Effects of a theory-based training program with follow-up home visits on self-management behavior, glycemic index, and quality of life among Iranian patients with type 2 diabetes mellitus

Diabetes mellitus, one of the most common chronic non-communicable diseases, is the leading cause of life-threatening disabilities, costly complications, decreased quality of life, and diminished life expectancy [1‐3]. It substantially burdens community health and socioeconomic development [4].

A high proportion of cases of diabetes are uncontrolled. The global prevalence of uncontrolled diabetes is reportedly 40% to 60% [5]. In this context, 36% of patients with type 2 diabetes mellitus (T2DM) in developing countries have never measured their hemoglobin A1c [HbA1c], and only 36.4% of those who have measured HbA1c have optimal glycemic control [6]. In Iran, the prevalence of uncontrolled T2DM is approximately 60%, consistent with studies carried out in the Middle East [7]. Uncontrolled T2DM is associated with several complications, such as glaucoma and cataracts, foot problems, skin infections, urinary tract infections, and genital problems. It has also been associated with cardiovascular complications, such as heart attack, renal failure, vision loss, peripheral artery disease, and amputation [8]. Diabetes is a major risk factor for premature death, mainly due to cardiovascular and cerebrovascular diseases [9]. In addition, it increases the risk of contracting infectious diseases, such as COVID-19, and the chance of adverse clinical outcomes [10].

Effective diabetes management includes three key components: medical treatment, environmental support [especially from the family], and self-management. Self-management is vital in accessing and benefiting from the other two. Numerous factors affect the performance and adherence to self-management behaviors at multiple levels. Many studies address the lack of knowledge and social and organizational [health centers] support, inappropriate attitudes, inadequate self-efficacy, and poor self-regulatory skills [11‐14]. Despite the multifactorial nature of self-management behaviors, most interventions focus solely on increasing knowledge and attitudes, lacking follow-ups, and neglecting contextual conditions, including socioeconomic status and social support required by the family [15‐18].

The design of educational interventions to cause desirable behavioral changes improves when all factors related to target behavior[s] determinants are considered [19]. Behavior change theories help give a better insight into the factors that influence behavior in the target population and choose the right approach to designing, implementing, and evaluating the intervention [19‐21].

Considering the intrapersonal and interpersonal factors affecting self-management among diabetic patients, the social cognitive theory (SCT), developed by Albert Bandura, was found to be a suitable theoretical framework to conduct and evaluate the intervention in this study. Its underlying concept, based on which human behavior is explained, is the triadic reciprocal determinism or the dynamic interplay among personal cognitive factors, the environment, and behavior [19, 20].

SCT defines several constructs as individual and interpersonal determinants of behavior. In the following, the constructs identified in the present analysis of health behavior in the target population are briefly described:

Badura states that knowledge is a precondition for behavior change [20]. Knowledge is a collection of information, facts, and experiences acquired by a person during life and education [21]. It enables recognizing the health risks and benefits of health-related choices and is a guide for choosing information and actions beneficial to health [19]. Outcome expectations refer to predicting possible outcomes that will result from the desired behavior [expected results] [22]. Self-efficacy refers to an individual's self-confidence in their ability to perform the behavior that leads to the result. Self-regulation refers to controlling behaviors based on personal standards [20]. Finally, social support implies understanding the support and encouragement received from one's social network [19].

As a practical implication of social support, home-based visits and/or follow-ups may help patients with T2DM improve self-management as an integral strategy [23]. The overcrowding of outpatient care centers and the mobility-related difficulties that T2DM patients face limit the provision of adequate training and follow-up care. Home visits are good opportunities to further educate patients and family members, involve them in the care process, and develop social support for patients [24]. This strategy can enhance adherence to self-care and improve health outcomes and quality of life [23]. Research shows that pursuing care through home visits promotes glycemic control, improves the quality of life [25], increases patient confidence in decision making, and enhances self-care behaviors [26].

In support of using SCT as a theoretical framework, evidence suggests that treatment plans, self-efficacy, situational factors, social support, and the involvement of significant others are decisive in diabetic self-management behavior [27, 28]. In addition, a cross-sectional study in Iran shows that SCT’s constructs significantly predict self-care behavior among T2DM patients [16]. It has been demonstrated that social support, self-efficacy, self-regulation, and outcome expectations are important determinants of nutritional behavior [14]. However, there are conflicting findings on the relationship between such variables and some outcomes in patients with type 1 diabetes (T1D): While high self-efficacy has been associated with lower hemoglobin A1c levels [29], no significant relationship has been found in another relevant study [30].

No relevant study has been found with a theoretical framework similar to the present study. Hence, the present study was designed to examine the effects of an SCT-based training program with follow-up home visits on SCT constructs, self-management behavior, glycemic index, and quality of life among patients with T2DM.

The mean age in the intervention and control groups was 49.32 ± 7.05 and 49.73 ± 7.95 years, respectively (t = 0.275, df = 97, p = 0.784). The majority of the participants in the groups were female [65.7%], housekeepers [58.6%], married [88%], and their education levels ranged from the 6^th to the 12^th grade. Besides, the majority of the participants were from Arab tribes (74.7%), homeowners (70.7%), and lived with their spouses and children (87.9%). The groups displayed no statistically significant differences in terms of demographic variables. Seventy-seven patients (77.8%) had had diabetes for more than five years. The mean duration of T2DM since diagnosis was not statistically significant between the intervention (2.60 ± 0.72 years) and control (2.73 ± 0.60 years) groups (t = 1, df = 97, p = 0.32).

At baseline, the mean score of knowledge in the intervention (13.58 ± 2.71) and control (13.20 ± 2.91) groups was not statistically different. After the intervention, the mean score of knowledge was 18.54 ± 0.58 in the intervention group and 13.34 ± 2.81 in the control group, and the independent samples t-test showed significant differences between the two groups (t = 12.76, df = 97, p < 0.001). The independent t-test indicated that the mean changes in the knowledge score in the intervention group (4.96 ± 0.37) and control group (0.14 ± 0.10) were significantly different (Table 2).

The mean score of outcome expectations in the intervention group increased from 46.14 ± 6.42 at baseline to 57.02 ± 4.53 three months after the intervention. (Paired t-test: t = -18.61, df = 49, p < 0.001). However, no significant change was observed within the control group after the intervention. Furthermore, the independent samples t-test showed that the mean changes in outcome expectancy scores were significantly different between the intervention group (10.88 ± 4.13) and the control group (0.34 ± 7.42) three months after the intervention (Table 2).

The mean self-efficacy score in the intervention group was 29.54 ± 2.44 before the intervention and 36.70 ± 5.08 after that (paired sample t-test; t = -11.31, df = 49, p < 0.001). However, the mean scores of this construct in the control group before [28.57 ± 6.42] and after the intervention (28.59 ± 6.77) were not statistically different (p = 0.23). The mean changes in self-efficacy scores between the intervention (7.16 ± 0.63) and control (0.02 ± 0.51) groups were significantly different, as showed by the independent samples t-test (p < 0.001) (Table 2).

The results revealed no significant difference between the intervention and control groups concerning the mean score of perceived social support before the intervention (15.62 ± 4.46 vs. 16.02 ± 2.72). After the intervention, the mean social support score was 28.86 ± 2.89 in the intervention group and 16.24 ± 2.89 in the control group. The independent t-test indicated a statistically significant difference between the groups (t = -22.43, df = 97, p < 0.001). This test also indicated a significant difference between the two groups regarding the changes in the social support mean score (Table 2).

Table 2 indicates that the mean self-regulation score in the intervention group changed from 30.76 ± 4.34 at baseline to 42.72 ± 3.88 three months after intervention (Paired sample t-test; t = -16.18, df = 49, p < 0.001). However, no significant difference was found in the control group regarding the mean score of this construct before (30.97 ± 3.38) and after (31.26 ± 2.99) the intervention. As indicated by the independent t-test, the mean of self-regulation score changes were higher in the intervention group (11.96 ± 5.22) than in the control group (0.28 ± 1.97).

In the intervention group, the mean self-management score increased from 36.06 ± 10.02 before the intervention to 64.94 ± 7.34 three months after the intervention. Also, the paired t-test showed that the difference was statistically significant (t = -17.72, df = 49, p < 0.001). However, this was not the case in the control group. Besides, the independent t-test revealed a significant difference between the two groups concerning the changes in the self-management mean score (Table 3).

Table 3 shows that the intervention group's mean quality of life score increased from 40.50 ± 7.21 at baseline to 57.40 ± 6.84 three months after the intervention (Paired t-test: t = -16.15, df = 49, p < 0.001). However, this was not the case in the control group. Furthermore, the mean change in the quality-of-life score was significantly higher in the intervention group [16.90 ± 7.39] than in the control group (0.57 ± 2.99).

In the intervention group, the mean HbA1c values decreased from 8.29 ± 1.027 before the intervention to 6.28 ± 1.30 three months after the intervention (Paired t-test: t = 20.88, df = 49, p < 0.001). Compared to baseline, no significant change in the mean HbA1c value was observed in the control group after the intervention. In addition, the independent t-test showed that the mean change in HbA1c in the intervention group (-2.01 ± 0.68) was higher than in the control group (-0.30 ± 1.31) (Table 3).

In the intervention group, the mean FBS value decreased from 193.64 ± 65.49 at baseline to 127.96 ± 25.99 three months after the intervention (Independent t-test: t = 5.75, df = 97, p < 0.001). No significant change was observed in the mean FBS values in the control group after the intervention. The independent t-test also showed that the mean change in FBS values after the intervention was significantly different between the intervention (-65.68 ± 7.78) and the control groups (-9.59 ± 7.37) (Table 3).

Considering the intra-group comparison based on paired t-test, significant differences were found in the intervention group in terms of mean scores of waist circumference (WC), body mass index (BMI), systolic and diastolic blood pressure (SBP & DBP) after the intervention. In this group, the mean WC score decreased from 103.50 ± 11.01 before the intervention to 98.16 ± 9.77 three months after the intervention (t = 9.30, df = 49, p < 0.001). In addition, the mean score of BMI significantly decreased from 31.04 ± 5.38 to 29.58 ± 4.55 three months after the intervention (t = 6.43, df = 49, p < 0.001). Besides, the mean SBP score decreased from 122.40 ± 15.85 before the intervention to 113.60 ± 14.21 three months after the intervention (t = 5.21, df = 49, p < 0.001). Finally, the mean DBP score decreased from 77.80 ± 11.83 before the intervention to 71.50 ± 10.01 three months after the intervention (t = 0.11, df = 49, p < 0.001). Despite the slight differences observed in the baseline, the independent samples t-test revealed no significant differences between the two groups in terms of these variables both at baseline and three-month after the intervention. However, the mean changes in the scores of these variables, as shown by the independent samples t-tests, were significantly different between the two groups after the intervention (Table 3).

Regression analysis was performed to determine the extent to which the SCT constructs [independent variables] could explain the variance of quality of life [dependent variable] in the studied patients (Table 4). The results demonstrated that all the constructs, except for self-efficacy, could significantly explain and predict 40% of the variance of quality of life (R² = 0.476, adjusted R² = 0.402, F = 6.49, p < 0.001). Accordingly, each unit's increase in knowledge, self-management, social support, self-regulation, and outcome expectations improved the mean score of quality of life by 0.249, 0.406, 0.260, 0.280, and 0.401 folds, respectively.

This study aimed to determine the effect of an SCT-based educational program followed by home visits on self-management behavior, glycemic index, and quality of life among T2DM patients. The findings indicated that multidisciplinary intervention with home visits significantly improved self-management behavior, glycemic index, and quality of life among T2DM patients in the interventional group compared to the control group. Before the intervention, no statistically significant difference was observed between the intervention and control groups concerning the desired variables, showing that the changes in the study's primary outcomes favored the educational intervention.

The findings have revealed a significant increase in the mean scores of SCT constructs, including knowledge, social support, self-efficacy, outcome expectation, and self-regulation among T2DM patients. These findings are consistent with the results of Mazloomi [36], Borhaninejad [16], Bougar [37], Tan. Ming [38], and Schillinger [39]. Borhaninejad et al. reported a significant positive correlation between self-care and T2DM knowledge. Besides, diabetes knowledge predicted 57% of the variance of self-care behaviors (p < 0.001) [40].

In addition, the perceived social support of patients was better in the intervention group than in the control group after the educational intervention. Similar results were obtained by Mazloomi [36], Mayberry [41], and Wang [42]. Haidari also studied the effect of the relationship between family support and blood sugar control among older adults with T2DM and reported a significant negative correlation between family support and HbA1C level [43]. Mazloomi et al. explored the predictors of self-care behavior in 200 T2DM patients based on the SCT and revealed an increase in the perceived social support [36]. In the same vein, the results of a study conducted by the American Diabetes Association in 2017 to determine the relationship between family support and glycemic control and medication adherence in adults with Type 2 diabetes indicated that patients with lower family support had weaker control [41]. Madden’s study also demonstrated that the patients who communicate better with their family and friends had better control over their illness, reflecting the perceived social support of an emotional type [44]. Furthermore, Nicklett et al. stated that social support was strongly associated with adherence to diabetes diet therapy and played a crucial role in promoting health [45]. Wang also reported that self-care, medication, and adherence behaviors were much higher in the patients with T2DM who were supported by their families and friends than in those who were not [42].

Furthermore, the participants in the intervention group displayed a significant increase in self-efficacy, which was in line with the results of Borhaninejad [40], Mazlumi [36], and Nouwen [46]. Wichit also conducted a randomized controlled trial on a family-centered self-management program to improve self-efficacy, glycemic control, and quality of life among individuals with T2DM. The results demonstrated significantly better self-efficacy, self-management, outcome expectations, and knowledge of diabetes in the intervention group than in the control group [47]. Chih et al. indicated that adolescents with Type 1 diabetes with high self-efficacy were 1.63 times more likely to achieve glycemic control [48].

The outcome expectation level among the participants had a significant increase in the intervention group as well, which was consistent with the results of the studies performed by Wichit [47], Jalily [49], and Heidari-Soureshjani [12]. Jalily et al. investigated the predictors of nutritional behaviors based on the SCT in pregnant women. They reported that awareness, outcome expectations, outcome expectancies, and self-regulation could effectively help design educational interventions to achieve healthy eating behaviors in pregnant women [49]. Heidari-Soureshjani et al. also investigated 198 women with diabetes in Shahrekord. They demonstrated that following health behaviors [diet and physical activity] directly correlated with outcome expectations, self-efficacy, and self-regulation [12].

As another concept of social cognitive theory, a significant increase was also observed in the self-regulation level among the participants in the intervention group. Although we could find no similar interventional studies based on the SCT in T2DM patients, this finding agreed with those obtained by Cellar [50], Heidari-Soureshjani [43], and Borhaninejad [16]. The research results performed by Peyman et al. showed that educational intervention using self-regulatory strategies increased physical activity and improved blood sugar and body mass index in women with Type 2 diabetes [28]. Furthermore, Cellar emphasized that goal-setting skills had a strong positive effect on self-regulatory behaviors [50].

In the present study, the final outcome of SCT-based intervention on self-management behavior, glycemic index, and quality of life was also positive. Accordingly, the results showed that the change in the mean score of self-management behavior was significant in the intervention group compared to the control group, proving the continued use of the learned skills in the daily life plans of patients. In other words, the educational program based on the SCT followed by home visits concerning self-management behavior was effective in the intervention group. Borhani Nejad et al. disclosed that using a self-care education program based on the SCT promoted knowledge, self-efficacy, social support, outcome expectations, outcome values, and self-regulation among T2DM patients and increased their self-care [16].

The improved quality of life of the participants in the intervention group was another finding of the present study after the educational intervention. This finding was consistent with [36] and [51]. A study in China examined the effect of the nurses working in home-visit programs on disabled patients and their caregivers and revealed a significant improvement in the intervention group’s social, physical, mental, and life satisfaction after the intervention [52]. Authors in examined thirty-four samples in Turkey during six months of home visits. An improvement was reported in self-care among T2DM patients in the intervention group [53]. In another study assessing the effect of home visits on the quality of life of children and adolescents with Type 1 diabetes, the results indicated that home visits and training positively affected the self-care and quality of life parameters [54].

A comparison of HbA1C and FBS means before and three months after the intervention revealed a significant decrease in the intervention group compared to the control group. In addition, the means of SBP and DBP decreased in the intervention group. However, there was no significant difference between the two groups regarding the means of systolic and diastolic blood pressure. These findings were consistent with those of the studies performed by Chrvala [55], Steinsbekk [51], and Hosseini [56], indicating the prominent effect of education on HbA1C FBS and blood pressure. Systematic reviews by Chrvala et al. [55] and Steinsbekk [51] have also confirmed the positive effect of self-management training on reducing HbA1C.

In the present study, no significant difference was found in the two groups’ mean scores of anthropometric indices [body mass index and waist circumference] before and after the intervention. However, these scores were significantly reduced in the intervention group three months after the intervention. Similar results were also obtained by Ramli [57], Schwedes [58], Steinsbekk [51] and Han [25]. A systematic review and meta-analysis by Steinsbekk also indicated that self-management training significantly improved body weight in group-based diabetes self-management education compared to routine treatment and care among people with T2DM. However, no statistically significant difference was observed between the intervention [self-management training] and control [routine care] groups with respect to body mass index, blood pressure, and blood lipids [51]. In addition, the results of the systematic review by Cortez revealed the effectiveness of empowerment programs in improving HbA1C, metabolic indices, and diastolic blood pressure. However, no significant changes were observed in anthropometric variables [body mass index and waist circumference] and systolic blood pressure in the reviewed studies [59]. Furthermore, Ramli’s study in Brazil showed that empowerment and self-management interventions effectively improved clinical outcomes. In addition to achieving primary results [HbA1C less than 6.7%], patients achieved improvement in secondary outcomes [blood pressure, fat profile, body mass index, and waist circumference] [57], which was not in agreement with the present study findings.

The findings in this study suggest that some changes should be made in research and practice [service delivery] approaches regarding diabetes prevention and control. Changes should be made in routine patient education and care methods, comprehensive behavior change theories, interactive and client-centered approaches [33], and family involvement and support. As one of the critical components of comprehensive interventions, home visits are also strongly recommended. Furthermore, it is strongly recommended that further studies using socio-ecological theoretical frameworks and planning for long-term evaluation are warranted.