Skip to main content
Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Examining the effect of information channel on COVID-19 vaccine acceptance

  • Rachael Piltch-Loeb ,

    Roles Conceptualization, Formal analysis, Writing – original draft

    rpl5@nyu.edu, piltch-loeb@hsph.harvard.edu

    Affiliation Division of Policy Translation & Leadership Development, Emergency Preparedness Research Evaluation & Practice [EPREP] Program, Harvard T.H. Chan School of Public Health, Boston, Massachusetts, United States of America

  • Elena Savoia,

    Roles Funding acquisition, Writing – review & editing

    Affiliation Division of Policy Translation & Leadership Development, Emergency Preparedness Research Evaluation & Practice [EPREP] Program, Harvard T.H. Chan School of Public Health, Boston, Massachusetts, United States of America

  • Beth Goldberg,

    Roles Conceptualization, Writing – review & editing

    Affiliation Jigsaw, Google LLC, New York, New York, United States of America

  • Brian Hughes,

    Roles Writing – review & editing

    Affiliation Center for University Excellence [CUE] and Polarization and Extremism Research and Innovation Lab [PERIL], American University, Washington, DC, United States of America

  • Tanner Verhey,

    Roles Writing – review & editing

    Affiliation Trust and Safety, Google LLC, Sunnyvale, California, United States of America

  • Juliette Kayyem,

    Roles Writing – review & editing

    Affiliation Harvard Kennedy School, Harvard University, Cambridge, Massachusetts, United States of America

  • Cynthia Miller-Idriss,

    Roles Funding acquisition, Writing – review & editing

    Affiliation Center for University Excellence [CUE] and Polarization and Extremism Research and Innovation Lab [PERIL], American University, Washington, DC, United States of America

  • Marcia Testa

    Roles Methodology, Writing – review & editing

    Affiliation Division of Policy Translation & Leadership Development, Emergency Preparedness Research Evaluation & Practice [EPREP] Program, Harvard T.H. Chan School of Public Health, Boston, Massachusetts, United States of America

Abstract

Hesitancy towards the COVID-19 vaccine remains high among the US population. Now that the vaccine is available to priority populations, it is critical to convince those that are hesitant to take the vaccine. Public health communication about the vaccine as well as misinformation on the vaccine occurs through a variety of different information channels. Some channels of information are more commonly found to spread misinformation. Given the expansive information environment, we sought to characterize the use of different media channels for COVID-19 vaccine information and determine the relationship between information channel and vaccine acceptance. We used quota sampling of vaccine priority groups [N = 2,650] between December 13 and 23, 2020 and conducted bivariate chi-squared tests and multivariable multinomial logistic regression analyses to determine the relative impact of channels of information on vaccine acceptance. We found traditional channels of information, especially National TV, National newspapers, and local newspapers increased the likelihood of vaccine acceptance. Individuals who received information from traditional media compared to social media or both traditional and social media were most likely to accept the vaccine. The implications of this study suggest social media channels have a role to play in educating the hesitant to accept the vaccine, while traditional media channels should continue to promote data-driven and informed vaccine content to their viewers.

Introduction

The COVID-19 vaccine has been met with a mix of excitement and apprehension. A significant portion of the United States population continue to have hesitancy towards a COVID-19 vaccine, with close to 40% of the population unsure if they will be vaccinated, and another 30% unlikely to do so as of the end of 2020 [1]. The level of vaccine hesitancy in anticipation of vaccine approval by regulatory agencies has become more critical now that the vaccine is available, especially for high priority health care workers and vulnerable populations. The control of COVID-19 is largely dependent upon its uptake. Accordingly, the impact of public risk communication efforts on the effectiveness, safety and availability of the vaccine are critical to vaccine uptake. Furthermore, risk communication efforts can be implemented through numerous information channels. How information channels are perceived by the public and which channels are used to receive information about both COVID-19 and the vaccine will determine the likelihood of achieving satisfactory levels of vaccine uptake [2].

Since the beginning of the COVID-19 pandemic, there has been an abundance of information, with nearly every media channel covering the latest developments [3]. Information channels, both traditional and social media, are sharing vaccine information and may be very influential in swaying public opinion as to whether or not members of the public want to be vaccinated. Past research has found that online forums, blogs, and social media have contributed to the spread of vaccine hesitancy. Several authors have examined how social media platforms contribute to vaccine hesitancy such as by promoting personal narratives over empirical data and connecting anti-vaccination themes to broader belief systems of freedom of choice and parental rights [47]. Social media has continued to be a vehicle for the spread of COVID-19 misinformation [2].

Misinformation related generally to the pandemic at large has spread online, and has increased with the introduction of the vaccine [2]. For example, there have been rampant conspiracy beliefs that the virus was created as a government bioweapon, and that the virus was the result of 5G cellular networks [8]. Singh and colleagues (2020) found that low quality sources that were unverified and appeared to promote misinformation on COVID-19 were more commonly retweeted than those with high quality information linked to verifiable health authorities. In a comparative analysis of the spread of COVID-19 misinformation on five social media platforms (Twitter, Instagram, YouTube, Reddit and Gab), Cinelli and colleagues (2020) analyzed more than 8 million comments and posts to model the spread of misinformation [9]. The authors found that amplification of misinformation varied by platform, suggesting that misinformation dissemination depends on the way in which people interact on the platform along with the platform’s algorithms and by the specific interaction patterns of groups of users engaged with the topic.

The content and spread of misinformation online can influence risk perception and vaccine hesitancy [10, 11]. Exposure to websites and social media posts discouraging immunizations, even when brief, can increase perception of vaccination risk while decreasing the perception of benefits [10]. Viewing such content can reduce viewers’ vaccination intentions [11]. Buller and colleagues (2019) describe how Facebook users appeared disproportionately swayed towards vaccine hesitancy due to narratives and emotional stories [12]. Nadler, Crain and Donovan (2018) describe this advantage of poor- quality information over good as a direct and predictable consequence of the digital media ecosystem in combination with practices and technologies of consumer monitoring, audience customization, and the automation of influence campaigns [13].

Individuals tend to receive information from multiple information channels during a pandemic [14, 15]. Channels of information are relied upon by risk communicators to push out a message, and the public who pulls on that information and pushes it to their own network [16, 17]. Bennet, Manheim and others, suggests that patterns of homogenization, polarization, and targeted marketing have created a “one-step flow” of persuasion even in legacy media, in which interpersonal social influence recedes as targeted media increasingly exercises direct influence over individual opinion [1820]. Further, media consumption patterns are often habitual, preceding a given event or information topic [2123]. There is much discussion and research on social media as a vehicle for misinformation and vaccine skepticism, and less on the role that traditional media, such as TV, newspapers, and radio can play in misinformation [24]. An individual’s perception of a given channel can impact how that person acts upon that information. Perceptions of credibility, authoritativeness, and persuasiveness vary by information source [25, 26]. For example, information that is seen as straightforward, not sensationalized, and accurate from legacy and local news outlets has been shown to increase vaccine acceptance [27].

Given the expansive information environment, habitual nature of media habits which precede vaccination attitudes, and need for vaccine uptake, we sought to characterize the use of different media channels for COVID-19 vaccine information, how that information is trusted, and the relative effect on vaccination likelihood. We specifically had two research questions, namely:

  1. How much do individuals trust vaccine information from different information channels?
  2. What is the relationship between channels of information and vaccine acceptance?

We hypothesized that information from traditional media would be more positive and trusted compared to social media channels, and that getting information from traditional media channels would be more likely to increase willingness to take the vaccine.

Methods

Study design

We conducted a cross-sectional online survey via mobile devices on the Pollfish survey platform. Pollfish pays mobile application developers to display the surveys within their applications. To incentivize participation, small monetary incentives are provided to randomly selected users who complete the surveys. The Pollfish platform uses random device engagement (RDE) to reach users engaged in using a mobile application who are identified only by a unique device ID [28]. Pollfish has over 900,000,000 users worldwide and selected a random sample of United States users who fit the eligibility criteria set by the research team (more below). The use of Pollfish biases the sample towards those familiar with using a mobile device. An initial survey draft underwent pilot cognitive testing with 20 individuals, and the survey was subsequently revised for length and clarity. The survey was designed to be completed in approximately ten minutes or less and for ease of completion on a mobile device. The survey was conducted between December 13th and 23rd, 2020. We created a non-probability, purposive sample of individuals who were likely to be in vaccine priority groups at the time the survey was conducted [29]. Respondents were eligible to participate if they resided in the United States, were 18 years of age or older, and were in a vaccine priority group at the time the survey was administered [which included healthcare workers and, per CDC guidance, essential frontline workers] based on national guidance available at the time the survey was developed [30]. This sample was selected to generate responses among those most likely to be in a place to be making a vaccine decision in the near future at the time of survey. The study protocol and survey instrument were approved by the Harvard T.H. Chan School of Public Health Institutional Review Board. Participants reviewed information on the study before consenting to participating by beginning the survey by clicking yes they agreed to participate. No minors were involved in this study.

Dependent variable

Respondents were asked about their intentions to take the vaccine by answering the question how likely they would be to receive a COVID-19 vaccine if offered to them at no cost within two months. The six response options were very likely, somewhat likely, somewhat unlikely, very unlikely, would consider it after two months, and not sure. For the scope of this analysis, the six response options were categorized into the dependent variable of “vaccine acceptance”, on the rating scale defined as: 1) “vaccine acceptant”- those that reported “very likely”, 2) “some hesitancy” in taking the vaccine- those that reported they were “somewhat likely” (19.7% of respondents), “somewhat unlikely” (5.8% of respondents), “would get it after two months” (7.1% of respondents), or were “not sure” (14.6% of respondents), and 3) “vaccine hesitant”- those who were “very unlikely.”

Independent variables

The effects of COVID-19 vaccine information channels, and the trust in information from those channels, on vaccine acceptance is the primary interest of this analysis. Respondents were asked to select up to three channels from which they had received most of their information on the COVID-19 vaccine. Since information channels are not mutually exclusive, each channel was treated as an indicator variable, dichotomized by whether or not the channel had been selected. In addition, we also created a variable to characterize the sources of information an individual selected with three distinct categories, namely: getting most information from only traditional media channels, which we defined as TV, newspaper, or radio; getting most information from only social media channels which we defined as Facebook, Instagram, YouTube, Twitter, or Tiktok; and getting most information from both social and traditional media channels. The categorization we used was based on prior literature, some of which also refers to these traditional media channels as legacy media or pre-social media channels [16, 3133].

Trust in information was measured by analyzing responses to the question “How much do you trust the information you got so far about the COVID-19 vaccine?” with response options: not at all, very little, somewhat, and a lot. Not at all, and very little were combined into a category named as “low trust” to obtain an ordered categorical “trust” variables with three levels, low trust, some trust, and high trust. Respondents also selected each channel of COVID-19 vaccine information they had been exposed to overall and rated the attitude of information received from that channel as positive, negative, or neutral.

In addition to the primary independent variables of interest described above—information channels accessed and trust in information—we also explored several independent variables that have previously been found to relate to vaccine hesitancy and health behaviors including socio-demographics, perceived risk, COVID-19 experience, and prior vaccination behaviors. Socio-demographic variables were age, gender, race, level of education, and type of job (working in the healthcare sector versus not working in this sector). Age categories were re-coded to combine small sample subgroups for age groups over 55. Lower education levels were collapsed to create one category that referenced high school education or lower and General Education Development (GED) or equivalent. COVID-19 risk perception was measured by asking respondents to report their level of concern of contracting COVID-19 at work or outside their work environment, and their level of concern about infecting family members or friends. Responses were dichotomized into two risk-related variables (medium/low reported risk vs. high risk). COVID-19 experience included having been sick with COVID-19 (yes/no), knowing someone who had a severe COVID-19 infection (yes/no), and knowing someone who had died of COVID-19 (yes/no). As a proxy for prior vaccination behavior, we asked respondents if they had received their flu vaccine this year.

Statistical analysis

To answer our first research question regarding the level of trust in COVID-19 information from various channels, we analyzed the proportion of respondents who utilized each information channel, the quality rating of vaccine information from each channel, as well as the level of trust per channel using descriptive statistics. In preparation for multivariable analysis, and to answer our second research question concerning acceptance of the vaccine, we conducted bivariate analyses using chi-squared tests and multivariable regression analysis to study the association between the independent variables and the likelihood of taking the COVID-19 vaccine. We conducted chi-squared tests of independence to test for associations between the levels of each independent variable and the levels of the dependent variable indicative of vaccine hesitancy, some hesitancy, or acceptant. We used a p-value of <0.05 as the threshold for inclusion of the predictor variable in the multinomial logistic regression model. We also tested for collinearity among predictors by Spearman’s rank correlation test prior to the completion of the regression analysis, using the cutoff of 0.7 as a measure of collinearity. We specifically tested for collinearity among information sources and found that the degree of collinearity was not high enough to exclude a particular source. Due to the significant challenges in convincing those who are strongly committed in their anti-vaccination beliefs [34, 35], for multivariable regression analysis we conducted multinomial logistic regression to identify the relative risk of being very likely to take the vaccine compared to those in the some-hesitancy group. A generalized Hosmer–Lemeshow goodness-of-fit test for multinomial logistic regression models was used to assess the goodness of fit [36]. Data analysis was performed using Stata Statistical Software: Release 16 College Station, TX: StataCorp LLC.

Results

Sample characteristics

There were 2,650 in our analytic sample. The sample was predominantly White 66.0%, male (53.9%), and 65.9% were between 25 and 44 years of age. The majority worked in the healthcare sector (61.4%) and had tended to have advanced degrees with 54.6% possessing a Bachelor’s degree or higher. In terms of COVID-19 experience, approximately one-quarter of respondents reported having COVID-19, 22.6% had a close family member or friend who was a severe case, and 11.3% had a close family member or friend who had died of COVID-19. The prevalence of COVID in the sample was over three times that reported in the United States (23,214,472 cases out of a population of 331,992,651 as of January 12, 2021) reflecting the intended high exposure and infection rate in the sample. The majority of respondents had a high level of perceived risk of contracting COVID-19 at work or outside of work (65.3%) and infecting others with COVID-19 (62.5%). About half of the sample had received their flu vaccine. Among all respondents, 12.8% were very unlikely to take the vaccine in the next two months 47.3% had some level of hesitancy, and 39.9% were very likely to do so. A detailed breakdown of these characteristics is given in Table 2.

Descriptive statistics

Table 1 describes the proportion of users of each information channel, the variations in attitude towards the vaccine across channels, as well as the level of trust in information among channels. The majority of respondents reported getting COVID-19 vaccine information from local TV (61%). The next highest source was Facebook (37.8%), followed by National TV, YouTube, National Newspaper, Instagram, Twitter, Radio, Local Newspaper, and Tiktok. Overall, 53.6% of respondents reported that the COVID-19 vaccine information they saw was mostly positive, 25.3% reported seeing it as neither positive or negative, 16.3% of respondents reported that what they heard about the was mostly negative, and 4.8% reported not seeing vaccine-related information on any channel. The quality ratings of the information varied across channels. In contrast though, among those who used social media channels, the attitude toward the vaccine among those channels appeared to be relatively positive. The majority of respondents indicated that what they heard about the vaccine was positive, compared to negative or neutral (64–74%). Of those who used Twitter, nearly 75% reported the information they saw was positive (the highest among any channel), compared to just 47% on National TV and 48% in National Newspapers. Overall trust in information was high for 23% of respondents, moderate for 40.5%, and low for 36.3%. Though the majority reported overall what they heard was positive information, those who reported the information they saw was generally negative on the vaccine had higher levels of trust in information (20% had high trust in positive information vs. 31% had high trust in negative information). The level of trust in vaccine information was highest for National newspapers and radio (approximately 34%).

thumbnail
Table 1. Description of COVID-19 information from different channels.

https://doi.org/10.1371/journal.pone.0251095.t001

Also, in Table 1, there were significant differences (p < 0.001) in both attitude of information and level of trust by channel type. Those who used only traditional media reported seeing information that was neither positive or negative at much higher rates (31.2%) than those that used social media or traditional media, and those that used both types of channels reported information was mostly positive (66.9%). Echoing the theme as looking at the individual channels, trust was higher in information from traditional media channels compared to social media channels, or a mix of the two sources. Fig 1 illustrates the level of trust in COVID-19 vaccine information across the channels described.

thumbnail
Fig 1. Trust in COVID-19 information by information channel.

https://doi.org/10.1371/journal.pone.0251095.g001

Bivariate and multivariable regression analysis

Table 2 presents the bivariate analysis among variables and vaccine acceptance. There were statistically significant differences in vaccine acceptance by gender, education, knowing someone who had died of COVID-19, level of perceived risk for contracting COVID-19, having received the flu vaccine, getting information from national TV, local TV, national newspaper, radio, Facebook, YouTube, Instagram, and Twitter, as well as level of trust in information. There was no significant difference in vaccination acceptance based on prior COVID-19 diagnosis. Females were more likely to be very likely to get the vaccine compared to males (41.7% vs. 38.0%), while those with post-graduate education were least likely to get the vaccine (37.0%) compared to other levels of education (Bachelor’s degree, 41.0%, Some-college 43.7%, and High school education or less 39.5%). A higher proportion of those who knew someone who had died of COVID-19 were very likely to get the vaccine. Those with higher perceived risk of contracting COVID-19, as well as those who had received the flu vaccine, were more hesitant. As shown in Table 2, a higher proportion of individuals who had gotten information from a national TV (47.4%), local TV (44.6%), national newspaper (54.6%), and radio (50.8) were vaccine acceptant compared to those who had not. Aggregating the channels of interest, there was a statistically significant difference in vaccine acceptance among those who had exclusively gotten information only from traditional media (46.9%), only from social media (29.3%), or both types of channels (37.1%). Those with high trust in COVID-19 vaccine information were more likely to get vaccinated (81.5%).

Table 3 shows the results of the first multinomial multivariable logistic regression analyzing the specific types of channels on vaccine acceptance. The generalized Hosmer–Lemeshow goodness-of-fit test for multinomial logistic regression models confirmed the model was a good fit for the data (p = 0.787). Three channels of information were significant predictors of being very likely to take the vaccine: those that got information from national TV were 25% more vaccine acceptant (Relative Risk Ratio (RRR 1.25, CI 1.02–1.53)), those that got information from local TV were 75% more likely (RRR 1.75, CI 1.40–2.19), and those that got information from a national newspaper were over 80% more acceptant (RRR 1.81, CI 1.45–2.24) to do so, compared to those who did not use the source. Trust in information greatly increased the relative risk of vaccine acceptance. Some trust in COVID-19 vaccine information doubled the relative risk of vaccine acceptance (RRR 2.01, CI 1.61–2.51) while high trust in information was fifteen times more likely (RRR 15.04, CI 11.26–20.09). Having a close family member or friend who had died of COVID-19, respondents were 47% more acceptant of the vaccine (OR 1.47, CI 1.08, 1.99). No other covariate increased the relative risk of vaccine acceptance. As shown in Table 4, we explored a second multivariable model to move beyond individual channels, to investigate whether there was an effect due to using a particular type of media channel (traditional vs. social vs. both). While there were no statistically significant changes to the relative risk of vaccine acceptance due to any other variable, there was a clear decrease in acceptance if individuals exclusively used social media (RRR 0.45, CI 0.32–0.64) or used both social media and traditional media channels (RRR 0.81, CI 0.66–1.00) compared to those who only used traditional media.

thumbnail
Table 3. Multivariable multinomial regression of vaccine acceptance.

https://doi.org/10.1371/journal.pone.0251095.t003

thumbnail
Table 4. Multivariable multinomial regression of likelihood of vaccine acceptance.

https://doi.org/10.1371/journal.pone.0251095.t004

Discussion

How to increase vaccine uptake in a population that has relatively high levels of vaccine hesitancy is an ongoing public health challenge. Our analysis compares being “very likely to take the vaccine,” which we defined as “acceptant” to “somewhat likely or unlikely”, which we defined as “hesitant” enabling us to isolate the factors that increase the relative risk of vaccine uptake relative to being hesitant. Our sample had high levels of exposure to COVID-19 (26% reported having had the virus) compared to the average US population estimates of 7% with ranges estimated between 1 and 23%, likely due to workforce exposure [37]. Overall, respondents were also more likely to be willing to get the vaccine compared to other poll results from the same time period [1].

The results show that the majority of respondents are using traditional media to obtain information on the COVID-19 vaccine in some way (86%) and use of traditional media sources was found to increase the likelihood of vaccination. In particular, obtaining information from TV, both local and national, and national newspapers, increased acceptance of vaccination (regardless of how much the channel is trusted). Traditional media channels are likely adhering to high quality sources, sharing fact-based vaccine information linked to governmental, healthcare, or academic data and reports, and are clearly crucial channels to promote immunization programs [38]. Traditional media channels should continue to promote vaccination information to their viewers and readers.

In contrast, there did not seem to be independent effects of receiving information from a given social media platform. However, the results also show that those who are less likely to get the vaccine are using social media as their sole source of information, or as at least one of their sources of information. Attention is needed from social media companies to address vaccine hesitancy and the spread of misinformation. Social media platforms have an opportunity to consider how information on those platforms can be crafted to encourage vaccination [39]. Given the vulnerability of social media channels to exploitation by bad actors, and their diminished trustworthiness relative to legacy media, it may be necessary to draw on traditional channels to pursue persuasive campaigns more pointedly addressing the needs of audiences with neutral and oppositional attitudes toward the COVID-19 vaccine. Trust is an influential factor that can make a source appear more credible and could buffer against the effective of disinformation [40]. The same customization and targeted marketing capabilities that enable exploitation by bad actors on social media might also offer opportunities to address these needs using a one-step communicative approach whereby information is targeted to an individual across multiple platforms [18, 19].

We also considered if trust was a potential mediator of the relationship between channel and hesitancy, hypothesizing if a channel was trusted, the relationship to vaccination likelihood would change. To identify if trust in a particular channel was driving the effect of that channel, we tested interaction terms for each traditional channel that was significant, as well as by channel types, but found no significant interaction effects between type of media channel and trust. This suggests it is not just trust in a given channel that is driving its impact on vaccination likelihood. We hypothesize it is the combination of familiarity in traditional media and perceived credibility of the sources they cite such as public health experts or academic leaders that is contributing to the effect of traditional media channels. There also may be an interaction between the type of information and the channel of information which could be explored in future work [41]. Traditional media channels are now accessible online, and often they have made their content on the COVID-19 vaccine free for public viewing.

Limitations

This is a cross-sectional study and cannot disentangle if those that are already more likely to take the vaccine are drawn to traditional media channels, while those that are more hesitant are using social media or other channels we did not include in our analysis. Further longitudinal analysis is necessary to explore this issue. Additionally, TV and newspaper channels may be promoted on social media channels such as when an individual sees a given newspaper’s story being shared on Facebook. This analysis cannot separate out the impact of this exchange. Respondents were also not asked exclusively to select a particular channel of information. This paper also did not evaluate the cumulative effect of getting information from multiple channels or the frequency of information from a given channel. Additionally, this is not a representative sample, but rather a purposive sample of workers in potential vaccine priority groups in the US. Future covariates to explore may be political party, given the politicized nature of the COVID-19 pandemic. The results may not be generalizable beyond this sample.

Conclusions

The COVID-19 vaccine rollout is already underway. Anecdotal reports suggest some of those who are eligible for the vaccine are refusing to get vaccinated [42, 43]. This paper demonstrates that in the United States it is useful to draw on traditional media sources to discuss the COVID-19 vaccine. We also show that because vaccine-hesitant individuals are more likely to identify social media as their sole source of information, social media platforms have a particularly important role to play in addressing vaccine hesitancy [44].

References

  1. 1. Hamel LK, A. Munana, C. Brodie, M. KFF COVID-19 Vaccine Monitor: December 2020. Kaiser Family Foundation [KFF]; 2020 December 15, 2020.
  2. 2. 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. Human Vaccines & Immunotherapeutics. 2020:1–8. pmid:32693678
  3. 3. Krause NM, Freiling I, Beets B, Brossard D. Fact-checking as risk communication: the multi-layered risk of misinformation in times of COVID-19. Journal of Risk Research. 2020:1–8.
  4. 4. Basch CH, MacLean SA. A content analysis of HPV related posts on instagram. Human vaccines & immunotherapeutics. 2019;15[7–8]:1476–8. pmid:30570379
  5. 5. Arif N, Al-Jefri M, Bizzi IH, Perano GB, Goldman M, Haq I, et al. Fake News or Weak Science? Visibility and Characterization of Antivaccine Webpages Returned by Google in Different Languages and Countries. Frontiers in Immunology. 2018;9[1215]. pmid:29922286
  6. 6. Ekram S, Debiec KE, Pumper MA, Moreno MA. Content and commentary: HPV vaccine and YouTube. Journal of pediatric and adolescent gynecology. 2019;32[2]:153–7. pmid:30445163
  7. 7. Moran MB, Lucas M, Everhart K, Morgan A, Prickett E. What makes anti-vaccine websites persuasive? A content analysis of techniques used by anti-vaccine websites to engender anti-vaccine sentiment. Journal of Communication in Healthcare. 2016;9[3]:151–63.
  8. 8. Imhoff R, Lamberty P. A bioweapon or a hoax? The link between distinct conspiracy beliefs about the Coronavirus disease [COVID-19] outbreak and pandemic behavior. Social Psychological and Personality Science. 2020;11[8]:1110–8.
  9. 9. Cinelli M, Quattrociocchi W, Galeazzi A, Valensise CM, Brugnoli E, Schmidt AL, et al. The covid-19 social media infodemic. arXiv preprint arXiv:200305004. 2020.
  10. 10. Betsch C, Renkewitz F, Betsch T, Ulshöfer C. The influence of vaccine-critical websites on perceiving vaccination risks. Journal of health psychology. 2010;15[3]:446–55. pmid:20348365
  11. 11. Nan X, Madden K. HPV vaccine information in the blogosphere: how positive and negative blogs influence vaccine-related risk perceptions, attitudes, and behavioral intentions. Health communication. 2012;27[8]:829–36. pmid:22452582
  12. 12. Buller DB, Walkosz BJ, Berteletti J, Pagoto SL, Bibeau J, Baker K, et al. Insights on HPV vaccination in the United States from mothers’ comments on Facebook posts in a randomized trial. Human vaccines & immunotherapeutics. 2019;15[7–8]:1479–87. pmid:30785361
  13. 13. Nadler A, Crain M, Donovan J. Weaponizing the digital influence machine. Data & Society. 2018.
  14. 14. Piltch-Loeb R, Merdjanoff AA, Abramson DM. How the US Population Engaged with and Prioritized Sources of Information about the Emerging Zika Virus in 2016. Health security. 2018;16[3]:165–77. pmid:29927341
  15. 15. Piltch-Loeb R. Optimizing Risk Communication In An Emerging Threat: The Impact Of Information Seeking Behavior And Information Source On Intervention Receptivity- Evidence From The 2016 Zika Epidemic From The United States Population [Dissertation]. ProQuest: New York University; 2019.
  16. 16. Mheidly N, Fares J. Leveraging media and health communication strategies to overcome the COVID-19 infodemic. Journal of public health policy. 2020:1–11. pmid:31932759
  17. 17. Steffens MS, Dunn AG, Leask J, Wiley KE. Using social media for vaccination promotion: Practices and challenges. DIGITAL HEALTH. 2020;6:2055207620970785.
  18. 18. Bennett WL, Manheim JB. The one-step flow of communication. The ANNALS of the American Academy of Political and Social Science. 2006;608[1]:213–32.
  19. 19. Hilbert M, Vásquez J, Halpern D, Valenzuela S, Arriagada E. One step, two step, network step? Complementary perspectives on communication flows in Twittered citizen protests. Social science computer review. 2017;35[4]:444–61.
  20. 20. Thorson K, Wells C. Curated flows: A framework for mapping media exposure in the digital age. Communication Theory. 2016;26[3]:309–28.
  21. 21. LaRose R. The problem of media habits. Communication Theory. 2010;20[2]:194–222.
  22. 22. Wonneberger A, Schoenbach K, Van Meurs L. Interest in news and politics—or situational determinants? Why people watch the news. Journal of broadcasting & electronic media. 2011;55[3]:325–43.
  23. 23. Vishwanath A. Habitual Facebook use and its impact on getting deceived on social media. Journal of Computer-Mediated Communication. 2015;20[1]:83–98.
  24. 24. Karasneh R, Al-Azzam S, Muflih S, Soudah O, Hawamdeh S, Khader Y. Media’s effect on shaping knowledge, awareness risk perceptions and communication practices of pandemic COVID-19 among pharmacists. Research in Social and Administrative Pharmacy. 2020.
  25. 25. Stephens KK, Barrett AK, Mahometa MJ. Organizational communication in emergencies: Using multiple channels and sources to combat noise and capture attention. Human Communication Research. 2013;39[2]:230–51.
  26. 26. Palen L, Anderson KM, Mark G, Martin J, Sicker D, Palmer M, et al., editors. A vision for technology-mediated support for public participation & assistance in mass emergencies & disasters. Proceedings of the 2010 ACM-BCS visions of computer science conference; 2010: British Computer Society.
  27. 27. Taha SA, Matheson K, Anisman H. The 2009 H1N1 Influenza Pandemic: The Role of Threat, Coping, and Media Trust on Vaccination Intentions in Canada. Journal of Health Communication. 2013;18[3]:278–90. pmid:23301849
  28. 28. Rothschild DK, T. Random Device Engagement [RDE] with Organic Samples. Pollfish; 2018.
  29. 29. Babbie ER. The practice of social research: Cengage learning; 2020.
  30. 30. Dooling K. The Advisory Committee on Immunization Practices’ Updated Interim Recommendation for Allocation of COVID-19 Vaccine—United States, December 2020. MMWR Morbidity and mortality weekly report. 2020;69.
  31. 31. Obar JA, Wildman SS. Social media definition and the governance challenge-an introduction to the special issue. Obar JA and Wildman S[2015] Social media definition and the governance challenge: An introduction to the special issue Telecommunications policy. 2015;39[9]:745–50.
  32. 32. Arrese Á, Kaufmann J. Legacy and native news brands online: do they show different news consumption patterns? International journal on media management. 2016;18[2]:75–97.
  33. 33. Casero-Ripollés A. Impact of Covid-19 on the media system. Communicative and democratic consequences of news consumption during the outbreak. Casero-Ripollés, Andreu [2020]“Impact of Covid-19 on the media system Communicative and democratic consequences of news consumption during the outbreak” El profesional de la información. 2020;29[2]:e290223.
  34. 34. Braddock K. Vaccinating Against Hate: Using Attitudinal Inoculation to Confer Resistance to Persuasion by Extremist Propaganda. Terrorism and Political Violence. 2019:1–23.
  35. 35. Ivanov B, Rains SA, Geegan SA, Vos SC, Haarstad ND, Parker KA. Beyond simple inoculation: Examining the persuasive value of inoculation for audiences with initially neutral or opposing attitudes. Western Journal of Communication. 2017;81[1]:105–26.
  36. 36. Fagerland MW, Hosmer DW. A generalized Hosmer–Lemeshow goodness-of-fit test for multinomial logistic regression models. The Stata Journal. 2012;12[3]:447–53.
  37. 37. Bajema KL, Wiegand RE, Cuffe K, Patel SV, Iachan R, Lim T, et al. Estimated SARS-CoV-2 Seroprevalence in the US as of September 2020. JAMA internal medicine. 2020.
  38. 38. Margolis MA, Brewer NT, Shah PD, Calo WA, Gilkey MB. Stories about HPV vaccine in social media, traditional media, and conversations. Preventive medicine. 2019;118:251–6. pmid:30414396
  39. 39. Brennen JS, Simon F, Howard PN, Nielsen RK. Types, sources, and claims of COVID-19 misinformation. Reuters Institute. 2020;7:3–1.
  40. 40. Nielsen RK, Fletcher R, Newman N, Brennen JS, Howard PN. Navigating the ‘infodemic’: How people in six countries access and rate news and information about coronavirus: Reuters Institute; 2020.
  41. 41. Horne Z, Powell D, Hummel JE, Holyoak KJ. Countering antivaccination attitudes. Proceedings of the National Academy of Sciences. 2015;112[33]:10321–4. pmid:26240325
  42. 42. Barry K. More than half of Ohio’s nursing home staff refusing vaccine as first round is nearly over. News 5 Cleveland. 2020 Jan 5, 2021.
  43. 43. Madani D. Many front-line workers refuse Covid vaccines as distribution rollout struggles. https://www.nbcnews.com/news/us-news/many-frontline-workers-refuse-covid-19-vaccines-distribution-rollout-struggles-n1252617.
  44. 44. Wilson SL, Wiysonge C. Social media and vaccine hesitancy. BMJ Global Health. 2020;5[10]:e004206. pmid:33097547