Hostname: page-component-586b7cd67f-vdxz6 Total loading time: 0 Render date: 2024-11-20T07:25:49.211Z Has data issue: false hasContentIssue false

The feasibility of a peer support intervention to encourage adoption and maintenance of a Mediterranean diet in established community groups at increased CVD risk: the TEAM-MED EXTEND study: a pilot cluster randomised controlled trial

Published online by Cambridge University Press:  07 October 2021

Roisin F. O’Neill*
Affiliation:
Centre for Public Health, Queen’s University Belfast, Institute of Clinical Sciences, A, Grosvenor Road, Belfast BT12 6BJ, UK
Laura McGowan
Affiliation:
Centre for Public Health, Queen’s University Belfast, Institute of Clinical Sciences, A, Grosvenor Road, Belfast BT12 6BJ, UK
Claire T. McEvoy
Affiliation:
Centre for Public Health, Queen’s University Belfast, Institute of Clinical Sciences, A, Grosvenor Road, Belfast BT12 6BJ, UK Trinity College Dublin, Global Brain Health Institute, Dublin, Ireland
Sara Megan Wallace
Affiliation:
Centre for Public Health, Queen’s University Belfast, Institute of Clinical Sciences, A, Grosvenor Road, Belfast BT12 6BJ, UK
Sarah E. Moore
Affiliation:
Centre for Public Health, Queen’s University Belfast, Institute of Clinical Sciences, A, Grosvenor Road, Belfast BT12 6BJ, UK
Michelle C. McKinley
Affiliation:
Centre for Public Health, Queen’s University Belfast, Institute of Clinical Sciences, A, Grosvenor Road, Belfast BT12 6BJ, UK UK Clinical Research Collaboration, Centre of Excellence for Public Health, Queen’s University Belfast, Grosvenor Road, Belfast BT12 6BJ, UK
Frank Kee
Affiliation:
Centre for Public Health, Queen’s University Belfast, Institute of Clinical Sciences, A, Grosvenor Road, Belfast BT12 6BJ, UK UK Clinical Research Collaboration, Centre of Excellence for Public Health, Queen’s University Belfast, Grosvenor Road, Belfast BT12 6BJ, UK
Margaret E. Cupples
Affiliation:
Centre for Public Health, Queen’s University Belfast, Institute of Clinical Sciences, A, Grosvenor Road, Belfast BT12 6BJ, UK UK Clinical Research Collaboration, Centre of Excellence for Public Health, Queen’s University Belfast, Grosvenor Road, Belfast BT12 6BJ, UK
Ian S. Young
Affiliation:
Centre for Public Health, Queen’s University Belfast, Institute of Clinical Sciences, A, Grosvenor Road, Belfast BT12 6BJ, UK UK Clinical Research Collaboration, Centre of Excellence for Public Health, Queen’s University Belfast, Grosvenor Road, Belfast BT12 6BJ, UK
Jayne V. Woodside
Affiliation:
Centre for Public Health, Queen’s University Belfast, Institute of Clinical Sciences, A, Grosvenor Road, Belfast BT12 6BJ, UK UK Clinical Research Collaboration, Centre of Excellence for Public Health, Queen’s University Belfast, Grosvenor Road, Belfast BT12 6BJ, UK
*
*Corresponding author: Roisin O’Neill, email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

This study aimed to evaluate the feasibility of a peer support intervention to encourage adoption and maintenance of a Mediterranean diet (MD) in established community groups where existing social support may assist the behaviour change process. Four established community groups with members at increased Cardiovascular Disease (CVD) risk and homogenous in gender were recruited and randomised to receive either a 12-month Peer Support (PS) intervention (PSG) (n 2) or a Minimal Support intervention (educational materials only) (MSG) (n 2). The feasibility of the intervention was assessed using recruitment and retention rates, assessing the variability of outcome measures (primary outcome: adoption of an MD at 6 months (using a Mediterranean Diet Score (MDS)) and process evaluation measures including qualitative interviews. Recruitment rates for community groups (n 4/8), participants (n 31/51) and peer supporters (n 6/14) were 50 %, 61 % and 43 %, respectively. The recruitment strategy faced several challenges with recruitment and retention of participants, leading to a smaller sample than intended. At 12 months, a 65 % and 76·5 % retention rate for PSG and MSG participants was observed, respectively. A > 2-point increase in MDS was observed in both the PSG and the MSG at 6 months, maintained at 12 months. An increase in MD adherence was evident in both groups during follow-up; however, the challenges faced in recruitment and retention suggest a definitive study of the peer support intervention using current methods is not feasible and refinement based on the current feasibility study should be incorporated. Lessons learned during the implementation of this intervention will help inform future interventions in this area.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - SA
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike licence (https://creativecommons.org/licenses/by-nc-sa/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the same Creative Commons licence is included and the original work is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use.
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of The Nutrition Society

Epidemiological evidence suggests that adherence to a Mediterranean diet (MD) is associated with a reduction in the risk of Cardiovascular Disease (CVD), Type 2 Diabetes and Metabolic Syndrome(Reference Sofi, Macchi and Abbate1Reference Soltani, Jayedi and Shab-Bidar4); a systematic review – pooling available cohort studies – suggests a 10 % (relative risk = 0·90; 95 % CI 0·87, 0·92) reduction in CVD risk(Reference Sofi, Macchi and Abbate1) and a 10 % (relative risk = 0·90; (95 % CI 0·89, 0·91) reduction in overall mortality per two-point increase in an MD adherence score(Reference Soltani, Jayedi and Shab-Bidar4). The exact mechanism for this reduction in disease risk is unknown; however, adherence to an MD is associated with improvements in risk factors for both CVD and diabetes, including blood pressure, lipids, biomarkers of inflammation and insulin resistance(Reference Tosti, Bertozzi and Fontana5,Reference Billingsley and Carbone6) . Experimental research supports these findings: in a population at increased risk of CVD, the Prevención con Dieta Mediterránea trial demonstrated that adoption of an MD led to an approximate 35 % (hazard ratio 0·65; 95 % CI 0·50, 0·85) reduction in CVD incidence and a 52 % (hazard ratio 0·48 (95 % CI 0·27, 0·86)) reduction in Type 2 Diabetes within the MD intervention arm (supplemented with nuts or extra virgin olive oil) compared with the low-fat diet control arm(Reference Salas-Salvadó, Bulló and Babio7,Reference Estruch, Ros and Salas-Salvadó8) .

Within such interventions, intensive methods – usually delivered by healthcare professionals – were required to encourage dietary behaviour change commensurate with an MD(Reference Salas-Salvadó, Bulló and Babio7Reference Logan, Woodside and Young10). Such strategies are not practical or cost effective when considering a population-level approach to behaviour change; however, peer support offers a potential alternative and less costly approach(Reference Funnell11,Reference Parry and Watt-Watson12) . Peer support may encourage behaviour change via the utilisation of social support and social networks between individuals; a peer supporter (PSR) is an individual with similar characteristics to the target population ‘who possesses experiential knowledge of a specific behaviour or stressor’ and can provide ‘emotional, appraisal, and informational assistance to address a health-related issue(Reference Dennis13). Many peer support approaches exist, including face-to-face, online, telephone and individual peer coaching(Reference Heisler14,Reference Dale, Williams and Bowyer15) ; however, qualitative research suggests that a group-based peer support approach is the preferred method to encourage a population at high risk of CVD towards adoption of an MD(Reference Erwin, McEvoy and Moore16).

The Trial to Encourage Adoption and Maintenance of a Mediterranean Diet

This intervention was designed by our research team to test a group-based peer support programme and compare it with a proven intensive dietitian-led MD intervention and a minimal MD education intervention for encouraging adoption of the MD in adults at high CVD risk in Northern Ireland (NI)(Reference McEvoy, Moore and Appleton17). Due to the individual level randomisation process, study participants within the peer support intervention arm were recruited and randomised independently, resulting in newly established groups with individuals varying by characteristics such as age, gender and socioeconomic status. This individual-level randomisation also led to a delay in initiation of the intervention, which did not begin until enough participants had been randomised to the peer support intervention, to allow the formation of a group(Reference McEvoy, Moore and Appleton17).

Research suggests that already established groups may have greater social cohesion and engagement compared with members in newly formed groups and the leveraging of existing social networks between members may enhance the effectiveness of peer support strategies to further encourage behaviour change(Reference Erwin, McEvoy and Moore16,Reference Hunt, Wyke and Gray18,Reference Hunt, Gray and Maclean19) . This is supported by published qualitative data in individuals at increased risk of CVD which suggests that effective peer support groups develop from individuals who consider each other ‘similar’ and can develop trust and honesty within their groups(Reference Erwin, McEvoy and Moore16). This led the research team to consider the effect of the TEAM-MED intervention in already established groups leading to the design of the TEAM-MED EXTEND feasibility study.

TEAM-MED EXTEND

The aim of this study was to determine the feasibility of the TEAM-MED peer support intervention to encourage adoption and maintenance of an MD(Reference McEvoy, Moore and Appleton17), in established community groups, in comparison with a less intensive MD minimal education intervention (control). This paper provides an overview of the study design, implementation strategy and outcomes assessed including the adoption of an MD (assessed by a change in MDS at 6 months from baseline (adoption) and change in MDS at 12 months from 6 months (maintenance)). We consider the challenges faced in implementation and adoption of this intervention in an established community group setting and consider the modifications necessary for the development of future group-based peer support interventions in populations at risk of CVD.

Methods

Study design

This pilot study employed a Cluster Randomised Controlled Trial design over a 12-month study period and was conducted according to the guidelines laid down in the Declaration of Helsinki. All procedures involving human participants were approved by the Research Ethics Committee for the School of Medicine, Dentistry and Biomedical Sciences, Queen’s University Belfast (Ref: 15·25.v5) and the trial also conforms to the Consolidating Standards of Reporting Trials statement’s(Reference Campbell20) extension to randomised pilot and feasibility trials(Reference Eldridge, Chan and Campbell21) – a checklist is included in the appendices.

Eligibility and recruitment

Recruitment was completed between January and June 2016. The recruitment strategy employed a similar approach to the original TEAM-MED study, which included the dissemination of email and media releases to community organisations through local community links in NI(Reference McEvoy, Moore and Appleton17).

An ‘established’ community group was defined as a group or network drawn from one community, containing regular service users and if possible homogenous sex. Interested groups contacted the research team to arrange for further information and a researcher attended to provide participant information sheets and a comprehensive overview of the study to community group members. Researchers then returned to screen individual group members and determine eligibility for groups and participants wishing to proceed. The individual screening process included a personal health and medical history questionnaire to determine CVD risk and a fourteen-item MDS questionnaire – to determine the baseline adherence to an MD. This is similar to the MD score used in the Prevención con Dieta Mediterránea study(Reference Estruch, Ros and Salas-Salvadó8) but has been modified to reflect the diet of an NI population(Reference McEvoy, Moore and Appleton17).

We intended that 75 % of community group members drawn from a given group (for example: a Men’s Shed or a Women’s Group) should be eligible in order for the overall group to be eligible to participate, with a target of recruiting 10–12 eligible participants per community group. Ineligible group members were welcome to participate in PS sessions if their community group was randomised to the Peer Support Group (PSG), but these individuals had no further contact with the research team post screening.

Inclusion & exclusion criteria – individual screening

Both peer supporters (described below) and community group members were eligible to participate if they were (a) aged ≥ 40 years; (b) had a Mediterranean Diet Score (MDS) ≤ 3 and (c) had at least one CVD risk factor as detailed in Table 1. The exclusion criteria included (a) a diagnosis of Diabetes Mellitus (excluded only if receiving oral medication or insulin treatment), (b) established CVD, (c) any medical conditions or dietary restrictions that would substantially limit ability to complete the study requirements, (d) inability to provide informed consent and (e) community groups led by health professionals. A detailed overview of the inclusion and exclusion criteria for this two-phase recruitment process is presented in Table 1. Written informed consent was obtained from all eligible individuals agreeing to participate in the study.

Table 1. Study inclusion and exclusion criteria for community groups, group members and peer supporters

* Modified from an initial requirement of an MDS score ≤ 3.

Recruitment and training of peer supporters

This is discussed in detail elsewhere(Reference McEvoy, Moore and Appleton17). Briefly, recruitment of PSR was completed separately to community group recruitment via the dissemination of a poster advertisement to community organisations and networks in NI. The screening process for PSR was similar to that of the community group participants (discussed above); however, eligible PSR also completed an interview (by the research team) to determine their commitment to participate and to identify if they had the attributes desirable for the PSR role; the peer supporters were not familiar with their allocated community group at the outset of the study, and this interview was used to facilitate the pairing of PSR to the most suitable community group, ensuring – as much as possible – that the PSR had similar characteristics to their allocated community groups, increasing the likelihood that they would be welcomed as peers by the community groups. The training provided was identical to that delivered in the previous intervention(Reference McEvoy, Moore and Appleton17). Two PSR were allocated per community group randomised to the intervention; where possible, one had experienced success in making positive changes to their diet and the other was familiar with group facilitation. Two additional PSR were recruited to act as reserves for either group if required.

Randomisation

Post-screening, eligible community groups were randomly allocated to either the PSG or a Minimum Support Group (MSG) (control) using a computer-based random allocation sequence generator (IBM Corp. Released 2016. IBM SPSS Statistics for Windows, Version 24·0. IBM Corp), which was performed by an independent member of the research team not involved in the screening or data collection process. The Centre/Project manager was informed of group assignment, and study participants were informed individually after their baseline measurements were completed.

Peer Support Intervention

The intervention was developed using the Medical Research Council’s guidance for developing complex interventions(Reference Craig, Dieppe and Macintyre22) and is based on the social support model in healthcare(Reference Dennis13,Reference Cohen, Underwood and Gottlieb23) ; this has been described in detail elsewhere(Reference McEvoy, Moore and Appleton17). Explicit Behaviour Change Techniques incorporated into the intervention included social support, goal-setting, self-monitoring and problem-solving(Reference Michie, Richardson and Johnston24,Reference Michie, Ashford and Sniehotta25) . The intervention consisted of eleven ∼2-h peer support sessions, conducted within the usual community group venue, designed to be interactive and non-directive with a focus on discussion and the sharing of experiences between the PSR and the group: these sessions were delivered at week 0 (baseline), week 2, week 4, week 6 and month 2, month 3, month 4 and month 6 during an initial intense phase and then months 8, 10 and 12 during the latter maintenance phase(Reference McEvoy, Moore and Appleton17). All sessions began with an MD educational component delivered by the PSR and topics covered included: ‘Health benefits of a MD’, ‘Enjoying Fruit & Vegetables’, ‘Eating more Wholegrain’, ‘Eating a Seasonal MD’ & ‘Shopping for a MD’. Practical demonstrations including tasting sessions of MD foods and dishes were incorporated throughout the intervention (during n 4 of the 11 sessions). Each participant was provided with a range of MD educational resources including written educational materials providing information on the MD, the health benefits of an MD and practical support to facilitate adoption of this dietary pattern including recipe books, shopping lists and meal plans. A workbook to facilitate goal setting and self-monitoring throughout the intervention was also provided to participants. PSR were trained to encourage participants to set Specific, Measureable, Achievable, Realistic & Time-based (SMART) goals at each intervention session(Reference Locke and Latham26,Reference Tosi, Locke and Latham27) .

Minimum Support Group

Participants within the community groups randomised to the MSG arm (n 2) received written educational literature, developed by the research team for the TEAM-MED study(Reference McEvoy, Moore and Appleton17) on the food components of the MD, seasonal recipe ideas, meal plans and shopping lists after their baseline visit. MSG participants received no further input, only follow-up data collection visits at 3, 6 and 12 months.

Study evaluation

The feasibility of the intervention was assessed using recruitment and retention rates, participant engagement (via attendance records of PS sessions), end-of-study evaluation measures (designed for the TEAM-MED intervention and including MD tolerance and group cohesion questionnaires (PSG only)). We also invited all participants randomised to the PSG – as well as the PSR – to complete a post intervention structured interview at study endpoint to assist in our process evaluation. These were completed either in-person (on a one-to-one basis) at the end of the final measurement visit or by phone within a week of the final visit if more convenient for the participant and took approximately 20 min to complete. Intervention fidelity was determined by (1) the standardisation of intervention delivery with a two-day training course provided to all PSR at the start of the study; (2) structured post-session phone calls with each PSR to offer support and answer questions in an effort to minimising drift in skills and knowledge acquired during the training course; (3) the observation (by a member of the research team) of three intervention sessions to ensure the monitoring of intervention delivery and consistent implementation across and between intervention groups and (4) attendance recorded at each session to determine the engagement of each group participant to the intervention.

Outcome assessment

Outcome measurements were collected to explore the variability of outcomes to inform a larger study and test the acceptability of the measurement tools used. The primary outcome of interest was adoption of an MD assessed by a change in MDS at 6 months from baseline (adoption) with change in MDS at 12 months from 6 months (maintenance) as a secondary outcome. MDS were determined using a fourteen-item questionnaire, similar to that used in the Prevención con Dieta Mediterránea study(Reference Estruch, Ros and Salas-Salvadó8) but modified for an NI population(Reference McEvoy, Moore and Appleton17). The MDS used in this study has been validated with MDS from previous studies(Reference Sofi, Macchi and Abbate1,Reference Logan, Woodside and Young10,Reference Trichopoulou, Costacou and Bamia28) and has demonstrated moderate agreement between this tool and the score used in the Prevención con Dieta Mediterránea study thus providing a potentially valid tool for determining MD adherence in a Northern European population. Secondary outcomes included changes in nutrition and health markers at follow-up from baseline, including anthropometry – weight (to the nearest 0·1 kg using Tanita HS-301 calibrated scales) and height (to the nearest 0·1 cm using a portable Stadiometer), both of which were used to calculate BMI (kg/m2), waist and hip circumference measurements (using a flexible tape measure to the nearest 0·1 cm), blood pressure (using a calibrated automated sphygmomanometer (Omron M5–1, OMRON Healthcare UK Ltd., Milton Keynes, UK)), dietary intake (4-d estimated food diary) and MD Knowledge using an MD Knowledge questionnaire(Reference Parmenter and Wardle29). Spot non-fasting urine and saliva samples (Greiner Bio-One Saliva Collection System) were collected at each time point for the future analysis of objective measures of nutritional status and CVD-related biomarkers. Physical activity levels were also determined using the General Practice Physical Activity Questionnaire(30). A social support questionnaire – based on a modified version of the validated UCLA social support inventory was used to collect information on the sources of support available to participants(Reference Toobert, Glasgow and Strycker9). Psychosocial measurements including health(Reference Apolone and Mosconi31) and dietary(Reference Freedman, Clifford and Tangrea32) related quality of life, mood(Reference Watson, Clark and Tellegen33), self-efficacy(Reference Calfas, Sallis and Zabinski34) and self-esteem(Reference Rosenberg, Schooler and Schoenbach35) were also collected (Table 2). A brief item assessing oral difficulties and frequency of dental visits(Reference Locker36,Reference Sheehan, Mcgarrigle and O’connell37) was used to assess dental health at baseline and endpoint only. An overview of study outcomes, measures used and the time point of assessment is summarised in Table 2. The duration of each follow-up visit was approximately 2 h; these were completed in a private room within the local community centre participating in the study. If participants were restricted for time, the physical measurements and the assessments relating to adoption of the MD (including the MDS score, review of the food diary and MD knowledge questionnaire) were prioritised during the in-person appointment, and participants were provided with a stamped addressed envelope and asked to complete the remaining questionnaires at home, posting these back to the study team within a week of their study measurement appointment.

Table 2. Outcome and evaluation measures used at each study time point

BL, baseline; MD, Mediterranean Diet; GPPAQ, General Practice Physical Activity Questionnaire.

This table is adapted from the original TEAM-MED protocol paper(Reference McEvoy, Moore and Appleton17).

* Modified for TEAM-MED.

Developed for TEAM-MED intervention.

Statistical analysis

A sample size calculation for this study was not appropriate, as the pilot data generated here will be used to inform the development of a large-scale trial and any changes in outcome data were exploratory only. For community groups, the recruitment rate is calculated based on those consenting to study screening compared with the total number of groups requesting study information. Individual recruitment is calculated as those eligible and consenting to participant compared with the total number of individuals requesting information and/or screened for eligibility (within the included community groups only). The recruitment rate for PSR is based on those completing PSG training compared with all individuals requesting information on the PSR role. Retention rates were calculated based on the number of participants completing measurements at each time point compared with the total number consenting to participate at baseline.

Baseline descriptive information on a range of demographic and health-related characteristics – by individual community group and by randomisation group (PSG and MSG) – are presented (Table 3). Descriptive statistics – including means and standard deviations for parametric data, medians and inter quartile range for non-parametric data – are presented for the primary and secondary outcomes across follow-up time points but inferential statistics were not completed. All quantitative analyses were conducted using the Statistical Package for Social Sciences (SPSS) (IBM Corp. Released 2016. IBM SPSS Statistics for Windows, Version 24.0. IBM Corp). The end-of-study interviews were recorded and transcribed verbatim and then coded by two members of the research team and analysed within a thematic framework following the steps outlined by Braun and Clark(Reference Braun and Clarke38).

Table 3. Baseline characteristics of participants by allocated intervention group

WC, waist circumference; HC, hip circumference; WHR, waist:hip ratio; MDS, Mediterranean Diet Score.

* Median (IQR) for non-parametric data.

Also includes those separated or divorced.

Results

Study recruitment and modifications to eligibility criteria

An overview of study recruitment and retention across the follow-up time points is presented in Fig. 1. We faced several challenges in the early phase of recruitment for several reasons including a lack of interest and concerns regarding the time commitment involved in participation (justifications made during informal discussions with the centre/project managers of the groups deciding not to complete screening), or ineligibility – with interested participants not meeting the group criteria and/or the individual screening criteria. To address this, the study team modified the eligibility criteria, making these less stringent to encourage a broader sample for inclusion. The following changes were made to the eligibility criteria to overcome low recruitment rates:

  1. (1) The target for 75 % of individual members of groups to be eligible in order for the group to participate was reduced to 50 % of the overall group.

  2. (2) The MDS screening criterion for inclusion was increased from ≤ 3 to ≤ 5.

Fig. 1. Overview of the study design, recruitment and retention rates.

Ten community organisations contacted researchers requesting further information and n 8 consented to study screening – an 80 % recruitment rate, of which half (n 4) met the eligibility criteria: n 3 were female only groups and n 1 male only group. Eight of fourteen interested PSR received training (57 %) with six recruited to the role (43 %). Seven of the n 8 peer supporters trained for the role were female (87·5 %).

Thirty-one of n 51 individual members across the four community groups met the eligibility criteria and consented to participate in the study (61 %); n 9 of all participants were male (29 %). Reasons for ineligibility of group participants at screening included an MDS score > 5, a low CVD risk after screening and/or participation in a commercial weight loss programme. The sizes of the four groups ranged from n 5–9 participants – less than the target of 10–12 participants per group – notably due to either ineligibility after screening or a lack of interest due to the time commitment involved in participation. Fourteen participants (one group of n 5 and another of n 9 participants) were randomised to receive the PSG intervention and n 17 (a group of n 9 and another of n 8) were randomised to the MSG.

Study retention

At both 6 and 12 months, the retention rate was 64 % (9/14) within the PSG arm and 76·5 % (13/17) within the MSG arm. The reasons provided for study drop-out by participants within the PSG arm included relocation (n 2), not contactable (n 1), no-show (n 1) and conflicting advice from a commercial weight loss programme regarding fat intake (n 1) – despite this being an exclusion criterion for participation. Within the MSG group, reasons included: work/family commitments (n 2), the burden of questionnaires at follow-up (n 1) and the diet upsetting symptoms of diverticulitis (n 1). One PSR dropped out due to ‘personal reasons’; however, a ‘personality clash’ with several group members appeared to have contributed to this when discussed. The protocol stated that in the event of a PSR dropping out another from the reserve list should act as a replacement. Upon consultation with the remaining PSR and PSG, the remaining PSR decided to continue the sessions independently to avoid disrupting the dynamic of the group.

Participant characteristics

The baseline characteristics of recruited participants are described in Table 3. Participants in the PSG were generally younger (54·6 ± 8·7) compared with the MSG (63·5 ± 12·1); however, this was driven by the range of ages across the four recruited groups: mean age ranged from 51·8 ± 7·3 to 67·1 ± 8·8. Only one male group was recruited to the study resulting in both PSG including women only. Participants in the PSG were also likely to be single (71·4 %) compared with 23·5 % of participants in the MSG. In terms of years spent in education, the median (interquartile range) of education levels varied within each community group ranging from 11·0 (2·0) years and 12·0 (2·0) years for both PSG1 and PSG2, respectively, and 11·0 (2·0) years and 14·0 (1·0) years for MSG1 and MSG2, respectively. Two participants within PSG1 had no formal education. Anthropometry measurements (including BMI and waist circumference) tended to be higher in the PSG compared with the MSG at baseline, and relatively fewer in the PSG were taking lipid-lowering and anti-hypertensive medication (Table 3). These data also suggest that both the PSG and MSG groups were similar in MDS and smoking status at baseline.

Intervention evaluation

Descriptive statistics were used to illustrate change in the MDS and several secondary outcomes across the study time points (Table 4). MDS scores were similar across groups at baseline increasing from 3·2 (1·8) to 5·8 (2·2) (PSG) and 3·4 (1·3) to 6·7 (2·3) (MSG) at 6 months; this increased score was maintained in both groups at endpoint with the PSG having a score of 5·4 (2·5) and the MSG group having an MDS of 6·8 (2·0) at 12 months (from 6 months).

Table 4. Mean (sd) for primary and secondary outcomes (anthropometry & blood pressure only) at baseline, 6 & 12 months in the Peer Support Group (PSG) and Minimum Support Group (MSG)

WHR, waist:hip ratio; WC, waist circumference; HC, hip circumference.

* Change in MDS calculated at 6 months from baseline (adoption) & 12 months from 6 months (Maintenance). Change has been calculated in n 7 of the 9 PSG who completed both MDS measurements at 6 and 12 months (n 2 PSG participants did not complete an MDS score at 6 months but finished the study and completed an MDS score at 12 months and n 2 different PSG participants completed 6 month measurements but not 12 months).

Based on n 13 (MSG) & n 9 (PSG) at 6 months & n 13 MSG and n 6 (PSG) at 12 months.

Median (IQR) for non-parametric data.

Table 5. Number of study participants (and percentages) in the Peer Support Group (PSG) and Minimum Support Group (MSG) adhering to each individual Mediterranean Diet Score (MDS) component at baseline and study endpoint

In terms of secondary outcomes, weight decreased from 79·6 (21·2) kg at baseline to 74·3 (21·0) kg and 68·5 (14·0) kg at 6 and 12 months in the PSG but remained relatively stable at 71 kg in the MSG group across the follow-up time points. BMI decreased from 31·1 (3·9) kg/m2 at baseline to 29·0 (2·6) kg/m2 at 12 months in the PSG and 26·1 (4·3) kg/m2 at BL to 25·3 (3·7) kg/m2 in the MSG group at 12 months. Waist circumference also decreased in the PSG from 103·1 ± 12·1 cm to 96·4 ± 8·4 cm at endpoint but remained stable in the MSG group across the follow-up time points. Systolic and diastolic BP also decreased in the PSG and increased in the MSG group across time points. Within the PSG, there appears to be a trend for improvements in several risk factors associated with CVD, as supported by the changes in anthropometric measurements and blood pressure across follow-up time points. However, this should be considered with caution due to the descriptive nature of the data, the small sample size and the number of participants lost to follow-up (Table 4). Inferential statistical analysis was not advised or conducted due to the pilot nature of this intervention.

Individual components of the Mediterranean Diet Score

At baseline, the most adhered to components of the MD in the total study sample were (1) preferential consumption of wholegrain foods with n 18 of 31 (58·1 %) study participants adhering to this component, (2) limiting consumption of red meat to ≤ 2 servings of red meat per week (n 16 of 31 (51·6 %)) and (3) consumption of olive oil or rapeseed oil as their main cooking fat (n 15 of 31 (48·4 %)). The least adhered to components of the MDS score (at baseline) were (1) consumption of ≥ 3 portions of vegetables per day (n 0 of 31 (0·0 %)), (2) ≥ 4 tbsp consumption of olive or rapeseed oil or 3 tsp spread/d  (n 0 of 31 (0·0 %)) and (3) consumption of olive oil-based spreads (n 3 of 31 (9·7 %)). At 12 months (study endpoint), the most adhered to components of the MDS in those completing the study were (1) consumption of olive oil or rapeseed oil as the main cooking fat (n 19 of 22 (86·4 %)), (2) preferential consumption of wholegrain foods (n 18 of 22 (81·8 %)) and (3) consumption of olive oil-based spreads (n 15 of 22 (68·2 %). The least adhered to components of the MDS at study endpoint were (1) consumption of confectionary and sweet foods ≤ 3 times per week (n 2 of 22 (9·1 %)), (2) consumption of ≥ 3 portions of vegetables per day (n 3 of 22 and 13·6 %)) and (3) consumption of ≥ 3 servings of natural nuts per week (n 5 of 22 (22·7 %)).

Acceptability and tolerance of the Peer Support intervention

PSG participants completing follow-up attended an average of six of eleven sessions; reasons provided for missing sessions were conflicting schedules, work commitments or holidays. The five-item tolerance questionnaire was completed by 61 % (n 18) of participants at 12 months: n 6 of 14 (43 %) PSG and n 12 of 17 (71 %) MSG participants. Fruit and vegetables, olive oil and reducing red and processed meat were the most ‘acceptable’ dietary changes, whereas several participants within the PSG stated that nuts and oily fish were ‘unacceptable’ due to the taste and/or texture. These qualitative findings are supported by quantitative data presenting the individual component score for each MDS item across groups and time points (discussed above), with the exception of adherence to the ≥ 3 portions of vegetables per day, as the quantitative data suggest low adherence to this component at both baseline and endpoint. When asked: ‘how is your general health now (compared to baseline)?’ all PSG and 61·5 % of MSG participants said their health was ‘better’ with reasons including ‘more energy’, ‘less bloating’reduction in swelling associated with arthritis’ and ‘skin feeling better’. In terms of side effects associated with following an MD, one participant in the PSG reported that ‘wholemeal foods sometimes upset Irritable Bowel Syndrome’.

As an objective measure of nutritional status and adherence to the intervention, we requested a saliva and urine sample from all study participants. At baseline, 84 % of participants provided a saliva sample and 97 % a urine sample compared to only 48 % and 61 % for each respective measurement at endpoint. This was generally due to an unwillingness to provide the samples, but in a few cases, participants had a blocked nose, which inhibited the use of the saliva testing kit. These samples were not analysed due to the limited number of participant samples provided at follow-up.

Process evaluation

Intervention resources and implementation

Six of the nine participants completing final follow-up measurements within the PSG also completed a structured process evaluation interview, which was used to determine the acceptability of the PSG and its components. There was a consensus amongst those interviewed that the location within the community centres was convenient. The educational materials provided – including the provision of recipe books and shopping lists as well as tasting sessions where participants shared dishes and tried new foods – were beneficial:

I: ‘What is your opinion about the seasonal recipe booklets/shopping lists? Did you find them useful?’

P12: I did actually, I done the soups and stuff…yeah, they were helpful’

P11: ‘they were helpful’

P31: ‘Yes, I look over them every so often’

I: what did you enjoy most about the programme?

P12: ‘the wee chats with everybody…also some samples that we actually tried which was nice’

Participants within the intervention group found the social support element useful to share experiences and learn from each other, which maintained motivation to attend sessions and modify behaviour:

I: What helped keep people in the group motivated to keep them on track (with the PSG intervention)?’

P11: ‘There was four of five of us doing it at a time and you know it was supporting each other’….‘are you not on the med diet?? – Get rid of that aul white bread!’ (in reference to a lunchtime conversation within the centre)

P13: ‘I think because we all kind of worked together as well so it’s like ‘are you going this week?’

Feedback on personal planners and goal setting suggested that these were not used and generally not helpful for encouraging behaviour change:

P11: ‘I did set goals in class…I think mine was quite repetitive…introduce more of this and more of that and every time I wrote: introduce more natural nuts, but I didn’t do it because they’re so yuk!’

P13: ‘not really that much – it wasn’t that useful I found’

P35: ‘Sometimes it was a pain. You couldn’t really be bothered filling it in to be honest with you.’

These views were supported by the PSR who were trained to encourage participants to set SMART goals but appeared to face resistance to this element of the PS intervention and expressed difficulties in encouraging goal setting:

I: ‘What aspects of the programme did you think they (study participants) were more responsive to?’

P2: ‘They loved the recipe books and you know the wee shopping lists ….the planners: it was hard to get them to take them out but I kept trying’

End-of-study interviews with the PSR (n 3) provided positive reviews on the support and training received throughout the study duration and intervention delivery. A PSR suggested creating a discussion forum – or similar method of communication and engagement in future studies – to provide an opportunity for PSR to remain in contact after the initial training and to share experiences with other PSR during delivery of the intervention; although the pairs of PSRs (matched to each PSG group) were in regular contact, it was suggested that such a forum could provide an extra element of support and sharing of experiences across the wider PSR group.

Process evaluation feedback from participants in the MSG, receiving education materials only, was generally positive and the majority of participants across the group felt that the MD resources such as the shopping lists, meal plans and seasonal recipes books were useful and easy to understand.

Outcome data collection

Evaluation data suggested that some individuals found the data collection process challenging, particularly questionnaire completion; in reference to baseline data collection a dropout participant remarked: ‘you’re a bit like a paratrooper if you get through that bit’ with another suggesting that this ‘affected the responses given’. Observations from the research team completing data collection suggested that the literacy levels of participants influenced the level of understanding, ability to complete questionnaires and the amount of support needed from the researcher for completion.

Discussion

This study explored the feasibility of implementation of the TEAM-MED peer support intervention to encourage adoption and maintenance of an MD, in established community groups, in comparison to a less intensive minimal support group. Challenges were faced in terms of recruitment of community groups, and recruitment of participants within the groups, with a relaxation of inclusion criteria midway through recruitment, while retention of participants throughout the study duration and completion of outcome measurement was also difficult, leading to concerns about feasibility without study design changes. These challenges meant that drawing a conclusion regarding the use of established community groups rather than newly formed groups to test the peer support intervention is not possible.

An increase in MDS was observed in both the PSG and the MSG at 6 months and was maintained at 12 months suggesting the adoption of components of an MD pattern by both groups, and – although descriptive – trends towards improvement in CVD risk factors were observed in the PSG group only. The most adhered to components of the MDS at endpoint were preferential consumption of wholegrain foods, use of olive oil as the main cooking fat and use of an olive oil-based spread. The least adhered to components were limiting confectionary, meeting recommendations for daily vegetable intake and consumption of natural nuts. End-of-study evaluation interviews with the PSG highlighted the beneficial impact of intervention participation on general health and provided useful information on intervention tolerability, highlighting the most ‘acceptable’ and ‘unacceptable’ components of the MD intervention in this group, further supporting the quantitative findings. Future interventions should consider the challenges involved in the adoption of specific MDS components in particular populations, considering additional behaviour change techniques for specific dietary components and placing an emphasis on those deemed harder or ‘less acceptable’ to change including vegetables, nuts and fish.

The study recruitment target was not met, and numerous challenges were encountered regarding implementation and evaluation of the intervention in an established community group setting. These challenges and proposed modifications/strategies for future learning will provide valuable lessons for researchers developing similar group and community-based, peer support interventions in this population.

Group-based and individual-level screening adds complexity to the recruitment process therefore thorough planning and a pragmatic approach is necessary to achieve recruitment targets and ensure a representative sample

The research team used a similar recruitment strategy to that of the original TEAM-MED study(Reference McEvoy, Moore and Appleton17), but this was more challenging in a group setting due to the group consensus necessary for participation and the eligibility requirement that the majority of the individuals within the group (75 %, later changed to 50 %) needed to also meet individual-level eligibility requirements.

A similar, group-based recruitment approach within a community setting in NI – to encourage physical activity in older female adults for CVD risk reduction – was more successful with 87 % of group members recruited and a 78 % retention rate(Reference Lawlor, Cupples and Donnelly39). Within this study, community groups were directly invited to participate and due to the nature of this intervention (education sessions to encourage physical activity), there were no exclusion criteria for individual members. Our group-based recruitment strategy may have proved more challenging due to the twofold screening and eligibility requirements. Although this approach was necessary to address the aim of this study, acknowledging the associated challenges and adapting less stringent eligibility criteria may be a consideration of future work.

In the initial stages of the study, a decision was made to modify several eligibility criteria to provide some flexibility and a less stringent approach to the recruitment process. One such modification was changing the definition of low MD adherence at baseline from an MDS cut-off of ≤ 3 to ≤ 5 (of 14). Similarly, a recently conducted intervention by our research group – the THINK-MED feasibility study which recruited a sample of NI patients with Mild Cognitive Impairment – used a score of ≤ 4 as a cut-off for baseline MD adherence and faced similar recruitment challenges(Reference McGrattan, McEvoy and Vijayakumar40). Identifying an appropriate cut-off for the baseline MDS is important to ensure that individuals recruited to the study have a low enough score to obtain optimal benefit from the dietary intervention, but where it is not so restrictive that it excludes individuals who would otherwise be eligible and may benefit from participation. Many previously published interventions have recruited participants with higher baseline MDS, some as high as nine(Reference Estruch, Ros and Salas-Salvadó41) – these studies are generally completed in Mediterranean populations where baseline adherence to a MedDiet would be higher than in a Northern Irish population. Given that NI is unlikely to have high MedDiet adherence across the population – and the fact that even those with moderate adherence may benefit from change – larger intervention studies may consider omitting this as an inclusion criteria, but measure it – and if necessary adjust for it within their analysis.

More female than male groups contacted the research team to request further information on the study. The reason for the lower engagement from male only groups is unknown, but this contributed to the imbalance in the baseline characteristics of participants and the recruitment of only one male group. Sex-specific group and community-based interventions have shown promise at encouraging health behaviour change in overweight men(Reference Hunt, Wyke and Gray18,Reference Hunt, Gray and Maclean19) . The recruitment strategy of future large-scale studies should consider techniques for engaging male community groups and could consider invitation rather than study advertisement as an option, with a focus on organisations and support groups engaging individuals at increased CVD risk. The inclusion of a male service user for Patient and Public Involvement (PPI) in any future intervention is another possible option to address this imbalance in sex(Reference Staley42).

Refinement of the data collection process and a focus on core outcomes are necessary to ensure data quality and sustained participation

The primary outcome assessment – the MDS score – a 14-item questionnaire was used to assess baseline MD adherence and adoption of the MD in this study. Both groups demonstrated a > 2-point increase at 6 months, also maintained at 12 months, and a two-point increase in MD score have been associated with a 10 % decrease in CVD(Reference Sofi, Macchi and Abbate1). A limitation of this dietary score is its subjective nature as it could be influenced by an individual’s participation in an MD intervention leading to a social desirability response bias(Reference Furnham43). To ensure robustness of the primary outcome in future interventions, additional measures to determine adoption of an MD should be considered in combination with the MDS score.

The amount of outcome data collected within the study were comprehensive and included multiple questionnaires and assessment tools to account for potential mediators of dietary behaviour change as well as exploring potential intervention moderators. Whilst collection of such data is important to our understanding of a complex behaviour change intervention(Reference Craig, Dieppe and Macintyre22), this should not be burdensome to participants or at the expense of data quality. Future interventions should consider the format of data collection (written questionnaires; use of online survey software; accessibility and literacy requirements) prioritising core outcomes to ensure data quality, limit questionnaire fatigue(Reference Pierce, Elmallah and Cherian44) and reduce study attrition.

Use of a suitable framework to assess, plan and deliver the intervention components will enhance intervention fidelity

Comprehensive consideration of methods to enhance the fidelity of intervention delivery was implemented during the development of the TEAM-MED intervention(Reference McEvoy, Moore and Appleton17); however, the group-based approach to intervention delivery was challenging. This was due to difficulties in synchronising multiple individual calendars to ensure the dates and timing of the PSG intervention sessions were convenient for all group members. This was anticipated and planned for: if a participant missed a session, the PSR discussed the content of the missed session with the person – either by a phone call or in person – prior to delivery of the next session. In future, it may be useful to record video or audio of all sessions so that PSG participants unable to attend have access to the content and full discussion of the sessions, or consider offering remotely – a more realistic option post COVID than when we initially designed and completed the intervention. As suggested by a PSR, the use of a discussion forum or similar method of engagement – to allow PSR to remain in contact after training and throughout the duration of the intervention delivery – may also provide a useful resource for support for PSR and may enhance intervention delivery. The National Institute of Health’s Behaviour Change Consortium’s Best Practice Guidance and Recommendations for ‘Enhancing Treatment Fidelity in Health Behaviour Change Studies’ offers a useful guide and key considerations and may be a useful framework to enhance the fidelity of future interventions(Reference Bellg, Borrelli and Resnick45).

PSR were trained to encourage participants to set SMART goals during delivery of the intervention(Reference Locke and Latham26,Reference Tosi, Locke and Latham27) but faced resistance to this element of the PS intervention; additional strategies to explore the barriers and facilitators of goal-setting behaviour within this population – and techniques to further promote self-efficacy and self-motivation of group participants – may also be necessary for future interventions.

Prioritisation of social support and social network data

The intervention was developed within a social support framework defined as ‘the process through which social relationships might promote health and wellbeing(Reference Cohen, Gottlieb and Underwood46) and recruited ‘established groups’ in the hope that a social support structure would already exist which may assist the behaviour change process(Reference Michie, Richardson and Johnston24). However, the definition of a ‘regular user’ may vary between organisations and the extent of ‘relationships’ between existing members may differ; it is important to acknowledge that some group members may have more established social support than others, as ‘hidden’ social networks may influence engagement and participation with the programme and therefore behaviour change(Reference Hunter, McAneney and Davis47). The social support questionnaire used within the current intervention measured the types and sources of social support, and there were no differences in social support scores between groups at baseline or any follow-up time point (data not presented); however, we did not collect data on existing friendships and social networks present within groups at baseline, but this is also an important consideration. Future larger scale trials recruiting within a CRCT design should consider the group dynamic and the extent to which groups are established socially at baseline and throughout follow-up(Reference Berkman and Kawachi48). This could be achieved with the collection of brief information on existing friendships or relationships at study time points so that any analysis to determine an intervention effect can examine how social support and social networks are influencing behaviour change within and between groups(Reference Hunter, McAneney and Davis47,Reference Valente49) .

The loss of a PSR during the process highlighted the potential for negative social interactions – ‘personality clashes’ – to occur when pairing PSRs from outside the community with established community groups. Consideration should be given to the impact of this process on group dynamics and the potential of creating an unintended power hierarchy, changing the dynamic from peer-support to a teacher–student relationship. A possible alternative option in a large-scale study is to recruit PSR directly from the same community – for example, by asking the community group to nominate a member to be trained as a PSR – or alternatively, to recruit a reserve of PSR from the community group members during the initial phase of the study – similar to the approach by Smith et al in their intervention in patients with diabetes(Reference Smith, Paul and Kelly50). Within the original TEAM-MED intervention(Reference McEvoy, Moore and Appleton17), PSR would not have been considered ‘outsiders’ in a newly formed group. PSR recruited from within the same community may lead to a more trusting and open environment if participants feel that the PSR are also ‘like them’. This would increase the likelihood of study participants valuing their PSR, which will have positive implications for engagement and participation in the intervention.

Strengths and limitations

This study explored the feasibility of delivering a peer support intervention for encouraging the adoption and maintenance of an MD in established community groups within a NI population and of testing its effectiveness in a cluster randomised controlled trial. We gathered both quantitative and qualitative data to indicate the acceptability of the intervention and the trial design to participants. The intervention was developed using the Medical Research Council guidance for developing and evaluating complex interventions thus ensuring a robust framework for the development, implementation, delivery and evaluation of the TEAM-MED intervention in this group. Validated measurement tools were used where possible to collect information on outcome measurements. The study has several limitations/findings relevant to the feasibility of the intervention delivery and trial design, including (1) a smaller, less representative sample than intended due to challenges with recruitment and study retention, (2) the MSG is not a true control group as participants in this study arm were provided with written education materials on the MD which appears to have encouraged dietary change and may have weakened any changes observed between the PSG and the MSG and (3) due to limited time and resource constraints, we did not complete a cost-effectiveness analysis.

Conclusion

This feasibility study to evaluate an MD PS intervention for encouraging adoption and maintenance of an MD in already established community groups compared with a minimal intervention group suggests an increase in MD adherence in both groups at 6 months, maintained at 12 months, with a trend in descriptive data towards improvement in CVD risk factors observed in the PSG group. Process evaluation interviews were positive in terms of the acceptability of the MD resources and the setting of intervention delivery and highlighted that some MD foods were less tolerated than others (including fish and nuts due to their taste and texture). Challenges were encountered with recruitment and retention of both community groups and participants, suggesting that a definitive study using the current trial design is unlikely to be feasible and that the effectiveness of a peer support intervention encouraging adherence to an MD should be tested using refined methods. Lessons learned will be useful to other researchers planning future complex health and/or peer support community-based interventions.

Acknowledgements

The research team would like to thank staff at the participating community groups for their time and assistance with several aspects of the study, including the facilitation of recruitment and the provision of meeting space during intervention delivery and data collection visits. Special thanks to study participants and PSR for their time and engagement with the study.

This study was funded by a project grant from Northern Ireland Chest Heart and Stroke (Reference 2015_02). The funding agency had no role in the design, analysis or writing of this article.

R. F. O’N. and L. McG. managed the study and led the details of the protocol development and conduct of the study, while S. M. W. also contributed to data entry and analysis. S. E. M. and C. T. McE. developed the TEAM-MED intervention tested in established community groups here. F. K. and M. E. C. advised on trial design and feasibility issues. R. F. O’N. initially drafted the manuscript, and all authors critically revised it. I. Y. and M. C. McK., along with J. V. W., initially conceived the study design and designed the interventions and evaluation. J. V. W. was principal investigator and led the study design and was responsible for its conduct. All authors contributed to data interpretation and critically evaluated the manuscript as well as agreeing to the current submission.

There are no conflicts of interest.

Supplementary material

For supplementary material/s referred to in this article, please visit https://doi.org/10.1017/S0007114521004050

References

Sofi, F, Macchi, C, Abbate, R, et al. (2013) Mediterranean diet and health status: an updated meta-analysis and a proposal for a literature-based adherence score. Public Health Nutr 17, 27692782.CrossRefGoogle Scholar
Mente, A, De Koning, L & Shannon, HS (2009) A systematic review of the evidence supporting a causal link between dietary factors and coronary heart disease. Arch Intern Med 169, 659669.CrossRefGoogle ScholarPubMed
Kastorini, CM, Milionis, HJ, Esposito, K, et al. (2011) The effect of Mediterranean diet on metabolic syndrome and its components: a meta-analysis of 50 studies and 534 906 individuals. J Am Coll Cardiol 57, 12991313.CrossRefGoogle ScholarPubMed
Soltani, S, Jayedi, A, Shab-Bidar, S, et al. (2019) Adherence to the Mediterranean diet in relation to all-cause mortality: a systematic review and dose-response meta-analysis of prospective cohort studies. Adv Nutr 10, 10291039.CrossRefGoogle Scholar
Tosti, V, Bertozzi, B & Fontana, L (2018) Health benefits of the Mediterranean diet: metabolic and molecular mechanisms. J Gerontol Ser A 73, 318326.CrossRefGoogle ScholarPubMed
Billingsley, HE & Carbone, S (2018) The antioxidant potential of the Mediterranean diet in patients at high cardiovascular risk: an in-depth review of the PREDIMED. Nutr Diabetes 8, 13.CrossRefGoogle ScholarPubMed
Salas-Salvadó, J, Bulló, M, Babio, N, et al. (2011) Reduction in the incidence of type 2 diabetes with the Mediterranean diet: results of the PREDIMED-Reus nutrition intervention randomized trial. Diabetes Care 34, 1419.CrossRefGoogle ScholarPubMed
Estruch, R, Ros, E, Salas-Salvadó, J, et al. (2018) Primary prevention of cardiovascular disease with a mediterranean diet supplemented with extra-virgin olive oil or nuts. N Engl J Med 378, e34.CrossRefGoogle ScholarPubMed
Toobert, DJ, Glasgow, RE, Strycker, LA, et al. (2007) Long-term effects of the Mediterranean lifestyle program: a randomized clinical trial for postmenopausal women with type 2 diabetes. Int J Behav Nutr Phys Act 4, 1.CrossRefGoogle Scholar
Logan, KJ, Woodside, JV, Young, IS, et al. (2010) Adoption and maintenance of a Mediterranean diet in patients with coronary heart disease from a Northern European population: a pilot randomised trial of different methods of delivering Mediterranean diet advice. J Hum Nutr Diet 23, 3037.CrossRefGoogle ScholarPubMed
Funnell, MM (2009) Peer-based behavioural strategies to improve chronic disease self-management and clinical outcomes: evidence, logistics, evaluation considerations and needs for future research. Family Practice 27, i17i22. https://doi.org/10.1093/fampra/cmp027 CrossRefGoogle ScholarPubMed
Parry, M & Watt-Watson, J (2010) Peer support intervention trials for individuals with heart disease: a systematic review. Eur J Cardiovasc Nurs 9, 5767.CrossRefGoogle ScholarPubMed
Dennis, CL (2003) Peer support within a health care context: a concept analysis. Int J Nurs Stud 40, 321332.CrossRefGoogle ScholarPubMed
Heisler, M (2007) Overview of peer support models to improve diabetes self-management and clinical outcomes. Diabetes Spectr 20, 214221.CrossRefGoogle Scholar
Dale, JR, Williams, SM & Bowyer, V (2012) What is the effect of peer support on diabetes outcomes in adults? A systematic review. Diabetic Med 29, 13611377.CrossRefGoogle ScholarPubMed
Erwin, CM, McEvoy, CT, Moore, SE, et al. (2018) A qualitative analysis exploring preferred methods of peer support to encourage adherence to a Mediterranean diet in a Northern European population at high risk of cardiovascular disease. BMC Public Health 18, 113.CrossRefGoogle Scholar
McEvoy, CT, Moore, SE, Appleton, KM, et al. (2018) Trial to Encourage Adoption and Maintenance of a Mediterranean Diet (TEAM-MED): protocol for a randomised feasibility trial of a peer support intervention for dietary behaviour change in adults at high cardiovascular disease risk. Int J Environ Res Public Heal 15, 1130.CrossRefGoogle ScholarPubMed
Hunt, K, Wyke, S, Gray, CM, et al. (2014) A gender-sensitised weight loss and healthy living programme for overweight and obese men delivered by Scottish Premier League football clubs (FFIT): a pragmatic randomised controlled trial. Lancet 383, 12111221.CrossRefGoogle ScholarPubMed
Hunt, K, Gray, CM, Maclean, A, et al. (2014) Do weight management programmes delivered at professional football clubs attract and engage high risk men? A mixed-methods study. BMC Public Health 14, 47.CrossRefGoogle Scholar
Campbell, MK (2012) Consort 2010 statement: extension to cluster randomised trials. BMJ 345, e5661.CrossRefGoogle ScholarPubMed
Eldridge, SM, Chan, CL, Campbell, MJ, et al. (2016) CONSORT 2010 statement: extension to randomised pilot and feasibility trials. Pilot Feasibility Stud 2, 64.CrossRefGoogle ScholarPubMed
Craig, P, Dieppe, P, Macintyre, S, et al. (2008) Developing and evaluating complex interventions: the new medical research council guidance. BMJ 337, 979983.Google ScholarPubMed
Cohen, S, Underwood, LG & Gottlieb, B (2000) Social Relationships and Health. Social Support Measurement and Intervention: a Guide for Health & Social Sciences. New York: Oxford University Press.CrossRefGoogle Scholar
Michie, S, Richardson, MS, Johnston, M, et al. (2013) The behavior change technique taxonomy (v1) of 93 hierarchically clustered techniques: building an international consensus for the reporting of behavior change interventions. Ann Behav Med 46, 8195.CrossRefGoogle ScholarPubMed
Michie, S, Ashford, S, Sniehotta, FF, et al. (2011) A refined taxonomy of behaviour change techniques to help people change their physical activity and healthy eating behaviours: the CALO-RE taxonomy. Psychol Health 26, 14791498.CrossRefGoogle ScholarPubMed
Locke, EA & Latham, GP (2002) Building a practically useful theory of goal setting and task motivation: a 35-year odyssey. Am Psychol 57, 705717.CrossRefGoogle ScholarPubMed
Tosi, HL, Locke, EA & Latham, GP (1991) A theory of goal setting and task performance. Acad Manag Rev 16, 480.CrossRefGoogle Scholar
Trichopoulou, A, Costacou, T & Bamia, C (2003) Adherence to a Mediterranean Diet and survival in a Greek Population. N Engl J Med 348, 25992608.CrossRefGoogle Scholar
Parmenter, K & Wardle, J (1999) Development of a general nutrition knowledge questionnaire for adults. Eur J Clin Nutr 53, 298308.CrossRefGoogle ScholarPubMed
Department of Health (2009) The General Practice Physical Activity Questionnaire (GPPAQ) a screening tool to assess adult physical activity levels, within primary care. NHS 2009, 121. https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/192453/GPPAQ_-_guidance.pdf (accessed January 2016).Google Scholar
Apolone, G & Mosconi, P (1998) The Italian SF-36 Health Survey: translation, validation and norming. J Clin Epidemiol 51, 10251036.CrossRefGoogle ScholarPubMed
Freedman, LS, Clifford, C, Tangrea, J, et al. (2001) Self-rated quality of life measures: effect of change to a low-fat, high-fiber, fruit, vegetable enriched diet. Ann Behav Med 23, 198207.Google Scholar
Watson, D, Clark, LA & Tellegen, A (1988) Development and validation of brief measures of positive and negative affect: the PANAS Scales. Therapy 54, 1995.Google ScholarPubMed
Calfas, KJ, Sallis, JF, Zabinski, MF, et al. (2002) Preliminary evaluation of a multicomponent program for nutrition and physical activity change in primary care: PACE+ for adults. Prev Med 34, 153161.CrossRefGoogle ScholarPubMed
Rosenberg, M, Schooler, C, Schoenbach, C, et al. (1995) Global self-esteem and specific self-esteem: different concepts, different outcomes. Am Sociol Rev 60, 141.CrossRefGoogle Scholar
Locker, D (1994) Evaluation of subjective oral health status indicators. J Public Health Dent 54, 167176.CrossRefGoogle ScholarPubMed
Sheehan, A, Mcgarrigle, C & O’connell, B (2017) Oral health and wellbeing in older irish adults. The Irish Longitudinal Study on Ageing (TILDA), 142. https://www.doi.org/10.38018/TildaRe.2017-04 Google Scholar
Braun, V & Clarke, V (2006) Using thematic analysis in psychology. Qual Res Psychol 3, 77101.CrossRefGoogle Scholar
Lawlor, ER, Cupples, ME, Donnelly, M, et al. (2019) Promoting physical activity among community groups of older women in socio-economically disadvantaged areas: randomised feasibility study. Trials 20, 115.CrossRefGoogle ScholarPubMed
McGrattan, AM, McEvoy, CT, Vijayakumar, A, et al. (2021) A mixed methods pilot randomised controlled trial to develop and evaluate the feasibility of a Mediterranean diet and lifestyle education intervention ‘THINK-MED’ among people with cognitive impairment. Pilot Feasibility Stud 7, 122.CrossRefGoogle ScholarPubMed
Estruch, R, Ros, E, Salas-Salvadó, J, et al. (2018) Primary prevention of cardiovascular disease with a Mediterranean Diet supplemented with extra-virgin olive oil or nuts. N Engl J Med 378, e34.CrossRefGoogle ScholarPubMed
Staley, K (2015) ‘Is it worth doing?’ Measuring the impact of patient and public involvement in research. Res Involv Engagement 1, 110.Google ScholarPubMed
Furnham, A (1986) Response bias, social desirability and dissimulation. Pers Indiv Diff 17, 385400.CrossRefGoogle Scholar
Pierce, TP, Elmallah, RDK, Cherian, JJ, et al. (2015) Standardized questionnaire time burden for practitioners and patients. Surg Technol Int 26, 302306.Google ScholarPubMed
Bellg, AJ, Borrelli, B, Resnick, B, et al. (2004) enhancing treatment fidelity in health behavior change studies: best practices and recommendations from the NIH behavior change consortium. Health Psychol 23, 443451.CrossRefGoogle ScholarPubMed
Cohen, S, Gottlieb, B & Underwood, LG (2000) Social Relationships and Health. New York: Oxford University Press.CrossRefGoogle Scholar
Hunter, RF, McAneney, H, Davis, M, et al. (2015) ‘Hidden’ social networks in behavior change interventions. Am J Public Health 105, 513516.CrossRefGoogle ScholarPubMed
Berkman, LF & Kawachi, I (2014) Social Epidemiology. New York: Oxford University Press.CrossRefGoogle Scholar
Valente, TW (2012) Network interventions. Science 336, 4953.CrossRefGoogle Scholar
Smith, SM, Paul, G, Kelly, A, et al. (2011) Peer support for patients with type 2 diabetes: cluster randomised controlled trial. BMJ 342, 482.Google ScholarPubMed
Siero, FW, Broer, J, Bemelmans, WJ, et al. (2000) Impact of group nutrition education and surplus value of Prochaska-based stage-matched information on health-related cognitions and on Mediterranean nutrition behavior. Health Educ Res 15, 635647.CrossRefGoogle ScholarPubMed
Barrera, M, Toobert, DJ, Angell, KL, et al. (2006) Social support and social-ecological resources as mediators of lifestyle intervention effects for type 2 diabetes. J Health Psychol 11, 483495.CrossRefGoogle ScholarPubMed
Glanz, K, Rimer, BK & Lewis, FM (2002) Health Behaviours and Health Education: Theory; Research & Practice, 3rd ed. San Francisco: Wiley & Sons.Google Scholar
Figure 0

Table 1. Study inclusion and exclusion criteria for community groups, group members and peer supporters

Figure 1

Table 2. Outcome and evaluation measures used at each study time point

Figure 2

Table 3. Baseline characteristics of participants by allocated intervention group

Figure 3

Fig. 1. Overview of the study design, recruitment and retention rates.

Figure 4

Table 4. Mean (sd) for primary and secondary outcomes (anthropometry & blood pressure only) at baseline, 6 & 12 months in the Peer Support Group (PSG) and Minimum Support Group (MSG)

Figure 5

Table 5. Number of study participants (and percentages) in the Peer Support Group (PSG) and Minimum Support Group (MSG) adhering to each individual Mediterranean Diet Score (MDS) component at baseline and study endpoint

Supplementary material: File

O’Neill et al. supplementary material

O’Neill et al. supplementary material

Download O’Neill et al. supplementary material(File)
File 232.4 KB