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. Author manuscript; available in PMC: 2018 Jun 22.
Published in final edited form as: Vaccine. 2017 May 27;35(29):3621–3638. doi: 10.1016/j.vaccine.2017.05.052

Semantic Network Analysis of Vaccine Sentiment in Online Social Media

Gloria J Kang 1,2, Sinclair R Ewing-Nelson 2, Lauren Mackey 2, James T Schlitt 1,2, Achla Marathe 2, Kaja M Abbas 1, Samarth Swarup 2
PMCID: PMC5548132  NIHMSID: NIHMS880167  PMID: 28554500

Abstract

Objective

To examine current vaccine sentiment on social media by constructing and analyzing semantic networks of vaccine information from highly shared websites of Twitter users in the United States; and to assist public health communication of vaccines.

Background

Vaccine hesitancy continues to contribute to suboptimal vaccination coverage in the United States, posing significant risk of disease outbreaks, yet remains poorly understood.

Methods

We constructed semantic networks of vaccine information from internet articles shared by Twitter users in the United States. We analyzed resulting network topology, compared semantic differences, and identified the most salient concepts within networks expressing positive, negative, and neutral vaccine sentiment.

Results

The semantic network of positive vaccine sentiment demonstrated greater cohesiveness in discourse compared to the larger, less-connected network of negative vaccine sentiment. The positive sentiment network centered around parents and focused on communicating health risks and benefits, highlighting medical concepts such as measles, autism, HPV vaccine, vaccine-autism link, meningococcal disease, and MMR vaccine. In contrast, the negative network centered around children and focused on organizational bodies such as CDC, vaccine industry, doctors, mainstream media, pharmaceutical companies, and United States. The prevalence of negative vaccine sentiment was demonstrated through diverse messaging, framed around skepticism and distrust of government organizations that communicate scientific evidence supporting positive vaccine benefits.

Conclusion

Semantic network analysis of vaccine sentiment in online social media can enhance understanding of the scope and variability of current attitudes and beliefs toward vaccines. Our study synthesizes quantitative and qualitative evidence from an interdisciplinary approach to better understand complex drivers of vaccine hesitancy for public health communication, to improve vaccine confidence and vaccination coverage in the United States.

Keywords: Vaccine hesitancy, vaccine sentiment, semantic network analysis, online social media, Twitter

1. INTRODUCTION

1.1 Vaccine hesitancy

Suboptimal vaccination coverage in the United States continues to pose significant risk of disease outbreaks, in part, due to vaccine hesitancy [1]. Vaccine hesitancy refers to a combination of beliefs, attitudes, and behaviors that influence an individual’s decision to vaccinate despite vaccine availability; these behaviors include refusal, delay, or reluctant acceptance despite having active concerns [2,3]. Strategies to address vaccine refusal have focused on individual reasons for not vaccinating, however, evidence of successful interventions remains limited. A review of vaccine hesitancy interventions expressed weak support for current strategies in mitigating vaccine resistance [4]; interventions targeted toward anti-vaccination groups are likely to be ineffective, unsustainable, and potentially more detrimental compared to no intervention at all [46].

Vaccine hesitancy stems from socio-cultural, political, and otherwise non-medical factors that are poorly understood [7]. The underlying causes of vaccine hesitancy should not be attributed to scientific illiteracy alone [8], but rather viewed as a deliberative and structured process that requires contextualized examination at local levels [9,10]. In the case of our study, we focus on semantic and rhetorical qualities of vaccine communication amongst the general public within contexts of differing vaccine sentiment.

1.2 Social network analysis and digital epidemiology

The advent of the Internet and social media has provided new platforms for persuasion and rapid spread of (mis)information, bringing forth new challenges and opportunities to an age-old public health problem. Social Network Analysis (SNA) broadly studies social interactions of contact networks with significant implications for public health [11], such as contributing evidence that belief systems are a primary barrier to vaccination [12]. Novel public health tools such as SNA employ computational frameworks in the context of digital epidemiology [13]. Online social media such as Twitter are novel avenues to acquire real-time data of attitudes, beliefs, and behaviors, particularly for underrepresented demographic groups who disproportionately comprise Twitter users [14]. By leveraging online data, studies can examine the dynamics of massively interacting populations, such as online health sentiment and its potential impact on infectious disease outbreaks [15,16].

1.3 Semantic networks

Semantic networks are graphical representations of knowledge based on meaningful relationships of written text, structured as a network of words cognitively related to one another [17,18], in this study, vaccine information. Within the semantic network, nodes are words that represent concepts found in text. The connections between nodes are referred to as edges which represent relationships between connected concepts. Semantic networks allow extraction of meaningful ideas by identifying emergent clusters of concepts rather than analyzing frequencies of isolated words [19]; in this way, analyzing online social media can enhance understanding of complex health behavior, particularly for vaccine hesitancy.

Similar studies have analyzed websites using search engine results and natural language processing (NLP) [20,21]. Text network analysis traditionally employs semi-automated techniques in which information is extracted and analyzed using both human and computerized methods, dealing with challenges such as coreference resolution, synonym resolution, and ambiguity [22]. To limit these issues, we constructed semantic networks manually and then performed network analysis within our study.

Both proximate and non-proximate determinants of vaccine hesitancy necessitate an interdisciplinary approach [23,24]. Our study presents a novel framework that applies methods of network analysis to semantic networks [25] within the context of vaccine sentiment.

1.4 Study objective

Our objective was to examine current vaccine sentiment on social media by constructing and analyzing semantic networks of vaccine information from highly shared websites of Twitter users in the United States.

1.5 Public health significance

The Strategic Advisory Group of Experts on Immunization (SAGE) Working Group on Vaccine Hesitancy (WG) reported specific research needs to better understand context-specific causes underlying vaccine hesitancy [26]. To help address this gap, we utilized quantitative network methods in analyzing qualitative aspects of vaccine information---an efficient approach to investigating the scope and variability of current attitudes and beliefs toward vaccines. Such findings are pivotal in informing and improving public health communication of vaccine confidence.

2. METHODS

2.1 Data retrieval and document selection

We used ChatterGrabber [27], a web-scraping tool that randomly samples public tweets of Twitter users in the United States. (Details on ChatterGrabber including search term conditions, qualifiers, and exclusions are in Appendix A). Webpage links from collected tweets identified current sources of vaccine information based on the frequency of link shares during the time of data collection. Our analysis focuses on the textual content of relevant webpage articles (also referred to as documents) and not the tweeted text per se. Document types selected for analysis included blog posts, media stories, informational articles, and news reports. We excluded academic publications, court documents, and media formats such as images, PDF files, and videos.

A total of 26,389 tweets were collected between April 16, 2015 and May 29, 2015 from which we obtained 8,416 unique web links. To generalize findings from a representative pool of popular vaccine articles, we screened the top 100 most shared links for relevance from which we randomly sampled 50 for analysis; we excluded articles concerning non-human vaccines.

2.2 Vaccine sentiment coding

Articles were read for content and manually coded as having either positive, negative, or neutral sentiment toward vaccines. Coding was determined by whole-text assessment which included examining the title/headline and the source/domain of articles. In general, differences between sentiment were determined based on consistency of statements that clearly identified group affiliation, such as encouraging vaccination and highlighting benefits (positive sentiment) or discouraging vaccination and highlighting risks (negative sentiment). Articles that were ambiguous or mixed in sentiment were coded as neutral. Three researchers (GJK, SRE, LM) independently coded a subset of 10 articles for sentiment; there was no inter-annotator variability and resulted in consistent sentiment coding.

2.3 Construction of vaccine sentiment networks

Document text networks were merged by sentiment group, thereby aggregating similar documents into a single semantic network, one for each vaccine sentiment (positive, negative, and neutral). We standardized node and edge labels to resolve lexical differences and grammatical dependencies across disparate sources. Details on semantic network annotation, construction, and analysis of vaccine sentiment networks are described in Appendix B.

2.4 Semantic network analysis

Our analysis of the positive, negative, and neutral sentiment networks was focused on the greatest connected component (or subgraph). We applied several measures of network analysis to the generated semantic networks in order to limit biased interpretation of selected network metrics [25] (Appendix B). Descriptive statistics included network size, density, and diameter, where network size is the total number of nodes (i.e., vaccine concepts); density measures the interconnectedness of nodes [28]; and diameter characterizes compactness of the network. We evaluated multiple measures of centrality which describes the importance, influence, or significance of concepts within the semantic network in various ways [29]; specific types include degree centrality, betweenness centrality, closeness centrality, and eigenvector centrality [30].

Community detection algorithms [31] describe cohesive groups in the network [32], and clusters of important vaccine concepts were visualized by the network’s maximum k-core (the maximal connected subgraph in which all nodes have degree of at least k) [33]. We assessed differences in emphasis framing, which is the salience of certain story elements over others [34], for central concepts from networks of differing sentiment. Closeness vitality [49] measures how much the distances between all pairs of nodes change when a particular node is removed. This is an indicator of how much each node contributes to the overall structural cohesion of the network.

NetworkX [35] and iGraph [36] were used in network construction and analysis; visualizations were created in Gephi [37].

3. RESULTS

3.1 Document characteristics

From the sample of webpages (n=50), we coded 23 documents as having positive vaccine sentiment, 21 documents with negative vaccine sentiment, and 6 documents were classified as neutral. Table 1 summarizes document characteristics grouped by vaccine sentiment. Blog posts were the most shared document type overall, followed by news and “alternative news” for positive and negative sentiment articles respectively. Content of positive sentiment documents focused on specific childhood, adolescent, and adult vaccines, whereas negative sentiment documents focused primarily on childhood vaccines and vaccination in general.

Table 1. Summary of sampled documents.

The table summarizes article characteristics by vaccine sentiment group and describes document type, article source, target vaccine population, vaccine type focus, and specific vaccine topics.

Vaccine sentiment
articles
(Total n = 50)		 Positive (n = 23) Negative (n = 21) Neutral (n = 6)
Document type Blog = 8 (34.8%) Blog = 15 (71.4%) News = 4 (66.7%)
News = 7 (30.4%) Alternative News = 2 (9.5%) Blog = 1 (16.7%)
Magazine = 5 (21.7%) Magazine = 2 (9.5%) Magazine = 1 (16.7%)
Informational = 3 (13.0%) Commercial = 1 (4.8%)
News = 1 (4.8%)
Article source type Media = 9 (39.1%) Media = 15 (71.4%) Government = 2 (33.3%)
Government = 8 (34.8%) Industry = 3 (14.3%) Media = 2 (33.3%)
News = 4 (17.4%) Personal = 2 (9.5%) News = 2 (33.3%)
Industry = 1 (4.4%) Forum = 1 (4.8%)
Resource = 1 (4.4%)
Target vaccine population Childhood = 16 (69.6%) Childhood = 15 (71.4%) Childhood = 3 (50.0%)
Adolescent = 3 (13.0%) Adolescent = 0 Adolescent = 2 (33.3%)
Adult = 1 (4.4%) Adult = 0 Adult = 1 (16.7%)
Multiple = 3 (13.0%) Multiple = 6 (28.6%) Multiple = 0
Vaccine type focus General = 8 (34.8%) General = 14 (66.7%) General = 3 (50%)
Specific = 15 (65.2%) Specific = 7 (33.3%) Specific = 3 (50%)
Specific vaccines Measles/MMR = 9 Shingles = 1 Whooping cough = 2
HPV = 3 Polio = 1 Influenza = 1
Influenza = 1 Gardasil = 1
Meningococcal = 1 Measles = 1
Rubella = 1 Swine flu = 1
Tdap = 1
Hepatitis B = 1
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3.2 Document text networks

Network properties of vaccine documents are summarized in Table 2. Negative sentiment documents (n=21) formed the largest semantic networks with a mean network size of 90.9 concepts (nodes) per document, compared to smaller networks of positive sentiment (n=23) and neutral sentiment documents (n=6) with a mean of 51.3 and 43.8 concepts per document respectively.

Table 2. Summary of measures for article text networks and sentiment group networks.

The table describes network characteristics of extracted web documents; joint semantic networks of positive, negative, and neutral vaccine sentiment; and the corresponding greatest connected component. Measures describe network size, density, and average centrality.

Vaccine sentiment Positive Negative Neutral
Document text networks
Number of documents (Total=50) 23 documents 21 documents 6 documents
Average number of nodes (per document) 53.1 nodes 90.9 nodes 43.8 nodes
Average number of edges (per document) 49 edges 90.7 edges 39.7 edges
Average degree (per document) 1.9 1.98 1.8
Vaccine sentiment networks
Average degree 3.356 2.95 2.348
Number of connected components 21 49 12
Greatest component subgraph
Nodes / Total network nodes 585 / 652 nodes 1140 / 1257 nodes 171 / 201 nodes
Edges / Total network edges 1042 / 1094 edges 1783 / 1854 edges 216 / 236 edges
Average degree 3.562 3.128 2.526
Diameter 12 13 17
Density 0.0061 0.0027 0.0149
Number of communities 21 31 10
Average path length 4.492 4.77 6.78
Average degree centrality 0.0061 0.0027 0.0149
Average betweenness centrality 0.006 0.0033 0.0342
Average closeness centrality 0.2292 0.2161 0.1533
Average node connectivity 1.3117 1.1835 1.035
Average clustering coefficient 0.196 0.14 0.131
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3.3 Vaccine sentiment networks

Document text networks were aggregated by vaccine sentiment to form 3 semantic networks representing positive, negative, and neutral sentiment. Network measures are summarized in Table 2. Network visualizations are in Appendix C.

In regards to the greatest component subgraph, size indicates the number of concepts in the network, whereas density describes interconnectedness of the concepts. The greatest component of the negative network was largest in size (1140 concepts) but less dense (0.0027) than the positive network (0.0061) also much smaller in size (585 concepts). Community detection analysis [31] identified 21 distinct communities within the positive network, 31 communities in the negative, and 10 communities in the neutral network. Compared to the original number of merged documents per sentiment network, the number of cohesive communities exceeded the number of original documents within the negative and neutral networks, whereas the positive network formed fewer communities than the original number of documents used in merging. Community findings and density measures for the positive network suggest a more cohesive and interconnected belief system among positive sentiment concepts compared to the larger, less-connected network of negative sentiment. Correspondingly, the average clustering coefficient (i.e., the tendency of nodes to form groups) and average node centrality for degree, betweenness, closeness, and eigenvector centrality were higher for the positive network compared to the negative. Positive and negative networks exhibited structural similarities in regards to diameter (12 and 13, respectively) and average path length (4.5 and 4.8, respectively). Visualizations of maximum k-core subgraphs for each sentiment network highlight clusters of significant concepts in Figure 1.

Figure 1. Maximum k-core subgraphs show clusters of significant vaccine concepts within the semantic networks.

Figure 1

Figure 1

Figure 1

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Visualizations of maximum k-cores (i.e., the maximal connected subgraph in which all nodes have degree of at least k) for networks of [a.] positive vaccine sentiment (k = 4), [b.] negative vaccine sentiment (k = 4), and [c.] neutral vaccine sentiment (k = 2) where increasing node and text size represents increasing betweenness centrality.

3.3 Central concepts

Figure 2 plots significant concepts of each sentiment network by centrality measures for degree, betweenness, and closeness centrality (Appendix D). The most central concepts (greater than 2 standard deviations from the mean) ranked by eigenvector centrality are plotted in Figure 3 and listed in Table 3.

Figure 2. Significant vaccine concepts by measures of degree centrality, betweenness centrality, and closeness centrality.

Figure 2

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The figure includes centrality measures for significant concepts from positive, negative, and neutral sentiment networks. Degree centrality (point size), betweenness centrality (x-axis), and closeness centrality (y-axis) are plotted.

Figure 3. Significant concepts ranked by eigenvector centrality.

Figure 3

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The figure plots the most central nodes by eigenvector centrality score for networks of positive, negative, and neutral vaccine sentiment.

Table 3. Top nodes by eigenvector centrality.

The table lists the most central concepts of each sentiment network ranked by eigenvector centrality score (greater than 2 standard deviations from the mean).

Eigenvector centrality
Positive sentiment network Negative sentiment network Neutral sentiment network
Mean = 0.0626 Mean = 0.0318 Mean = 0.0975
Std Dev = 0.0936 Std Dev = 0.06 Std Dev = 0.11
parents 1 vaccines 1 SB 277 1
vaccines 0.8209 children 0.6188 vaccines 0.4304
measles 0.7458 thimerosal 0.5248 anti-vaccination 0.4177
vaccination 0.6373 CDC 0.5054 parents 0.3863
children 0.5382 vaccine industry 0.4898 children 0.3830
SB 277 0.4207 mercury 0.4440 pertussis vaccine 0.3540
autism 0.4025 autism 0.3894 home-school 0.3209
community 0.3937 flu shots 0.3367 education 0.3206
religious groups 0.3905 mainstream media 0.3342
anti-vaccination 0.3802 doctors 0.2862
vaccine-autism link 0.3608 SB 277 0.2659
herd immunity 0.3058 vaccine ingredients 0.2632
vaccine refusal 0.3024 mandatory vaccines 0.2457
vaccination exemption 0.3013 pharmaceutical companies 0.2400
personal belief exemption 0.2909 vaccine-autism link 0.2041
disease 0.2829 toxic chemical ingredients 0.1999
measles vaccine 0.2706 aluminum 0.1889
schools 0.2685 vaccination 0.1853
HPV vaccine 0.2674 monosodium glutamate 0.1811
vaccine delay 0.2603 hepatitis B vaccine 0.1793
meningococcal disease 0.2551 vaccine-injured children 0.1763
vaccine safety 0.1721
evidence 0.1655
informed consent 0.1643
intelligent questions 0.1612
formaldehyde 0.1609
pregnant women 0.1598
pandemic H1N1 swine flu vaccine 0.1595
Big Pharma 0.1591
vaccines are safe 0.1565
quackery 0.1552
vaccine damage 0.1547
SV40 0.1545
science 0.1531
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Excluding expected nodes such as vaccines and vaccination, the most central concepts for the positive network included parents, measles, children, SB 277, autism, community, religious groups, anti-vaccination, vaccine-autism link, HPV vaccine, meningococcal disease, and MMR vaccine. Significant concepts within the negative sentiment network were children, thimerosal, CDC, vaccine industry, mercury, autism, flu shots, mainstream media, doctors, SB 277, vaccine ingredients, mandatory vaccines, and pharmaceutical companies. And the most central concepts of the neutral network were SB 277, anti-vaccination, parents, children, pertussis vaccine, homeschool, education, pertussis, vaccine-autism link, side effects, Dwoskin Family Foundation, whole-cell vaccine, effective, acellular pertussis vaccine, and high-dose flu vaccine.

3.4 Dynamic visualizations

Dynamic, interactive visualizations and network data files from this study are available online (Appendix E).

4. DISCUSSION

4.1 Semantic network analysis of vaccine sentiment

A long line of research in the psychology of memory and semantic processing has provided evidence for semantic network-like organization of internal representations and spreading activation as a process by which memories are activated and meaning is processed [53, 54, 50, 51]. In this model, when an item in memory is activated, e.g., by a person reading about it or hearing about it, the activation spreads from that node in the person’s internal semantic network to nearby nodes. Spreading activation is also hypothesized as the model for the automatic activation of attitudes [55].

From this perspective, closeness centrality is a useful metric to understand the organization of the vaccination semantic networks (though other centrality measures are quite similar in ranking, as the results show). Closeness centrality is a direct measure of which concepts are likely to be activated repeatedly in each of the semantic networks, even as different concepts are mentioned.

Many central concepts of the positive network were present in the negative network, but not vice versa. For example, while positive and neutral sentiment documents explicitly addressed the concept of anti-vaccination, negative sentiment articles did not. In regards to highly central concepts of the negative network, the positive network lacked any reference to the vaccine industry and mainstream media; CDC and doctors also held lesser significance in the context of positive vaccine sentiment.

Significant concepts within the positive network were related to health and medicine, such as measles, autism, HPV vaccine, vaccine-autism link, meningococcal disease, and MMR vaccine. In contrast, significant concepts of the negative network referred to organizational bodies such as CDC, vaccine industry, doctors, mainstream media, pharmaceutical companies, and United States. A notable contrast was the emergence of parents as the most central concept in the positive network, versus children, the most central node in the negative network.

Documents expressing positive and neutral vaccine sentiment were characterized by dense semantic networks with fewer concepts, compared to the semantic network of negative sentiment which presented a high number of vaccine concepts with low connectivity. Compared to the positive sentiment network, the negative sentiment network has more components, lower edge density, a larger diameter, and larger average path length [Table 2]. Hence, positive sentiment documents indicated greater cohesiveness in vaccine-positive discourse compared to vaccine-negative documents which addressed a broad range of topics as potential contributors to vaccine hesitancy.

4.2 Message framing

Our study revealed sentiment-specific terminology used in framing positive and negative messages within vaccine communication. This included differences in term valence such as required vaccines versus mandated vaccines and side effects versus adverse effects, the selective targeting of parents versus children, and the overall presentation of evidence-based science versus social commentary related to issues of governance for the positive and negative vaccine sentiment networks, respectively.

Overall, the prevalence of negative vaccine sentiment was demonstrated through diverse messaging, framed around institutional distrust and skepticism towards the organizations that deliver scientific evidence of positive vaccine benefits. This is also shown by the list of top nodes for the closeness vitality measure for each network [Table D4], which is an indicator of the concepts which are responsible for providing structural cohesion to the semantic network [49]. Positive and negative vaccine articles largely differed in the framing of trust. Positive articles emphasized trust in vaccination by relying on scientific evidence as trusted authority. Negative articles framed trust issues not around vaccination science itself, but around the institutions that govern or finance matters of personal health. Neutral vaccine articles exemplified various sources of news coverage that expressed a mix of both positive and negative attitudes toward vaccines. Top news stories at the time of data collection included a new study debunking the vaccine-autism link and the passing of California Senate Bill 277 [38], which removed exemptions from school vaccination requirements. News coverage generally expressed positive vaccine sentiment, reporting official statements and statistics. In contrast, news coverage by negative vaccine articles additionally introduced a range of tangential topics, often proposing arguments through rhetorical questions and reframing official statistics.

4.3 Limitations

We assumed that popular vaccination information shared on Twitter is representative of prevalent vaccine sentiment, but may not reflect the broad spectrum of vaccine sentiment in the general population. Coding documents for neutral sentiment was difficult since documents presented a mix of both positive and negative attitudes, and not truly vaccine-neutral. Because health behaviors are founded upon a variety of beliefs and attitudes that change over time, vaccine sentiment categories are difficult to delineate since they do not exist as polarized groups.

While we attempted to resolve issues of meaning and context by manually transcribing implicit statements into explicit statements, reference resolution grew increasingly difficult across different documents. Consequently, there is potential inconsistency from the manual annotation of document text into network data, particularly when dealing with ambiguous language such as slang, hyperbole, and poetic devices. Despite these limitations, employing human interpretation of text greatly enhances qualitative aspects of data and is arguably more accurate than current NLP methods which lack explicit domain-specific knowledge or situational information [22]. Lastly, our analysis did not assess the qualitative relationships of connected concepts. Future studies incorporating edge data can provide detailed insight into the comparison of belief structures of varying vaccine sentiment.

Our study presents only a broad overview of general network measures. Greater depth into specific metrics, such as community detection analysis, can provide useful insight and should be addressed in future studies.

4.4 Implications for public health and vaccine communication

The SAGE WG on Vaccine Hesitancy [26] states that communication is a tool to address vaccine sentiment rather than a determinant of hesitancy. However, poor communication can undermine vaccine acceptance in any setting [39]. Our study lends itself to the development of effective communication strategies for target populations by identifying specific factors that influence vaccine hesitancy---an integral component of every immunization program [39].

Semantic network analysis of vaccine sentiment in online social media can enhance our understanding of the scope and variability of attitudes and beliefs toward vaccination. Our findings emphasize the need to improve the framing and messaging of public health communication, that not only highlights the vaccine benefits, but also addresses specific issues related to vaccine hesitancy and institutional distrust. Enhancing public trust in relevant scientific institutions and engaging in efficient public health communication is critical in improving vaccine confidence and vaccination coverage [40].

4.5 Conclusion

We discussed findings from a novel framework that uses semantic network analysis as an efficient and effective way to analyze vaccine sentiment. This study adds to a growing body of vaccine hesitancy research by investigating emerging topics and the various discourse surrounding current vaccine perspectives. Findings related to significant concepts, the structure of its relations, and semantic qualities can better inform targeted vaccine communication strategies and enhance effectiveness of public health efforts to increase vaccine confidence.

Acknowledgments

Funding: This study is supported by NIH/NIGMS R01GM109718, NSF/NRT 1545362, and NSF IBSS Grant SMA-1520359. The funding sources had no role in study design; collection, analysis, and interpretation of data; writing of the paper; or the decision to submit it for publication.

Appendix A: ChatterGrabber parameters, search terms, and summary of results

ChatterGrabber search terms were selected through an iterative process involving manual selection and testing of data retrieval as detailed in [27].

A1.

Description of ChatterGrabber parameters

Location United States
Tweet Data Text, ID, Time Posted, Retweet Count, Favorite Count
User Data Screen Name, Language
Media Data Url, Display Url
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A2.

ChatterGrabber search terms

Conditions Qualifiers Exclusions
vaccine autism bullshit
vaccinat autistic penn & teller
vacine conspiracy penn and teller
vacinate gave my enter the kingdom of heaven
MMR gave me heroin
antivac oprah eye of a needle
aspergers thread
poison molds
jenny mccarthy record
kristin cavallari efficacy
conspiracy shoot up
mercury needle exchange
aluminum morphine
truther knit
bravo crochet
anti fracking
manufacturers insulin
have known malware
vaccine choice pincushion
your child addict
your right fuel
cancer needlework
fertility felt
constitution caffeine
risks scaling
dangerous space
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A3.

Twitter data via ChatterGrabber

n
Total number of collected tweets 26389
Number of unique urls 8416
Number of unique domains 2372
Number of web articles selected for analysis 50
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Appendix B: Network methods

Network annotation and construction

To create document networks, article text was manually transcribed into structured belief statements, or relevant information extracted from natural language text. Similar to methods of information extraction used by the Knowledge Vault project [41], document text was formatted as triples, in which (subject, predicate, object) correspond to (node, edge, node) in the network. For example, the sentence “Vaccines prevent communicable diseases” is represented by (vaccines, prevent, communicable diseases). Three researchers initially annotated a subset of 10 documents to gauge inter-annotator variability in transcribing article documents into network datasets. All co-references were resolved and the original text was adhered to as much as possible. Discordant results were resolved through consensus in order to maintain standard formatting of network data. Final network datasets were synthesized by standardizing terminology, resolving grammatical dependencies and lexical differences in the semantic network.

The resulting standards for network vocabulary were based on term frequency. For example, synonymous nodes labeled “communicable diseases”, “infectious diseases”, and “contagious diseases”, we applied the most commonly used term across same-sentiment documents (in this case “infectious diseases”) to replace labels of all semantically equivalent nodes.

Definitions of network measures

Network size is the total number of nodes or vaccine-related concepts. Density measures the interconnectedness of nodes, calculated as the proportion of existing edges (or relations between concepts) over all possible edges in the network [42]. Diameter characterizes the compactness of the network, measured as the longest path of all shortest paths across all node pairs.

Degree centrality characterizes how connected a node is to other nodes in the network, measured by its number of connections (and normalized by the total number of network connections) [43]. Betweenness centrality measures the frequency of a given node on the shortest paths to all other pairs of connected nodes, representing the probability of a concept to be involved in connecting two other concepts in the semantic network [43,44]. Closeness centrality measures closeness, calculating the sum of the shortest paths between a node to all other nodes in the network [43]. Nodes with smaller path lengths have higher closeness centrality and are interpreted to be more important concepts than nodes with longer paths [45]. Lastly, eigenvector centrality provides a more complex measure of node influence by assigning relative scores to all concepts in the network, based on the number and quality of its relationships; a concept is significant to the extent that it is connected to other significant concepts [46].

Community detection using the Newman-Girvan algorithm detects communities by consecutively removing each edge with the highest edge betweenness from the graph [31]. Edge-betweenness refers to the number of shortest paths from one node to another that traverse through that edge. Cohesive groups in the network are measured by modularity, in which a good partition has more intra-community edges than expected at random; modularity values other than zero represent deviations from randomness [32].

Appendix C: Network visualizations

[C1-C3]: Full semantic networks of vaccine sentiment

Visualizations for full semantic networks of [C1.] positive vaccine sentiment, [C2.] negative vaccine sentiment, and [C3.] neutral vaccine sentiment. Node size represents betweenness centrality.

C1.

C1

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Full semantic network of positive vaccine sentiment.

C2.

C2

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Full semantic network of negative vaccine sentiment.

C3.

C3

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Full semantic network of neutral vaccine sentiment.

[C4-C6]: Greatest component subgraph of vaccine sentiment networks

Visualizations of the greatest component subgraph for networks of [C4.] positive vaccine sentiment, [C5.] negative vaccine sentiment, and [C6.] neutral vaccine sentiment, where increasing node size represents greater betweenness centrality.

C4.

C4

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Greatest component subgraph of the positive sentiment network.

C5.

C5

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Greatest component subgraph of the negative sentiment network.

C6.

C6

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Greatest component subgraph of the neutral sentiment network.

Appendix D: Degree centrality, betweenness centrality, closeness centrality, and eigenvector centrality

[D1-D3]: Significant vaccine concepts by centrality

Centrality characterizes the importance, influence, or power of vaccine-related concepts in the semantic network. The table lists measures for the most central concepts (greater than 2 standard deviations from the network mean) by degree centrality, betweenness centrality, closeness centrality, and eigenvector centrality for [D1.] positive sentiment, [D2.] negative sentiment, and [D3.] neutral sentiment networks.

D1.

Most central nodes and centrality measures for the positive sentiment network.

Positive vaccine sentiment network
Degree centrality Betweenness centrality Closeness centrality Eigenvector centrality
Mean = 0.0061 Mean = 0.006 Mean = 0.2292 Mean = 0.0626
Std Dev = 0.0107 Std Dev = 0.0203 Std Dev = 0.038 Std Dev = 0.0936
vaccines 0.1079 parents 0.2718 parents 0.3687 parents 1
parents 0.0993 vaccines 0.2176 vaccines 0.3482 vaccines 0.8209
measles 0.0993 measles 0.1546 children 0.3415 measles 0.7458
vaccination 0.0856 anti-vaccination 0.1261 measles 0.3382 vaccination 0.6373
autism 0.0616 religious groups 0.1018 community 0.3227 children 0.5382
HPV vaccine 0.0565 vaccine-autism link 0.0917 religious groups 0.3219 SB 277 0.4207
vaccine-autism link 0.0531 meningococcal disease 0.0905 autism 0.3188 autism 0.4025
meningococcal disease 0.0531 children 0.0825 SB 277 0.3158 community 0.3937
anti-vaccination 0.0479 autism 0.0799 vaccine-autism link 0.3148 religious groups 0.3905
children 0.0445 HPV vaccine 0.0732 anti-vaccination 0.3121 anti-vaccination 0.3802
MMR vaccine 0.0411 community 0.0574 vaccination 0.3100 vaccine-autism link 0.3608
religious groups 0.0394 SB 277 0.0571 herd immunity 0.3058
measles vaccine 0.0377 measles vaccine 0.0523 vaccine refusal 0.3024
SB 277 0.0342 side effects 0.0510 vaccination exemption 0.3013
disease 0.0308 Gardasil 0.0496 personal belief exemption 0.2909
vaccination exemption 0.0291 disease 0.2829
autism risk 0.0291 measles vaccine 0.2706
schools 0.2685
HPV vaccine 0.2674
vaccine delay 0.2603
meningococcal disease 0.2551
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D2.

Most central nodes and centrality measures for the negative sentiment network.

Negative vaccine sentiment network
Degree centrality Betweenness centrality Closeness centrality Eigenvector centrality
Mean = 0.0027 Mean = 0.0033 Mean = 0.2161 Mean = 0.0318
Std Dev = 0.0058 Std Dev = 0.0148 Std Dev = 0.0365 Std Dev = 0.06
vaccines 0.1054 vaccines 0.3280 vaccines 0.3582 vaccines 1
children 0.0623 children 0.1889 children 0.3375 children 0.6188
thimerosal 0.0588 CDC 0.1274 vaccine industry 0.3275 thimerosal 0.5248
CDC 0.0527 vaccine industry 0.1213 autism 0.3249 CDC 0.5054
vaccine industry 0.0518 autism 0.1028 mercury 0.3245 vaccine industry 0.4898
autism 0.0386 thimerosal 0.0869 thimerosal 0.3209 mercury 0.4440
doctors 0.0351 doctors 0.0863 CDC 0.3197 autism 0.3894
mainstream media 0.0351 mercury 0.0629 SB 277 0.3072 flu shots 0.3367
mercury 0.0334 mainstream media 0.0624 mainstream media 0.3070 mainstream media 0.3342
flu shots 0.0263 mandatory vaccines 0.0583 flu shots 0.3037 doctors 0.2862
pharmaceutical companies 0.0263 flu shots 0.0576 doctors 0.3028 SB 277 0.2659
mandatory vaccines 0.0255 pharmaceutical companies 0.0552 vaccine ingredients 0.2990 vaccine ingredients 0.2632
vaccination 0.0237 informed consent 0.0485 mandatory vaccines 0.2969 mandatory vaccines 0.2457
SB 277 0.0228 people 0.0474 toxic chemical ingredients 0.2958 pharmaceutical companies 0.2400
United States 0.0202 vaccine ingredients 0.0453 vaccine-autism link 0.2952 vaccine-autism link 0.2041
measles 0.0193 United States 0.0449 vaccine safety 0.2933 toxic chemical ingredients 0.1999
vaccine ingredients 0.0184 measles 0.0444 intelligent questions 0.2905 aluminum 0.1889
informed consent 0.0184 vaccination 0.0438 vaccines are safe 0.2895 vaccination 0.1853
people 0.0184 vaccine safety 0.0399 monosodium glutamate 0.1811
pandemic H1N1 swine flu vaccine 0.0184 adverse effects 0.0354 hepatitis B vaccine 0.1793
Merck 0.0184 vaccine-injured children 0.1763
measles mortality 0.0184 vaccine safety 0.1721
evidence 0.1655
informed consent 0.1643
intelligent questions 0.1612
formaldehyde 0.1609
pregnant women 0.1598
pandemic H1N1 swine flu vaccine 0.1595
Big Pharma 0.1591
vaccines are safe 0.1565
quackery 0.1552
vaccine damage 0.1547
SV40 0.1545
science 0.1531
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D3.

Most central nodes and centrality measures for the neutral vaccine network.

Neutral vaccine sentiment network
Degree centrality Betweenness centrality Closeness centrality Eigenvector centrality
Mean = 0.0149 Mean = 0.0342 Mean = 0.1533 Mean = 0.0975
Std Dev = 0.0204 Std Dev = 0.0839 Std Dev = 0.0296 Std Dev = 0.11
SB 277 0.1824 vaccines 0.5749 vaccines 0.2335 SB 277 1
vaccines 0.1118 Dwoskin Family Foundation 0.4092 side effects 0.2208 vaccines 0.4304
anti-vaccination 0.1059 pertussis vaccine 0.3947 pertussis vaccine 0.2199 anti-vaccination 0.4177
pertussis vaccine 0.0824 vaccine-autism link 0.3620 whole-cell vaccine 0.2133 parents 0.3863
pertussis 0.0824 SB 277 0.3294 effective 0.2133 children 0.3830
high-dose flu vaccine 0.0647 children 0.2643 pertussis vaccine 0.3540
anti-vaccination 0.2554 home-school 0.3209
side effects 0.2347 education 0.3206
acellular pertussis vaccine 0.2077
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D4.

Top ranked nodes by closeness vitality for the three networks

Closeness vitality
Negative sentiment network Neutral sentiment network Positive sentiment network
Mean = 19148.407 Mean = 7029.871 Mean = 8449.754
Std Dev = 24052.786 Std Dev = 16597.291 Std Dev = 9778.734
thimerosal 239154 vaccines 127564 meningococcal disease 79948
MTHFR C677T defect 222220 Dwoskin Family Foundation 109972 vaccination 77396
millions of dollars 210944 vaccine-autism link 100468 polio vaccine opposition 74438
children with autism 201122 SB 277 49768 Wakefield study 64018
measles mortality 179468 acellular pertussis vaccine 48048 HPV vaccine 63748
vaccine court 172456 artificial vaccine 43430 vaccines 61934
National Vaccine Injury Compensation Program 168948 anti-vaccination 41638 autism 61016
anti-vaccination 145200 Generation Rescue 37594 orthodox Hasidic Jews 55846
measles 141736 immune response 34424 measles 47038
adverse effects 141140 Focus for Health 32640 hepatitis A vaccine 44804
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Appendix E: Data files

Data files and dynamic web-based interactive visualizations of semantic networks can be accessed online at: http://staff.vbi.vt.edu/swarup/vaccine_sentiment/.

Footnotes

Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

Conflicts of Interest: None

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