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Open Access

Peer-reviewed

Research Article

Barriers and facilitators of vaccine hesitancy for COVID-19, influenza, and pertussis during pregnancy and in mothers of infants under two years: An umbrella review

  • Bethany Nichol,

    Roles Data curation, Formal analysis, Methodology, Writing – original draft

    Affiliation Department of Social Work, Education and Community Wellbeing, Faculty of Health and Life Sciences, Northumbria University, Newcastle upon Tyne, United Kingdom

  • Jemma Louise McCready,

    Roles Data curation, Formal analysis, Methodology, Writing – review & editing

    Affiliation Department of Nursing, Midwifery and Health, Faculty of Health and Life Sciences, Northumbria University, Newcastle upon Tyne, United Kingdom

  • Mary Steen,

    Roles Conceptualization, Methodology, Writing – review & editing

    Affiliation Department of Nursing, Midwifery and Health, Faculty of Health and Life Sciences, Northumbria University, Newcastle upon Tyne, United Kingdom

  • John Unsworth,

    Roles Funding acquisition, Resources, Writing – review & editing

    Affiliation Department of Biomedical Science and Human Oncology, University of Bari "Aldo Moro", Bari, Italy

  • Valentina Simonetti,

    Roles Supervision, Writing – review & editing

    Affiliation Department of Social Work, Education and Community Wellbeing, Faculty of Health and Life Sciences, Northumbria University, Newcastle upon Tyne, United Kingdom

  • Marco Tomietto

    Roles Conceptualization, Funding acquisition, Methodology, Project administration, Resources, Supervision, Writing – review & editing

    marco.tomietto@northumbria.ac.uk

    Affiliations Department of Nursing, Midwifery and Health, Faculty of Health and Life Sciences, Northumbria University, Newcastle upon Tyne, United Kingdom, Research Unit of Nursing Science and Health Management, University of Oulu, Oulu, Finland, Visiting Professor, University of Bari “Aldo Moro”, Bari, Italy

Abstract

Background

Vaccination during pregnancy has been repeatedly demonstrated to be safe and effective in protecting against infection and associated harms for the mother, developing baby, and subsequent infant. However, maternal vaccination uptake remains low compared to the general population.

Objectives

An umbrella review to explore the barriers and facilitators to Influenza, Pertussis and COVID-19 vaccination during pregnancy and within 2 years after childbirth, and to inform interventions to encourage uptake (PROSPERO registration number: CRD42022327624).

Methods

Ten databases were searched for systematic reviews published between 2009 and April 2022 exploring the predictors of vaccination or effectiveness of interventions to improve vaccination for Pertussis, Influenza, or COVD-19. Both pregnant women and mothers of infants under two years were included. Barriers and facilitators were organised using the WHO model of determinants of vaccine hesitancy through narrative synthesis, the Joanna Briggs Institute checklist assessed review quality, and the degree of overlap of primary studies was calculated.

Results

19 reviews were included. Considerable overlap was found especially for intervention reviews, and the quality of the included reviews and their primary studies varied. Sociodemographic factors were specifically researched in the context of COVID-19, exerting a small but consistent effect on vaccination. Concerns around the safety of vaccination particularly for the developing baby were a main barrier. While key facilitators included recommendation from a healthcare professional, previous vaccination, knowledge around vaccination, and communication with and support from social groups. Intervention reviews indicated multi-component interventions involving human interaction to be most effective.

Conclusion

The main barriers and facilitators for Influenza, Pertussis and COVID-19 vaccination have been identified and constitute the foundation for policy development at the international level. Ethnicity, socioeconomic status, concerns about vaccine safety and side effects, and lack of healthcare professionals’ recommendations, are the most relevant factors of vaccine hesitancy. Adapting educational interventions to specific populations, person-to-person interaction, healthcare professionals’ involvement, and interpersonal support are important strategies to improve uptake.

Citation: Nichol B, McCready JL, Steen M, Unsworth J, Simonetti V, Tomietto M (2023) Barriers and facilitators of vaccine hesitancy for COVID-19, influenza, and pertussis during pregnancy and in mothers of infants under two years: An umbrella review. PLoS ONE 18(3): e0282525. https://doi.org/10.1371/journal.pone.0282525

Editor: Mohsen Abbasi-Kangevari, Tehran University of Medical Sciences, ISLAMIC REPUBLIC OF IRAN

Received: September 20, 2022; Accepted: February 17, 2023; Published: March 2, 2023

Copyright: © 2023 Nichol et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All relevant data are within the paper and its Supporting Information files. Furthermore the protocol is available in PLOS One (PONE-D-22-20568, accepted) and in PROSPERO (https://www.crd.york.ac.uk/prospero/display_record.php?RecordID=327624). More materials are also avaliable in OSF (https://osf.io/g94nu/).

Funding: This study has been supported by an internal funding provided by Northumbria University at Newcastle Upon Tyne (UK) (https://www.northumbria.ac.uk/). MT and JU received the funding. Bethany Nichol is the recipient. The funder had and will not have a role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. Our study has been internally supported by the University of Northumbria (Newcastle). Due to this, we don’t have a formal letter from the funder, as usually required according to the PLOS One guidelines for the external funders.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Vaccine hesitancy is defined as the delay in accepting or rejecting safe vaccines despite the availability of vaccination services and it describes a continuum between undecided and anti-vaccination behaviors [1]. Vaccine hesitancy is higher in women (21%) than in men (14.7%) [1]. Vaccination coverage is particularly low among pregnant women, with average uptake rarely exceeding 50% for Pertussis [2], Influenza [2, 3] and COVID-19 [4]. Uptake is especially low in women of lower socioeconomic status [5]. This is a public health concern as pregnant women are a vulnerable population and, if unvaccinated, are at higher risk of hospitalisation [6] or even death during pregnancy [7], with an increased chance of pre-eclampsia [8], the need for emergency caesarean section [6, 8], and stillbirth [6] from contracting COVID-19. Pertussis and Influenza pose a threat to the unborn child, as mortality is highest in infants under six months [9, 10]. Maternal vaccination provides a safe [1116] and cost effective [13, 17] way to protect the mother and infant from contracting both Influenza [17] and Pertussis [13], reducing preterm births [14, 18], low birth weight [18], and stillbirths [15]. Although the evidence on COVID-19 vaccination during pregnancy is in its infancy, emerging evidence supports the safety of vaccination [19].

The World Health Organisation (WHO) SAGE group ‘model of determinants for vaccine hesitancy’ [20] classifies vaccination behaviour into three domains [21]: contextual influences (relating to one’s wider sociodemographic, political, institutional, or economic background)(I), individual and group influences (including social environment, attitudes, and beliefs)(II), and vaccine and vaccine-specific issues (relating to access or the vaccination process)(III). Maternal vaccination for COVID-19, Influenza, and Pertussis are currently recommended by key advisory bodies such as the Advisory Committee on Immunization Practices in the United States [19, 22, 23]. Additionally, the COVID-19 Vaccine Global Access Federation Facility (COVAX) aims to ensure equitable access to affordable vaccination across the world [24] in partnership the World Health Organisation (WHO). Following increased availability and access, individual level determinants of vaccine hesitancy have become most important for investigating differences in uptake of maternal vaccination.

The determinants of COVID-19 vaccination hesitancy differ in comparison to other maternal vaccinations. For example, the influence of mass media and fake news have led to concerns about vaccine safety for the mother and the baby, and a mistrust to healthcare professionals’(HCPs) recommendations or institutional guidelines [25]. These factors are amplified by certain demographic characteristics such as identifying as an ethnic minority [26]. Understanding the determinants of vaccine hesitancy during pregnancy specifically and how these differ between vaccinations is a pre-requisite to developing interventions to increase uptake. Further, comparison of the findings from COVID-19 and Influenza after the Influenza pandemic in 2009 is beneficial in forecasting not only future COVID-19 action but reactions to future pandemics too.

A synthesis of the evidence exploring vaccine hesitancy during pregnancy over the past decade is required. Given the numerous primary studies and reviews available on this topic, an umbrella review offers a broad scope to provide an overall picture of the evidence, whilst assessing its quality and credibility [27]. The aim of this umbrella review is therefore to synthesise the established literature on Influenza with the emerging literature on COVID-19, to assess the most influential barriers and facilitators to vaccination during pregnancy.

Methods

The protocol for this umbrella review was registered via PROSPERO [28], (registration number: CRD42022327624). The PRISMA guidelines for reporting were used throughout [29].

Inclusion exclusion criteria

Systematic reviews of quantitative or mostly quantitative studies with or without meta-analysis were included that investigated the barriers and facilitators to vaccine hesitancy, either for COVID-19, Influenza, Pertussis, or a combination. Study samples were required to be pregnant or have been pregnant within the past two years, and either not vaccinated or partially unvaccinated.

Search strategy

A systematic search was performed on 22nd April 2022 (and last updated on the 3rd January 2023) on ten databases including EPISTEMONIKOS, CINAHL via EPSCO, and PsychArticles and The Health Research Collection via ProQuest (Consumer Health Database, Health & Medical Collection, Healthcare Administration Database, MEDLINE®, Nursing & Allied Health, Database, Psychology Database, and Public Health Database). Published systematic reviews were peer-reviewed, published in English, and from 2009 onwards. This cut-off was reflective of the Influenza pandemic in 2009 [30]. 2009 is also significant as the first RCT demonstrating the effectiveness of the seasonal Influenza vaccine during pregnancy had been published [31]. A library information specialist was consulted to check the search strategy against the PRESS statement [32]. The search strategy (Table 1, see also Supplementary Material 1 in S1 File for specific search queries) was created in accordance with the inclusion criteria and combined with Boolean operators ‘AND’ and ‘OR’. Search terms were divided into the topic of vaccination, the type of vaccination, specifying vaccine hesitancy, and the population of pregnant women. Discussion with other academics and forward and backward citation searching was applied to ensure a comprehensive search. As the Pertussis vaccine is often combined together with Tetanus and Diphtheria vaccine (Tetanus, Diphtheria And Pertussis–TDAP vaccine) and recommended during pregnancy, the TDAP vaccine has been specifically included in the search strategy. However, the main target of this vaccine during pregnancy is Pertussis, and, in some countries, it is not combined with Tetanus and Diphtheria. For this reason, this umbrella review specifically focused on Pertussis.

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Table 1. A summary of the search strategy, each column was divided by the Boolean operator ‘AND’ during the search.

https://doi.org/10.1371/journal.pone.0282525.t001

Study selection

Search results were downloaded from EPSCO and ProQuest via a RIS file and uploaded onto Rayyan [33] for screening. Following removal of duplicates, reviewer BN screened the remaining studies against the inclusion criteria based on title and abstract, followed by the remaining articles based on full text. For both of these stages, a second reviewer (JM) independently screened 10%, with any differences in decisions resolved through discussion.

Quality appraisal

Quality appraisal for the included reviews were conducted by BN using The Joanna Brigg’s Institute (JBI) critical appraisal tool for systematic reviews and research syntheses [34], which examines reviews for trustworthiness and quality of findings using eleven distinct aspects. The eleven aspects were analyzed using “yes”, “no”, “unclear” and “not applicable” criteria. Rather than excluding reviews based on quality, quality was considered when synthesising results. Again, second reviewer JM independently conducted quality appraisal, with differences in conclusion resolved through discussion. Cohen’s kappa statistic [35] was calculated to judge the degree of agreement between reviewers, following the judgement parameters from Altman [36].

Data extraction and synthesis

Data extraction followed guidance for overviews of reviews by Cochrane [37]. Data was extracted relating to study information, characteristics, search strategy, inclusion criteria, outcomes studied, findings, and conclusions. Reviewer JM completed data extraction for 10% of included studies, with any discrepancies resolved through discussion. Summarising rather than re-analysing the data was applied, in accordance to the nature of the research question [37]. Barriers and facilitators identified by the included reviews were mapped onto the WHO framework [38]. Heterogeneity statistics, pooled estimates, and 95% confidence intervals were collected where reviews included meta-analysis.

Data analysis

Studies were first entered into a table mapping the primary studies contained within included systematic reviews, to analyse the degree of overlap between reviews. ‘Calculated covered area’ (CCA) was calculated to estimate degree of overlap in terms of a percentage, using the equation by Pieper et al. [39]. To aid in the discussion of the quality appraisal of included reviews by categorising reviews based on quality, the scoring system by Kilich et al. [40] was applied. Any item marked ‘yes’ scored two, items marked ‘no’ subtracted two, items marked ‘unclear’ subtracted one, and ‘not applicable’ did not affect the scores. Scores were categorised into very low, low, moderate, and strong. Overlap, quality of each review, and quality assessment of primary studies for the included reviews were mapped together onto one table.

Results

Search outcomes

The PRISMA [29] diagram (Fig 1) illustrates the screening of 3366 retrieved articles. Articles were screened out based on full text for the following reasons; reviews were not systematic [4152], samples were included other than pregnant samples [3, 5355], the article was a primary study [5660], the review described implementation rather than individual level barriers and facilitators [61], the focus was around tetanus vaccination [62], and the paper described a review protocol [63].

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Fig 1. PRISMA 2020 diagram (Page et al., 2021), illustrating the exclusion process and distinguishing between article sources.

https://doi.org/10.1371/journal.pone.0282525.g001

Overlap

Degree of overlap in primary studies amongst included reviews was calculated separately for each of the following based on their exclusivity in the literature; barriers and facilitators related to COVID, barriers and facilitators related to all other included vaccinations, and reviews of interventions to increase vaccination. Including them in one overlap calculation would have artificially minimised the degree of overlap. Degree of overlap was found to be moderate for vaccination studies including Influenza, Pertussis and tetanus (7%), high in studies including COVID (15%), and very high for reviews assessing the effect of interventions (26%).

Quality of included primary studies

13 reviews assessed included studies for either quality or risk of bias [40, 6474], with the Newcastle-Ottawa scale and JBI quality assessments the most frequently used tools. Of the reviews that did assess for quality, their quality assessment is displayed alongside the review’s own quality appraisal and the assessment tool they used in Supplementary material 2 in S1 File. Interestingly, none of the primary studies of COVID-19 vaccination were judged to be as high risk of bias or of low quality. The quality and risk of bias assessments for Influenza and Pertussis were mixed and used a wide range of assessment tools.

Quality appraisal of included reviews

The JBI score for included reviews ranged between -5 to 22 out of a possible 22. Included reviews were mostly rated at either extreme, but most rated strong quality. Seven were rated as very low [38, 69, 7579], two low [64, 66], two as moderate [67, 70], and eight as strong [40, 65, 68, 7174, 80]. As shown in Supplementary material 3 in S1 File, the main issues that led to low scoring was the lack of a protocol to clarify the research questions before screening, a minimal search strategy, missing details about data extraction, quality assessment, whether they were cross-checked, no validated quality assessment or test for publication bias, and a lack of direction for future research. Cohen’s kappa statistic was fair (k = .32, CI = -.20-.27, p = .013).

Publication bias

The eight studies that assessed publication bias did so using funnel plots [40, 65, 67, 70, 72, 74], Egger’s [65, 67, 70, 73, 80] or Begg’s tests [70, 80]. Although several predictors did not acquire enough included studies to assess publication bias [40, 65, 74], reviews mostly concluded that there was no publication bias [65, 70, 73, 80].

Review characteristics

The 19 included reviews (Table 2) can be divided into three main categories; nine assessed barriers and facilitators to COVID-19 [67, 6971, 73, 7780], four assessed barriers and facilitators to one or both of Influenza and Pertussis [38, 40, 64, 65], and six assessed the effectiveness of interventions to increase vaccination of one or both of Influenza and Pertussis [66, 68, 72, 7476]. Of those in the latter two categories, six studied Influenza alone [64, 65, 72, 7476], one studied Pertussis only [68], and three included both [38, 40, 66]. No reviews assessed the effects of interventions to increase COVID-19 vaccination, likely due to the short period from the start of the COVID-19 outbreak. Of the 16 reviews, eight included a meta-analysis [40, 65, 67, 69, 70, 72, 73, 80], of which five were concerning COVID-19 vaccination. Number of included studies ranged from three [80] to 155 [38], with reported sample sizes of included studies ranging from 10 [38] to 1, 862, 705 [65]. Although most reviews only included pregnant women, some included postpartum participants [40, 65, 74, 77, 79] up to 2 years after birth [40]. Others researchers narrowed their review scope to samples diverse in ethnicities [75], or to those within the US [71]. One study also included HCPs [38], although the findings from HCPs are not reported in this review.

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Table 2. Characteristics of included reviews.

Note, the conclusion of whether a meta-analysis was performed was based on whether it was performed for the outcome of interest (i.e not for safety of vaccination). SS = sample size.

https://doi.org/10.1371/journal.pone.0282525.t002

Findings

Barriers and facilitators to COVID vaccination

Contextual influences.

Black [67, 71, 78, 79] and Hispanic [78, 79] ethnicity and low socioeconomic status, either at the individual [77, 78] or area level [67], were reported as barriers to vaccination for COVID-19. There were mixed findings for the remaining sociodemographic variables [69, 73], particularly age [7880] and not precited by review quality, although income and education were more frequently concluded to be positive predictors of vaccination [70, 71, 7779]. Additional contextual predictors included suspicions around politically motivated vaccination campaigns [77, 78], possessing gestational diabetes [67] or fertility treatment [78], full-time employment [79], urban living [78] working as a HCP [78, 79], and being within the third trimester of pregnancy [70, 79].

Individual/ Social group influences.

Concerns around the safety and side effects [67, 71, 77, 78], specifically for the unborn child [71, 77, 78], were the most frequently cited beliefs that were a barrier to vaccination, whilst previous receipt of other vaccinations was cited by the most reviews as a key facilitator [70, 71, 73, 7779]. Other facilitators cited by more than one review were trust in the COVID-19 vaccine [67, 77] and healthcare system [78], knowledge of COVID-19 [69, 70, 78, 79], and compliance to other COVID-19 guidelines such as mask wearing and social distancing [70, 77, 78]. Less frequently cited barriers were concerns around effectiveness [71] and mistrust in the government [67], with less frequently cited facilitators including perception of the vaccine as safe and effective [79], diagnosis of COVID-19 during pregnancy [67, 79], fear of COVID-19 during pregnancy [67], and a sense of duty to one’s country [77, 78]. Whilst communication around the safety of the vaccine was reported as a facilitator by one review [77], knowledge was found to be a non-significant predictor by another [69].

Vaccine and vaccine-specific issues.

Only one review [71] highlighted barriers around vaccination such as lack of a recommendation by a HCP, refusal of the Influenza vaccine, and allergies to vaccines as barriers. Another review [78] found recommendation by a HCP to be a key facilitator of vaccination, and receiving counselling about vaccination from a HCP to be an effective intervention.

Barriers and facilitators to influenza and pertussis vaccination

Contextual influences.

Black [65, 75] and ethnic minority ethnicities [38] were amongst the most commonly cited barriers of vaccination, with only one review finding no effect of ethnicity [65]. Evidence for education as a predictor of vaccination was mixed, with one review citing low education as a barrier [64], supported by one primary study, and another finding no association [65]. Older age, employment, and being married were found to predict vaccination, whilst no effect was found for income or socioeconomic status in general [65]. Concerning wider influences, awareness of a national policy to support vaccination resulted in a three-times higher probability of vaccination [40], with access and convenience another frequently cited facilitator [40]. One review each cited lack of convenience [38], and conspiracy theories [64] as barriers to vaccination.

Findings from the reviews of interventions found that when tailored to ethnic minorities, pamphlets were found to eliminate inequalities of vaccination by ethnicity [75]. Additionally, providing transport to the vaccination centre was reported to be an effective intervention [76], suggesting access and convenience as facilitators.

Individual/ Social group influences.

Concerns about safety of the vaccination were the most commonly referred to barriers around individual/social group for Influenza and Pertussis [38, 40, 64, 75], both for the pregnant women [64], but mostly the unborn child [40, 64, 75]. Related barriers included emotions such as fear and worry [40]. Doubts about efficacy of the vaccine were also common [38, 64], and may be related to the influence of both low perceived risk of the illness [38, 64, 75] and perceived benefits of vaccination [38, 40]. Previous receiving of the vaccine was found to be a facilitator of maternal vaccination [40, 65, 75], increasing vaccination between three and five times [40], with an especially large effect on pandemic, and no effect on seasonal Influenza vaccination [40]. The influence of social groups could either act as a barrier [40, 64] or facilitator [38, 40] to vaccination. For example, hearing of bad experiences from one’s social network was cited as a barrier in a participants’ own decision to vaccinate [64], but encouragement from a partner acted as a facilitator [38]. The success of ‘immunisation champions’ reported by once review [75] support the findings of social encouragement and support as a facilitator.

Level of knowledge around the illness was cited as an important predictor of vaccination [38, 40]. However, the included intervention reviews found inconsistent evidence in support of education delivered by pamphlets [66, 74, 76], poster [66] or in-person sessions [66], and education provided through video did not significantly increase vaccination [66, 68, 75].

Vaccine and vaccine-specific issues.

Recommendation from a HCP was the most frequently cited vaccine-specific facilitator of vaccination [38, 40, 75], increasing vaccination by 12 times for Influenza and 10 for Pertussis [40]. In support, the included intervention reviews found interventions involving a recommendation by a HCP [76], or increased contact (e.g. attending prenatal care) [65, 66, 75] with HCPs to increase vaccination uptake. Additional vaccine-specific barriers included a general aversion to vaccination [64, 75], a preference for natural immunity [40], pain [40], and needle fears [64].

Interacting factors.

Two reviews discussed the influence of recommendation from a HCP for COVID-19, which was much more frequently cited for Pertussis and Influenza vaccination. Further, reviews investigating barriers and facilitators to COVID-19 were more likely to cite sociodemographic predictors and attitudes towards governing bodies, and those exploring Influenza and Pertussis were more likely to discuss social influences such as one’s partner and views of the community. Additionally, previous receiving of vaccination for other illnesses was a prominent predictor of COVID-19 vaccination and cited by a larger portion of included reviews than for Influenza and Pertussis. An awareness of the presence of the government in encouraging vaccinations was cited in relation to COVID-19 only. Only one review (rated the highest quality) assessed barriers and facilitators to seasonal and pandemic Influenza separately [40] and found that concerns around the safety of vaccination for the developing baby and side effects were particularly surrounding pandemic rather than seasonal Influenza.

Differences in COVID-19 vaccination rates by country [69, 70, 73, 77, 78] are possibly explicable by socioeconomic variables, as significantly lower rates were found in low- and middle-income countries [70], and as discussed, socioeconomic variables such as income and education were consistently cited in the included reviews. Country also interacted with effect of advice from a partner on maternal vaccination, namely through cultural gender norms and expectations [38].

Mode of delivery mattered for interventions to improve vaccination. Text messaging alone was consistently ineffective [72, 76], either to deliver education [75], to provide reminders [66], or both [74]. Video interventions were also found to be ineffective [68]. Generally, there was a pattern that in-person or physical rather than virtual interventions were more effective in increasing uptake, although one review focusing on the effect of digital interventions concluded that they were more effective than non-digital interventions [72]. Text-message reminders were effective when part of larger combined intervention that were practice-wide [74, 75], although it is difficult to identify their individual influence in increasing vaccination.

Findings from meta-analyses.

Meta-analyses were only performed for Influenza and COVID-19 aside from one for Pertussis [40]. One review performed meta-analyses separately where possible [40]. As shown in Supplementary material 4 in S1 File, the findings for contextual influences of vaccination were mixed. Overall, Odd Ratios (ORs) for contextual factors were small in comparison to other predictors. The largest ORs observed were for education and age, although findings were inconsistent. Education was only explored in the context of COVID-19. The review reporting the lowest odds ratio (OR) was of high heterogeneity and low quality [69], and the remaining two found odds ratios of 1.33 [73] and 1.84 [70]. ORs for age were also highly inconsistent [65, 69, 70, 73, 80], ranging from 1.02 [80] to 2.01 [70], and not predicted by whether the vaccination was for Influenza or COVID-19, the quality of the included review, the quality of included studies, heterogeneity of included studies, or the possibility of publication bias. Employment [65, 73], being married [65, 73], income [69], being pregnant for the first time [73], having no children [65, 80], living in a rural area [65], and being Black ethnicity compared to other ethnicities in high income countries [65] had a minimal or no effect on vaccination.

Individual/social group influences generally predicted vaccination on a much larger magnitude, although again, the heterogeneity was large. The highest ORs were observed for recommendation from a HCP for seasonal Influenza and Pertussis [40]. Other predictors with a large magnitude included previous receipt of vaccination during pregnancy and in general and perceived benefit to the mother for pandemic Influenza [40], perceived benefit of vaccination and knowledge or information provision for seasonal Influenza [40], good practice (one’s general motivation to prevent illness and engagement in health behaviours to do so) for COVID-19 [70], and previous receipt of vaccination in general and Influenza [40, 65]. In terms of barriers to vaccination, perceiving the vaccine as unsafe and to cause birth defects or miscarriage, and knowledge of vaccine side effects predicted the lowest odds of vaccination uptake for Influenza [40]. Pre-existing comorbidities [73], history of infection [73], and being in the third trimester [70] exerted negligible effects on COVID-19 vaccination, comparable to smoking status [65] for Influenza.

The prediction of knowledge/information remained relatively similar across COVID-19 [69, 70] and pandemic Influenza [40], but was especially high for seasonal Influenza [40]. ORs for general previous receipt of vaccination were inconsistent [40, 65, 70, 80], with the lowest for COVID-19 [80] and the highest for pandemic Influenza [40]. A similar pattern was found for previous receipt of vaccination during pregnancy [40, 73], although the lowest OR was found for seasonal Influenza [40].

Overall acceptance rates.

The only meta-analyses for vaccination acceptance rates were conducted for COVID-19 [67, 69, 73, 80], as shown in Supplementary Material 5 in S1 File. Perhaps predictably, actual vaccination rate was almost half the rate of acceptance of vaccination and intention to vaccine [67, 69], at 28% [73]. The reviews that did not apply meta-analysis found similar acceptance rates, ranging from 29.7% and 77.4% [77] and 3% and 65% [71] overall. One review found acceptance rates to be moderated by study quality, namely that as pooled estimates were higher for studies of moderate compared to low risk of bias, and for cross-sectional rather than cohort designs [67].

Discussion

Nineteen reviews of maternal vaccination hesitancy and the effectiveness of interventions were retrieved. Knowledge and information, previous receipt, and concerns around the safety were found to be the most consistent predictors of vaccination during pregnancy. Demographic predictors such as ethnicity and age were frequently cited, although results could be inconsistent, and the magnitude of their effect was low. Mapping onto the model for determinants of vaccine hesitancy [21], individual and social group factors were found to be the largest and most consistent predictors, with only sparse evidence for vaccine and vaccine-specific issues.

There was consistent evidence that recommendation from a HCP predicted vaccination rates with a large magnitude, particularly for Influenza and Pertussis. This mirrors the strong consistent relationship found in the general population [81], which also applies to other preventative health behaviours such as screening. For example, discussion with a HCP has been cited as a key predictor of uptake of both breast [82, 83] and prostate [84] cancer screening, and endorsement from a HCP increased colorectal cancer screening by 6% [85]. Thus, interventions to improve attitudes of HCPs towards vaccination are essential in encouraging maternal vaccination. Of the included reviews that identified provider-focused interventions, providing training and education for HCPs [66, 68], reminding HCPs to discuss vaccination with patients [66, 74, 76], and a midwife delivery programme [66, 68] were found to be effective in increasing maternal vaccination. However, many strategies were part of combined interventions, therefore future interventions would benefit from testing their impact individually. Similarly, previous vaccination was a consistent predictor for vaccination of Influenza and COVID-19. This predictor aligns with the prominent prediction of past behaviour for vaccination [86] and a range of other health behaviours [87]. The influence of past behaviour is arguably indicative of habit, in which the behaviour becomes automatic. In support, habit and vaccination being thought of as an automatic process with little decision making involved significantly predict vaccination [88]. Relatedly, the current review found good practice of preventative healthcare to strongly predict maternal vaccination [70], which suggests that habits may translate to similar behaviours. Indeed, Fleig et al. found that the ability to transfer learning from one context into another mediated the relationship between habit strength and engaging in increased physical activity and improving diet together [89]. Therefore, future interventions should target those who have never been vaccinated before to ensure future vaccination adherence to other infectious diseases.

Whilst many barriers and facilitators remained constant across infectious diseases, there were some notable differences. For example, ethnicity and socioeconomic status were noted as predictors of COVID-19 vaccination, but inconsistently predicted Influenza and Pertussis vaccination. One explanation that the current review found is that mistrust in governing bodies is more relevant for COVID-19, which has been found to predict COVID-19 vaccination uptake [90]. Since mistrust in the government, scientists and medical professionals is higher in ethnic minorities [91, 92], the two factors may interact. However, mistrust was not found to fully mediate the relationship between ethnicity and COVID-19 vaccination [93]. Thus, investigation is required to explore the mediating factors for the increased influence of ethnicity for COVID-19 vaccination specifically. Additionally, predictors of Influenza vaccination varied between seasonal and pandemic strains. Whilst recommendation from a HCP, beliefs, knowledge and attitudes were more important for seasonal Influenza, previous vaccination was more important in predicting pandemic Influenza. Taken together with the finding that pandemic Influenza vaccination is predicted by previous receipt of seasonal Influenza vaccination [94], this supports the notion that there are numerous factors predicting vaccination for the first time, but after that, past behaviour becomes the strongest predictor of future vaccination, as discussed above [86]. However, the magnitude of the prediction of past behaviour did not translate from pandemic Influenza to COVID-19, indicating separate and distinct factors.

The inclusion of intervention reviews enriched the understanding of the current review of how barriers and facilitators may interact. For example, whilst most reviews reported knowledge as a key predictor of vaccination, the findings from the included effectiveness reviews indicate that education is rarely sufficient. Secondly, the included intervention reviews generally found person-to-person interventions to be more effective, potentially indicating social interaction as a facilitator for vaccination. Indeed, reviews of the general population have also found interventions delivered either in person or via telephone to be more effective than virtual or text messaging interventions [95, 96], demonstrating the influence of interpersonal support in encouraging vaccination. Finally, the current review found multi-component interventions to be most effective, reflecting the numerous barriers and facilitators identified and similar to findings from interventions to encourage vaccination in the general population [97]. Additionally, the current review suggests that when designing interventions for pregnant women, specific attention needs to be directed towards education and emotional regulation around the safety of the developing baby and subsequent infant.

This review has also provided valuable insights into the current state of the research into vaccine hesitancy during pregnancy. Firstly, the sociodemographic influences were most frequently discussed in the context of COVID-19. Whilst it may be that sociodemographic factors such as socioeconomic status are more relevant for COVID-19 vaccination, an alternate explanation is that the literature to explore its predictive factors is in its infancy. This may have created a bias towards investigating these factors as sociodemographic questions are relatively easy and quick to measure. Where barriers and facilitators outside of sociodemographic factors were explored, there lacked a quantitative analysis of findings. Related to this finding, recommendation from a HCP was minimally explored in the context of COVID-19. Interestingly, evidence relating to COVID-19 from primary studies is inconsistent [98, 99], with one finding that pregnant individuals resist recommendation from a HCP with a preference to delay vaccination until after pregnancy [99]. Therefore, more research is required to explore whether the prediction of recommendation from a HCP also applies to COVID-19 vaccination. Secondly, the current review found primary studies on COVID-19 to be judged as higher quality and with lower risk of bias than the literature on Influenza and Pertussis. A potential explanation is that none of the reviews on COVID-19 assessed risk of bias or quality using Cochrane tools or the GRADE framework, which is arguably the most rigorous assessment method as it considers numerous predictors of quality including risk of bias [100]. Alternatively, it may be that the literature on COVID-19 is of better quality because it is more recent, possibly due to an increased demand by funders for researchers to adhere to open science practices such as pre-registration [101]. Thirdly, the high ORs found for individual and social group factors in predicting Influenza vaccination were mainly driven by one review [40]. Although the review itself was judged to be of strong quality, publication bias was not assessed for most predictors, and the included primary studies were assessed to be of mixed quality. Therefore, conclusions for predictors based on only one review must be interpreted with caution.

There are several limitations to the current umbrella review that must be acknowledged. Most importantly, the degree of overlap of included primary studies was high especially for COVID-19 and intervention reviews, thus inflating the influence of repeated primary studies on the conclusions made. Nevertheless, a meta-analysis of meta-analyses was not performed, thus the problem of providing disproportionate statistical power to these studies was avoided [39]. Additionally, as the scope was to investigate barriers and facilitators on the level of pregnant individuals, this inherently missed some of the contextual and vaccine-specific determinants of vaccine hesitancy such as economics, health systems, and vaccine access [102]. Lastly, as the current review included multiple types of study and infectious disease, conclusions made for each domain are limited in their generalisability. However, this scope did allow for useful comparisons and contrasts to be made which can help inform the nuances of future targeted interventions.

Conclusion

Although sociodemographic factors predict vaccine hesitancy, their influence is small compared to individual and social group influences. Policymakers should consider different levels of intervention to promote vaccination uptake and further research should directly compare predictive factors across COVID-19, and Influenza and Pertussis. In conclusion, more research, specifically quantitative synthesis, is needed to explore the barriers and facilitators to COVID-19 vaccination outside of sociodemographic variables, and the potential of interventions to improve COVID-19 vaccination rates. This will help inform on whether interventions to improve vaccination should be tailored depending on the infectious disease. Interventions to increase maternal vaccination during pregnancy and two years after childbirth should target first time vaccinators, be delivered through person-to-person contact, and be multi-component. Suggested components include targeting social norms and interpersonal support, knowledge, emotional regulation, and habit formation. Multi-level interventions should engage and provide education to HCPs, to encourage them to provide recommendations to pregnant women.

References

  1. 1. Robertson E, Reeve KS, Niedzwiedz CL, Moore J, Blake M, Green M, et al. Predictors of COVID-19 vaccine hesitancy in the UK household longitudinal study. Brain, behavior, and immunity. 2021;94:41–50.
  2. 2. Barber A, Muscoplat MH, Fedorowicz A. Coverage with tetanus, diphtheria, and acellular pertussis vaccine and influenza vaccine among pregnant women—Minnesota, March 2013–December 2014. Morbidity and Mortality Weekly Report. 2017;66(2):56. pmid:28103212
  3. 3. Yuen CYS, & Tarrant M. Determinants of uptake of influenza vaccination among pregnant women–a systematic review. Vaccine. 2014;32(36):4602–13. pmid:24996123
  4. 4. Carbone L, Di Girolamo R, Mappa I, Saccone G, Raffone A, Di Mascio D, et al. Worldwide beliefs among pregnant women on SARS-CoV-2 vaccine: a systematic review. European Journal of Obstetrics & Gynecology and Reproductive Biology. 2021. pmid:34920272
  5. 5. Stock SJ, Carruthers J, Calvert C, Denny C, Donaghy J, Goulding A, et al. SARS-CoV-2 infection and COVID-19 vaccination rates in pregnant women in Scotland. Nature medicine. 2022;28(3):504–12. pmid:35027756
  6. 6. Vousden N, Ramakrishnan R, Bunch K, Morris E, Simpson N, Gale C, et al. Management and implications of severe COVID‐19 in pregnancy in the UK: data from the UK Obstetric Surveillance System national cohort. Acta Obstetricia et Gynecologica Scandinavica. 2022. pmid:35213734
  7. 7. Nakamura-Pereira M, Andreucci CB, Menezes M, Knobel R, Takemoto MLS. Worldwide maternal deaths due to COVID-19: A brief review. Int J Gynecol Obstet. 2020;151(1):148–50. pmid:32706925
  8. 8. Gurol-Urganci I, Jardine JE, Carroll F, Draycott T, Dunn G, Fremeaux A, et al. Maternal and perinatal outcomes of pregnant women with SARS-CoV-2 infection at the time of birth in England: national cohort study. American journal of obstetrics and gynecology. 2021;225(5):522. e1ߝ. e11. pmid:34023315
  9. 9. Bhat N, Wright JG, Broder KR, Murray EL, Greenberg ME, Glover MJ, et al. Influenza-associated deaths among children in the United States, 2003–2004. New England Journal of Medicine. 2005;353(24):2559–67. pmid:16354892
  10. 10. Dabrera G, Amirthalingam G, Andrews N, Campbell H, Ribeiro S, Kara E, et al. A case-control study to estimate the effectiveness of maternal pertussis vaccination in protecting newborn infants in England and Wales, 2012–2013. Clinical Infectious Diseases. 2015;60(3):333–7. pmid:25332078
  11. 11. Juvet LK, Robertson AH, Laake I, Mjaaland S, Trogstad L. Safety of Influenza A H1N1pdm09 Vaccines: An Overview of Systematic Reviews. Frontiers in immunology. 2021:4540. pmid:34777351
  12. 12. McMillan M, Clarke M, Parrella A, Fell DB, Amirthalingam G, Marshall HS. Safety of tetanus, diphtheria, and pertussis vaccination during pregnancy. Obstetrics & Gynecology. 2017;129(3):560–73.
  13. 13. Furuta M, Sin J, Ng ES, Wang K. Efficacy and safety of pertussis vaccination for pregnant women–a systematic review of randomised controlled trials and observational studies. BMC pregnancy and childbirth. 2017;17(1):1–20.
  14. 14. Lu QC, Zhang TY, Bundhun PK, Chen C. One “misunderstood” health issue: demonstrating and communicating the safety of influenza a vaccination in pregnancy: a systematic review and meta-analysis. BMC Public Health. 2021;21(1):1–14.
  15. 15. Jeong S, Jang EJ, Jo J, Jang S. Effects of maternal influenza vaccination on adverse birth outcomes: A systematic review and Bayesian meta-analysis. PloS one. 2019;14(8):e0220910. pmid:31412058
  16. 16. Gidengil C, Goetz MB, Newberry S, Maglione M, Hall O, Larkin J, et al. Safety of vaccines used for routine immunization in the United States: An updated systematic review and meta-analysis. Vaccine. 2021;39(28):3696–716. pmid:34049735
  17. 17. Quach THT, Mallis NA, Cordero JF. Influenza vaccine efficacy and effectiveness in pregnant women: systematic review and meta-analysis. Maternal and child health journal. 2020;24(2):229–40. pmid:31865602
  18. 18. Nunes MC, Aqil AR, Omer SB, Madhi SA. The effects of influenza vaccination during pregnancy on birth outcomes: a systematic review and meta-analysis. American journal of perinatology. 2016;33(11):1104–14. pmid:27603545
  19. 19. Prevention CfDCa. COVID-19 Vaccines While Pregnant or Breastfeeding 2022 [Available from: https://www.cdc.gov/coronavirus/2019-ncov/vaccines/recommendations/pregnancy.html.
  20. 20. WHO. SAGE working group dealing with vaccine hesitancy (March 2012 to November 2014) 2012. Available from: http://www.who.int/immunization/sage/sagewgvaccinehesitancyapr12/en/
  21. 21. Larson HJ, Jarrett C, Eckersberger E, Smith DM, Paterson P. Understanding vaccine hesitancy around vaccines and vaccination from a global perspective: a systematic review of published literature, 2007–2012. Vaccine. 2014;32(19):2150–9. pmid:24598724
  22. 22. Havers FP, Moro PL, Hunter P, Hariri S, Bernstein H. Use of tetanus toxoid, reduced diphtheria toxoid, and acellular pertussis vaccines: updated recommendations of the Advisory Committee on Immunization Practices—United States, 2019. Morbidity and Mortality Weekly Report. 2020;69(3):77. pmid:31971933
  23. 23. Grohskopf LA, Sokolow LZ, Broder KR, Walter EB, Fry AM, Jernigan DB. Prevention and control of seasonal influenza with vaccines: recommendations of the Advisory Committee on Immunization Practices—United States, 2018–19 influenza season. MMWR Recommendations and Reports. 2018;67(3):1. pmid:30141464
  24. 24. Emanuel EJ, Luna F, Schaefer GO, Tan K-C, Wolff J. Enhancing the WHO’s proposed framework for distributing COVID-19 vaccines among countries. American Public Health Association; 2021. p. 371–3. pmid:33566663
  25. 25. Hu Z, Yang Z, Li Q, Zhang A. The COVID-19 infodemic: infodemiology study analyzing stigmatizing search terms. Journal of medical Internet research. 2020;22(11):e22639. pmid:33156807
  26. 26. Lin C, Tu P, Beitsch LM. Confidence and receptivity for COVID-19 vaccines: a rapid systematic review. Vaccines. 2020;9(1):16. pmid:33396832
  27. 27. Gianfredi V, Nucci D, Amerio A, Signorelli C, Odone A, Dinu M. What Can We Expect from an Umbrella Review? Advances in Nutrition. 2022;13(2):684–5.
  28. 28. Nichol B, Tomietto M., McCready J., Unsworth J., Steen M. Barriers and facilitators to vaccination for COVID-19, pertussis and influenza during pregnancy: an umbrella review. CRD42022327624. PROSPERO: International prospective register of systematic reviews.: PROSPERO; 2022 [Available from: https://www.crd.york.ac.uk/PROSPERO/display_record.php?RecordID=327624.
  29. 29. Page MJ, McKenzie JE, Bossuyt PM, Boutron I, Hoffmann TC, Mulrow CD, et al. Updating guidance for reporting systematic reviews: development of the PRISMA 2020 statement. Journal of clinical epidemiology. 2021;134:103–12. pmid:33577987
  30. 30. Organization WH. Pandemic H1N1 2009. WHO Regional Office for South-East Asia; 2009.
  31. 31. Zaman K, Roy E, Arifeen SE, Rahman M, Raqib R, Wilson E, et al. Effectiveness of maternal influenza immunization in mothers and infants. New England Journal of Medicine. 2008;359(15):1555–64. pmid:18799552
  32. 32. McGowan J, Sampson M, Salzwedel DM, Cogo E, Foerster V, Lefebvre C. PRESS peer review of electronic search strategies: 2015 guideline statement. Journal of clinical epidemiology. 2016;75:40–6.
  33. 33. Ouzzani M, Hammady H, Fedorowicz Z, Elmagarmid A. Rayyan—a web and mobile app for systematic reviews. Systematic reviews. 2016;5(1):1–10. pmid:27919275
  34. 34. Aromataris E, Fernandez R, Godfrey CM, Holly C, Khalil H, Tungpunkom P. Summarizing systematic reviews: methodological development, conduct and reporting of an umbrella review approach. JBI Evidence Implementation. 2015;13(3):132–40. pmid:26360830
  35. 35. McHugh ML. Interrater reliability: the kappa statistic. Biochemia medica. 2012;22(3):276–82. pmid:23092060
  36. 36. Altman DG. Practical statistics for medical research: CRC press; 1990.
    • 37. Pollock M, Fernandes RM, Becker LA, Pieper D, Hartling L. Chapter V: overviews of reviews. Cochrane handbook for systematic reviews of interventions version. 2020;6.
    • 38. Wilson RJ, Paterson P, Jarrett C, Larson HJ. Understanding factors influencing vaccination acceptance during pregnancy globally: a literature review. Vaccine. 2015;33(47):6420–9. pmid:26320417
    • 39. Pieper D, Antoine S-L, Mathes T, Neugebauer EA, Eikermann M. Systematic review finds overlapping reviews were not mentioned in every other overview. Journal of clinical epidemiology. 2014;67(4):368–75. pmid:24581293
    • 40. Kilich E, Dada S, Francis MR, Tazare J, Chico RM, Paterson P, et al. Factors that influence vaccination decision-making among pregnant women: a systematic review and meta-analysis. PloS one. 2020;15(7):e0234827. pmid:32645112
    • 41. Blanchard-Rohner G, Siegrist C-A. Vaccination during pregnancy to protect infants against influenza: Why and why not? Vaccine. 2011;29(43):7542–50. pmid:21820480
    • 42. Ferdinand A. Boosting uptake of flu vaccination in pregnant women. Practice Nurse. 2012;42(15):12–4.
    • 43. Nickalls K. The challenge of increasing uptake of flu and COVID-19 vaccinations in pregnancy. Practice Nursing. 2021;32:S4–S.
    • 44. Ault KA, Heine RP, Riley LE. Programmatic and research priorities for improving influenza immunization of pregnant women. American journal of obstetrics and gynecology. 2012;207(3):S75–S7. pmid:22920064
    • 45. Iacobucci G. Covid-19 and pregnancy: vaccine hesitancy and how to overcome it. BMJ: British Medical Journal (Online). 2021;375.
    • 46. Launay O, Tsatsaris V. Maternal influenza immunisation in resource-limited settings. The Lancet Infectious Diseases. 2016;16(9):983–4. pmid:27261068
    • 47. Müller-Schulte E, Gärtner BC. Vaccinations during pregnancy: a call to sting into action. Future Microbiology. 2019;14(11):995–1006.
    • 48. Shavell VI, Moniz M. H., Gonik B., & Beigi R. H. Influenza immunization in pregnancy: overcoming patient and health care provider barriers. American Journal of Obstetrics & Gynecology. 2012;207(3):S67–74. pmid:22920063
    • 49. Hamilton B. Understanding why there is a higher maternal uptake of the pertussis vaccine (whooping cough) in comparison to the influenza vaccine: a literature review. MIDIRS Midwifery Digest. 2020;30(4):472–82.
    • 50. Krishnaswamy S, Wallace E, Buttery J, Giles M. Antenatal pertussis vaccination: Are we implementing best evidence into practice? Australian and New Zealand Journal of Obstetrics and Gynaecology. 2016;56(6):552–5. pmid:27704540
    • 51. Yuen CY, Tarrant M. A comprehensive review of influenza and influenza vaccination during pregnancy. The Journal of perinatal & neonatal nursing. 2014;28(4):261–70. pmid:25347105
    • 52. Qiu X, Bailey H, Thorne C. Barriers and facilitators associated with vaccine acceptance and uptake among pregnant women in high income countries: A mini-review. Frontiers in Immunology. 2021;12:1246. pmid:33981298
    • 53. Raut S, Apte A, Srinivasan M, Dudeja N, Dayma G, Sinha B, et al. Determinants of maternal influenza vaccination in the context of low- and middle-income countries: A systematic review. PLoS One. 2022;17(1). pmid:35081138
    • 54. Guzman-Holst A, DeAntonio R, Prado-Cohrs D, Juliao P. Barriers to vaccination in Latin America: A systematic literature review. Vaccine. 2020;38(3):470–81. pmid:31767469
    • 55. Lutz CS, Carr W, Cohn A, Rodriguez L. Understanding barriers and predictors of maternal immunization: Identifying gaps through an exploratory literature review. Vaccine. 2018;36(49):7445–55. pmid:30377064
    • 56. Asavapiriyanont S, Kittikraisak W, Suntarattiwong P, Ditsungnoen D, Kaoiean S, Phadungkiatwatana P, et al. Tolerability of trivalent inactivated influenza vaccine among pregnant women, 2015. BMC Pregnancy and Childbirth. 2018;18(1):1–7.
    • 57. Gorman JR, Brewer NT, Wang JB, Chambers CD. Theory-based predictors of influenza vaccination among pregnant women. Vaccine. 2012;31(1):213–8. pmid:23123019
    • 58. Lu AB, Halim AA, Dendle C, Kotsanas D, Giles ML, Wallace EM, et al. Influenza vaccination uptake amongst pregnant women and maternal care providers is suboptimal. Vaccine. 2012;30(27):4055–9. pmid:22521842
    • 59. University C. Covid 19 Vaccine Acceptance in Egyptian Pregnant Women. clinicaltrialsgov. 2022.
    • 60. Vila-Candel R, Navarro-Illana P, Navarro-Illana E, Castro-Sánchez E, Duke K, Soriano-Vidal FJ, et al. Determinants of seasonal influenza vaccination in pregnant women in Valencia, Spain. BMC Public Health. 2016;16(1):1–7. pmid:27871262
    • 61. Baïssas T, Boisnard F, Cuesta Esteve I, Garcia Sánchez M, Jones CE, Rigoine de Fougerolles T, et al. Vaccination in pregnancy against pertussis and seasonal influenza: key learnings and components from high-performing vaccine programmes in three countries: the United Kingdom, the United States and Spain. BMC public health. 2021;21(1):1–15.
    • 62. Faria A, da Silva T, Duarte C, Mendes L, Santos F, Matozinhos F. Tetanus vaccination in pregnant women: a systematic review and meta-analysis of the global literature. Public Health. 2021;196:43–51. pmid:34144334
    • 63. Parsons J, Atherton H. How effective are digital interventions in increasing flu vaccination amongst pregnant women? A systematic review protocol. Systematic reviews. 2020;9(1):1–6.
    • 64. Adeyanju G E E, L K, T R, IBM S, MG H, et al. Determinants of influenza vaccine hesitancy among pregnant women in Europe: a systematic review. European journal of medical research. 2021;26(1):116. pmid:34583779
    • 65. Okoli GN, Reddy V. K., Al‐Yousif Y., Neilson C. J., Mahmud S. M., & Abou‐Setta A. M. Sociodemographic and health-related determinants of seasonal influenza vaccination in pregnancy: A systematic review and meta-analysis of the evidence since 2000. Acta obstetricia et gynecologica Scandinavica. 2021;100(6):997–1009. pmid:33420724
    • 66. Bisset KA, Paterson P. Strategies for increasing uptake of vaccination in pregnancy in high-income countries: A systematic review. Vaccine. 2018;36(20):2751–9. pmid:29661584
    • 67. Galanis P, Vraka I, Siskou O, Konstantakopoulou O, Katsiroumpa A, Kaitelidou D. Uptake of COVID-19 vaccines among pregnant women: a systematic review and meta-analysis. medRxiv. 2022:2022.04. 01.22273296. pmid:35632521
    • 68. Mohammed H, McMillan M, Roberts CT, Marshall HS. A systematic review of interventions to improve uptake of pertussis vaccination in pregnancy. PloS one. 2019;14(3):e0214538. pmid:30921421
    • 69. Nikpour M, Sepidarkish M, Omidvar S, Firouzbakht M. Global prevalence of acceptance of COVID-19 vaccines and associated factors in pregnant women: a systematic review and meta-analysis. Expert Review of Vaccines. 2022(just-accepted). pmid:35285374
    • 70. Nindrea RD, Djanas D, Darma IY, Hendriyani H, Sari NP. The risk factors and pregnant women’s willingness toward the SARS-CoV-2 vaccination in various countries: A systematic review and meta-analysis. Clinical Epidemiology and Global Health. 2022:100982. pmid:35169659
    • 71. S R, RL T, RH S, HN Y. COVID-19 Vaccination among Pregnant People in the U.S.: A Systematic Review. American journal of obstetrics & gynecology MFM. 2022:100616.
    • 72. Parsons J, Griffiths SE, Thomas N, Atherton H. How effective are digital interventions in increasing flu vaccination among pregnant women? A systematic review and meta-analysis. J Public Health. 2021;10.
    • 73. Shamshirsaz AA, Hessami K., Morain S., Afshar Y., Nassr A. A., Arian S. E., et al. Intention to receive COVID-19 vaccine during pregnancy: A systematic review and meta-analysis. American journal of perinatology. 2021. pmid:34670322
    • 74. Wong VW, Lok KY, Tarrant M. Interventions to increase the uptake of seasonal influenza vaccination among pregnant women: A systematic review. Vaccine. 2016;34(1):20–32. pmid:26602267
    • 75. Callahan AG, Coleman-Cowger V. H., Schulkin J., & Power M. L. Racial disparities in influenza immunization during pregnancy in the United States: A narrative review of the evidence for disparities and potential interventions. Vaccine. 2021. pmid:34312009
    • 76. Ellingson MK, Dudley M. Z., Limaye R. J., Salmon D. A., O’Leary S. T., & Omer S. B. Enhancing uptake of influenza maternal vaccine. Expert review of vaccines. 2019;18(2):191–204. pmid:30587042
    • 77. Januszek SM, Faryniak-Zuzak A., Barnaś E., Łoziński T., Góra T., Siwiec N., et al. The approach of pregnant women to vaccination based on a COVID-19 systematic review. Medicina. (Kaunas, Lithuania). 2021;57(9):977. pmid:34577900
    • 78. Badell ML, Dude CM, Rasmussen SA, Jamieson DJ. Covid-19 vaccination in pregnancy. bmj. 2022;378. pmid:35948352
    • 79. Sarantaki A, Kalogeropoulou VE, Taskou C, Nanou C, Lykeridou A. COVID-19 Vaccination and Related Determinants of Hesitancy among Pregnant Women: A Systematic Review and Meta-Analysis. Vaccines. 2022;10(12):2055. pmid:36560464
    • 80. Azami M, Nasirkandy MP, Esmaeili Gouvarchin Ghaleh H, Ranjbar R. COVID-19 vaccine acceptance among pregnant women worldwide: A systematic review and meta-analysis. PloS one. 2022;17(9):e0272273. pmid:36170334
    • 81. Paterson P, Meurice F, Stanberry LR, Glismann S, Rosenthal SL, Larson HJ. Vaccine hesitancy and healthcare providers. Vaccine. 2016;34(52):6700–6. pmid:27810314
    • 82. Nekhlyudov L, Ross-Degnan D, Fletcher SW. Beliefs and expectations of women under 50 years old regarding screening mammography. Journal of General Internal Medicine. 2003;18(3):182–9.
    • 83. Roberts RA, Birch NJ. A comparison of breast cancer secondary prevention activities and satisfaction with access and communication issues in women 50 and over. Preventive medicine. 2001;32(4):348–58. pmid:11304096
    • 84. Cormier L, Reid K, Kwan L, Litwin MS. Screening behavior in brothers and sons of men with prostate cancer. The Journal of urology. 2003;169(5):1715–9. pmid:12686816
    • 85. Hewitson P, Ward A, Heneghan C, Halloran S, Mant D. Primary care endorsement letter and a patient leaflet to improve participation in colorectal cancer screening: results of a factorial randomised trial. British journal of cancer. 2011;105(4):475–80. pmid:21829202
    • 86. Lin CJ, Nowalk MP, Toback SL, Rousculp MD, Raymund M, Ambrose CS, et al. Importance of vaccination habit and vaccine choice on influenza vaccination among healthy working adults. Vaccine. 2010;28(48):7706–12. pmid:20638452
    • 87. McEachan RRC, Conner M, Taylor NJ, Lawton RJ. Prospective prediction of health-related behaviours with the theory of planned behaviour: A meta-analysis. Health psychology review. 2011;5(2):97–144.
    • 88. van Keulen HM, Otten W, Ruiter RA, Fekkes M, van Steenbergen J, Dusseldorp E, et al. Determinants of HPV vaccination intentions among Dutch girls and their mothers: a cross-sectional study. BMC public health. 2013;13(1):1–21. pmid:23388344
    • 89. Fleig L, Kerschreiter R, Schwarzer R, Pomp S, Lippke S. ‘Sticking to a healthy diet is easier for me when I exercise regularly’: cognitive transfer between physical exercise and healthy nutrition. Psychology & Health. 2014;29(12):1361–72. pmid:24894668
    • 90. Gotanda H, Miyawaki A, Tabuchi T, Tsugawa Y. Association between trust in government and practice of preventive measures during the COVID-19 pandemic in Japan. Journal of general internal medicine. 2021;36(11):3471–7. pmid:34159544
    • 91. Wagner AL, Wileden L, Shanks TR, Goold SD, Morenoff JD, Gorin SNS. Mediators of Racial Differences in COVID-19 Vaccine Acceptance and Uptake: A Cohort Study in Detroit, MI. Vaccines. 2021;10(1):36. pmid:35062697
    • 92. Paul E, Fancourt D, Razai M. Racial discrimination, low trust in the health system and COVID-19 vaccine uptake: a longitudinal observational study of 633 UK adults from ethnic minority groups. Journal of the Royal Society of Medicine.01410768221095241. pmid:35512716
    • 93. Allington D, McAndrew S, Duffy B, Moxham-Hall V. Trust and experiences of National Health Service healthcare do not fully explain demographic disparities in coronavirus vaccination uptake in the UK: a cross-sectional study. BMJ open. 2022;12(3):e053827. pmid:35304394
    • 94. Setbon M, Raude J. Factors in vaccination intention against the pandemic influenza A/H1N1. European journal of public health. 2010;20(5):490–4. pmid:20444821
    • 95. Szilagyi P, Vann J, Bordley C, Chelminski AE, Kraus RM, Margolis PA, et al. Interventions aimed at improving immunization rates. Cochrane database of systematic reviews. 2002(4). pmid:12519624
    • 96. Lau D, Hu J, Majumdar SR, Storie DA, Rees SE, Johnson JA. Interventions to improve influenza and pneumococcal vaccination rates among community-dwelling adults: a systematic review and meta-analysis. The Annals of Family Medicine. 2012;10(6):538–46. pmid:23149531
    • 97. Ndiaye SM, Hopkins DP, Shefer AM, Hinman AR, Briss PA, Rodewald L, et al. Interventions to improve influenza, pneumococcal polysaccharide, and hepatitis B vaccination coverage among high-risk adults: a systematic review. American journal of preventive medicine. 2005;28(5):248–79. pmid:15894160
    • 98. Battarbee AN, Stockwell MS, Varner M, Newes-Adeyi G, Daugherty M, Gyamfi-Bannerman C, et al. Attitudes toward COVID-19 illness and COVID-19 vaccination among pregnant women: a cross-sectional multicenter study during August–December 2020. American journal of perinatology. 2022;39(01):075–83. pmid:34598291
    • 99. Riad A, Jouzová A, Üstün B, Lagová E, Hruban L, Janků P, et al. COVID-19 vaccine acceptance of pregnant and lactating women (PLW) in Czechia: an analytical cross-sectional study. International Journal of Environmental Research and Public Health. 2021;18(24):13373. pmid:34948987
    • 100. Zhang Y, Akl EA, Schünemann HJ. Using systematic reviews in guideline development: the GRADE approach. Research synthesis methods. 2019;10(3):312–29.
    • 101. Kaplan RM, Irvin VL. Likelihood of null effects of large NHLBI clinical trials has increased over time. PloS one. 2015;10(8):e0132382. pmid:26244868
    • 102. MacDonald NE. Vaccine hesitancy: Definition, scope and determinants. Vaccine. 2015;33(34):4161–4. pmid:25896383