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Effect of a Health Belief Model-based education program on patients’ belief, physical activity, and serum uric acid: a randomized controlled trial

Authors Shao C, Wang J, Liu J, Tian F, Li H

Received 24 February 2018

Accepted for publication 13 May 2018

Published 17 July 2018 Volume 2018:12 Pages 1239—1245

DOI https://doi.org/10.2147/PPA.S166523

Checked for plagiarism Yes

Review by Single anonymous peer review

Peer reviewer comments 2

Editor who approved publication: Dr Naifeng Liu



Chunhai Shao,1,* Jiwei Wang,2,* Jingfang Liu,1 Fang Tian,1 Hua Li3

1Department of Nutrition, Huashan Hospital, Fudan University, Shanghai, People’s Republic of China; 2Key Laboratory of Health Technology Assessment of Ministry of Health, School of Public Health, Fudan University, Shanghai, People’s Republic of China; 3Department of Cardiac Surgery, Zhongshan Hospital, Fudan University, Shanghai, People’s Republic of China

*These authors contributed equally to this work

Objective: We aimed to investigate the effect of a Health Belief Model (HBM)-based education program on the perception scores of 5 HBM domains, physical activity, and serum uric acid (SUA) among asymptomatic hyperuricemia (AHU) patients in a randomized controlled trial.
Methods: One hundred and ninety-three AHU patients were involved in this prospective experimental interventional study in Shanghai, China. Subjects were randomly divided into interventional or control group. The educational program was designed based on HBM component for the improvement of knowledge and promotion of lifestyle adherence in terms of low-purine diet and physical activity among AHU patients. This program included educational booklets and educational classes. Data were collected from interventional and control group members both before and after the intervention, using a questionnaire covering sociodemographic characteristics, HBM variables, physical activity from the Health-Promoting Lifestyle Profile II, and a check list for recording the subject’s SUA values, as well as the body mass index, waist–hip ratio, systolic blood pressure, and diastolic blood pressure.
Results: In the interventional group, the mean scores of the HBM variables (perceived susceptibility, perceived severity, perceived benefit, perceived barriers, and self-efficacy), SUA values, physical activity, body mass index, and waist–hip ratio were improved significantly after the intervention (p<0.05), whereas no significant differences were detected in the control group between baseline and follow-up measures.
Conclusion: This study showed the importance of the educational program based on the HBM in improving the model constructs and physical activity, as well as in decreasing the SUA values in AHU patients.

Keywords: Health Belief Model, asymptomatic hyperuricemia, education, adherence

Introduction

Uric acid has now been identified as a marker for a number of metabolic and hemodynamic abnormalities.13 Furthermore, an abundance of evidence has suggested that hyperuricemia (HU) may be an independent risk factor for the development and pathogenesis of hypertension, stroke, and atherosclerosis.46 The worldwide prevalence rate of HU has been increasing substantially over the past 2 decades. In China, the prevalence rates of HU were reported to range from 6% to 25%.7

The progressive increase of serum uric acid (SUA) levels may be attributed to the rising prevalence of overweight and obesity,8 as well as the increase in consumption of beer and foods with high purine level,9 fructose-based drinks and fructose-flavored foods,10 and physical inactivity.11 Most patients with HU never develop gout or stones. Pharmacologic treatment for asymptomatic HU (AHU) is not considered beneficial or cost-effective due to side effects; therefore, it is not generally recommended.12 However, these patients can be advised on lifestyle changes, such as changes in diet, reduction in alcohol intake, and exercise, all of which may lower uric acid levels.13 In asymptomatic patients, nonadherence with lifestyle modifications, such as changes in dietary habits or exercise regimens, is also common.14

Previous studies showed that some theory-based educational programs that applied cognitive frameworks could have a positive effect on behavioral changes.1517 The Health Belief Model (HBM) has served as a successful model in a number of health education programs. It provides a means to understand the attitude, behaviors, and educational needs of people; therefore, it is used as a practical tool to develop effective intervention strategies.1820 HBM consists of key constructs that can help subjects to adopt a healthy lifestyle, including perceived susceptibility, perceived severity, perceived benefit, perceived barrier, and self-efficacy.21 However, to our knowledge, such programs have not yet been specifically used to educate HU patients.

In this randomized controlled trial, the HBM was used as the theoretical framework to develop the health educational program. Furthermore, we investigated the interventional effects on the perception scores of 5 HBM domains, physical activity, and SUA level.

Methods

Participants

This study was conducted on AHU patients through the resident’s routine health checkup in a community health service center in Pudong Xin District in Shanghai, China, in 2016.

The inclusion criteria were as follows: 1) AHU patients not on treatment; 2) no other chronic diseases that need taking of medicine regularly; 3) age >17 years; 4) no participation in a similar study; 5) mental competence to provide consent; and 6) physical competence to follow intervention. HU was defined as uric acid level ≥420 μmol/L for males and ≥360 μmol/L for females.

Among the enrolled 200 AHU patients, 193 (96.5%) subjects participated in this study. Seven AHU patients refused to participate in this program because they had no time. One research statistician performed the random assignment. Subjects were randomly assigned to interventional group or control group by using software-generated random numbers. Thus, 97 subjects in the interventional group and 96 subjects in the control group participated in the baseline survey. After 6-week intervention, all subjects were followed up.

Ethical approval to conduct this study was granted by the Medical Research Ethics Committee of the Huashan Hospital, Fudan University, Shanghai, China (protocol number KY2016-356). A written informed consent was obtained from each patient. The participants were free to continue or give up the procedures at any time during the study. They were assured of the confidentiality of their information.

The study design is shown in Figure 1.

Figure 1 Flow diagram of the progress through the phases of the randomized trial.

Educational program

The educational program was designed based on the HBM components for the improvement of knowledge and promotion of lifestyle adherence in terms of low-purine diet and physical activity among AHU patients. This program included educational booklets and educational classes. The content of the booklet included definitions of HU, risk factors, and the benefits of adopting a low-purine diet and physical activity in reducing SUA levels and preventing long-term complications of HU.

The course included 6 weekly teaching units (lectures and group discussions, 45–60 minutes each). The 1st and the 2nd teaching units acquainted the patients with the interactive group method and educated them about the risk factors and complications of HU. The 3rd teaching unit educated them about the low-purine diet, including the type and the amount of food. The 4th teaching unit educated about the physical activity programs, including the type, duration, frequency, and intensity of physical activity. The 5th and the 6th teaching units discussed the benefits and barriers of low-purine diet and physical activity program, as well as proposed methods to decrease perceived barriers and enhance the confidence in adherence.

Both the interventional group and the control group received the same low-purine diet pamphlets provided by the nutrition department of the community health service center.

Measures

The questionnaire included 3 sections that comprised 35 questions: 5 questions for demographic features; 22 questions for HBM variables; and 8 questions about physical activity. Through face-to-face structured interviews, data were collected by the registered nurses who were blinded to intervention allocation throughout the study.

Prior to conducting the main project, a pilot test was conducted to assess the readability and comprehension of the questionnaire. Ten AHU patients participated in the pilot test and were not subsequently included in the main study. After the pilot test, all the respondents were required to talk about whether they had any difficulties in understanding and completing the instrument. No respondent had hesitations, requests for clarification, or suggestions for different wordings on this instrument.

Sociodemographic characteristics

The sociodemographic characteristics included age, gender, marital status, and the highest educational level achieved.

HBM variables

In this study, we developed the items that assessed the components of the HBM,2224 and 22 items were combined under 5 major constructs: 1) perceived susceptibility; 2) perceived severity; 3) perceived benefit; 4) perceived barrier; and 5) self-efficacy. Three items were designed to measure perceived susceptibility, which referred to a person’s opinion regarding his or her personal chances of developing a condition. Three items were designed to measure perceived severity, which referred to a person’s opinion about the seriousness of a specific condition and its consequences. Five items were designed to measure perceived benefit to lifestyle adherence, which referred to a person’s belief in the efficacy of the advised action to reduce risk or seriousness of impact. Six items were designed to evaluate perceived barrier to lifestyle adherence, which referred to any impediments in the way of adopting a recommended health-related behavior. Five items were designed to assess self-efficacy in lifestyle adherence, which referred to an individual’s belief in his or her capacity to execute behaviors necessary to produce specific performance attainments.

In order to facilitate respondents’ responses to the items, all items were standardized to a 5-point Likert scale, ranging from 0 (strongly disagree) to 4 (strongly agree). Every subscale mean was determined by dividing the total points of all the subscale items by the total number of items. Therefore, the mean score of the HBM model variables (perceived susceptibility, perceived severity, perceived benefit, and perceived barriers, as well as self-efficacy) could range from 0 to 4. A higher score indicates a greater level of belief.

Test–retest reliability coefficients (Cronbach’s alpha, before and after intervention) for each HBM construct were as follows: severity (0.88; 0.91); susceptibility (0.89; 0.88); barrier (0.85; 0.86); benefit (0.92; 0.91); and self-efficacy (0.88; 0.89). These results demonstrated that the questionnaires were internally consistent.

Physical activity

Physical activity was measured with the Health-Promoting Lifestyle Profile II (HPLP II).25 The HPLP II instrument consists of 52 items in 6 subdimensions: 1) Health responsibility, 9 items; 2) Physical activity, 8 items; 3) Nutrition, 9 items; 4) Spiritual growth, 9 items; 5) Interpersonal relations, 9 items; and 6) Stress management, 8 items. All items were scored on a 4-point Likert scale (1 – not at all; 2 – sometimes; 3 – often; and 4 – always). In this study, the subdimension “Physical activity” was used for measuring the physical activity.

Mean score of physical activity was obtained by calculating the subject’s response. Therefore, the physical activity score could range from 1 to 4. A higher score indicates a greater level of physical activity behaviors.

Test–retest reliability coefficients (Cronbach’s alpha, before and after intervention) for physical activity of HPLP II were 0.84 and 0.85. These results demonstrated that this instrument was internally consistent.

Anthropometric indices, blood pressure, and SUA level

The body mass index (BMI), waist–hip ratio (WHR), systolic blood pressure (SBP), diastolic blood pressure (DBP), and SUA level were measured at the beginning and at the end of the intervention. The BMI was defined as the body mass divided by the square of the body height, mass represented in kilograms and height in meters. The WHR was calculated as waist measurement divided by hip measurement. A mercury sphygmomanometer was used to measure blood pressure. The blood sample was taken via the venous line. The determination of SUA levels was done by the Sigma enzymatic procedure (Sigma Diagnostics, St Louis, MO, USA) using colorimetric methods. All subjects’ SUA levels at the baseline met the inclusion criteria.

Statistical analysis

Traditional sociodemographic characteristics (age, gender, marital status, and highest grade/education achieved) were initially examined using descriptive statistics. Independent 2-samples t-test, paired 2-samples t-test, and χ2 analysis were used to examine bivariate relationships between sociodemographic variables, 5 major constructs of HBM, physical activity, and SUA for continuous and categorical variables, respectively. A p-value ≤0.05 was considered statistically significant. All statistical analyses were performed using the Statistical Package for the Social Sciences for Windows (Version 21.0; IBM Corporation, Armonk, NY, USA).

Results

Sociodemographic characteristics of subjects

A total of 193 patients with AHU were involved in this study. Among the 193 patients, the mean age in the interventional and control groups was 59.7±6.0 years and 60.4±6.0 years, respectively. Further, 78.4% in the interventional group and 86.5% in the control group were males. Most of the participants were married and had received primary or middle school education. There were no significant differences between the 2 groups in terms of age, gender, marital status, educational status, and household income (Table 1).

Table 1 Baseline characteristics of the interventional and control groups

Mean score of HBM variables

There was no significant difference in the mean scores of the 5 domains of HBM between the interventional group and the control group before intervention (p>0.05). The mean scores for the independent variables among the AHU patients were significantly improved after intervention: perceived susceptibility increased from 2.46 to 2.69; perceived severity increased from 2.40 to 2.59; perceived benefit increased from 2.77 to 2.94; perceived barriers increased from 2.70 to 2.86; self-efficacy increased from 2.70 to 2.92 (Table 2).

Table 2 Mean scores of Health Belief Model variables before and after educational program
Notes: Values are expressed as means (standard deviations). The p-values A1 vs A2 and B1 vs B2 are obtained by comparing means between the groups using the paired-samples t-test. The p-values A1 vs B1, A2 vs B2, A1 vs B2, and A2 vs B1 are obtained by comparing means between the groups using the independent-samples t-test.

Mean score of physical activity

The mean score of physical activity was similar in both interventional and control groups, and there was no significant difference (p>0.05, Table 3). The mean score of physical activity was significantly improved from 2.48 to 2.72 after intervention (p<0.001); meanwhile, no significant difference was found in the control group (Table 3).

Table 3 Mean scores of physical activity before and after educational program
Notes: Values are expressed as means (standard deviations). The p-values A1 vs A2 and B1 vs B2 are obtained by comparing means between the groups using the paired-samples t-test. The p-values A1 vs B1, A2 vs B2, A1 vs B2, and A2 vs B1 are obtained by comparing means between the groups using the independent-samples t-test.

Mean levels of indices

Before the educational program, there were no significant differences in BMI, WHR, SBP, DBP, and SUA level between the interventional group and the control group (p>0.05). The mean BMI was significantly reduced after the intervention (25.70±3.10 vs 24.7±3.00; p=0.025), so were the WHR (0.90±0.06 vs 0.88±0.06; p=0.032) and the SUA level (493.2±44.1 vs 459.5±54.3 μmol/L; p<0.001), while the intervention had no significant effects on the SBP and DBP. There were no significant differences in all indices between baseline levels and follow-up levels in the control group (p>0.05 for all) (Table 4).

Table 4 Mean levels of indices before and after educational program
Notes: Values are expressed as means (standard deviations). The p-values A1 vs A2 and B1 vs B2 are obtained by comparing means between the groups using the paired-samples t-test. The p-values A1 vs B1, A2 vs B2, A1 vs B2, and A2 vs B1 are obtained by comparing means between the groups using the independent-samples t-test.
Abbreviations: SBP, systolic blood pressure; DBP, diastolic blood pressure; BMI, body mass index; WHR, waist–hip ratio; SUA, serum uric acid.

Discussion

In the present study, the HBM was utilized as a theoretical framework to design the educational program among the AHU patients. In the interventional group, results of the baseline and 6-week follow-up clearly demonstrated the significant intervention effects on the variables of the HBM, including perceived severity, perceived susceptibility, perceived benefit, perceived barrier, and self-efficacy, as well as on the physical activity. Additionally, BMI, WHR, and SUA values were significantly improved in the interventional group. This result implied that our intervention had an effect on patients’ health beliefs concerning HU and induced corresponding lifestyle adherence in the interventional group.

Previous studies showed that the perception of the disease’s severity and susceptibility could lead to a higher level of lifestyle adherence among patients with some chronic diseases, such as diabetes and coronary heart disease.19,26 Therefore, the improvement of perceived benefits and the reduction of perceived barriers might enhance the lifestyle adherence among them. Our research demonstrated similar results, namely, that the educational intervention program could increase the perception of disease among AHU patients, resulting in enhanced lifestyle adherence.

In the present study, self-efficacy and physical activity in the interventional group were significantly higher after the intervention compared with the same at baseline. Some studies indicated that praising or rewarding participants for their “attempts” at achieving a behavioral goal was associated with significantly higher self-efficacy and physical activity.2729 In our educational program, we also adopted these educational techniques, such as positive feedback to the participants. Through focusing on small successes and progression toward behavioral goals rather than actual achievement of final target behaviors, the self-efficacy of patients was enhanced. This followed Bandura’s view that personal performance successes enhance perceived self-efficacy.30

The participants in the control group also received regular health advice through booklets; however, our results indicated that they did not follow these suggestions such as the ones about physical activity. The truth is that knowledge alone will not change behavior. The main proposed reason for failure to lifestyle adherence was the patients’ belief that they did not really need the lifestyle changes, especially in asymptomatic patients.31 AHU is often associated with major chronic disorders, such as diabetes and an increased risk of cardiovascular disease and mortality.6 Therefore, in order to improve the physical activity and dietary behavior adherence, health education program for AHU patients should incorporate the elements of health benefits.

There are several limitations in the present study. The follow-up time after education was relatively short. Therefore, a long-term follow-up is recommended. The dietary education was included in the education program; however, the dietary contents were not included in the survey due to difficulties in recording so many dietary items. So the present study did not investigate the direct effect of dietary alterations. Future research should survey this part through designing more feasible and valid instruments. Convenience sampling was also a limitation to this study. Participants of the study were from 1 community health service center in Shanghai City; these people might differ in terms of social and economic characteristics compared to those from other areas of China; therefore, random sampling procedures with a larger sample size across China would be beneficial in future research.

Conclusion

This study showed the importance of the educational program based on the HBM in both improving the model constructs and physical activity, as well as decreasing SUA values, in AHU patients.

Acknowledgment

This study was supported by the Shanghai Municipal Commission of Health and Family Planning (award number 20134256).

Disclosure

The authors report no conflicts of interest in this work.


References

1.

Yu TY, Jee JH, Bae JC, et al. Serum uric acid: a strong and independent predictor of metabolic syndrome after adjusting for body composition. Metabolism. 2016;65(4):432–440.

2.

Soltani Z, Rasheed K, Kapusta DR, Reisin E. Potential role of uric acid in metabolic syndrome, hypertension, kidney injury, and cardiovascular diseases: is it time for reappraisal? Curr Hypertens Rep. 2013;15(3):175–181.

3.

Kanbay M, Jensen T, Solak Y, et al. Uric acid in metabolic syndrome: from an innocent bystander to a central player. Eur J Intern Med. 2016;29:3–8.

4.

Kuwabara M. Hyperuricemia, cardiovascular disease, and hypertension. Pulse. 2016;3(3–4):242–252.

5.

Feig DI. Hyperuricemia and hypertension. Adv Chronic Kidney Dis. 2012;19(6):377–385.

6.

Acevedo A, Benavides J, Chowdhury M, et al. Hyperuricemia and cardiovascular disease in patients with hypertension. Conn Med. 2016;80(2):85–90.

7.

Smith E, March L. Global prevalence of hyperuricemia: a systematic review of population-based epidemiological studies [abstract]. Arthritis Rheumatol. 2015;67(suppl 10).

8.

Duan Y, Liang W, Zhu L, et al. Association between serum uric acid levels and obesity among university students (China). Nutr Hosp. 2015;31(6):2407–2411.

9.

Choi HK, Curhan G. Beer, liquor, and wine consumption and serum uric acid level: the third national health and nutrition examination survey. Arthritis Rheum. 2004;51(6):1023–1029.

10.

Rho YH, Zhu Y, Choi HK. The epidemiology of uric acid and fructose. Semin Nephrol. 2011;31(5):410–419.

11.

Chen JH, Wen CP, Wu SB, et al. Attenuating the mortality risk of high serum uric acid: the role of physical activity underused. Ann Rheum Dis. 2015;74(11):2034–2042.

12.

Levy G, Cheetham TC. Is it time to start treating asymptomatic hyperuricemia? Am J Kidney Dis. 2015;66(6):933–935.

13.

Ramirez MEG, Bargman JM. Treatment of asymptomatic hyperuricemia in chronic kidney disease: a new target in an old enemy – a review. J Adv Res. 2017;8(5):551–554.

14.

Lemstra M, Blackburn D, Crawley A, Fung R. Proportion and risk indicators of nonadherence to statin therapy: a meta-analysis. Can J Cardiol. 2012;28:574–580.

15.

White SM, Wójcicki TR, McAuley E. Social cognitive influences on physical activity behavior in middle-aged and older adults. J Gerontol B Psychol Sci Soc Sci. 2012;67(1):18–26.

16.

Simoni JM, Franks JC, Lehavot K, Yard SS. Peer interventions to promote health: conceptual considerations. Am J Orthopsychiatry. 2011;81(3):351–359.

17.

Jeihooni AK, Hidarnia A, Kaveh MH, Hajizadeh E, Askari A. Application of the health belief model and social cognitive theory for osteoporosis preventive nutritional behaviors in a sample of Iranian women. Iran J Nurs Midwifery Res. 2016;21(2):131–141.

18.

Ghaffari M, Tavassoli E, Esmaillzadeh A, Hassanzadeh A. Effect of health belief model based intervention on promoting nutritional behaviors about osteoporosis prevention among students of female middle schools in Isfahan, Iran. J Educ Health Promot. 2012;1:14.

19.

Shojaei S, Farhadloo R, Aein A, Vahedian M. Effects of the health belief model (HBM)-based educational program on the nutritional knowledge and behaviors of CABG patients. J Tehran Heart Cent. 2016;11(4):181–186.

20.

Zare M, Ghodsbin F, Jahanbin I, Ariafar A, Keshavarzi S, Izadi T. The Effect of health belief model-based education on knowledge and prostate cancer screening behaviors: a randomized controlled trial. Int J Community Based Nurs Midwifery. 2016;4(1):57–68.

21.

Wai CT, Wong ML, Ng S, et al. Utility of the health belief model in predicting compliance of screening in patients with chronic hepatitis B. Aliment Pharmacol Ther. 2005;21(10):1255–1262.

22.

Becker MH. The health belief model and personal health behavior. Health Educ Monogr. 1974;2:4.

23.

Champion VL, Skinner CS. The health belief model. In: Glanz K, Rimer BK, Viswanath K, editors. Health Behavior and Health Education: Theories, Research, and Practice. San Francisco, CA: Jossey Bass; 2008:45–65.

24.

Bandura A. Self-Efficacy: The Exercise of Control. New York: W H Freeman/Times Books/Henry Holt & Co; 1997.

25.

Walker SN, Sechrist KR, Pender NJ. The health-promoting lifestyle profile: development and psychometric characteristics. Nurs Res. 1987;36(2):76–81.

26.

Harvey JN, Lawson VL. The importance of health belief models in determining self-care behaviour in diabetes. Diabet Med. 2009;26(1):5–13.

27.

Lewis BA, Williams DM, Frayeh AL, Marcus BH. Self-efficacy versus perceived enjoyment as predictors of physical activity behaviour. Psychol Health. 2016;31(4):456–469.

28.

Darker CD, French DP, Eves FF, Sniehotta FF. An intervention to promote walking amongst the general population based on an ‘extended’ theory of planned behaviour: a waiting list randomised controlled trial. Psychol Health. 2010;25(1):71–88.

29.

Hu L, Cheng S, Lu J, Zhu L, Chen L. Self-efficacy manipulation influences physical activity enjoyment in Chinese adolescents. Pediatr Exerc Sci. 2016;28(1):143–151.

30.

Bandura A. Self-efficacy: toward a unifying theory of behavioral change. Psychol Rev. 1977;84(2):191–215.

31.

Hyman DJ, Pavlik VN. Characteristics of patients with uncontrolled hypertension in the United States. N Engl J Med. 2001;345(7):479–486.

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