the number of invitations) was 72.3% (6940/9593). The final analysed sample size was 6922.

Measures

Behavioural intention of receiving COVID-19 vaccination

The behavioural intention of receiving COVID-19 vaccination was assessed by two items: the participants' perceived chance of taking up (1) free and (2) self-paid (price: 400 RMB, about 60 USD) COVID-19 vaccines during the first 6 months since the vaccines' availability in the country, assuming the vaccine was 80% effective and had rare mild side effects. The response categories ranged from 1 = ‘definitely not’ to 5 = ‘definitely yes’. Those who answered ‘probably yes’ or ‘definitely yes’ were defined as having a behavioural intention of receiving COVID-19 vaccination for free (BICV-F) or having a behavioural intention of receiving COVID-19 vaccination with a self-payment (BICV-SP).

Exposure to information about COVID-19 vaccination via social media

Passive social media exposure. The participants were asked to recall their frequencies of viewing COVID-19 vaccination-related information via (1) governmental social media accounts and (2) civil social media accounts on social media platforms (e.g. Weibo and WeChat) in the past month. In China, governmental accounts and civil accounts are both accessible on major social media platforms. Some governmental agencies (e.g. the central and local governments, state media, health commissions and CDCs) use their social media accounts to communicate with the general public and disseminate official information, whereas the general public use their civil social media accounts for daily interactions. The response categories were 1 = ‘never’, 2 = ‘rarely’, 3 = ‘sometimes’, 4 = ‘often’, 5 = ‘always’. A composite scale (the frequency of passive social media exposure scale) was constructed by taking the average of the two item scores to represent the overall frequency of passive exposure (range: 1–5).

Active social media interaction. The participants were asked to rate their frequencies of (1) actively searching or seeking consultation about COVID-19 vaccination-related information via social media, and (2) actively sharing COVID-19 vaccination-related information with others on social media (e.g. forwarding messages, comments and ‘like’). The response categories were similar to those of the passive social media exposure. A composite scale was also constructed using the average of the two item scores to represent the overall frequency of active social media interaction (range: 1–5).

Peer discussions about COVID-19 vaccination

A single item, ‘How frequently did you discuss with your classmates or friends about COVID-19 vaccination in the past month?’, was used to measure the frequency of peer discussions. The responses ranged from 1 = ‘never’ to 5 = ‘always’.

Perceived sufficiency of the obtained information about COVID-19 vaccination for decision-making (perceived information sufficiency)

A single item, ‘Do you think that the information about COVID-19 vaccination you have currently obtained is sufficient for you to decide whether to take up COVID-19 vaccines?’, was used. The responses included 1 = ‘very insufficient’, 2 = ‘somewhat insufficient’, 3 = ‘neutral’, 4 = ‘somewhat sufficient’, 5 = ‘very sufficient’.

Background information

Background information including age, sex, ethnicity, faculty, grade and COVID-19-related experiences (i.e. whether had been mandatorily quarantined due to COVID-19 and whether had been diagnosed with COVID-19) were collected.

Data analysis

Univariate logistic regression was conducted to examine the crude associations between the background variables/studied independent variables (i.e. frequency of passive social media exposure, frequency of active social media interaction, frequency of peer discussion, level of perceived information sufficiency) and the two binary dependent variables (i.e. BICV-F and BICV-SP). Age and the studied independent variables were included as continuous variables in the logistic regression and subsequent analyses, whereas other variables were treated as binary variables. Adjusted odds ratio (AOR) was derived to assess the association between each of the studied independent variables and the two dependent variables, adjusted for those background variables that were significantly associated with the dependent variables in the univariate analysis. Pearson's correlations among the independent variables were then derived. Finally, path analysis with weighted least square mean and variance adjusted estimation was adopted to test the hypothesised mediation models, adjusted for significant background variables (Figs 1 and 2). The direct and indirect effects of passive social media exposure/active social media interaction/peer discussions on the dependent variables via perceived information sufficiency were reported. The 95% bias-corrected confidence interval (CI) of the indirect effects were estimated based on 2000 bootstrapped samples. The paths' standardised coefficients and statistical significance were exhibited. Indices of good model fit included root mean square error of approximation (RMSEA) <0.06, comparative fit index (CFI) and Tucker Lewis index (TLI) >0.95. The analyses were conducted using SPSS 24.0 and MPlus 8.3 software. A two-sided P below 0.05 was considered statistically significant.

Fig. 1. Proposed mediation model for the behavioural intention of receiving free COVID-19 vaccination. ***P < 0.001, **P < 0.01, *P < 0.05.

Fig. 2. Proposed mediation model for the behavioural intention of receiving self-paid COVID-19 vaccination. ***P < 0.001, **P < 0.01, *P < 0.05.

Results

Distributions of the studied variables

Among the 6922 participants, the mean age was 19.4 (standard deviation = 1.5); the majority were females (63.6%) and Han people (86.8%). The main faculties of the participants included arts (12.9%), science (10.2%), engineering (11.8%) and medicine/pharmacy (50.3%) (Table 1). The main grades comprised of first-year (43.2%), second-year (27.4%) and third-year (16.8%). Thus, the medical/pharmaceutical students and first-year students were over-sampled. About 13.9% of the sample reported a history of mandatory quarantine due to COVID-19, and 2.8% reported a history of COVID-19 diagnosis.

Table 1. Distributions of the studied variables (N = 6922)

s.d., standard deviation; COVID-19, coronavirus disease 2019.

a The response categories were 1 = ‘never’, 2 = ‘rarely’, 3 = ‘sometimes’, 4 = ‘often’, 5 = ‘always’.

b The response categories were 1 = ‘very insufficient’, 2 = ‘somewhat insufficient’, 3 = ‘neutral’, 4 = ‘somewhat sufficient’, 5 = ‘very sufficient’.

The prevalence of BICV-F and a BICV-SP was 78.1% and 57.7%, respectively. The mean level of the frequency of passive social media exposure was 2.7 (s.d. = 1.0); that of the frequency of active social media interaction was 2.3 (s.d. = 1.0) and that of the frequency of peer discussions was 2.4 (s.d. = 0.9). For these variables, ‘2’ meant ‘rarely’ and ‘3’ meant ‘sometimes’. The mean level of the perceived information sufficiency variable was 2.7 (s.d. = 0.9), with ‘2’ indicating ‘somewhat insufficient’ and ‘3’ indicating ‘neutral’. Again, these independent variables were used as continuous variables in the subsequent analysis.

Crude associations between the background variables and BICV-F/BICV-SP

The simple logistic regression showed that the significant background factors of BICV-F included continuous age (OR = 0.95, P = 0.013), being a male (OR = 0.86, P = 0.015), being a first-year student (OR = 1.17, P = 0.008), experience of mandatory quarantine (OR = 0.73, P < 0.001) and a COVID-19 diagnosis (OR = 0.30, P < 0.001) (Table 2). These variables were similarly associated with BICV-SP except that there was no significant sex difference.

Table 2. Crude associations between the background variables and the behavioural intention of receiving COVID-19 vaccination (N = 6922)

OR, odds ratio; CI, confidence interval; COVID-19, coronavirus disease 2019.

a Simple logistic regression on the binary intention of receiving free/self-paid COVID-19 vaccination was performed for each background variable.

Associations between the independent variables and BICV-F/BICV-SP

Both the simple and multivariable (adjusting for the background variables) logistic regressions found that BICV-F was all positively associated with the frequency of passive social media exposure (AOR = 1.32, P < 0.001), the frequency of active social media interaction (AOR = 1.13, P < 0.001), the frequency of peer discussions (AOR = 1.17, P < 0.001) and the level of perceived information sufficiency (AOR = 1.53, P < 0.001) (Table 3).

Table 3. Crude and adjusted associations of the behavioural intention of receiving COVID-19 vaccination with social media exposures, peer discussions and perceived information sufficiency (N = 6922)

OR, odds ratio; AOR, adjusted odds ratio; CI, confidence interval; COVID-19, coronavirus disease 2019.

***P < 0.001.

a Simple logistic regression on the binary intention of receiving free/self-paid COVID-19 vaccination was performed for each independent variable.

b Multivariable logistic regression on the binary intention of receiving free/self-paid COVID-19 vaccines was performed for each independent variable, with age, sex, grade, history of being mandatorily quarantined due to COVID-19 and history of being diagnosed with COVID-19 being controlled for.

c Multivariable logistic regression on the binary intention of receiving free/self-paid COVID-19 vaccines was performed for each independent variable, with age, grade, history of being mandatorily quarantined due to COVID-19 and history of being diagnosed with COVID-19 being controlled for.

Similarly, BICV-SP was positively associated with the frequency of passive social media exposure (AOR = 1.44, P < 0.001), the frequency of active social media interaction (AOR = 1.28, P < 0.001), the frequency of peer discussions (AOR = 1.27, P < 0.001) and the level of perceived information sufficiency (AOR = 1.55, P < 0.001).

Correlations among the independent variables

Significant correlations were found between the frequencies of passive social media exposure and active social media interaction (r = 0.79, P < 0.001), the frequencies of passive social media exposure and peer discussions (r = 0.49, P < 0.001) and the frequencies of active social media interaction and peer discussions (r = 0.47, P < 0.001) (Table 4). The frequencies of passive social media exposure (r = 0.34, P < 0.001), active social media interaction (r = 0.34, P < 0.001) and peer discussions (r = 0.36, P < 0.001) were all significantly associated with the level of perceived information sufficiency.

Table 4. Correlations between social media exposures, peer discussions and perceived information sufficiency (N = 6922)

***P < 0.001; a value of 1 implies a perfect correlation.

The mediation effects of perceived information sufficiency

The proposed mediation model for BICV-F fitted the study data well (CFI = 0.973; TLI = 0.952; RMSEA = 0.032). First, the three indirect effects of the frequencies of passive social media exposure (standardised coefficient = 0.03; 95% CI 0.02–0.04; P < 0.001)/active social media interaction (standardised coefficient = 0.03; 95% CI 0.02–0.04; P < 0.001)/peer discussions (standardised coefficient = 0.05; 95% CI 0.04–0.06; P < 0.001) on BICV-F via the level of perceived information sufficiency were all statistically significant. Second, the direct effect from the frequency of passive social media exposure to BICV-F was significantly positive (standardised coefficient = 0.23, P < 0.001). The direct effect from the frequency of active social media interaction to BICV-F was significantly negative (standardised coefficient = −0.17, P < 0.001). The direct effect from the frequency of peer discussions to BICV-F was statistically non-significant. The standardised coefficient and statistical significance of each pathway of the model are exhibited in Figure 1. The mediation model for BICV-SP also fitted the study data well (CFI = 0.983; TLI = 0.968; RMSEA = 0.028). Its indirect and direct effects were very similar to those of the BICV-F model (see Fig. 2).

Discussion

The study found that about 3/4 and 3/5 of the sampled university students intended to take up free and self-paid COVID-19 vaccination, respectively, during the first 6 months since the vaccines' availability in China, assuming the vaccine was 80% effective and had rare mild side effects. The prevalence was higher than that of the Maltese university students (30.5%) [Reference Grech and Gauci35] but was lower than that of the Italian university students (86.1%) [Reference Barello36] and Pilipino college students (81.3%) [Reference Baloran37]. There are prompt needs for health promotion, especially if free COVID-19 vaccination was not made available to university students in China, although such a scenario is unlikely to occur. As university students are usually responsive to public health issues and relatively open to new measures [Reference Barello36], they are more likely to be better informed about COVID-19 vaccine development than the general public. It is contended that their prevalence of the intention to receive COVID-19 vaccination may be higher than that of the general population, which can be tested in future studies.

Attention should be given to the potential importance of perceived information sufficiency about the COVID-19 vaccines, as the variable was positively associated with the intention to vaccinate and mediated the associations between passive social media exposure/active social media interaction/peer discussions and the intention to vaccinate significantly. The findings suggest that boosting passive/active social media exposures and peer discussions may increase students' perceived sufficiency of COVID-19 vaccination-related information for decision-making, which may in turn raise their vaccination intention. Previous studies have found that sufficient knowledge was significantly and positively associated with health-related behaviours [Reference Brewer42], including the uptake of vaccination such as influenza vaccination [Reference Esteban-Vasallo31, Reference Korkmaz32] and childhood vaccination [Reference Kaufman33]. It is warranted to increase the perceived information sufficiency regarding COVID-19 vaccination among university students, as despite the fact that half of the participants were medical/pharmaceutical students, the average level of perceived information sufficiency was relatively low. It was only between ‘somewhat insufficient’ and ‘neutral’, implying the majority of the university students might not possess sufficient information to decide whether to take up COVID-19 vaccination. This is somehow understandable as none of the COVID-19 vaccines had been approved by the time of the survey (November 2020). Thus, little information about their efficacy and safety was then available.

The frequency of passive social media exposure (e.g. view) was significantly and positively associated with the two types of intention to vaccinate (free and self-paid) in the logistic regression. The path analysis gave a more elaborated picture, that besides the aforementioned mediation via perceived information sufficiency, passive social media exposure showed a significantly positive direct effect on the intention to vaccinate against COVID-19. The findings imply that even passive exposure (i.e. viewing posted information instead of searching or seeking consultations) may improve the vaccination intention. It is a limitation that we did not ask the students about the contents they viewed on social media platforms and whether the contents supported or hindered their intention to vaccinate. However, there are reasons to believe that the related social media messages tended to support COVID-19 vaccination, as research has shown that the Chinese media, including social media, in general frame the development of COVID-19 vaccines in China positively [Reference Yin16]. Furthermore, the country has taken some measures to tackle the spread of online misinformation about COVID-19 based on the Cybersecurity Law (2017) [Reference Rodrigues and Xu43]. Social media users are encouraged to report such messages to the social media platforms and/or ask for fact-checking. Messages containing detected rumours and misinformation would be removed from the social media, and the responsible accounts may be suspended [Reference Rodrigues and Xu43]. Thus, some ‘filtering’ of COVID-19 vaccination-related information on social media may have occurred in China, which may lead to the possibility that more positive than negative messages about COVID-19 vaccination have appeared on social media platforms. The disproportionately positive messages might have contributed to the observed positive association between passive social media exposure and the vaccination intention. As it was a partial instead of full mediation via perceived information sufficiency, other mediators may exist (e.g. increased cue to action according to the health belief model [Reference Strecher and Rosenstock44] or observational learning of the social cognitive model [Reference Cury45]). Such potential mechanisms require testing in future research.

Interestingly, although the frequency of active social media interaction (e.g. active search, consult, comment, forward and like) was positively associated with the intention to vaccinate against COVID-19 via an increased perceived information sufficiency, its direct effect on the intention was significantly negative. The findings thus suggest that besides the potential positive effects, active social media interaction may also have some elements that may de-motivate the intention of receiving COVID-19 vaccination. It is plausible that active searching may increase the likelihood of finding some negative news about COVID-19 vaccines that may increase vaccine hesitancy. Prior studies reported that the social media in China had exposed problems about several vaccines (e.g. influenza vaccine and childhood vaccines), and the concerns had reduced people's intention of taking up related vaccines [Reference Hu46, Reference Yang, Penders and Horstman47]. Thus, active social media interaction may both increase and reduce the intention of receiving COVID-19 vaccination. Other potential suppressors between active social media interaction and the vaccination intention (e.g. higher exposure to information doubting COVID-19 vaccines) need to be examined in future studies. The findings remind us about possible inconsistent effects of social media exposures and caution needed when using social media to promote COVID-19 vaccination.

The frequency of discussion with peers (e.g. friends and classmates) also presented a significantly positive association with the intention to vaccinate in the logistic regression, whereas its indirect effect on the vaccination intention via perceived information sufficiency was significantly positive. The findings support previous research which showed that peer discussions could be used to promote vaccination behaviours (e.g. promotion of HPV vaccines in China) [Reference Reiter, Pennell and Katz27Reference Teo29, Reference Brewer42, Reference Li and Li48]. Peer discussions are interactive communications occurring in offline or online settings, during which the questions and answers between peers may increase students' perceived information sufficiency about COVID-19 vaccination and subsequently promote their intention to vaccinate. The direct effect of peer discussions on the intention of receiving COVID-19 vaccination was statistically non-significant in the study. It may be because that the association between peer discussions and the vaccination intention was fully mediated by the perceived information sufficiency, or because that there existed some other mediators (e.g. subjective norm towards COVID-19 vaccination) and suppressors (e.g. negative attitudes towards COVID-19 vaccines from peers) that offset the potential positive and negative effects [Reference Larson28, Reference Brewer42].

Notably, the sampled university students' frequencies of passive/active social media exposures and peer discussions regarding COVID-19 vaccination were not particularly high (between ‘rarely’ and ‘sometimes’). It is plausible that COVID-19 vaccination has not been made available to the public in China yet. It was thus not a very ‘hot’ topic. The situation may change over time when COVID-19 vaccines appear on the market. Future interventions to promote COVID-19 vaccination among university students may consider to boost their passive social media exposure and peer discussions, so as to help them accumulate accurate information about COVID-19 vaccines [Reference Brewer42]. For instance, first, health organisations (e.g. China CDC) and key opinion leaders may post updated information about COVID-19 vaccines on their social media accounts frequently, which have shown to be effective at raising knowledge and intention of taking up HPV vaccination [Reference Ortiz49] and childhood vaccination [Reference Shoup50]. Second, to attract students to view the vaccination-related information on social media, live presenters and animated presentation are suggested to be used. A recent study analysed the top 100 widely viewed COVID-19 vaccine videos on YouTube, and found almost all of the videos (90%) featured a live presenter, whereas 10% featured an animated presentation [Reference Basch51]. Third, links to pages of COVID-19 vaccines on the websites of official health organisations (e.g. WHO and CDC) should be widely disseminated on social media platforms for accessing accurate information and fact-checking [Reference Ozoma52]. In addition, on-campus seminars/events about COVID-19 vaccination and dissemination of evidence-based materials (e.g. signs and posters) [Reference Gerend, Murdock and Grove38] are suggested to stimulate peer discussions about COVID-19 vaccination.

This study has some limitations. First, the cross-sectional design had a limited ability of causal inference. The path model was only exploratory. Longitudinal studies are needed to confirm the causal relationships. Second, selection bias might exist due to non-random sampling and non-responses. The sample was overrepresented by the first-year students (43.2%) who showed a significantly higher odd of vaccination intention in the regression analysis, suggesting an overestimation of the prevalence of BICV-F and BICV-SP. Medical and pharmaceutical students also accounted for a large proportion of the sample, who might have a higher level of perceived information sufficiency about COVID-19 vaccination. However, the variable was not significantly associated with the vaccination intention. The bias may thus not be substantial. Third, social desirability bias might also lead to an overestimation of the prevalence of BICV-F and BICV-SP. Last but not least, the generalisation of the study findings to a broader population should be made cautiously, as the study was limited to the university students in five universities in China.

In conclusion, the study demonstrated that the frequencies of passive social media exposure and peer discussions about COVID-19 vaccination were positively associated with the level of perceived information sufficiency of COVID-19 vaccination, which might subsequently increase both the intentions to receive free and self-paid COVID-19 vaccinations. Future vaccination promotion programmes targeting university students may consider increasing the levels of these factors. In addition, the frequency of active interaction on social media showed a negative direct effect on the vaccination intention. Such opposite findings remind us that exposure to social media messages may have both positive and negative effects on the vaccination intention and caution is needed when using social media platforms to promote COVID-19 vaccination. Future studies need to confirm the current study findings.

Acknowledgement

The authors thank Wenjie Hou from the Baotou Medical College, Dongdong Gao from the Henan University, Xiaolian Tu, Nani Ding and Jingjing Zhang from the Wenzhou Medical University and Yingjie Xiao, Ping Li, Dongyue Lin, Haotao Li, Qiang Fang, Shanyan Yu and Mingqiang Liu from the Shantou University for their contributions in data collection. They also thank the participants for their time and efforts.

Financial support

This work was supported by the internal funding of the corresponding author's institution.

Conflict of interest

None.

Data availability statement

The paper has contained sufficient information to allow others to understand the findings. Readers can contact the authors if they want access to materials to replicate the findings.

Footnotes

*

These authors contributed equally to the study.

References

WHO (2020) COVID-19 vaccines. [cited 7 December 2020]. Available at https://www.who.int/emergencies/diseases/novel-coronavirus-2019/covid-19-vaccines.Google Scholar
Megget, K (2020) Even COVID-19 can't kill the anti-vaccination movement. BMJ 369(m2184), 12.Google ScholarPubMed
WHO (2019) Top Ten Threats to Global Health in 2019. Geneva, Switzerland: WHO: Emergencies.Google Scholar
Wang, J et al. (2020) Acceptance of COVID-19 vaccination during the COVID-19 pandemic in China. Vaccines 8, 482.CrossRefGoogle ScholarPubMed
Frank, K and Arim, R (2020) Canadians’ willingness to get a COVID-19 vaccine when one becomes available: what role does trust play?. Canada: Statistics Canada.Google Scholar
Jose, R et al. (2020) Public perception and preparedness for the pandemic COVID 19: a health belief model approach. Clinical Epidemiology and Global Health 9, 4146.CrossRefGoogle ScholarPubMed
Fisher, KA et al. (2020) Attitudes toward a potential SARS-CoV-2 vaccine: a survey of US adults. Annals of Internal Medicine 173(12), 964973.CrossRefGoogle Scholar
Harapan, H et al. (2020) Acceptance of a COVID-19 vaccine in Southeast Asia: a cross-sectional study in Indonesia. Frontiers in Public Health 8(381), 18.CrossRefGoogle ScholarPubMed
Neumann-Böhme, S et al. (2020) Once we have it, will we Use it? A European Survey on Willingness to be Vaccinated against COVID-19 The European Journal of Health Economics 21, 977982.CrossRefGoogle ScholarPubMed
Lazarus, JV et al. (2021) A global survey of potential acceptance of a COVID-19 vaccine. Nature Medicine 27, 225228.CrossRefGoogle ScholarPubMed
Saud, M, Mashud, Mi and Ida, R (2020) Usage of social media during the pandemic: seeking support and awareness about COVID-19 through social media platforms. Journal of Public Affairs 20, e2417.Google Scholar
Lin, Y et al. (2020) Influence of mass and social media on psychobehavioral responses among medical students during the downward trend of COVID-19 in Fujian, China: Cross-sectional study. Journal of Medical Internet Research 22, e19982.CrossRefGoogle ScholarPubMed
Betsch, C et al. (2010) The influence of vaccine-critical websites on perceiving vaccination risks. Journal of Health Psychology 15, 446455.CrossRefGoogle ScholarPubMed
Nan, X and Madden, K (2012) HPV vaccine information in the blogosphere: how positive and negative blogs influence vaccine-related risk perceptions, attitudes, and behavioral intentions. Health Communication 27, 829836.CrossRefGoogle ScholarPubMed
Yang, G and Myrick, JG (2020) Online media use and HPV vaccination intentions in mainland China: integrating marketing and communication perspectives to improve public health. Health Education Research 35, 110122.CrossRefGoogle ScholarPubMed
Yin, F et al. (2021) Unfolding the determinants of COVID-19 vaccine acceptance in China. Journal of Medical Internet Research 23, e26089.CrossRefGoogle ScholarPubMed
Zhang, J et al. (2021) Effects of fact-checking social media vaccine misinformation on attitudes toward vaccines. Preventive Medicine 145, 106408.CrossRefGoogle ScholarPubMed
Ortiz, RR, Smith, A and Coyne-Beasley, T (2019) A systematic literature review to examine the potential for social media to impact HPV vaccine uptake and awareness, knowledge, and attitudes about HPV and HPV vaccination. Human Vaccines & Immunotherapeutics 15, 14651475.CrossRefGoogle ScholarPubMed
Ahmed, N et al. (2018) Social media use and influenza vaccine uptake among white and African American adults. Vaccine 36, 75567561.CrossRefGoogle ScholarPubMed
Johnson, NF et al. (2020) The online competition between pro- and anti-vaccination views. Nature 582, 230233.CrossRefGoogle ScholarPubMed
Puri, N et al. (2020) Social media and vaccine hesitancy: new updates for the era of COVID-19 and globalized infectious diseases. Human Vaccines & Immunotherapeutics 16, 25862593.CrossRefGoogle ScholarPubMed
Wang, Y et al. (2019) Systematic literature review on the spread of health-related misinformation on social media. Social Science & Medicine 240, 112552.CrossRefGoogle ScholarPubMed
Cornwall, W (2020) Officials gird for a war on vaccine misinformation. American Association for the Advancement of Science.CrossRefGoogle Scholar
Facebook (2020) An Update on Our Work to Keep People Informed and Limit Misinformation About COVID-19. [cited 2021 March 11]. Available at https://about.fb.com/news/2020/04/covid-19-misinfo-update/#removing-more-false-claims.Google Scholar
WHO (2019) Vaccine Misinformation: Statement by WHO Director-General on Facebook and Instagram. [cited 2021 March 11]. Available at https://www.who.int/news/item/04-09-2019-vaccine-misinformation-statement-by-who-director-general-on-facebook-and-instagram.Google Scholar
Southwell, BG and Yzer, MC (2007) The roles of interpersonal communication in mass media campaigns. Annals of the International Communication Association 31, 420462.CrossRefGoogle Scholar
Reiter, PL, Pennell, ML and Katz, ML (2020) Acceptability of a COVID-19 vaccine among adults in the United States: how many people would get vaccinated? Vaccine 38, 65006507.CrossRefGoogle ScholarPubMed
Larson, HJ et al. (2014) Understanding vaccine hesitancy around vaccines and vaccination from a global perspective: a systematic review of published literature, 2007–2012. Vaccine 32, 21502159.CrossRefGoogle ScholarPubMed
Teo, L et al. (2019) Attitudes and perception of influenza vaccines among older people in Singapore: a qualitative study. Vaccine 37, 66656672.CrossRefGoogle ScholarPubMed
Dubé, E et al. (2013) Vaccine hesitancy: an overview. Human Vaccines & Immunotherapeutics 9, 17631773.CrossRefGoogle ScholarPubMed
Esteban-Vasallo, MD et al. (2018) Adequacy of information provided by healthcare professionals on vaccines: results of a population survey in Spain. Patient Education and Counseling 101, 12401247.CrossRefGoogle ScholarPubMed
Korkmaz, P et al. (2019) Influenza vaccination prevalence among the elderly and individuals with chronic disease, and factors affecting vaccination uptake. Central European Journal of Public Health 27, 4449.CrossRefGoogle ScholarPubMed
Kaufman, J et al. (2018) Face-to-face interventions for informing or educating parents about early childhood vaccination. Cochrane Database of Systematic Reviews 5, 193.Google ScholarPubMed
Burton-Jeangros, C, Golay, M and Sudre, P (2005) Compliance and resistance to child vaccination: a study among Swiss mothers. Revue d'epidemiologie et de sante publique 53, 341.CrossRefGoogle ScholarPubMed
Grech, V and Gauci, C (2020) Vaccine hesitancy in the university of Malta faculties of health sciences, dentistry and medicine vis-à-vis influenza and novel COVID-19 vaccination. Early Human Development Nov 12, 105258. doi: 10.1016/j.earlhumdev.2020.105258. [Epub ahead of print].CrossRefGoogle Scholar
Barello, S et al. (2020) Vaccine hesitancy’ among university students in Italy during the COVID-19 pandemic. European Journal of Epidemiology 35, 781783.CrossRefGoogle ScholarPubMed
Baloran, ET (2020) Knowledge, attitudes, anxiety, and coping strategies of students during COVID-19 pandemic. Journal of Loss and Trauma 25, 635642.CrossRefGoogle Scholar
Gerend, MA, Murdock, C and Grove, K (2020) An intervention for increasing HPV vaccination on a university campus. Vaccine 38, 725729.CrossRefGoogle ScholarPubMed
Caleb, S et al. (2020) How colleges intervene to increase student body vaccination coverage. Journal of American College Health May 14, 18. doi: 10.1080/07448481.2020.1752698. AHEAD-OF-PRINTCrossRefGoogle Scholar
Zachos, G, Paraskevopoulou-Kollia, E-A and Anagnostopoulos, I (2018) Social media use in higher education: a review. Education Sciences 8, 194.CrossRefGoogle Scholar
Xin, M et al. (2020) Negative cognitive and psychological correlates of mandatory quarantine during the initial COVID-19 outbreak in China. American Psychologist 75, 607.CrossRefGoogle ScholarPubMed
Brewer, NT et al. (2017) Increasing vaccination: putting psychological science into action. Psychological Science in the Public Interest 18, 149207.CrossRefGoogle Scholar
Rodrigues, UM and Xu, J (2020) Regulation of COVID-19 fake news infodemic in China and India. Media International Australia 177, 125131.CrossRefGoogle Scholar
Strecher, VJ and Rosenstock, IM (1997) The health belief model. Cambridge Handbook of Psychology, Health and Medicine 113, 117.Google Scholar
Cury, F et al. (2006) The social-cognitive model of achievement motivation and the 2×2 achievement goal framework. Journal of Personality and Social Psychology 90, 666.CrossRefGoogle Scholar
Hu, D et al. (2020) Chinese social media suggest decreased vaccine acceptance in China: an observational study on Weibo following the 2018 Changchun Changsheng vaccine incident. Vaccine 38, 27642770.CrossRefGoogle ScholarPubMed
Yang, R, Penders, B and Horstman, K (2020) Addressing vaccine hesitancy in China: a scoping review of Chinese scholarship. Vaccines 8, 2.CrossRefGoogle Scholar
Li, L and Li, J (2020) Factors affecting young Chinese women's intentions to uptake human papillomavirus vaccination: an extension of the theory of planned behavior model. Human Vaccines & Immunotherapeutics 16, 31233130.CrossRefGoogle ScholarPubMed
Ortiz, RR et al. (2018) Development and evaluation of a social media health intervention to improve adolescents’ knowledge about and vaccination against the human papillomavirus. Global Pediatric Health 5, 2333794X18777918.CrossRefGoogle ScholarPubMed
Shoup, JA et al. (2015) Development of an interactive social media tool for parents with concerns about vaccines. Health Education & Behavior 42, 302312.CrossRefGoogle ScholarPubMed
Basch, CH et al. (2020) YouTube coverage of COVID-19 vaccine development: implications for awareness and uptake. Human Vaccines & Immunotherapeutics 16, 25822585.CrossRefGoogle ScholarPubMed
Ozoma, I (2019) Bringing authoritative vaccines results to Pinterest search. Pinterest Newsroom 28.Google Scholar
Figure 0

Fig. 1. Proposed mediation model for the behavioural intention of receiving free COVID-19 vaccination. ***P < 0.001, **P < 0.01, *P < 0.05.

Figure 1

Fig. 2. Proposed mediation model for the behavioural intention of receiving self-paid COVID-19 vaccination. ***P < 0.001, **P < 0.01, *P < 0.05.

Figure 2

Table 1. Distributions of the studied variables (N = 6922)

Figure 3

Table 2. Crude associations between the background variables and the behavioural intention of receiving COVID-19 vaccination (N = 6922)

Figure 4

Table 3. Crude and adjusted associations of the behavioural intention of receiving COVID-19 vaccination with social media exposures, peer discussions and perceived information sufficiency (N = 6922)

Figure 5

Table 4. Correlations between social media exposures, peer discussions and perceived information sufficiency (N = 6922)