Next Article in Journal
Rapid Generation of Recombinant Flaviviruses Using Circular Polymerase Extension Reaction
Next Article in Special Issue
Belarusian Healthcare Professionals’ Views on Monkeypox and Vaccine Hesitancy
Previous Article in Journal
A Mother’s Dilemma: The 5-P Model for Vaccine Decision-Making in Pregnancy
Previous Article in Special Issue
Knowledge, Attitudes, and Practices of Influenza Vaccination among Parents of Children with Asthma: A Cross-Sectional Study
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Vaccines
Volume 11
Issue 7
10.3390/vaccines11071249
vaccines-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

COVID-19 Vaccination Booster Dose: Knowledge, Practices, and Intention among Pregnant/Planning to Get Pregnant and Lactating Women

by
Walid Al-Qerem
1,*,
Anan Jarab
2,3,
Yara Shawabkeh
1,
Jonathan Ling
4,
Alaa Hammad
1,
Badi’ah Alazab
1 and
Fawaz Alasmari
5
1
Department of Pharmacy, AlZaytoonah University of Jordan, Amman 11733, Jordan
2
College of Pharmacy, Al Ain University, Abu Dhabi P.O. Box 64141, United Arab Emirates
3
Department of Clinical Pharmacy, Faculty of Pharmacy, Jordan University of Science and Technology, Irbid 22110, Jordan
4
Faculty of Science and Wellbeing, University of Sunderland, Sunderland SR1 3SD, UK
5
Department of Pharmacology and Toxicology, College of Pharmacy, King Saud University, Riyadh 12372, Saudi Arabia
*
Author to whom correspondence should be addressed.
Vaccines 2023, 11(7), 1249; https://doi.org/10.3390/vaccines11071249
Submission received: 12 June 2023 / Revised: 12 July 2023 / Accepted: 13 July 2023 / Published: 17 July 2023
(This article belongs to the Special Issue Recent Advances in Factors Associated with Vaccine Hesitancy and Acceptance)
Review Reports Versions Notes

Abstract

:
Pregnant women are at higher risk of developing severe COVID-19 symptoms. Therefore, booster dose against COVID-19 was recommended for this special population in Jordan. However, vaccine hesitancy/refusal remains the main obstacle to providing immunity against the spread of COVID-19. Thus, the aim of this study is to examine the intention of pregnant/planning to get pregnant and lactating women towards receiving a booster dose against COVID-19 and its associated factors. A questionnaire was given to Jordanian pregnant/planning to get pregnant and lactating females. A total of 695 females were enrolled in the study. Older age, having a chronic disease, high education, high income, and high perceived risk of COVID-19 were significantly associated with higher knowledge about COVID-19. High perceived risk of COVID-19 was significantly associated with better practice. Participants who anticipated they might contract COVID-19 in the next six months, had high perceived risk of COVID-19, had high knowledge, had received the COVID-19 vaccine based on conviction, and smokers had higher intention to receive a booster dose of the COVID-19 vaccination. In order to increase pregnant and lactating women’s intention to receive a booster dose of the COVID-19 vaccine, public health organizations should consider developing comprehensive health education campaigns.

1. Introduction

Coronavirus disease 2019 (COVID-19) emerged in December 2019 in Wuhan, China. According to the (World Health Organization) WHO, as of 19 April 2023, there have been over 763 million confirmed cases of the disease and more than six million deaths globally [1]. It is estimated that by the end of the pandemic the total financial cost of COVID-19 will likely be between USD 8.1–15.8 trillion worldwide [2].
Although there are emerging medications to treat COVID-19, preventative vaccination has been an extremely effective measure in reducing the incidence of COVID-19 and its complications, notably serious disease and disease-attributable mortality [3,4]. Nonetheless, vaccine refusal and hesitancy are significant barriers for vaccination programs’ success. Previous studies found that frequent reasons for vaccine hesitancy are personal and religious beliefs, wanting more information from healthcare providers, and safety concerns [5]. Due to new SARS-CoV-2 variants and the reduction of serum anti-spike IgG antibody levels that occur several months after vaccination, booster vaccination strategies have been implemented in several regions and are recommended globally by different health organizations, including the WHO [6,7].
Jordan has implemented a range of comprehensive and stringent preventive measures at multiple levels to effectively combat the transmission of COVID-19. However, as of 25 May 2022, authorities in Jordan have implemented relaxed COVID-19 measures. The compulsory use of facemasks in both indoor and outdoor public areas is no longer mandatory. Furthermore, all restrictions on public gatherings, including those at places of worship and wedding venues, have been lifted, but all the preventable instructions are still recommended including wearing face masks, maintaining a social distance of 3 feet in indoor settings, and hand hygiene. These decisions align with a decline in the number of COVID-19 cases [8,9].
Pregnant women are at higher risk of developing severe COVID-19 symptoms which may lead to more severe complications that require hospitalizations than non-pregnant women. A previous study suggested an association between the severity of COVID-19 during pregnancy and the Delta (B.1.617.2) variant of the SARS-CoV-2 virus [10]. Accordingly, The Centers for Disease Control and Prevention (CDC) recommend COVID-19 booster vaccines for pregnant females and consider them as a high-risk group. Similarly, CDC classifies lactating woman as a high-risk group receive COVID-19 vaccine [11].
Previous studies have shown suboptimal vaccination acceptance rates among pregnant and lactating women. For example, an Iranian study reported that only 42.9% of pregnant women consented to receive the COVID-19 vaccine [12]. A high rate of vaccine hesitancy was reported in a study from Italy (86.4%). This study revealed that the main reported reasons for hesitancy were concerns about the safety of the vaccine, no recommendation from a gynecologist, and a lack of knowledge [13]. Similarly, several studies have reported high hesitancy among lactating women in receiving the COVID-19 vaccine [14,15]. High hesitancy/refusal rates for receiving the COVID-19 vaccine in this subgroup could be attributed to the limited clinical studies that have enrolled pregnant women [16].
As far as we know, no previous studies have assessed Jordanian lactating, pregnant, or planning to get pregnant females’ intention to receive a booster dose against COVID-19. Thus, the primary aim of the present study is to evaluate the intention of these special populations toward receiving the first booster dose against COVID-19 (which will be referred to in the rest of the manuscript as the booster dose) and its associated factors, the study will also evaluate participants’ knowledge and practices towards COVID-19 and its vaccine.

2. Materials and Methods

This study is a multi-center cross-sectional study that was conducted across six different gynecologist clinics in Jordan. The distribution of participants is as follows: two clinics in Amman, with a combined total of 290 participants; one clinic in Irbid, which enrolled 150 participants; one clinic in Zarqa, which enrolled 140 participants; one clinic in Madaba, which recruited 138 participants; and one clinic in Aqaba, with a total of 132 participants. The current study included only the pregnant/planning to get pregnant and lactating females who were previously vaccinated with two doses of the COVID-19 vaccine. The research pharmacist approached pregnant/planning to get pregnant and lactating women attending different gynecologist clinics in Jordan. A quick interview was conducted with each participating woman to ensure that she met the inclusion criteria. The research pharmacist provided the enrolled women with an information sheet describing the study details and purposes. The researcher emphasized that participation was voluntary, and the participants had the right to refuse or withdraw from the study at any time without any effect on the provided healthcare. Women who agreed to participate were asked to sign a consent form. A Google Forms link was sent to the enrolled participants to complete the study questionnaire. Google Forms eliminates any possibility of missing data as it does not allow the participants to submit the form before completing all the required questions. The data were collected between May 2022 and April 2023. The principles of the Declaration of Helsinki were met, and the ethical approval was conceded by the Al-Zaytoonah Research Ethics Committee.

2.1. Sampling Type and Sample Size

Convenience sampling was adopted for participant recruitment in the present study. To calculate the minimum required sample size, the Krejcie and Morgan formula [17] was applied.
The formula is:
s = X2NP(1 − P) + d2 (N − 1) + X2P(1 − P)
s = required sample size;
X2 = the table value of chi-square for 1 degree of freedom at the desired confidence level (3.841);
N = the population size;
P = the population proportion;
d = the degree of accuracy expressed as a proportion (0.5).
Krejcie and Morgan composed sample size tables based on the above formula for different population sizes, confidence levels, and margin of errors. The population size was assumed to be above 1,000,000 (indefinite) and the minimum required sample was 384 for 95% CI and 5% margin of error.

2.2. Study Instrument

The present study’s questionnaire is based on a previously published study by Al-Qerem et al. [18] that evaluated intentions toward receiving the COVID-19 booster dose among the general population after adapting it to pregnant/planning to get pregnant and lactating females by adding relevant questions to these specific populations. These questions were added after an extensive literature review that evaluated intentions toward receiving the COVID-19 vaccine among the designated population [19,20,21].
The questionnaire was composed of several sections. The first section gathered participants’ sociodemographic characteristics. The second section evaluated the participants’ previous experiences and attitudes toward COVID-19 and included questions about previous infection, perceived possibility of future reinfection with COVID-19, knowing someone who died due to COVID-19, and the perceived risk of COVID-19 infection, which was evaluated by a single question with a response scale from 1 (indicating very low perceived risk) to 5 (indicating very high risk). The next part evaluated participants’ experiences and attitudes toward the COVID-19 vaccine, which included reasons for previous vaccination against COVID-19, type of vaccine received, intention to receive a booster dose, and side effects experienced due to the COVID-19 vaccine. A side effects score was computed by adding up all the reported side effects with a maximum possible score of 10. The fourth section evaluated participants’ knowledge about COVID-19 symptoms, protective practices against COVID-19, methods of infection transmission, and management of COVID-19, which included 22 items; one point was granted for each correct answer, while no points were granted for wrong answers, and then the sum of the points of the correct answers was used to compute the knowledge scale with a maximum possible score of 22. The fifth part evaluated participants’ adherence to protective practices against COVID-19, which included 5 items: wearing face masks, washing hands with soap regularly, using detergent, social distancing, and avoiding touching face/mouth/nose/eyes. The response scale for these items ranged from 1 point for “never” to 5 points for “always”, with the highest possible score of 25. The final part evaluated reasons for not receiving the booster dose among those who were reluctant/refused to receive the booster dose. The questionnaire is available in the Supplementary Materials (File S1).

2.3. Survey Validity and Reliability

The questionnaire was initially written in English and then translated into Arabic before it was back translated to English by native English speakers. The two English versions were deemed comparable. The content validity was verified by a panel of experts that included public health specialists, clinical pharmacists, and medical doctors specializing in infectious diseases. To determine face validity, the questionnaire was given to 40 participants and their feedback was obtained to enhance the questionnaire items. The data collected from the pilot study was excluded from the final dataset. The present study composed two latent variables: knowledge about COVID-19 and the adherence of protective practices against COVID-19; the reliability of these two latent variables was evaluated by examining Cronbach’s alpha value to ensure internal consistency.

2.4. Statistical Analysis

All statistical analyses were conducted using SPSS version 28. Categorical variables were presented as frequencies and percentages. The normality of the continues variables, perceived risk, side effects score, knowledge score, and practice score were assessed using Q-Q plots, and these plots indicated that all the continuous variables were not normally distributed; therefore, continuous variables were presented as median 95% CI and nonparametric analysis was conducted. The medians for the knowledge and practice scores were computed and the participants who were above the median were included in the “High” level group, while the least were included in the “Low” level group and the median for each score was reported in the result section. To identify variable associations with knowledge and practice, bivariate analyses using Chi-square and Mann–Whitney U tests were performed. For intention to receive a booster dose of COVID-19, Chi-square and Kruskal–Wallis tests were applied. Two binary regression models were built to assess variables associated with knowledge and practice levels, and a multinomial logistic regression model was performed to evaluate variable association with the intention to take a booster dose of COVID-19. The independent variables in the three regression models were defined as the variables that had p-values less than 0.2 in the bivariate analysis. A significant level was determined at p-value < 0.05.

3. Results

In total, 850 females who met the inclusion criteria were invited to participate in the present study, of whom 695 females (82%) agreed to participate. Sample demographic characteristics show that over half of the sample were between 18 and 29 years old (62.7%). Half of the enrolled participants were planning to get pregnant (51.1%), and almost three-quarters held a bachelor’s degree or higher (72.4%) (Table 1).
The normality of the continuous variables, perceived risk, side effect score, knowledge score, and practice score were assessed using Q-Q plots. These plots indicated that the all of the continuous variables were not normally distributed; therefore, nonparametric analyses were conducted. Most of the sample (77.7%) reported knowing someone who died due to COVID-19, and 50.4% of them reported previously being infected with COVID-19, while 18.6% were unsure if they had been infected (Table 2).
Participants’ experiences and attitudes toward the COVID-19 vaccine are shown in Table 3. The most frequently received vaccination was Pfizer’s (74.8%), and the most reported reason for taking the first doses of COVID-19 vaccine was conviction (67.8%). More than half of the enrolled participants intended to receive the booster dose of the COVID-19 vaccine (59.1%), while 23.5% of them were unsure. The most stated level of side effects due to COVID-19 vaccine severity was moderate (41%), and the most reported side effects were pain at the site of injection and fever (68.1% and 56.4%, respectively). The least reported side effect was water retention (1.2%). The median for the side effects score was 3 (3–4) out of 10.
As shown in Table 4, the most frequent knowledge item about the symptoms of COVID-19 was fever (95.4%), followed by loss of smell and taste (92.4%), while the least frequent was otitis media (34%). Additionally, the highest correct answer for protective practices were social distancing and wearing face masks (94.5% and 91.8%, respectively), while the lowest was medical herb consumption (44%). Furthermore, knowledge about the transmission of COVID-19 was obtained, and the most frequently correct item was the inhalation of respiratory droplets from an infected person (96.4%), while the least was eating or touching wild animals (42.2%). Regarding knowledge about the management of COVID-19, the most frequently reported correct item was for “What is the protective time that the vaccine provides against COVID-19?” (68.5%), while the least was “Is it necessary for the booster dose of the vaccine to be of the same type of vaccine used in the initial doses?” (27.9%).
The median for the Knowledge scores was 15 (15–16) out of a maximum possible score of 22. Knowledge scores were divided into two categories based on each score median, with those who scored less than or equal to the median classified as “low”, while the rest were classified as the high-knowledge group. The internal consistency of the knowledge scale was confirmed by computing Cronbach’s alpha (0.714) (Table 4).
Participants’ responses to the practice items are included in Table 5. The highest always/usually performed practices were washing hands with regular soap, followed by wearing face masks (91.6% and 82.4%, respectively), while the lowest was avoiding touching face/mouth/nose/eyes (70.5%). The median for the practice score was 22 (22–23) out of a maximum possible score of 25. The scores were divided into two categories based on each score median. Cronbach’s alpha was computed, and the results revealed that the practice scale had high internal consistency (0.841).
Bivariate analysis using Chi-square and Mann–Whitney U tests assessed the association between the knowledge and practice levels. Age was significantly associated with knowledge level (p < 0.001). Along with pregnancy status (p < 0.001), education (p-value < 0.001), household monthly income level (p < 0.001), chronic diseases (p = 0.12), perceived possibility of COVID-19 infection in the next 6 months (p < 0.001), and how serious the participants thought the infection with COVID-9 was (p < 0.001) were all associated with knowledge. Furthermore, the variables that were significantly associated with practice level were how serious the participants thought infection with COVID was (p < 0.001) and education (p = 0.09) (Table S1).
The variables associated with intention to get a booster dose of COVID-19 are presented in Table S2. The results show that the vaccine type (p-value = 0.002), age (p-value = 0.016), pregnancy status (p = 0.006), education (p = 0.011), household monthly income (p = 0.003), smoking (p < 0.001), reason to receive COVID-19 vaccine (p < 0.001), reporting knowing someone who died due to COVID-19 (p = 0.029), perceived possibility to be infected with COVID-19 in the next 6 months (p < 0.001), perceived risk the infection with COVID-19 is (p < 0.001), knowledge level (p < 0.001), and finally practice level (p < 0.001) were significantly associated with the intent to receive COVID-19.
Table 6 shows the binary regression results for variable association with the knowledge level. Participants aged from 30 to 39 had higher odds of being in the high-knowledge group compared to participants aged 18–29 years old (OR = 1.576, 95% CI (1.071–2.319), p = 0.021). Participants with chronic diseases had higher odds of being in the high-knowledge group compared to those with no chronic diseases (OR = 1.913, 95% CI (1.007–3.632), p = 0.047). Likewise, those who were highly educated had higher odds of being in the high-knowledge group compared to those with lower education (OR = 2.959, 95% CI (1.896–4.618), p < 0.001). Furthermore, having household income between JOD 500 and 1000 and more than JOD 1000 increased the likelihood of being in the high-knowledge group compared to those with a household income less than JOD 500 (OR = 2.713, 95% CI (1.803–4.083), p < 0.001; and OR = 4.803, 95% CI. (2.938–7.852), p < 0.001, respectively). Finally, as the perceived risk of COVID-19 increased, the odds of being in the high-knowledge group increased (OR = 1.361, 95% CI (1.169–1.586), p < 0.001).
The binary regression model for variables associated with the practice level is displayed in Table 7. “How serious is the infection with COVID?” was the only significant variable that increased the odds of being in the high-practice group (OR = 1.272, 95% CI (1.116–1.450), p < 0.001).
Multinomial regression was conducted to assess the variables related to responding “No” or “Maybe” vs. “Yes” regarding the intention to receive a booster dose of the COVID-19 vaccine. Participants who believed they would not be infected with COVID-19 in the next six months had higher odds of answering “No” when compared to those who believed they would be infected with severe symptoms (OR = 8.667, 95% CI (1.569–47.881), p = 0.013). Furthermore, the low-knowledge group had higher odds of answering “No” or “Maybe” when compared to the high-knowledge group (OR = 1.875, 95% CI (1.062–3.311), p = 0.030). Participants whose reason for receiving the COVID-19 vaccine was imposed laws or both conviction and imposed laws had higher odds of answering “No” (OR = 19.859, 95% CI (10.059–39.207), p < 0.001; and OR = 2.604, 95% CI. (1.344–5.043), p = 0.005, respectively) or “Maybe” (OR = 4.369, 95% CI = 2.241, p = 8.518; and OR = 2.081, 95% CI (1.221–3.546), p < 0.001, respectively) when compared to conviction only. Non-smoking participants had higher odds of answering “Maybe” when compared to smokers (OR = 3.774, 95% CI (1.916–7.432), p < 0.001). Finally, as the perceived risk of COVID-19 increased, the likelihood of answering “No” decreased (OR = 0.750, 95% CI (0.604–0.931), p = 0.009) s(Table 8).
Those who answered “No” to the question “Do you intend to receive the booster dose for COVID-19 vaccine?” were assigned to the vaccine refusal group, while participants who answered “Maybe” were assigned to the vaccine hesitancy group. The main reasons for reported vaccine hesitancy/refusal included “Lack of sufficient studies that evaluated the safety of COVID-19 on pregnant/lactating women” which was reported by 94% of the participants who refused or were reluctant to receive the booster dose. This was followed by “I am worried that the booster dose will harm my fetus/infant” (90.8%), while the least reported reason was “I was infected with COVID-19, therefore I do not need the booster dose” (Table S3).

4. Discussion

The majority of participants intended to receive the booster dose of the COVID-19 vaccine (59.1%). In comparison, nearly half of the participants surveyed in a study conducted in Ghana showed their acceptance of the COVID-19 vaccine booster dose [22], while higher acceptance of a booster dose of the COVID-19 vaccine was reported in studies conducted in Australia [23], Pakistan [24], and Malaysia [25].
In the current study, the majority of participants indicated that they encountered pain at the injection site (68.1%) and experienced fever (56.4%) following administration of the COVID-19 vaccine. The Centers for Disease Control and Prevention (CDC) have also highlighted that in terms of COVID-19 vaccine safety, the majority of individuals have reported mild-to-moderate side effects like headaches, fatigue, and soreness at the injection site, which typically subside within a few days, whereas fever and chills are commonly experienced by adults aged 18 years or older [26,27]. Findings from a systematic review of evidence on the safety data from COVID-19 vaccine trials indicated that the most frequently reported local adverse events were pain, swelling, and redness at the injection site, while systemic reactions included fever, fatigue, muscle pain, and headaches [28].
Although the majority of the participants in the present study expressed good knowledge regarding COVID-19, there were certain gaps in knowledge with regard to COVID-19 symptoms, protective practices, methods of transmission, and management. Specifically, a significant number of participants were unaware that otitis media can be a symptom of COVID-19 (66%), did not recognize the protective effects of medical herb consumption against COVID-19 (55.7%), were unaware of the potential transmission risks associated with eating or touching wild animals (57.8%), and lacked knowledge about the booster dose of the vaccine (72.1%). Therefore, addressing these knowledge gaps and misconceptions through targeted education, awareness campaigns, and accurate information dissemination can contribute to better public health outcomes, improved prevention practices, and effective management of future infectious disease outbreaks.
Based on the observations from the current study, it is encouraging to see that participants generally displayed good adherence to protective precautions against COVID-19. The result indicated high protective practices, including adherence to wearing masks and preserving social distancing; this is similar to a previous Saudi study that reported high levels of awareness in relation to social distancing as a preventive step to control the spread of COVID-19 [29,30,31]. Therefore, healthcare authorities should exert efforts to educate the public about the risks associated with close contact and face-touching, as well as provide information on alternative ways to greet, interact, and manage habits. People can better appreciate the importance of these measures and be encouraged to modify their behavior through educational campaigns.
In the current study, several sociodemographic and medical characteristics, such as older age, having a chronic disease, and high education, were significantly associated with higher knowledge about COVID-19, which may be justified by the superior awareness of this population with regard to the COVID-19 pandemic and its associated risks. Higher income was also linked to better knowledge in the present study. The reason behind this finding is likely that individuals with higher income tend to have greater access to diverse information sources, such as trustworthy news platforms and subscriptions to scientific journals. This enhanced accessibility to information sources can expose them to more precise and current information about COVID-19, ultimately resulting in a higher level of knowledge. A study conducted in Brazil found that participants who had a higher education level had better knowledge about COVID-19 than their peers [32]. A systematic review reported that the education, income, and age were among the significant factors associated with poor knowledge regarding the pandemic of COVID-19 [33]. Another study found that Ghanaians’ knowledge about COVID-19 was significantly affected by their age and education [34]. Ethiopian healthcare professionals’ knowledge about COVID-19 was also affected by their age, education, and income [35]. Furthermore, the findings of our study showed a significant relationship between perceived risk of COVID-19 and both knowledge about it and practice of the preventive measures against it. This discovery might be connected to a greater concern exhibited about the pandemic, which increases their curiosity about the disease and their keenness to practice the preventive precautions to avoid getting infected with COVID-19. According to a qualitative study, perceptions of the risk of COVID-19 are impacted by information and guidance campaigns, which in turn shapes their protective behavior [36]. Based on these study results, it is important to develop educational campaigns specifically tailored to reach populations with lower levels of knowledge about COVID-19, with particular focus on younger individuals, those with lower education, and lower incomes.
If participants in the current investigation anticipated that they might contract COVID-19 in the next six months, their intention to receive a booster dose of the COVID-19 vaccination significantly increased. Perception of the risk connected to COVID-19 can be increased if people anticipate the likelihood of contracting it soon. Individuals may seek out additional precautions, such as booster vaccine doses, to reduce the probability of infection as a result of their elevated feeling of risk. This was also observed in our study, where participants expressed a much greater intention to receive a booster dose of the COVID-19 vaccination when they believed the disease to be more threatening. Consistent results were reported in earlier research [23,37]. Furthermore, participants who had high knowledge about COVID-19, and those who received the COVID-19 vaccine based on conviction, had significantly higher intention to take a booster dose of the vaccine. Participants in Jordan who were legally forced to obtain COVID-19 vaccination, as opposed to those who received the vaccination out of personal conviction, showed greater resistance to receiving a third, booster, shot [18]. These results imply that education about COVID-19 and the necessity of the booster dose, rather than mandating vaccination through the legal system, may raise people’s intention to get the vaccine. This can be utilized as a productive strategy to encourage the uptake of the booster dose of the COVID-19 vaccine. Smokers in our study showed higher intention to take the vaccine than nonsmokers. This association may be explained by smokers’ greater concern about the potentially serious symptoms this virus may have on their lungs when compared to nonsmokers [38,39], which will enhance their desire to receive the booster dose of the vaccine to lower their risk of contracting the infection.
The most frequently reported reasons for vaccine hesitancy/refusal in the present study were concerns about the harmful effects of the booster dose of COVID-19 on the developing fetus, and lack of sufficient studies that evaluated the safety of COVID-19 on pregnant/lactating women. Similar results were reported in studies conducted in Iran [40], Italy [13], the UK [41], and Saudi Arabia [15], where most of the participating pregnant women reported that the reason behind their refusal of COVID-19 vaccination was their fear of its side effects on the fetus. According to a study conducted in the UK, a lack of research about long-term outcomes for the baby was among the most common reasons for COVID-19 vaccine uptake refusal in pregnancy [42]. This lack of direct evidence on the safety and efficacy of COVID-19 vaccines in pregnant and lactating populations has contributed to hesitancy among individuals in these groups. Therefore, strong research studies that especially assess the safety and effectiveness of COVID-19 vaccinations in pregnant and breastfeeding women must be conducted. By filling in these knowledge gaps, comprehensive research can reduce concerns and give precise data to inform vaccination decisions in these communities.

Study Strengths and Limitations

This is a multi-centered study which may increase the reliability and generalizability of the study results. Moreover, the present study did not only evaluate intention to receive a COVID-19 booster dose but also evaluated its association with different factors, including previous experience with COVID-19 and COVID-19 vaccines, knowledge about the COVID-19 vaccine, and adherence to protective practices, in addition to different demographic variables. However, the cross-sectional design used in this study limits its ability to establish a cause–effect relationship. The convenience sampling technique could have led to selection bias. Additionally, the study relied on self-reported data, which may be subject to social desirability and recall biases.

5. Conclusions

In the present study, a sample of pregnant/planning to get pregnant and lactating women were asked about their intention to receive the COVID-19 booster dose. As the results showed, a substantial portion of this special population were hesitant or refused to receive the COVID-19 booster dose. Low knowledge about COVID-19 was one of the main variables associated with booster dose refusal. This is also evident in the participants who had low perceived risk of COVID-19 or assumed that future reinfection with COVID-19 was unlikely. The participants demonstrated average knowledge about COVID-19 and its vaccine, and the main variables that were associated with knowledge included age, chronic disease status, and socioeconomic status. Lastly, the participants reported high adherence toward protective practices against COVID-19, particularly among participants who had high perceived risk of COVID-19.

Practice Implications

Public health organizations should consider developing comprehensive health education campaigns to ensure accurate knowledge dissemination, improve awareness about COVID-19 vaccination, and increase the intention of pregnant and lactating women to receive a booster dose of the vaccine. In addition, comprehensive research is required to give precise data on the safety and effectiveness of COVID-19 vaccination in pregnancy and breastfeeding to reduce these women’s concerns regarding this issue.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/vaccines11071249/s1, File S1: Questionnaire on COVID-19 booster dose intentions in pregnant/planning to get pregnant and lactating women; Table S1: Variable association with knowledge and practice; Table S2: Variables association with the intention to receive a booster dose of COVID-19; Table S3: Reasons for booster dose refusal/hesitancy.

Author Contributions

Conceptualization, W.A.-Q. and A.J.; methodology, W.A.-Q., A.J., Y.S. and B.A.; software, W.A.-Q. and A.H.; validation, J.L., B.A. and Y.S.; formal analysis, W.A.-Q., B.A. and Y.S.; investigation, Y.S.; resources, F.A.; data curation, W.A.-Q., Y.S. and B.A.; writing—original draft preparation, W.A.-Q., A.J., B.A., A.H., J.L., F.A. and Y.S.; writing—review and editing, J.L.; visualization, W.A.-Q. and B.A.; supervision, W.A.-Q.; project administration, W.A.-Q. and B.A.; funding acquisition, F.A. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the researchers supporting project number (RSP2023R235), King Saud University, Riyadh, Saudi Arabia.

Institutional Review Board Statement

Ethical approval was obtained from the Al-Zaytoonah ethical committee approval number (Ref#22/23/2020–2021), on 21 September 2021.

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

Available upon request.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. World Health Organization. WHO Coronavirus (COVID-19) Dashboard. WHO Coronavirus (COVID-19) Dashboard with Vaccination Data. Available online: https://covid19.who.int (accessed on 13 May 2023).
  2. World Health Organization. Fighting COVID-19 Could Cost 500 Times as Much as Pandemic Prevention Measures. Strategic Partnership for Health Security and Emergency Preparedness (SPH) Portal. Available online: https://extranet.who.int/sph/fighting-covid-19-could-cost-500-times-much-pandemic-prevention-measures (accessed on 13 May 2023).
  3. World Health Organization. Therapeutics and COVID-19: Living Guideline, 13 January 2023. Available online: https://www.who.int/publications/i/item/WHO-2019-nCoV-therapeutics-2023.1 (accessed on 13 May 2023).
  4. Hussein, T.; Hammad, M.H.; Fung, P.L.; Al-Kloub, M.; Odeh, I.; Zaidan, M.A.; Wraith, D. COVID-19 Pandemic Development in Jordan-Short-Term and Long-Term Forecasting. Vaccines 2021, 9, 728. [Google Scholar] [CrossRef]
  5. McKee, C.; Bohannon, K. Exploring the Reasons Behind Parental Refusal of Vaccines. J. Pediatr. Pharmacol. Ther. JPPT 2016, 21, 109. [Google Scholar] [CrossRef] [Green Version]
  6. Meng, H.; Mao, J.; Ye, Q. Strategies and Safety Considerations of Booster Vaccination in COVID-19. Bosn. J. Basic Med. Sci. 2022, 22, 366–373. [Google Scholar] [CrossRef] [PubMed]
  7. Ndwandwe, D.; Wiysonge, C.S. COVID-19 Vaccines. Curr. Opin. Immunol. 2021, 71, 111–116. [Google Scholar] [CrossRef] [PubMed]
  8. Ministry of Health. The Official Website of the Jordanian Ministry of Health. Coronavirus Disease. Available online: https://corona.moh.gov.jo/en (accessed on 25 June 2023).
  9. Jordan: Authorities Ease COVID-19 Restrictions as of May 25 /Update 84. Crisis24. Available online: https://crisis24.garda.com/alerts/2022/05/jordan-authorities-ease-covid-19-restrictions-as-of-may-25-update-84 (accessed on 25 June 2023).
  10. Adhikari, E.H.; SoRelle, J.A.; McIntire, D.D.; Spong, C.Y. Increasing Severity of COVID-19 in Pregnancy with Delta (B.1.617.2) Variant Surge. Am. J. Obstet. Gynecol. 2022, 226, 151. [Google Scholar] [CrossRef] [PubMed]
  11. COVID-19 Vaccines While Pregnant or Breastfeeding. Available online: https://www.cdc.gov/coronavirus/2019-ncov/vaccines/recommendations/pregnancy.html (accessed on 13 May 2023).
  12. Firouzbakht, M.; Sharif Nia, H.; Kazeminavaei, F.; Rashidian, P. Hesitancy about COVID-19 Vaccination among Pregnant Women: A Cross-Sectional Study Based on the Health Belief Model. BMC Pregnancy Childbirth 2022, 22, 611. [Google Scholar] [CrossRef]
  13. Del Giudice, G.M.; Folcarelli, L.; Napoli, A.; Corea, F.; Angelillo, I.F. COVID-19 Vaccination Hesitancy and Willingness among Pregnant Women in Italy. Front. Public Health 2022, 10, 995382. [Google Scholar] [CrossRef]
  14. Chawanpaiboon, S.; Anuwutnavin, S.; Kanjanapongporn, A.; Pooliam, J.; Titapant, V. Breastfeeding Women’s Attitudes towards and Acceptance and Rejection of COVID-19 Vaccination: Implementation Research. Vaccine 2023, 41, 1198–1208. [Google Scholar] [CrossRef]
  15. AlHefdhi, H.A.; Mahmood, S.E.; Alsaeedi, M.A.I.; Alwabel, H.H.A.; Alshahrani, M.S.; Alshehri, E.Y.; Alhamlan, R.A.O.; Alosaimi, M.N. COVID-19 Vaccine Uptake and Hesitancy among Pregnant and Lactating Women in Saudi Arabia. Vaccines 2023, 11, 361. [Google Scholar] [CrossRef]
  16. Marbán-Castro, E.; Pons-Duran, C.; García-Otero, L.; Chen, H.; Herrera, L.B.; Del Mar Gil, M.; Goncé, A.; Ferriols-Pérez, E.; Rodríguez, M.Á.; Toro, P.; et al. Acceptability of Clinical Trials on COVID-19 during Pregnancy among Pregnant Women and Healthcare Providers: A Qualitative Study. Int. J. Environ. Res. Public Health 2021, 18, 10717. [Google Scholar] [CrossRef]
  17. Abdul, S.; Bukhari, R.; Ali, M. Sample Size Determination Using Krejcie and Morgan Table Islamic Banking View Project the Enron Case Study: History, Ethics and Governance Failures View Project. Ph.D. Thesis, Islamic University of Technology, Gazipur, Bangladesh, 2022. [Google Scholar] [CrossRef]
  18. Al-Qerem, W.; Al Bawab, A.Q.; Hammad, A.; Ling, J.; Alasmari, F. Willingness of the Jordanian Population to Receive a COVID-19 Booster Dose: A Cross-Sectional Study. Vaccines 2022, 10, 410. [Google Scholar] [CrossRef]
  19. Ashour, H.A.; Alhinti, S.F.; Hawsaoi, S.A.; Alsuwailem, A.A.; AlFarhan, A.; Abdulmajeed, I.; Ashour, H.A.; Alhinti, S.; Hawsawi, S.A.; Alsuwailem, A.; et al. Knowledge, Attitude, and Practice (KAP) of COVID-19 Vaccine Among Saudi Mothers. Cureus 2023, 15, e36826. [Google Scholar] [CrossRef]
  20. Naqvi, S.; Saleem, S.; Naqvi, F.; Billah, S.M.; Nielsen, E.; Fogleman, E.; Peres-da-Silva, N.; Figueroa, L.; Mazariegos, M.; Garces, A.L.; et al. Knowledge, Attitudes, and Practices of Pregnant Women Regarding COVID-19 Vaccination in Pregnancy in 7 Low- and Middle-Income Countries: An Observational Trial from the Global Network for Women and Children’s Health Research. BJOG Int. J. Obstet. Gynaecol. 2022, 129, 2002–2009. [Google Scholar] [CrossRef] [PubMed]
  21. Naz, S.; Dur e Shawar, S.; Saleem, S.; Malik, A.; Raza, A. Knowledge, Attitudes, and Practices (KAP) towards COVID-19 Pandemic among Pregnant Women in a Tertiary Hospital in Karachi, Pakistan. PLoS ONE 2022, 17, e0274252. [Google Scholar] [CrossRef] [PubMed]
  22. Storph, R.P.; Essuman, M.A.; Duku-Takyi, R.; Akotua, A.; Asante, S.; Armah, R.; Donkoh, I.E.; Addo, P.A. Willingness to Receive COVID-19 Booster Dose and Its Associated Factors in Ghana: A Cross-Sectional Study. Health Sci. Rep. 2023, 6, e1203. [Google Scholar] [CrossRef]
  23. Allen, K.; Lambert, S.B.; Yuen, A.; Pourmarzi, D. Factors Associated with COVID-19 Booster Vaccine Willingness among Migrants from the Eastern Mediterranean Living in Australia: A Cross-Sectional Study. BMC Public Health 2022, 22, 2205. [Google Scholar] [CrossRef]
  24. Moeed, A.; Najeeb, H.; Saleem, A.; Asghar, M.S.; Rafi, H.M.; Khattak, A.K.; Bilal, Z.; Seboka, B.T. Willingness and Perceptions Regarding COVID-19 Vaccine Booster Dose in Pakistani Vaccinated Population: A Cross-Sectional Survey. Front. Public Health 2022, 10, 911518. [Google Scholar] [CrossRef]
  25. Chang, C.T.; Lim, X.; Chew, C.; Rajan, P.; Chan, H.; Abu Hassan, M.R.; Shafie, A.A.; Lee, S.W.H. Preferences and Willingness of Accepting COVID-19 Vaccine Booster: Results from a Middle-Income Country. Vaccine 2022, 40, 7515–7519. [Google Scholar] [CrossRef] [PubMed]
  26. CDC. Possible Side Effects after Getting a COVID-19 Vaccine. Available online: https://www.cdc.gov/coronavirus/2019-ncov/vaccines/expect/after.html (accessed on 25 June 2023).
  27. CDC. Selected Adverse Events Reported after COVID-19 Vaccination. Available online: https://www.cdc.gov/coronavirus/2019-ncov/vaccines/safety/adverse-events.html (accessed on 25 June 2023).
  28. Kaur, R.J.; Dutta, S.; Bhardwaj, P.; Charan, J.; Dhingra, S.; Mitra, P.; Singh, K.; Yadav, D.; Sharma, P.; Misra, S. Adverse Events Reported from COVID-19 Vaccine Trials: A Systematic Review. Indian J. Clin. Biochem. 2021, 36, 427–439. [Google Scholar] [CrossRef] [PubMed]
  29. Bazaid, A.S.; Aldarhami, A.; Binsaleh, N.K.; Sherwani, S.; Althomali, O.W. Knowledge and Practice of Personal Protective Measures during the COVID-19 Pandemic: A Cross-Sectional Study in Saudi Arabia. PLoS ONE 2020, 15, e0243695. [Google Scholar] [CrossRef]
  30. Aldarhami, A.; Bazaid, A.S.; Althomali, O.W.; Binsaleh, N.K. Public Perceptions and Commitment to Social Distancing “Staying-at-Home” during COVID-19 Pandemic: A National Survey in Saudi Arabia. Int. J. Gen. Med. 2020, 13, 677–686. [Google Scholar] [CrossRef] [PubMed]
  31. Yezli, S.; Khan, A. COVID-19 Social Distancing in the Kingdom of Saudi Arabia: Bold Measures in the Face of Political, Economic, Social and Religious Challenges. Travel Med. Infect. Dis. 2020, 37, 101692. [Google Scholar] [CrossRef] [PubMed]
  32. Rosa, D.A.C.; de Sousa, S.S.; da Silva, M.N.R.; Gamboge, L.R.R.; Deusdará, R.; Lapa, J. Knowledge about COVID-19 and Associated Factors Early in the Outbreak among the Brazilian Population. Int. J. Environ. Res. Public Health 2022, 19, 13824. [Google Scholar] [CrossRef] [PubMed]
  33. Bekele, F.; Sheleme, T.; Fekadu, G.; Bekele, K. Patterns and Associated Factors of COVID-19 Knowledge, Attitude, and practice among General Population and Health Care Workers: A Systematic. SAGE Open. Med. 2020, 8, 2050312120970721. [Google Scholar] [CrossRef] [PubMed]
  34. Kwabla, M.P.; Nyasordzi, J.; Kye-Duodu, G.; Ananga, M.K.; Amenuvegbe, G.K.; Otoo, J.; Nuertey, D.D.; Mensah, E.K.; Asante-Afari, K.; Aboagye, D.; et al. Factors Associated with COVID-19 Knowledge among Ghanaians: A National Survey. PLoS ONE 2022, 17, e0276381. [Google Scholar] [CrossRef]
  35. Bitew, G.; Sharew, M.; Belsti, Y. Factors Associated with Knowledge, Attitude, and Practice of COVID-19 among Health Care Professional’s Working in South Wollo Zone Hospitals, Northeast Ethiopia. SAGE Open Med. 2021, 9, 20503121211025148. [Google Scholar] [CrossRef]
  36. Siddiqui, S.; Qamar, A.H. Risk Perception and Protective Behavior in the Context of COVID-19: A Qualitative Exploration. Asian Bioeth. Rev. 2021, 13, 401–420. [Google Scholar] [CrossRef]
  37. Paul, E.; Fancourt, D. Predictors of Uncertainty and Unwillingness to Receive the COVID-19 Booster Vaccine: An Observational Study of 22,139 Fully Vaccinated Adults in the UK. Lancet Reg. Health Eur. 2022, 14, 100317. [Google Scholar] [CrossRef]
  38. Zhang, H.; Ma, S.; Han, T.; Qu, G.; Cheng, C.; Uy, J.P.; Shaikh, M.B.; Zhou, Q.; Song, E.J.; Sun, C. Association of Smoking History with Severe and Critical Outcomes in COVID-19 Patients: A Systemic Review and Meta-Analysis. Eur. J. Integr. Med. 2021, 43, 101313. [Google Scholar] [CrossRef]
  39. Alqahtani, J.S.; Oyelade, T.; Aldhahir, A.M.; Alghamdi, S.M.; Almehmadi, M.; Alqahtani, A.S.; Quaderi, S.; Mandal, S.; Hurst, J.R. Prevalence, Severity and Mortality Associated with COPD and Smoking in Patients with COVID-19: A Rapid Systematic Review and Meta-Analysis. PLoS ONE 2020, 15, e0233147. [Google Scholar] [CrossRef]
  40. Moini, A.; Rabiei, M.; Pirjani, R.; Abiri, A.; Maleki-Hajiagha, A. COVID-19 Vaccine Hesitancy among Pregnant Women and Their Reported Reasons for Vaccine Refusal—A Prospective Study in Tehran, Iran. Vaccine 2023, 41, 1495. [Google Scholar] [CrossRef] [PubMed]
  41. Skirrow, H.; Barnett, S.; Bell, S.; Riaposova, L.; Mounier-Jack, S.; Kampmann, B.; Holder, B. Women’s Views on Accepting COVID-19 Vaccination during and after Pregnancy, and for Their Babies: A Multi-Methods Study in the UK. BMC Pregnancy Childbirth 2022, 22, 33. [Google Scholar] [CrossRef] [PubMed]
  42. Mhereeg, M.; Jones, H.; Kennedy, J.; Seaborne, M.; Parker, M.; Kennedy, N.; Beeson, S.; Akbari, A.; Zuccolo, L.; Davies, A.; et al. COVID-19 Vaccination in Pregnancy: Views and Vaccination Uptake Rates in Pregnancy, a Mixed Methods Analysis from SAIL and the Born-In-Wales Birth Cohort. BMC Infect. Dis. 2022, 22, 932. [Google Scholar] [CrossRef] [PubMed]
Table
Table 1. Sociodemographic characteristics of participants.
Table 1. Sociodemographic characteristics of participants.
Frequency (%)
Age18–29 years old436 (62.7%)
30–39 years old259 (37.3%)
Educational levelLow192 (27.6%)
High503 (72.4%)
Household monthly income levelLess than 500 JOD242 (34.8%)
500–1000 JOD300 (43.2%)
More than 1000 JOD153 (22%)
Pregnancy statusPlanning to get pregnant355 (51.1%)
Lactating138 (19.9%)
Pregnant202 (29.1%)
SmokerNo577 (83%)
Yes118 (17%)
Do you have any chronic diseases?No638 (91.8%)
Yes57 (8.2%)
Table
Table 2. Participants’ experiences and attitudes toward COVID-19.
Table 2. Participants’ experiences and attitudes toward COVID-19.
Frequency (%), or Median (95% CI.)
Participants’ experiences toward COVID-19.
Previously infected with COVID-19No216 (31.1%)
Not sure129 (18.6%)
Yes350 (50.4%)
Do you personally know someone who died due to COVID-19No154 (22.3%)
Yes538 (77.7%)
Participants’ attitudes toward COVID-19.
Perceived possibility to be infected with COVID-19 in the next 6 monthsI don’t think I will be infected249 (35.8%)
I think I will be infected with mild symptoms419 (60.3%)
I think I will be infected with severe symptoms27 (3.9%)
Yes538 (77.7%)
In your opinion, how serious is the infection with COVID?3 (3–4)
Table
Table 3. Participants’ experiences and attitudes toward COVID-19 vaccine.
Table 3. Participants’ experiences and attitudes toward COVID-19 vaccine.
Frequency (%), or Median (95% CI.)
Do you intend to receive the booster dose for COVID-19 vaccine?No121 (17.4%)
Maybe163 (23.5%)
Yes411 (59.1%)
Participants’ experiences toward COVID-19 vaccine.
Reasons for receiving COVID-19 vaccinesImposed laws110 (16%)
Conviction and imposed laws112 (16.3%)
Conviction467 (67.8%)
Previously received COVID-19 vaccinePfizer520 (74.8%)
Astra Zeneca77 (11.1%)
Sinopharm98 (14.1%)
Perceived side effect level due to COVID-19 vaccineNo symptoms83 (11.9%)
Mild232 (33.4%)
Moderate285 (41%)
Severe95 (13.7%)
Side effects reported by the participant due to COVID-19 vaccine
FeverNo303 (43.6%)
Yes392 (56.4%)
HeadacheNo369 (53.1%)
Yes326 (46.9%)
NauseaNo589 (84.7%)
Yes106 (15.3%)
Pain at the site of injectionNo222 (31.9%)
Yes473 (68.1%)
SpasmNo332 (47.8%)
Yes363 (52.2%)
ChillsNo614 (88.3%)
Yes81 (11.7%)
Muscle painNo478 (68.8%)
Yes217 (31.2%)
RashNo669 (96.3%)
Yes26 (3.7%)
Water retentionNo687 (98.8%)
Yes8 (1.2%)
WeaknessNo372 (53.5%)
Yes323 (46.5%)
No symptomsYes66 (9.5%)
No629 (90.5%)
Side effects score3 (3–4)
Table
Table 4. Participants’ responses to the knowledge items.
Table 4. Participants’ responses to the knowledge items.
Frequency (%)
Knowledge about the symptoms of COVID-19
FeverYes *663 (95.4%)
No32 (4.6%)
ChillsYes *298 (42.9%)
No397 (57.1%)
DiarrheaYes *447 (64.3%)
No248 (35.7%)
CoughYes *621 (89.4%)
No74 (10.6%)
Otitis media (earache)Yes459 (66%)
No *236 (34%)
Loss of smell and tasteYes *642 (92.4%)
No53 (7.6%)
No symptomsYes *504 (72.5%)
No191 (27.5%)
Knowledge about the protective practices against COVID-19
Wearing face masksYes *638 (91.8%)
No57 (8.2%)
Washing hands with regular soapYes *584 (84%)
No111 (16%)
Using detergentsYes *627 (90.2%)
No68 (9.8%)
Social distancingYes *657 (94.5%)
No38 (5.5%)
Avoiding touching face/mouth/nose/eyesYes *615 (88.5%)
No80 (11.5%)
Avoid consuming meatYes251 (36.1%)
No *444 (63.9%)
Medical herb consumptionYes387 (55.7%)
No *308 (44.3%)
Knowledge about the transmission of COVID-19
Drinking unclean waterYes324 (46.6%)
No *371 (53.4%)
Eating unclean foodYes362 (52.1%)
No *333 (47.9%)
Inhalation of respiratory droplets from an
infected person		Yes *670 (96.4%)
No25 (3.6%)
Eating or touching wild animalsYes402 (57.8%)
No *293 (42.2%)
Knowledge about the management of COVID-19
Is there currently a drug in pharmacies or hospitals that treats COVID-19 completely?Yes270 (38.8%)
No *425 (61.2%)
What is the protective time that the vaccine provides against COVID-19? Days69 (9.9%)
Months *476 (68.5%)
Years150 (21.6%)
Is it necessary for the booster dose of the
vaccine to be of the same type of vaccine used in the initial doses?		Yes501 (72.1%)
No *194 (27.9%)
Children105 (15.1%)
Which people need the booster dose?Elderly202 (29.1%)
All people *388 (55.8%)
* Indicates the correct answer.
Table
Table 5. Participants’ responses to the practice items.
Table 5. Participants’ responses to the practice items.
NeverRarelySometimesUsuallyAlways
Frequency (%)Frequency (%)Frequency (%)Frequency (%)Frequency (%)
Wearing face masks4 (0.6%)35 (5%)83 (11.9%)169 (24.3%)404 (58.1%)
Washing hands with regular soap4 (0.6%)11 (1.6%)43 (6.2%)144 (20.7%)493 (70.9%)
Using detergent5 (0.7%)36 (5.2%)104 (15%)144 (20.7%)406 (58.4%)
Social distancing16 (2.3%)53 (7.6%)131 (18.8%)161 (23.2%)334 (48.1%)
Avoiding touching face/mouth/nose/eyes18 (2.6%)72 (10.4%)115 (16.5%)149 (21.4%)341 (49.1%)
Table
Table 6. Binary regression for variable association with the knowledge level.
Table 6. Binary regression for variable association with the knowledge level.
OR95% CI for ORp-Value
LowerUpper
Age30–391.5761.0712.3190.021
18–29(REF)(REF)(REF)(REF)
StatusLactating0.6440.3951.0510.078
Pregnant0.7270.4861.0870.120
Planning to get pregnant (REF)(REF)(REF)(REF)
EducationHigh2.9591.8964.618<0.001
Low(REF)(REF)(REF)(REF)
Household monthly income500–1000 JOD2.7131.8034.083<0.001
>1000 JOD4.8032.9387.852<0.001
<500 JOD(REF)(REF)(REF)(REF)
Do you have any chronic diseases? Yes1.9131.0073.6320.047
No(REF)(REF)(REF)(REF)
In your opinion, how serious is the infection with COVID?1.3611.1691.586<0.001
Previously infected with COVID-19Not sure0.8580.5061.4550.570
Yes0.8900.5931.3380.576
No(REF)(REF)(REF)(REF)
Perceived possibility to be infected with COVID-19 in the next 6 monthsI think I will be infected with mild symptoms1.2400.8501.8080.264
I think I will be infected with severe symptoms0.4960.1851.3330.164
I don’t think I will be infected(REF)(REF)(REF)(REF)
Table
Table 7. Binary regression for variables associated with the practice level.
Table 7. Binary regression for variables associated with the practice level.
OR95% CI for ORp-Value
LowerUpper
In your opinion, how serious is the COVID infection? 1.2721.1161.450<0.001
EducationHigh1.3420.9531.9190.092
Low(REF)(REF)(REF)(REF)
Previously infected with COVID-19Not sure0.7320.4701.1400.167
Yes0.7080.5011.0020.051
No(REF)(REF)(REF)(REF)
Table
Table 8. Multinomial regression model for variable association with the intention to receive a booster dose of COVID-19 vaccine.
Table 8. Multinomial regression model for variable association with the intention to receive a booster dose of COVID-19 vaccine.
No vs. YesMaybe vs. Yes
OR95% IR for ORp-ValueOR95% CI for ORp-Value
Lower BoundUpper BoundLower BoundUpper Bound
In your opinion, how serious is the COVID infection?0.7500.6040.9310.0090.9530.7901.1500.619
Age18–291.3390.7522.3840.3211.1500.7171.8420.562
30–39(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
StatusPlanning to get pregnant0.9520.5251.7260.8710.9980.6121.6270.994
Lactating1.5820.7533.3240.2261.5400.8262.8700.174
Pregnant(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
EducationLow0.6020.3251.1180.1081.1290.6881.8520.632
High(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
Household monthly income<500 JOD1.1440.5332.4550.7300.8570.4581.6040.629
500–1000 JOD1.3950.6842.8450.3591.4230.8142.4880.216
>1000 JOD(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
SmokerNo 1.9040.9223.9310.0823.7741.9167.432<0.001
Yes(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
Do you personally know someone who died due to COVID-19No1.3990.7962.4580.2430.6680.3951.1270.130
Yes(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
Reasons for receiving COVID-19 vaccinesImposed laws19.85910.05939.207<0.0014.3692.2418.518<0.001
Conviction and imposed laws2.6041.3445.0430.0052.0811.2213.5460.007
Conviction(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
Vaccine typePfizer0.8270.4171.6400.5870.9520.5311.7090.870
Astra Zeneca0.3210.0951.0820.0670.5430.2171.3590.192
Sinopharm(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
Side effect levelNo symptoms0.8300.3102.2230.7111.4560.5873.6090.417
Mild0.9890.4462.1900.9781.7100.8303.5200.145
Moderate0.7830.3621.6970.5361.5510.7723.1170.217
Severe(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
Previously infected with COVID-19No0.9910.5581.7590.9740.8550.5221.4010.535
Not sure0.6340.3071.3070.2171.1830.6912.0230.541
Yes(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
Perceived possibility to be infected with COVID-19 in the next 6 monthsI don’t think I will be infected8.6671.56947.8810.0131.7620.6145.0550.292
I think I will be infected with mild symptoms4.6360.85325.1980.0761.0160.3662.8220.976
I think I will be infected with severe symptoms(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
Knowledge levelLow1.8751.0623.3110.0301.6551.0452.6220.032
High(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
Practice levelLow1.2050.7262.0010.4712.1611.4223.284<0.001
High(REF)(REF)(REF)(REF)(REF)(REF)(REF)(REF)
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Al-Qerem, W.; Jarab, A.; Shawabkeh, Y.; Ling, J.; Hammad, A.; Alazab, B.; Alasmari, F. COVID-19 Vaccination Booster Dose: Knowledge, Practices, and Intention among Pregnant/Planning to Get Pregnant and Lactating Women. Vaccines 2023, 11, 1249. https://doi.org/10.3390/vaccines11071249

AMA Style

Al-Qerem W, Jarab A, Shawabkeh Y, Ling J, Hammad A, Alazab B, Alasmari F. COVID-19 Vaccination Booster Dose: Knowledge, Practices, and Intention among Pregnant/Planning to Get Pregnant and Lactating Women. Vaccines. 2023; 11(7):1249. https://doi.org/10.3390/vaccines11071249

Chicago/Turabian Style

Al-Qerem, Walid, Anan Jarab, Yara Shawabkeh, Jonathan Ling, Alaa Hammad, Badi’ah Alazab, and Fawaz Alasmari. 2023. "COVID-19 Vaccination Booster Dose: Knowledge, Practices, and Intention among Pregnant/Planning to Get Pregnant and Lactating Women" Vaccines 11, no. 7: 1249. https://doi.org/10.3390/vaccines11071249

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop