The aim of the COR-PRIM study was to demonstrate the better effectiveness of patient problem-based learning over home-sent patient information for evaluating long-term effects of patient empowerment and self-care in patients with CHD.

The COR-PRIM study was a prospective, randomised, parallel, and single centre study (NCT01462799) involving 157 patients with CHD in a primary care setting in south-eastern Sweden. The COR-PRIM study tested the hypothesis that 1 year of problem-based patient education improves a patients’ empowerment and self-efficacy, to change self-care significantly compared to 1 year of standardised home-sent patient information. Recruitment began in November 2011 and tests were performed at baseline [25] and one, three, and 5 years, which will be finalised in 2020, after completion of a one-year problem-based learning programme for patients with CHD. Here, we report only data from baseline and one-year follow-up, which was finally collected in 2015.

According to the COR-PRIM study, [19] the following inclusion criteria were used: (i) CHD verified by myocardial infarction and/or Percutaneous Coronary Intervention (PCI) and/or coronary artery by-pass surgery (CABG) within 12 months before planned start of the intervention irrespective of age; (ii) stable cardiac condition; (iii) optimised cardiac medication not substantially changed the previous month; and (iv) completed hospital heart school at one of the identified six primary health care centres. The following exclusion criteria were used: (i) planned CABG or other conditions demanding continuing cardiologic care such as on-going contact with heart failure clinic; (ii) life-expectancy ≤1 year; (iii) documented psychiatric disease impeding cooperation with other people; (iv) obvious abuse of alcohol or narcotics; and (v) inability to read or communicate in Swedish.

During a follow-up at hospital, nurses informed patients about the study and those patients who agreed to receive further information were contacted by the principal researcher by letter and telephone. Some patients voluntarily stated their reasons for not participating in the study – e.g., difficulties leaving work/home; long distance to the primary health care centres; and disapproval of group activity. The patients who agreed to participate, returned informed consent document and who had completed the baseline questionnaires were randomised (1:1 ratio) to either the experimental group (received problem-based learning) or the control group (received patient information leaflets delivered to the home address) before any intervention. The randomisation was carried out with sealed unmarked opaque envelopes and were assigned by an administrator in a room separated from the research and intervention area. We used a block of 18 study numbers that were blindly allocated to either problem-based learning or home-sent patient information [26]. The envelopes contained a unique number starting from number 1 that were hand-picked by an administrator who was blinded during this procedure.

All patients were offered a brief conventional cardiac rehabilitation programme at an outpatient clinic in hospital care that included counselling visits with a nurse and a cardiologist about 1 month and 6–12 months after discharge respectively; physical exercise 1–2 times per week, for 3–4 months and diet counselling. Additionally, patients were offered a day long heart school primarily focussing on CHD, medication, physical exercise, and diet. If the patient’s condition was stable, he or she was referred to a general practitioner in primary care. The conventional care provided and the design of the interventions are described below and in a previous paper [19]. Here, we provide a short description of the interventions.

The patients in the home-sent patient information group served as controls. After receiving conventional care, 6–9 patients per group met directly after randomisation in the primary health care centres to discuss self-care goals and follow-ups during the study year. Predetermined written patient information was provided [24] at this meeting to support self-care as suggested in brochures produced, for example, by The Swedish Heart and Lung Foundation. Next, the patient information was mailed to the patient’s home address at the same times as the problem-based meetings (explained below) during the study year. Finally, after 1 year of intervention the patients were invited to a focus-group interview to share their beliefs about their performance of self-care; experiences of the study materials and participating in the study.

The patients in the experimental group (6–9 patients/group) started the one-year problem-based learning intervention at a primary health care centre. There were 13 scheduled meetings, one in each of the following weeks 1, 2, 3, 4, 6, 8, 10, 12, 16, 20, 26, 39 and 52. Each meeting was for 2 h. The problem-based intervention was completed 1 year after start. The goal was to improve self-care by strengthening patient empowerment with a focus on understanding cardiac symptoms e.g. angina pectoris, swelling legs and dyspnoea, medications, and the health benefits associated with lifestyle changes regarding diet, physical activity, and mental health including depression, anxiety and fear. Nurses who were trained to tutor the patients in the problem-based learning process [27] were fundamental to this study. The nurses took part in a training session for 2 days given by the project team and later the nurses were tutored monthly by the authors, AKK and PT to discuss and develop their work. The training session included learning about tutoring, in problem-based learning regarding self-directed learning and problem-solving, to help patients to formulate issues and self-care goals. The patients used scenarios as triggers e.g. pictures, texts and concreate materials as a starting point for learning during the meetings. Moreover, the nurses supported the patients to choose learning materials and challenged patients to choose evidence-based literature. Resource professionals (e.g., physician and dietician) were invited to discuss questions not solved by the patients. Patients’ relatives were also invited to the meetings. During the final meeting, follow-up focus-group interviews were performed to collect data about patients’ beliefs about their performance of self-care and about their experiences of participating in the study. For further descriptions, see Kärner et al. [19].

The primary outcome was patient empowerment to reach self-care goals 1 year after randomisation. The questionnaires used to assess the primary and secondary outcomes are briefly presented here and more thoroughly elsewhere [25]. Patient empowerment was assessed using the Swedish-Coronary Empowerment Scale 10 which was developed to survey patient empowerment in patients with CHD. The Swedish-Coronary Empowerment Scale 10, based on the Swedish Diabetes Empowerment Scale 23, is a valid and reliable tool for assessing patient empowerment in patients with diabetes mellitus. The scale consists of four empowerment subscales: goal achievement, self-awareness, stress management and readiness to change. The Cronbach’s α-coefficient for the total Swedish Diabetes Empowerment Scale 23 ranged from 0.68 to 0.91 [28‐30]. The Swedish Diabetes Empowerment Scale 10, a shortened version of the Swedish Diabetes Empowerment Scale 23, was also found to be reliable with the Cronbach’s α-coefficient value α = 0.84. After securing approval from the author of the scale, we replaced the word ‘diabetes’ with ‘coronary heart disease’. The Swedish-Coronary Empowerment Scale 10 has four subscales: 1) Goal achievement and overcoming barriers to goal achievement; 2) Self-awareness; 3) Managing stress; and 4) Assessing dissatisfaction and readiness to change. The items are scored on a five-point Likert scale ranging from strongly agree (1) to strongly disagree (5). A higher value means a stronger patient empowerment [31]. Secondary outcomes were self-efficacy in general, [32] healthy diet, [33] and physical exercise [34, 35]. Self-efficacy was assessed using the General Self-efficacy Scale, which uses a four-point Likert scale ranging from not at all true (1) to exactly true (4). A higher score indicates a higher general self- efficacy. The General Self-efficacy Scale has been confirmed to be highly reliable, stable, and valid. The internal consistency of the scale was excellent with the Cronbach’s α-coefficient value α = 0.88 [36, 37]. Healthy diet was assessed using the Nutrition Self-efficacy Scale and physical exercise using the Physical Exercise Self-efficacy Scale, both which use a four-point Likert scale ranging from very uncertain (1) to very certain (4). A higher score indicates a higher Nutrition/Physical Exercise self-efficacy. The Nutrition Self-efficacy Scale and the Physical Exercise Self-efficacy Scale are assessed to be reliable and valid tools, with internal consistency values were α = 0.87 and 0.88 respectively [33]. Physical exercise was also assessed using Stages of Change Scale [34].Well-being [38] was assessed using the Cantril Ladder of Life, a single-item indicator with a ladder of steps numbered from zero at the bottom to 10 at the top. Zero means the worst possible life, and 10 the best. The patients also answer on which step they stood 1 year ago, one which step they stand at present and they are asked to predict on which step they will stand 1 year in the future. Cantril’s Ladder of Life is used in large populations and validity and test-retest coefficients of 0.70 have been reported [39]. This ladder has also been used in patients ≥65 years recovering from an acute coronary event [40]. The EuroQoL 5-dimensions scale, [41] is a reliable and valid tool for use in patients with CHD. The Cronbach’s α-coefficient value of the EuroQoL 5-dimensions scale indicated an acceptable internal consistency with a value of α = 0.73. Discriminative validity analyses have confirmed that this scale distinguished well between patient groups with a different age, gender, or educational level. Self-rated health was measured by a Visual Analogue Scale within the EuroQoL 5-dimensions scale. This scale makes scores of 0–100, with higher scores indicating a better overall quality of life [42]. The Visual analogue Scale is easy to administer and produce stable intraclass correlations score (0.79) showing acceptable reliability, and satisfactory validity in patients with acute coronary syndrome [43]. Blood pressure, BMI, waist size, and blood tests were used at follow-up to measure effects of self-care. Primary and all secondary outcome data were included in the intention-to-treat analysis, which means that [44] all randomised patients in the groups which they were randomly assigned to were included in the analysis, regardless from deviation from protocol.

As presented in Fig. 1, all 157 patients were randomised and assigned to the problem-based learning intervention group (n = 79) or to home-sent patient information group (n = 78). No patient died during the study year. In the problem-based learning group, losses to one-year follow-up were due to missing the one-year visit (n = 32) and failure to submit questionnaires (n = 38). The patients participated in the problem-based learning intervention for a median of eight occasions of 13 (range 4–11). Seven patients did not attend the problem-based learning sessions but are included in the intention - to - treat analysis. Table 1, shows that there were no significant differences between the two study groups with respect to sociodemographic and clinical baseline characteristics.

Table 2 shows that patient empowerment as assessed with the Swedish-Coronary Empowerment Scale − 10 did not significantly differ between the problem-based learning group and the home-sent patient information group after 1 year.

Table 2 shows that self-efficacy – assessed by The General Self-efficacy Scale, the Nutrition Self-efficacy Scale and the Physical Exercise Self-efficacy Scale – did not significantly differ between the problem-based learning group and the home-sent patient information group after 1 year. Well-being (assessed by the Cantril Ladder and EuroQoL 5-dimensions) and Self-rated Health (assessed by EuroQoL-Visual Analogue Scale) showed no significant differences between the problem-based learning group and the home-sent patient information group after 1 year. There were no differences between the groups regarding stages of change.

Table 3 shows that there was significant weight loss and therefore lower BMI in the problem-based learning group compared to the home-sent information group after 1 year. There was also a significant increase in HDL cholesterol favouring the problem-based learning group.

In this study we tested a problem-based learning intervention [22], where the patients chose their own learning material according to own preferences and in line with the problems they discussed during the physical meetings in primary care. Problem-based learning was the foundation for the learning process, which was tested against the control group. The control group was informed by predetermined written patient information, based on a traditional model of information transferred to individuals [24]. In that way we compared the two pedagogical models.

We hypothesised that 1 year of problem-based patient education improves a patient’s self-efficacy, and patient empowerment to change self-care significantly compared to 1 year of standardised home-sent patient information. This study showed no effects on the Swedish-Coronary Empowerment Scale 10 that could be explained by the problem-based learning intervention. However, the problem-based learning intervention had a positive impact on secondary outcomes, weight loss and BMI. Also, the HDL cholesterol mean level was significantly increased after 1 year compared to the controls (i.e., home-sent patient information). These results are positively related to the problem-based learning group and should be interpreted cautiously as secondary outcomes have limited generalisability. Nonetheless, we interpret these results as an indication that a problem-based learning intervention provided by trained nurses may improve these risk factors after CHD when patients meet in groups in primary care. This result may also be due to that the problem-based learning intervention included consultations with physician and dietician, an offer that the controls were not given. When comparing our results with a review of patient education studies, [10] it can be stated that educational interventions significantly improve dietary and physical activity habits. However, it is not possible to conclude what intervention is most effective as most the interventions are poorly described. A strength of our study is that the intervention is thoroughly described [23]. To minimise large differences between usual care and the problem-based learning intervention, we offered the control group the similar information with parallel intervals as the experimental group. The controls had to have a pedagogical challenge so that problem-based learning was not tested against only usual care. We cannot guarantee that the controls read or used the written materials they were offered, and that is not the point with our study. Instead, we want to emphasise patients to take control of their own life and their recovery i.e. be empowered and manage their health. Another strength with this study is that the randomisation was well performed, and that the problem-based learning intervention group and the home-sent patient information group did not significantly differ regarding baseline characteristics.

Despite that the COR-PRIM study was performed in accordance with the design article, [19] we acknowledge that the patients were highly selected in regard to patient empowerment and losses to follow-up were large. Of 446 eligible patients 35% (n = 157) consented to participate in the study, which may be considered as low. Reasons for declining participation included that the patients already felt empowered, so they did not believe they needed the intervention, which was quite demanding as the group discussions were scheduled for 1 year and there was a five-year follow-up. Problems with emphasising patients to join cardiac rehabilitation is not new [49]. Only 20–50% of eligible patients attend cardiac rehabilitation that could facilitate physical exercise and other effective preventive actions. Despite major efforts to increase the numbers of patients taking part in cardiac rehabilitating this has not improved in the last 20 years [50]. However, we believe that the patients who chose to be included in our study felt that they needed more support after hospital care. This indicate that joining peer-groups after CHD fills a place within cardiac rehabilitation [51, 52].