Patient’s adherence to protein and phosphorus regimens was examined using the BUN index. Receiving adequate calories and energy through carbohydrate and fat intake and receiving alternative supplements for protein in the diet were examined by checking BUN and albumin levels. Patient’s adherence to fluid and sodium consumption restrictions were assessed by examining IWG and the sodium index. Also, the patient’s adherence to regular dialysis attendance, diet, and drugs was assessed by examining phosphorus, potassium, sodium, and calcium levels, and IWG.

BUN levels over 100.0 mg/dL indicated nonadherence to a low-protein diet. Potassium levels over 6.5 mEq/L indicated nonadherence to a low potassium diet whereas potassium levels 5.6–6.5 mEq/L showed average adherence and potassium levels 3.5–5.5 mEq/L indicated good adherence. A serum phosphate level over 6.5 mg/dL indicated nonadherence to a low phosphate diet and medication regimen, 4.6–6.5 mg/dL indicated average adherence, and 2.5–4.5 mg/dL indicated good adherence. A normal calcium range and adherence was considered between 8.5–10.5 mg/dL (lower was considered nonadherence). A normal sodium range and adherence was considered between 135.0–145.0 mg/dL (higher was considered nonadherence). A severe loss of albumin was a level less than 3.0 mg/dL, an average loss of albumin was 3.0–3.5 mg/dL, and a normal albumin level was more than 3.5 mg/dL and were considered as nonadherence, average adherence, and good adherence, respectively. If the weight difference between two consecutive sessions of hemodialysis was more than 3.0 kg, it showed that the patient did not adhere to restrictions on fluid intake. A weight difference between two hemodialysis sessions of 1.6–3.0 kg represented average adherence, and a weight difference in the range of 1.0–1.5 kg represented good adherence to fluid intake.3 All laboratory tests were done at Vali-Asr Hospital Laboratory with the same equipment. It must be noted that the scales used for weighing patients in both groups were identical and their accuracy was evaluated before each use.

Biochemical indicators and IWG at baseline were measured in the fourth, eighth, and the twelfth week of the study in both experimental and control groups.

At baseline, in the experimental group, according to a preliminary collection of biochemical indicators and IWG, the problem of nonadherence to treatment became clear. Based on the patient’s needs, two to three face-to-face counseling sessions for each patient were held in the hospital educational classroom. Through in-person meetings, problems related to treatment adherence were identified. Then, via these sessions and under the guidance of researchers, patients could choose the best solution for their nonadherence problem. In addition, based on the information given by the patient and biochemical indicators, which were measured monthly for each patient in the experimental group, a diet with multiple options was designed by a dietitian and given to the patients at the beginning of the intervention, and in the fourth and eighth week of the research.

After in-person consultations, follow-up consultations were conducted by phone. During phone conversations, patients’ adherence to the treatment programs (adhering to dietary restrictions and fluid intake, the timely taking of medicines, and regular attendance for hemodialysis) were evaluated at regular intervals. Phone follow-up for the experimental group was 28 phone calls over 12 weeks (in the first four weeks three calls per week and in the remaining eight weeks two calls per week). On average, phone talk time was 10 to 15 minutes. In these conversations, patients were evaluated in all aspects of treatment adherence and treatment program, their questions were answered and, if there was a problem, appropriate and various solutions were suggested so that they could choose among them. Nurse researcher and dietitian’s phone numbers were available to all patients, so they could call if necessary and ask about their problem.

In the control group, there was no special nurse in charge of educating patients and tracking their treatment adherence. Patients received their information from different nurses; thus, these pieces of information were not consistent and ongoing. Patients recently recommended for hemodialysis treatment received general education about hemodialysis (including diet, mobility rates, and fistula and shunt care) at the beginning of their introduction to the hemodialysis ward. During the hemodialysis period, according to the results of the patients’ biochemical indicators, the patients were notified about following the diet, medication, and attendance at dialysis sessions by the doctor or nurses present in the ward, but the reasons for the patients’ nonadherence were not negotiated. However, to observe ethical considerations in this research, a booklet was given to the patients in the control group. This booklet contained information about diet, fluid restrictions, and the importance of regular drug use and regular presence in dialysis sessions. If the patients in the control group had questions about the information of the booklet, the researcher would answer these questions.

For data analysis, descriptive statistics (frequency, mean, and standard deviation) was used. The Kolmogorov-Smirnov test was used to review the test data for normality. Chi-square test and Fisher’s exact test were used to compare the biochemical indicators and IWG in the experimental and control groups. Friedman and Cochran’s Q tests were employed to evaluate the changes within the experimental and control groups during the four time points of the variable under study.

Results

In this study, all 86 patients assessed were assigned to the two groups. Each group consisted of 43 patients, and all 86 patients completed the study. The mean age of the patients was 52.5±11.3 years, over half (55.8%) were male, and the majority (82.6%) did not have a high school diploma. Most (43.1%) were undergoing hemodialysis for one to two years. The demographic characteristics were not significantly different between the two groups [Table 1].

At baseline, comparing indices of sodium, phosphorus, calcium, BUN, and IWG using the chi-square test, and potassium and albumin with Fisher’s exact test showed that the differences in these indices were not statistically significant [Tables 2 and 3] in either group.

In the fourth week of the study, comparing calcium index between the two groups using Fisher’s exact test and IWG with the chi-square test showed significant differences. However, in the BUN index, there were no significant differences between the experimental and control groups when using the chi-square test, and sodium index, potassium, phosphorus, and albumin indices with Fisher’s exact test [Tables 2 and 3].

In the eighth week of study, comparing calcium, phosphorus, potassium, and IWG indices between the two groups using Fisher’s exact test and BUN index with chi-square test revealed significant differences between the two groups suggesting increased adherence in the experimental group. Comparing sodium and albumin indices using Fisher’s exact test showed no statistically significant differences between the experimental and control groups [Tables 2 and 3].

In the twelfth week of study, comparing potassium, phosphorus, calcium, albumin, and IWG indices between the two groups using Fisher’s exact test indicated statistically significant differences. However, comparing sodium and BUN indices using Fisher’s exact test demonstrated no statistically significant difference between the groups [Tables 2 and 3].

Intra-group comparison of indices changes in potassium, phosphorus, albumin, and IWG at the four time-points of the study (baseline, fourth, eighth, and twelfth weeks) in the experimental group using the Friedman test found statistically significant differences, suggesting an increased adherence. In the control group, intra-group changes were not statistically significant [Tables 2 and 3].

To investigate the effect of the intervention on biochemical indicators at the four time points of the study, we used generalized estimating equations (GEE). GEE results showed that the effect of the intervention on potassium, phosphorus, IWG, albumin, and calcium indices were statistically significant. The intervention had no significant statistical effect on sodium, blood urea, and nitrogen indices [Table 4].

Discussion

Counseling and phone follow-up led to the improvement of calcium index and IWG in the experimental group in the fourth week. In the eighth week of the study, calcium, phosphorus, potassium, BUN, and IWG indices in the experimental group had a favorable condition compared to the control group. By the twelfth week, in the experimental group, calcium, phosphorus, potassium, albumin, and IWG were still within the recommended treatment adherence range and showed a statistically significant difference when compared to the control group. Intervention in the experimental group resulted in an improvement of most biochemical indicators and IWG over the 12-week study. Reviewing the biochemical indicators in the eighth and twelfth weeks after the intervention showed that most patients in the experimental group (when compared with the control group) were at good adherence level in terms of potassium index. Our result is inconsistent with the results of two other studies, which reported that patients’ potassium index in the experimental group was in the normal range following educational interventions.23,24 In both studies, educational and nutritional sessions were held to increase adherence. Face-to-face teaching methods and video playback were used to enhance the effectiveness of these studies. In the current study, having the choice of the recommended nutritional items and mutual interaction between researchers and patients led to the active participation of patients in their health care and consequently increased adherence.

Low treatment adherence often results in increased serum potassium and phosphorus levels.9 Analyzing the data regarding phosphorus index showed that phosphorus levels of patients in the experimental group was significantly reduced. No patients in the experimental group in the twelfth week after the intervention had nonadherence regarding phosphorus index, which was associated with following the low-phosphorus diet and medication regimen. This result concurs with the results of two other studies, which concluded that implementing educational intervention and self-care education led to diet compliance.25,26 Moreover, a decrease in phosphorus level demonstrates that nurses conducting educational interventions can play an important role in controlling phosphorus levels and complications related to its inappropriate control.25,26 Nursing consultation and a patient’s active role and engagement in clinical decisions leads to an increase in the patient’s awareness and understanding level, leading to improved treatment adherence.16

In our study, patients’ reduction in IWG in the experimental group was statistically significant compared with the control group. Another study concluded that educational intervention reduced IWG in hemodialysis patients.19 However, there was no follow-up in the study.19 A similar study concluded that better control of IWG is achieved if educational services are accompanied with follow-up in hemodialysis patients.27 In our study, frequent follow-up phone calls were affecting factors in reducing IWG for patients in the experimental group, which caused the patients to attend dialysis sessions regularly.

There was no statistically significant difference in blood albumin between the two groups at the beginning of the intervention and four and eight weeks after. Nevertheless, this difference was significant in the twelfth week after the intervention and a greater percentage of patients in the experimental group were within the normal albumin range. Two studies found no significant differences in the mean albumin range before and after the educational intervention.23,26 One of the reasons for the positive effect of the intervention we observed on albumin range might be due to the follow-up phone calls, which increased treatment adherence. Similarly, another study found a significant difference in mean albumin levels before and after the educational intervention. The authors of this study also used the continual care model, which showed the positive effect of follow-up on improving adherence in hemodialysis patients.28 In our study, in addition to frequent follow-up, we included carbohydrates and fats as sources of energy in the diet to improve albumin levels. The calcium level of the participants was also modified and reached normal levels as a result of modifying the albumin levels (due to nutritional counseling). Regular attendance, attending all dialysis sessions, and full implementation of the pharmacological recommendations by patients were other factors leading to the changes in blood calcium in the intervention group.

There was no statistically significant difference in the blood sodium levels of the two groups at baseline, and the fourth, eighth, and twelfth weeks of the study. This result is consistent with other studies, which found no significant difference in the sodium range after the intervention.26,27 This lack of difference was because, at baseline, sodium levels in more than 90% of patients in both groups were within the normal range. Although the level of BUN was decreased at four, eight, and 12 weeks after the intervention, only BUN levels at week eight were statistically significant. Although the two indices of sodium and BUN were not statistically significant between the two groups, providing the patients with a monthly diet together with continuous counseling was able to reduce other biochemical indicators and IWG.

Intra-group comparison of biochemical indicators and IWG changes from baseline to 12-weeks post-intervention showed that the experimental group experienced an increase in adherence. However, in the control group by the twelfth week, no statistically significant change was observed in treatment adherence. This result suggests that counseling and frequent phone follow-up in the studied group increased adherence and, in turn, improved biochemical indicators and IWG in the experimental group.

Considering that 82.6% of participants in this study had a low level of education, the study intervention was effective due to the continuous relationship between the researcher and the patients in increasing adherence. Asking patients to participate in identifying any misunderstandings and misconceptions about treatment adherence improved their compliance.

One of the major limitations of this study was the irregular attendance of some patients due to economic reasons, which overshadowed patient treatment adherence. Random allocation was performed to modify the confounding effect of the patients’ economic problems in this research. The other limitation of this study was the low sample size, which limits the generalizability of this study. Hence, a similar study design with high sample size is recommended.

Conclusion

Consultation and follow-up phone calls in hemodialysis patients are suggested because they improve patient adherence and, as a result, their biochemical indicators. We recommend that nurses in hemodialysis centers are in charge of conducting patient follow-up by phone so that they can monitor patients’ diet and treatment adherence. Also, we recommend applying this intervention in low-literacy hemodialysis patients to control biochemical indicators and IWG.

Disclosure

The authors declared no conflict of interests. This study was supported by a research grant from Zanjan University of Medical Sciences.

Acknowledgements

The current research forms a part of the MSc thesis of the second author. The researchers of this study express their sincere thanks to the Vice-chancellery for Research of Zanjan University of Medical Sciences due to his financial support for this project, to all staff in hemodialysis ward of Vali-Asr Hospital in Zanjan city and to honorable hemodialysis patients.

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