The role of risk perception, risk communication, and demographic factors in COVID-19 preventive behaviors: an online survey in Iran

Article information

Osong Public Health Res Perspect. 2022;13(4):282-289
Publication date (electronic) : 2022 August 31
doi : https://doi.org/10.24171/j.phrp.2021.0345
1Social Development and Health Promotion Research Center, Health Institute, Kermanshah University of Medical Sciences, Kermanshah, Iran
2Kermanshah Office of Education, Kermanshah, Iran
3Social Determinants of Health Research Center, University of Social Welfare and Rehabilitation Sciences, Tehran, Iran
4Research Center for Environmental Determinants of Health, Health Institute, Kermanshah University of Medical Sciences, Kermanshah, Iran
5Department of Sport Management, Faculty of Sport Science, Razi University, Kermanshah, Iran
Corresponding author: Yahya Salimi Social Development and Health Promotion Research Center, Health Institute, Kermanshah University of Medical Sciences, Laleh alley, Shahid Beheshti Blvd, Kermanshah 67146-49115, Iran E-mail: salimiyahya@yahoo.com
Received 2022 January 15; Revised 2022 May 23; Accepted 2022 August 1.

Abstract

Objectives

This study investigated preventive behaviors toward coronavirus disease 2019 (COVID-19) and related factors in a Kurdish Iranian sample.

Methods

This online survey was conducted among the population aged 18 and above in Kermanshah Province, in western Iran, in April 2020. Samples were invited and recruited through social media. Data were collected using a questionnaire consisting of 4 sections (questions on demographic variables, risk perception, risk communication, and COVID-19 preventive behaviors) and analyzed using Stata ver. 8.

Results

The Pearson correlation test showed that risk communication was significantly correlated with COVID-19 preventive behaviors (r=0.320, p<0.01). In the final model, where the explanatory power increased with the entry of the risk communication variable, the variables explained a total of 14% of variance in COVID-19 preventive behaviors. Sex (β=−0.482), risk perception (β=0.047), and risk communication (β=0.662) were significant determinants.

Conclusion

Risk communication and risk perception related to COVID-19, as well as being a woman, were determinants of COVID-19 preventive behaviors.

Introduction

The World Health Organization declared a global public health emergency in January 2020 following the rapid and sudden outbreak of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) [1]. According to statistics, SARS-CoV-2 spread faster in some parts of the world than in others [2]. Iran is still among the leading countries in the Eastern Mediterranean region in terms of the total number of cases and deaths due to coronavirus disease 2019 (COVID-19) [3].

The rapid transmission and unknown aspects of COVID-19, as well as the lack of definitive treatments, have posed serious challenges for disease control [4]. Personal protection measures (e.g., face mask wearing, hand washing, and personal hygiene), travel restrictions, and physical distancing can help reduce the risk of infection and control the spread of disease [5]. People’s willingness to participate in self-care plays an important and decisive role in implementing the preventive guidelines recommended by public health authorities. However, encouraging the public to take preventive measures and receive vaccinations remains a problem for health [6]. Assessing the people's perceptions, beliefs, and behavioral responses during epidemics can provide useful information for effective risk communication and successful changes in health behaviors [7].

The lack of attention to scientific analyses, the inability to explain the role of psychosocial patterns, and the lack of appropriate models and theories are some reasons for the failure of national health programs [8]. The health belief model (HBM) aims to explain preventive behaviors, for which the issue of risk perception has been discussed. According to the HBM, to perform a health behavior, people must first feel their vulnerability to the problem (in this case, COVID-19), and then perceive the physical and mental severity of the danger [9]. Risk perception, which is a mental judgment that people make about the characteristics and severity of a risk, is influenced by psychological factors and environmental and social conditions [10]. Understanding the risk of disease can greatly affect the care process and have a significant impact on changing behaviors and lifestyles [11]. According to the protection motivation theory, the adoption of protective measures in individuals is significantly affected by their level of risk perception. This theory suggests that perceptions of the severity of a health threat and vulnerability to that threat determine the degree of risk perception [12]. Evidence shows a moderate correlation between risk perception and health behaviors [13], and research has found that people who are cautious in dangerous situations make more rational decisions [14]. Studies have also shown that attention to health warnings provided by the media is a factor affecting risk perception in society [15].

Health communication is an essential tool for achieving public health goals, facilitating and supporting behavioral changes, and reducing health inequalities [16]. Risk communication is a key concept in health communication to increase understanding of health threats and support people in making informed decisions to reduce risks [17]. Risk communication involves the effective and accurate exchange of information about health risks during a crisis or emergency condition that promotes risk awareness and health protective behaviors among individuals, communities, and institutions [18]. Risk communication is also effective both for limiting mortality and for minimizing damage to the national economy and public health infrastructure [1].

Previous studies have suggested that the level of attention to health warnings about COVID-19 from state-owned media and social media is an important issue [1921]. Strengthening health messages during a pandemic can increase the role of health communication and media attention. EffectiveRisk communication means that all related risk messages can be presented and shared openly and in a timely manner with the aim of bridging the knowledge gap between informants and the recipients of messages [22].

In this study, we consideredrisk communication as the level of attention to health warnings about the negative effects of COVID-19 and its role in preventive behaviors [23]. The study by Heydari et al. [24] showed that risk communication has direct and indirect positive effects on preventive behaviors. Since few studies have been conducted in Iran on the relationships of risk perception and risk communication with preventive behaviors, the present study was conducted to investigate COVID-19 preventive behaviors and its related factors in western Iran.

Materials and Methods

Study Design and Participants

This online survey was conducted among the population aged 18 and over in Kermanshah Province, western Iran in April 2020, in which samples were selected through social media (WhatsApp and Telegram). During the 2 weeks that the questionnaire page was available online to the respondents, 3,795 people visited and 2,155 (56.8% response rate) completed the research questionnaire. The inclusion criteria were agreement to participate in the study, living in Kermanshah Province, and being at least 18 years old. Subjects were excluded from the study if the questionnaire was incomplete or the person was under 18 years of age. In order to comply with ethical principles, an informed consent form was provided on the first page of the online questionnaire, in which the participants were assured that all their information would be confidential and anonymous, and participants indicated their agreement by checking a box.

Measurements

The data collection tool in this study included a 4-part questionnaire. The first part contained demographic and contextual questions, including age, sex, marital status, level of education, job status, number of family members, and whether friends and family had been infected with or died from COVID-19. Subjective socioeconomic status (SES) was asked with a question on a 10-point scale. The second part of the questionnaire contained 6 questions about risk perception related to COVID-19, which were scored with a 5-point Likert scale, yielding a total score that ranged from 6 to 30, on which a higher score indicated higher risk perception. Risk communication was assessed by the following question: “How much do you pay attention to the news, information, and warnings from the official and social media about COVID-19?” The answers were scored on a 5-point Likert scale. The final part of the questionnaire examined health preventive behaviors, which were assessed through 6 questions on the individual's behaviors: (1) observance of physical distancing instructions, (2) use of gloves, (3) use of masks, (4) hand washing, (5) disinfection of one’s home space, and (6) disinfection of cell phones and laptops. The answers were evaluated with 3 options: no (score 1), yes occasionally (score 2) and always (score 3). The lowest score was 6 and the highest score was 18. A higher score indicated better and more appropriate preventive behaviors for dealing with COVID-19.

The face validity of the questionnaire was assessed by a panel of experts, including 10 specialists in epidemiology, health education and health promotion, sociology, psychology and social welfare. According to the panel, the content validity ratio and content validity index were 100% and 89%, respectively. In addition, internal consistency of risk perception questions was acceptable, with a Cronbach’s alpha of 0.706.

Ethical Statement

The present study was approved by the ethics committee of Kermanshah University of Medical Sciences (code: IR.KUMS.REC.1398.1220).

Data Collection and Statistical Analysis

This online survey was conducted among the population aged 18 and over in Kermanshah Province, western Iran in April 2020. The collected data were analyzed using descriptive and analytical statistics in Stata ver. 8 (StataCorp. LLC, College Station, TX, USA). Mean values with the standard deviation were used for descriptive analysis, and multiple linear regression was used to identify determinants of COVID-19 preventive behaviors. Before running the regression model, we assessed the assumptions of multiple regression. Since the Durbin-Watson statistic was 1.95, and the variance inflation factor was 1.25, conducting the regression model was justified. The normality of the data was confirmed using the Kolmogorov-Smirnov test. The research variables were entered into the regression model in 3 steps: contextual and demographic variables in the first step (model 1), risk perception related to COVID-19 in the second step (model 2), and risk communication in the third model (model 3). In this study, a 95% (p<0.05) significance level was adopted.

Results

The total number of participants in this study was 2,155. Among the respondents 61.4% were women, 32.3% were single, and 76.3% had a university education. More than half of the respondents lived in a family with 4 to 6 people, and more than 39% perceived themselves as being in the middle class of SES. The mean±SD age of the respondents was 37.62±10.03 years. The mean±SD score of SES was 5.53±2.04. More than half (52%) of the respondents stated that they always paid attention to health warnings from the media. About 9% of respondents did not use gloves at all and about 40% always wore a mask. The mean±SD of the risk perception score was 24.16±3.04 (Table 1).

Characteristics of the study participants

The Pearson correlation test showed that risk communication had a significant correlation with COVID-19 preventive behaviors (r=0.320, p<0.01), and the association between risk communication and risk perception was moderate and positive; in other words, with increasing risk perception, risk communication also increased (r=0.445, p<0.01) (Table 2).

Correlations among the main variables

Multiple linear regression was used to identify factors associated with COVID-19 preventive behaviors. For this purpose, in the first step (model 1), demographic and contextual variables were entered in the model. The analysis in this section showed that demographic and contextual variables explained 4.89% of the changes in dependent variable (R2=0.0489, adjusted R2=0.0364). Among the variables included in the model, age (β=0.010), sex (β=−0.567), employment as a shopkeeper (β=−0.460), and very high SES (β=0.483) were significant determinants of preventive behaviors (Table 3).

Multiple regression analysis of factors associated with COVID-19 preventive behaviors, Kermanshah, Iran, 2020

In the second step (model 2), in addition to the contextual and demographic variables, Risk perception related to COVID-19 was also included. In this step, the explanatory power of the model was increased to 8.88%, reflecting a change of approximately 4 percentage points (R2=0.0888, adjusted R2=0.0762), which indicates the importance of the risk perception of COVID-19. In model 2, the variables of age (β=0.010), sex (β=−0.553), very high perceived SES (β=0.446), and risk perception (β=0.113) remained in the model (Table 3).

In the third step (model 3), risk communication was entered into the model in addition to the variables of model 2. The new analysis showed that the sum of the variables in model 3 explained 14.23% (R2=0.1423, adjusted R2=0.13) of variance in preventive behaviors toward COVID-19. Sex (β=−0.482), risk perception (β=0.047), andrisk communication (β=0.662) remained in the final model (Table 3).

Discussion

The aim of this study was to investigate the effect of contextual and demographic variables, risk communication, and risk perception on COVID-19 prevention behaviors in western Iran.Risk communication had a direct effect on preventive behaviors that was greater in magnitude than the other variables included in the regression model. This finding is consistent with the study by Heydari et al. [24], who similarly emphasized the role ofrisk communication in COVID-19 preventive behaviors. Studies on the mechanism of the relationship between risk communication and individual performance and adopting appropriate strategies have emphasized the following steps: (a) receiving a warning message (b) understanding the relevant content, (c) accepting and believing the importance of the existing message, (d) confirming the truth of their interpretations with other people, and (e) acting in response to save lives [25].

Risk communication plays an important role in effectively communicating, supporting public needs, and carrying out preventive measures in stressful situations and epidemics [26,27]. Understanding how people interpret risk, and especially how people use risk information to make important decisions about health behaviors, is effective for preventing disease [28]. It is important to identify the factors that are likely to lead to behavior change because ignoring audience perceptions can ultimately promote destructive and high-risk behaviors for health [29]. Risk communication is one of the most important components related to health that can enhance correct perceptions of risk and reduce the risk of harm through preventive behaviors [30].

Another finding of this study was the direct effect of risk perception on COVID-19 preventive behaviors. This finding was consistent with the study of Heydari et al. [24], although the effect of risk perception in their study was greater than that observed herein. It seems that increasing risk perception and engaging in protective behaviors are effective ways to moderate the risk factors of the disease [31]. The results of a prior study showed an association between increasedrisk perception and increased protective measures [12]. According to other studies, increasing risk communication can enhance risk perception and subsequently, increase protective behavior [32,33].

One of the important results of this study was the significance of age and sex variables in all 3 regression models. The results of this study showed that age had a positive and significant effect on COVID-19 preventive behaviors. This finding is inconsistent with the study by Khazaee-Pool et al. [34] in Iran, but Tabibi et al. [35] showed that older participants had adapted more to COVID-19 preventive measures. Other studies have also shown more positive intentions to follow preventive measures in older individuals [36,37]. The elderly are at a significantly higher risk of morbidity and mortality due to COVID-19. Observance of COVID-19 preventive behaviors at older ages seems to be directly related to the degree of their vulnerability and risk perception [38].

Regarding sex, several studies have shown sex differences in preventive behaviors to avoid the spread of disease. For example, women are more likely than men to observe social distance and personal hygiene [39,40], which is consistent with our study. Fard et al. [41] in Iran showed that the sex variable explained 9% of variance in self-care behaviors associated with COVID-19. Firouzbakht et al. [42], in a study in Iran, showed that women generally had better preventive behaviors. In a meta-analysis, Moran and Del Valle [43] showed that women are more likely to avoid crowds and physical contact with others to prevent respiratory diseases. They also showed that women engage in more preventive behaviors than men to adapt to new conditions. These results indicate an inherent difference in how men and women respond to respiratory diseases and epidemics.

Another noteworthy result of this study was the effect of SES on COVID-19 preventive behaviors. In our study, in model 1 and model 2, having a very high subjective SES had a positive and moderate effect on COVID-19 prevention behaviors, but in model 3, the effect of subjective SES was not significant with the entry of risk communication. Some studies [42,44] have emphasized the role of SES in preventive behaviors, which is consistent with the results of models 1 and 2 in this study. Although evidence has shown that SES is among the strongest predictors of individual morbidity and mortality [45,46], in this study, the inclusion of risk communication removed SES from the final model.

Limitations

One of the limitations of this study is that data were collected by self-reporting. Therefore, some degree of measurement error may have occurred. In addition, due to less access to the internet and smartphones among the elderly and economically low-status groups, the population of this study might not have been fully representative. Nonetheless, the present study presents a good picture of the effect of risk communication and risk perception on COVID-19 preventive behaviors. Furthermore, the use of an appropriate sample size enhanced the accuracy of the conclusions.

Conclusion

This study showed that risk communication, risk perception, female sex, and older age were significant determinants of COVID-19 preventive behaviors. It seems that strengthening appropriate and timely programs and messages through mass media would likely be effective for preventing high-risk behaviors for COVID-19 in Iran. Paying attention to health warnings in the COVID-19 pandemic plays a role beyond all economic, social, and cultural factors and diminishes the effects of those factors. In general, based on the findings of this study, the importance of media and messages should be acknowledged as an important and influential source of preventive behaviors beyond SES.

Notes

Ethics Approval

This study was approved by the ethics committee of Kermanshah University of Medical Sciences (code: IR.KUMS.REC.1398.1220).

Conflicts of Interest

The authors have no conflicts of interest to declare.

Funding

This work was supported by the Kermanshah University of Medical Sciences Research Fund in 2020.

Availability of Data

All data generated or analyzed during this study are included in this published article. For other data, these may be requested through the corresponding author.

Authors’ Contributions

Conceptualization: MR, NRG, YS; Data curation: FJN, NS; Formal analysis: MR, FN; Supervision: ZJS; Validation: MK, AA, ShS, SaS; Visualization: NRG, YS; Writing-original draft: NRG, YS, MK; Writing-review & editing: all authors.

References

1. Lai CC, Shih TP, Ko WC, et al. Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and coronavirus disease-2019 (COVID-19): the epidemic and the challenges. Int J Antimicrob Agents 2020;55:105924.
2. World Health Organization (WHO). Weekly epidemiological update on COVID-19-6 April 2021 [Internet]. Geneva: WHO; 2021 [cited 2022 Aug 9]. Available from: https://www.who.int/publications/m/item/weekly-epidemiological-update-on-covid-19---6-april-2021.
3. Ariapooran S, Khezeli M. Symptoms of anxiety disorders in Iranian adolescents with hearing loss during the COVID-19 pandemic. BMC Psychiatry 2021;21:114.
4. Xu Z, Shi L, Wang Y, et al. Pathological findings of COVID-19 associated with acute respiratory distress syndrome. Lancet Respir Med 2020;8:420–2.
5. Luo Y, Yao L, Zhou L, et al. Factors influencing health behaviours during the coronavirus disease 2019 outbreak in China: an extended information-motivation-behaviour skills model. Public Health 2020;185:298–305.
6. Khosravi M. Perceived risk of COVID-19 pandemic: the role of public worry and trust. Electron J Gen Med 2020;17em203.
7. Vaughan E, Tinker T. Effective health risk communication about pandemic influenza for vulnerable populations. Am J Public Health 2009;99 Suppl 2(Suppl 2):S324–32.
8. Bashirian S, Jenabi E, Khazaei S, et al. Factors associated with preventive behaviours of COVID-19 among hospital staff in Iran in 2020: an application of the Protection Motivation Theory. J Hosp Infect 2020;105:430–3.
9. Champion VL, Skinner SC. The health belief model. In: Glanz K, Rimer BK, Viswanath K, editors. Health behavior and health education: theory, research, and practice. San Francisco, CA: Jossey-Bass; 2008. p. 45-65.
10. Wolff K, Larsen S, Ogaard T. How to define and measure risk perceptions. Ann Tour Res 2019;79:102759.
11. Posey AD. Symptom perception: a concept exploration. Nurs Forum 2006;41:113–24.
12. Rogers RW. A protection motivation theory of fear appeals and attitude change1. J Psychol 1975;91:93–114.
13. Floyd DL, Prentice‐Dunn S, Rogers RW. A meta‐analysis of research on protection motivation theory. J Appl Soc Psychol 2000;30:407–29.
14. Hablemitoglu S, Yildirim F. The relationship between perception of risk and decision making styles of turkish university students: a descriptive study of individual differences. World Appl Sci J 2008;4:214–24.
15. Schmälzle R, Renner R, Schupp HT. Health risk perception and risk communication. Policy Insights Behav Brain Sci 2017;4:163–9.
16. Freimuth VS, Quinn SC. The contributions of health communication to eliminating health disparities. Am J Public Health 2004;94:2053–5.
17. Lowbridge CP, Leask J. Risk communication in public health. N S W Public Health Bull 2011;22:34.
18. DiClemente RJ, Jackson JM. Risk communication. In : Quah SR, ed. International encyclopedia of public health 2nd edth ed. Oxford: Academic Press; 2017. p. 378–82.
19. Malecki KMC, Keating JA, Safdar N. Crisis communication and public perception of covid-19 risk in the era of social media. Clin Infect Dis 2021;72:697–702.
20. Hou Z, Du F, Jiang H, et al. Assessment of public attention, risk perception, emotional and behavioural responses to the COVID-19 outbreak: social media surveillance in China [Preprint]. Posted 2020 Mar 17. medRxiv 2020.03.14.20035956. https://doi.org/10.1101/2020.03.14.20035956.
21. Rahmanti AR, Ningrum DNA, Lazuardi L, et al. Social media data analytics for outbreak risk communication: public attention on the "New Normal" during the COVID-19 pandemic in Indonesia. Comput Methods Programs Biomed 2021;205:106083.
22. Zhang L, Li H, Chen K. Effective risk communication for public health emergency: reflection on the COVID-19 (2019-nCoV) outbreak in Wuhan, China. Healthcare (Basel) 2020;8:64.
23. Florin MV, Burkler MT. Introduction to the IRGC risk governance framework Lausanne: EPFL International Risk Governance Center; 2017.
24. Heydari ST, Zarei L, Sadati AK, et al. The effect of risk communication on preventive and protective Behaviours during the COVID-19 outbreak: mediating role of risk perception. BMC Public Health 2021;21:54.
25. Blanchard-Boehm RD. Understanding public response to increased risk from natural hazards: application of the hazards risk communication framework. Int J Mass Emerg Dis 1998;16:247–78.
26. Nicoll A, Murray V. Health protection: a strategy and a national agency. Public Health 2002;116:129–37.
27. Reynolds B, Seeger MW. Crisis and emergency risk communication as an integrative model. J Health Commun 2005;10:43–55.
28. Berry D, Raynor T, Knapp P, et al. Over the counter medicines and the need for immediate action: a further evaluation of European Commission recommended wordings for communicating risk. Patient Educ Couns 2004;53:129–34.
29. Schuz N, Schuz B, Eid M. When risk communication backfires: randomized controlled trial on self-affirmation and reactance to personalized risk feedback in high-risk individuals. Health Psychol 2013;32:561–70.
30. Paek HJ, Hove T. Risk perceptions and risk characteristics [Internet]. Oxford Research Encyclopedia; 2017 [cited 2022 Aug 9]. Available from: https://oxfordre.com/communication/view/10.1093/acrefore/9780190228613.001.0001/acrefore-9780190228613-e-283.
31. Nutbeam D, Harris E, Wise W. Theory in a nutshell: a practical guide to health promotion theories Sydney: McGraw-Hill; 2010.
32. Taylor VM, Taplin SH, Urban N, et al. Repeat mammography use among women ages 50-75. Cancer Epidemiol Biomarkers Prev 1995;4:409–13.
33. Haber G, Ahmed NU, Pekovic V. Family history of cancer and its association with breast cancer risk perception and repeat mammography. Am J Public Health 2012;102:2322–9.
34. Khazaee-Pool M, Shahrvsand S, Naghibi SA. Predicting Covid-19 preventive behaviors based on health belief model: an internet-based study in Mazandaran Province, Iran. J Mazandaran Univ Med Sci 2020;30:56–66.
35. Tabibi Z, Abedini E, Gholipour F, et al. The influence of demographic features and psychological constructs on observing government-advised preventive measures for COVID-19: the case of Iran. J Iran Med Council 2021;4:39–48.
36. Kim JK, Crimmins EM. How does age affect personal and social reactions to COVID-19: results from the national Understanding America Study. PLoS One 2020;15e0241950.
37. Raude J, Lecrique JM, Lasbeur L, et al. Determinants of preventive behaviors in response to the COVID-19 pandemic in France: comparing the sociocultural, psychosocial, and social cognitive explanations. Front Psychol 2020;11:584500.
38. Chen Y, Zhou R, Chen B, et al. Knowledge, perceived beliefs, and preventive behaviors related to COVID-19 among Chinese older adults: cross-sectional web-based survey. J Med Internet Res 2020;22e23729.
39. Liao Q, Cowling B, Lam WT, et al. Situational awareness and health protective responses to pandemic influenza A (H1N1) in Hong Kong: a cross-sectional study. PLoS One 2010;5e13350.
40. Park JH, Cheong HK, Son DY, et al. Perceptions and behaviors related to hand hygiene for the prevention of H1N1 influenza transmission among Korean university students during the peak pandemic period. BMC Infect Dis 2010;10:222.
41. Fard SP, Taheri AA, Ghvami M, et al. Individual, gender differences and corona: the relationship between personality traits and gender differences with corona self care behaviour. Shenakht J Psychol Psychiatr 2020;7:67–77.
42. Firouzbakht M, Omidvar S, Firouzbakht S, et al. COVID-19 preventive behaviors and influencing factors in the Iranian population; a web-based survey. BMC Public Health 2021;21:143.
43. Moran KR, Del Valle SY. A meta-analysis of the association between gender and protective behaviors in response to respiratory epidemics and pandemics. PLoS One 2016;11e0164541.
44. Zhong BL, Luo W, Li HM, et al. Knowledge, attitudes, and practices towards COVID-19 among Chinese residents during the rapid rise period of the COVID-19 outbreak: a quick online cross-sectional survey. Int J Biol Sci 2020;16:1745–52.
45. Winkleby MA, Jatulis DE, Frank E, et al. Socioeconomic status and health: how education, income, and occupation contribute to risk factors for cardiovascular disease. Am J Public Health 1992;82:816–20.
46. Calixto OJ, Anaya JM. Socioeconomic status. The relationship with health and autoimmune diseases. Autoimmun Rev 2014;13:641–54.

Article information Continued

Table 1.

Characteristics of the study participants

Variable Value
Female sex (n=2,063) 1,266 (61.4)
Age (y) (n=1,977) 37.62±10.03
 18−29 459 (23.2)
 30−39 737 (37.3)
 40−49 483 (24.4)
 50−59 245 (12.4)
 >60 53 (2.7)
Marital status (n=2,053)
 Single 664 (32.3)
 Married 1,338 (65.2)
 Divorced 32 (1.6)
 Widowed 19 (0.9)
Number of household members (n=2,059)
 ≤3 947 (46.0)
 4−6 1,034 (50.2)
 >6 78 (3.8)
Highest level of education (n=2,061)
 Primary school 16 (0.8)
 Secondary school 61 (3.0)
 Diploma degree 411 (19.9)
 University degree 1,573 (76.3)
Family or friends infected with COVID-19 (n=2,065)
 Yes 111 (5.4)
 No 1,954 (94.6)
Family or friends died from COVID-19 (n=2,067)
 Yes 37 (1.8)
 No 2,030 (98.2)
Job (n=2,062)
 Housekeeper 462 (22.4)
 Government employee 918 (44.5)
 Workman 77 (3.7)
 Shopkeeper 73 (3.5)
 Vendor 3 (0.1)
 Military 21(1.0)
 Unemployed 199 (9.7)
 University student 88 (4.3)
 Others 213 (10. 3)
Socioeconomic status (n=2,063) 5.53±2.04
 Very low 171 (8.3)
 Low 389 (18.8)
 Moderate 807 (39.1)
 High 586 (28.4)
 Very high 110 (5.3)
Risk perception (n=2,051) 24.16±3.04
Risk communication (n=2,064) 4.42±0.67
 Almost never 3 (0.1)
 Rarely 11(0.5)
 Occasionally 165 (8.0)
 Often 811(39.3)
 Almost always 1,074 (52.0)
Wear gloves (n=2,064)
 Always 141 (6.8)
 Sometimes 185 (9.0)
 No 1,585 (76.8)
 Not available 153 (7.4)
Wear a mask (n=2,062)
 Always 741 (35.9)
 Sometimes 1,002 (48.6)
 No 319 (15.5)
Physical distance (n=2,067)
 Yes, comply 1,625 (78.6)
 Economic condition does not permit 379 (18.3)
 Never 63 (3.0)
Wash hands (n=2,067)
 Always 1,947 (94.2)
 Sometimes 118 (5.7)
 Never 2 (0.1)
Disinfect one’s home (n=2,065)
 Yes always 1,594 (77.2)
 Yes, sometimes 425 (20.6)
 Never 46 (2.2)
Disinfect one’s personal devisees (n=2,066)
 Yes always 1,486 (71.9)
 Yes sometimes 511 (24.7)
 Never 69 (3.3)
 Total score for COVID-19 preventive behaviors (n=2,069) 14.55±1.45

Data are presented as n (%) or mean±standard deviation.

COVID-19, coronavirus disease 2019.

Table 2.

Correlations among the main variables

Variable Total COVID-19 preventive behaviors Risk perception Risk communication
Total COVID-19 preventive behaviors 1.00 0.201** 0.320**
Risk perception 0.201** 1.00 0.445**
Risk communication 0.320** 0.445** 1.00

COVID-19, coronavirus disease 2019.

**

p<0.01.

Table 3.

Multiple regression analysis of factors associated with COVID-19 preventive behaviors, Kermanshah, Iran, 2020

Independent variable Model 1 Model 2 Model 3
Coefficient (β) SE Coefficient (β) SE Coefficient (β) SE
Age 0.010* 0.004 0.009* 0.004 0.007 0.004
Sex −0.567** 0.09 −0.553** 0.089 −0.482** 0.087
Marital status
 Married −0.182 0.103 −0.125 0.102 −0.168 0.099
 Divorced −0.300 0.318 −0.270 0.312 −0.323 0.303
 Widowed −0.638 0.421 −0.374 0.415 −0.070 0.404
Highest level of education
 Secondary −0.554 0.536 −0.849 0.528 −0.799 0.512
 Diploma −0.542 0.49 −0.774 0.482 −0.640 0.468
 Academic −0.553 0.49 −0.815 0.482 −0.703 0.468
Job
 Government employee 0.005 0.121 −0.064 0.119 −0.066 0.116
 Workman −0.105 0.230 −0.147 0.228 −0.045 0.221
 Shopkeeper −0.460* 0.232 −0.403 0.228 −0.391 0.222
 Vendor −1.01 0.962 −1.220 0.945 −0.925 0.917
 Military 0.210 0.391 0.091 0.384 0.299 0.373
 Unemployed 0.016 0.167 0.038 0.165 0.001 0.160
 University student −0.189 0.215 −0.192 0.212 −0.145 0.206
 Other 0.101 0.156 0.045 0.153 0.050 0.149
Socioeconomic status
 Low -0.078 0.162 −0.026 0.16 −0.012 0.156
 Moderate -0.007 0.151 0.031 0.149 −0.016 0.145
 High 0.134 0.157 0.164 0.155 0.048 0.151
 Very high 0.483* 0.219 0.446* 0.216 0.325 0.210
Chronic diseases 0.106 0.114 0.117 0.113 0.089 0.109
Family or friend infected with COVID-19 −0.066 0.179 0.015 0.176 0.037 0.171
Family or friend died from COVID-19 −0.266 0.302 −0.334 0.297 −0.322 0.288
No. of household members
 4−6 0.028 0.080 0.052 0.079 0.077 0.076
 >6 −0.382 0.204 −0.270 0.201 −0.196 0.195
Risk perception 0.113** 0.012 0.047** 0.013
Risk communication 0.662** 0.061
Cons 16.65** 0.691 13.20** 0.734 11.96** 0.712
N 1,916 1,902 1,900
p>F 0.001 0.001 0.001
R-squared 0.0489 0.0888 0.1423
Adjusted R-squared 0.0364 0.0762 0.13
Root mean-square error 1.64 1.61 1.57

COVID-19, coronavirus disease 2019; SE, standard error.

*

p<0.05,

**

p<0.01.