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Implementation of a multicomponent telemonitoring intervention to improve nutritional status of community-dwelling older adults: a process evaluation

Published online by Cambridge University Press:  03 September 2018

Marije N van Doorn-van Atten*
Affiliation:
Wageningen University & Research, Division of Human Nutrition, PO Box 17, 6700 AAWageningen, The Netherlands
Lisette CPGM de Groot
Affiliation:
Wageningen University & Research, Division of Human Nutrition, PO Box 17, 6700 AAWageningen, The Netherlands
Albert Collet Romea
Affiliation:
Meditecnologia, Barcelona, Spain
Simon Schwartz
Affiliation:
Meditecnologia, Barcelona, Spain
Jeanne HM de Vries
Affiliation:
Wageningen University & Research, Division of Human Nutrition, PO Box 17, 6700 AAWageningen, The Netherlands
Annemien Haveman-Nies
Affiliation:
Wageningen University & Research, Division of Human Nutrition, PO Box 17, 6700 AAWageningen, The Netherlands Wageningen University & Research, Strategic Communication Chair, Wageningen, The Netherlands
*
*Corresponding author: Email Marije.vandoorn@wur.nl
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Abstract

Objective

The present study aimed to conduct a process evaluation of a multicomponent nutritional telemonitoring intervention implemented among Dutch community-dwelling older adults.

Design

A mixed-methods approach was employed, guided by the process evaluation framework of the Medical Research Council and the Unified Theory of Acceptance and Use of Technology. The process indicators reach, dose, fidelity and acceptability were measured at several time points within the 6-month intervention among participants and/or nurses.

Setting

The intervention was implemented in the context of two care organisations in the Netherlands.

Subjects

In total, ninety-seven participants (average age 78 years) participated in the intervention and eight nurses were involved in implementation.

Results

About 80 % of participants completed the intervention. Dropouts were significantly older, had worse cognitive and physical functioning, and were more care-dependent. The intervention was largely implemented as intended and received well by participants (satisfaction score 4·1, scale 1–5), but less well by nurses (satisfaction score 3·5, scale 1–5). Participants adhered better to weight telemonitoring than to telemonitoring by means of questionnaires, for which half the participants needed help. Intention to use the intervention was predicted by performance expectancy (β=0·40; 95 % CI 0·13, 0·67) and social influence (β=0·17; 95 % CI 0·00, 0·34). No association between process indicators and intervention outcomes was found.

Conclusions

This process evaluation showed that nutritional telemonitoring among older adults is feasible and accepted by older adults, but nurses’ satisfaction should be improved. The study provided relevant insights for future development and implementation of eHealth interventions among older adults.

Type
Research paper
Copyright
© The Authors 2018 

Undernutrition impedes healthy ageing as it has been associated with increased morbidity and mortality( Reference Norman, Pichard and Lochs 1 ). It is estimated that 5·8 % of community-dwelling older adults are undernourished and another 31·8 % are at risk of undernutrition( Reference Kaiser, Bauer and Ramsch 2 ). Among home care clients the estimated prevalence of undernutrition is 35 %( Reference Schilp, Kruizenga and Wijnhoven 3 ). Nevertheless, it is stated that undernutrition is ‘under-recognized and under-treated’( Reference Elia, Zellipour and Stratton 4 ). Nutrition education and nutritional monitoring may improve awareness among older adults and health-care professionals and may lead to timely detection and prevention( Reference Norman, Pichard and Lochs 1 ).

In previous research the effectiveness of the PhysioDom Home Dietary Intake Monitoring (HDIM) intervention was studied( Reference Van Doorn-van Atten, Haveman-Nies and van Bakel 5 ). This intervention consisted of telemonitoring, nutrition education and follow-up by a nurse, and was implemented in a health-care setting among Dutch community-dwelling older adults. The intervention improved nutritional status in participants at risk of undernutrition and improved diet quality. No effects on physical functioning and quality of life were found( Reference Van Doorn-van Atten, Haveman-Nies and van Bakel 5 ).

Besides effect evaluation of such a complex, multicomponent intervention, process evaluation of PhysioDom HDIM is indispensable. First, insights from a process evaluation guide implementation quality and ensure that the intervention is carried out as intended( Reference Saunders, Evans and Joshi 6 ). Second, research to the context, implementation and mechanisms of impact of PhysioDom HDIM is crucial to interpret findings from the effect evaluation and to implement the intervention in another setting( Reference Moore, Audrey and Barker 7 ). Third, policy makers frequently highlight the role of technology in supporting ageing in place and effort is put into developing technology to improve health and self-management of diseases( 8 ). However, several barriers hinder successful implementation and widespread adoption of eHealth among older adults is lacking( Reference Peek, Wouters and Luijkx 9 ). Research on eHealth adoption by older adults has mostly focused on the pre-implementation stage and often comprised qualitative studies( Reference Peek, Wouters and van Hoof 10 ). More research is needed to understand what factors contribute to sustained use of eHealth. Therefore, process evaluation of the PhysioDom HDIM intervention could provide insight into what contributes to successful eHealth adoption by older adults. The aims of the present paper were to study how PhysioDom HDIM was delivered and received by participants and nurses, and to study the intervention’s mechanisms of impact.

Methods

Theoretical framework

A mixed-methods approach was employed guided by the framework of the Medical Research Council( Reference Moore, Audrey and Barker 7 , Reference Venkatesh, Morris and Davis 11 ). Based on this framework, we included the process indicators reach, dose, fidelity and acceptability. Acceptability was studied in further detail by using the Unified Theory of Acceptance and Use of Technology (UTAUT). UTAUT is a widely used framework that unifies several technology acceptance models into one, explaining up to 70 % of intention to use technology through four factors: performance expectancy, effort expectancy, social influence and facilitating conditions( Reference Venkatesh, Morris and Davis 11 ). UTAUT has been widely applied in research also among older adults( Reference Venkatesh, Morris and Davis 11 Reference Cimperman, Makovec Brencic and Trkman 14 ) and is helpful in understanding the drivers of acceptance and in designing interventions that will be optimally used( Reference Venkatesh, Morris and Davis 11 ).

Study design

The current process evaluation was conducted as part of a 6-month intervention study which followed a parallel arm pre-test/post-test design and took place from April 2016 until June 2017( Reference van Doorn-van Atten, Haveman-Nies and Pilichowski 15 ). We used data from the intervention group only. Measurements were conducted at baseline (T0), 4·5 months after the start of the study (T1) and 6 months after the start of the study (T2). Furthermore, continuous implementation monitoring took place through log data and registration of study procedures by researchers and nurses. The study was registered at ClinicalTrials.gov (identifier NCT03240094; http://bit.ly/2zFTs3P).

Participants

Participants were recruited from the municipalities of Ermelo, Harderwijk, Nunspeet, Putten and Renkum in the Netherlands. They were invited via advertisements in local newspapers and public spaces, post and letters from the care organisations Zorggroep Noordwest-Veluwe and Opella. Persons could respond when they were 65 years or older and received home care and/or lived in a service flat or sheltered accommodation. Interested persons were visited by a researcher to receive more information about the study, ask questions, sign the informed consent and be screened on the exclusion criteria. Persons were excluded if they were cognitively impaired (Mini Mental State Examination (MMSE) score <20), had diagnosed cancer, received terminal care, were bedridden or bound to a wheelchair, or were unable to watch television. In total, 107 persons were screened on eligibility for participation in the intervention group, of whom ninety-seven were allocated to the intervention group. During the intervention period, twenty-one participants were lost to follow-up. This was mainly due to health problems (n 10) or difficulties with the telemonitoring technology (n 5).

Intervention

The PhysioDom HDIM intervention consisted of three components: nutritional telemonitoring, nutrition education, and follow-up of telemonitoring measurements by a nurse. These components are explained briefly below; a full description can be found elsewhere( Reference van Doorn-van Atten, Haveman-Nies and Pilichowski 15 ). Participants performed self-measurements of body weight (weekly), steps taken during a day (one week per month) and blood pressure (monthly or bimonthly, only upon indication of a nurse). Participants also filled out questionnaires about nutritional status, appetite and diet quality using the Mini Nutritional Assessment Short-Form (MNA-SF)( Reference Kaiser, Bauer and Ramsch 16 ), the Simplified Nutritional Appetite Questionnaire (SNAQ)( Reference Wilson, Thomas and Rubenstein 17 ) and the Dutch Healthy Diet Food Frequency Questionnaire (DHD-FFQ)( Reference van Lee, Feskens and Meijboom 18 ), respectively (at T0 and three months later). Participants could do this on a tablet, on their own computer, or via a telephone interview with researchers, and were trained for this during an individual at-home training at T0. A helpdesk was available to support participants if they encountered difficulties. Furthermore, participants received three television messages per week containing general information about nutrition and physical activity. These short text messages (<500 characters) were displayed on a special television channel. Participants also received two letters with tailored information about how to improve compliance with Dutch guidelines for diet and physical activity. Tailoring was based on an individual’s DHD-FFQ results: for each guideline, one out of two to five available advices was given, according to the score for that specific guideline. Finally, a team of eight nurses and three dietitians assessed the telemonitoring results. Nurses viewed the results on a website and checked the alerts that were activated in case of undernutrition, risk of undernutrition, obesity or new blood pressure measurements. Nurses decided about proper follow-up with the help of decision trees( Reference van Doorn-van Atten, Haveman-Nies and Pilichowski 15 ). In case of risk of undernutrition, nurses investigated the causes and advised participants on how to improve protein and energy intakes( 19 ). In case of undernutrition and obesity, nurses discussed with participants whether referral to a general practitioner or dietitian was desired. In case of deviating blood pressure measurements, nurses followed regular care pathways. Nurses were trained during four preparatory meetings of 1·5h with the researchers. They also attended a workshop from a dietitian to improve knowledge about nutrition in older adults. The researchers held monthly to bimonthly telephone meetings with nurses to address questions and to ensure proper implementation.

Measurements

Reach

Reach is defined as ‘proportion of the intended priority audience that participates in the intervention’( Reference Saunders, Evans and Joshi 6 ). Reach was investigated by keeping a logbook of dropout and by collecting background characteristics of participants. Sex, age, BMI, education level, civil status, living situation, number of diagnoses, cognitive functioning as measured by the MMSE( Reference Folstein, Folstein and McHugh 20 ), the presence of dental and/or swallowing problems and type of care were recorded during a screening visit before T0. Other characteristics were measured at T0, including nutritional status, measured by the Mini Nutritional Assessment (MNA)( Reference Vellas, Villars and Abellan 21 ), and physical functioning, measured by the Short Physical Performance Battery and the Katz-15( Reference Guralnik, Simonsick and Ferrucci 22 , Reference Laan, Zuithoff and Drubbel 23 ).

Fidelity

Fidelity is defined as ‘the extent to which an intervention was implemented as planned’ and was assessed by keeping a logbook of study procedures and a paper questionnaire for nurses( Reference Saunders, Evans and Joshi 6 ). This questionnaire was filled out half-way during the project and contained questions on how much time the health-care professional spent on the project and how often the health-care professional used the project website.

Dose received

Dose received is defined as ‘the extent to which participants actively engage with, interact with, are receptive to, and/or use materials or recommended resources’( Reference Saunders, Evans and Joshi 6 ). Dose received was measured by log data from the television channel and project website, paper questionnaires for participants and nurses, and registration lists of nurses. With log data the proportion of requested weight and step count measurements that participants actually performed was measured. It should be noted that participants also wrote down their steps on paper, so log data only partially reveal dose received concerning step counts. The questionnaire for participants was filled out at T1 and T2 and contained questions on the frequency of reading television messages and telemonitoring of body weight. The questionnaire for nurses was filled out half-way during the project and included the question ‘How long on average did the contact moments take with participants with risk of undernutrition?’

Acceptability

Acceptability of the intervention was studied by using the UTAUT model( Reference Venkatesh, Morris and Davis 11 ). UTAUT constructs were measured at T1 and T2 by paper questionnaires for participants. The questionnaires contained statements that were answered on a five-point Likert scale ranging from ‘completely disagree’ to ‘completely agree’. Performance expectancy is defined as ‘the degree to which an individual believes that using the system will help him or her to attain gains in job performance’ and was translated into ‘gains in health behaviour or health’ to fit in the context of the study. Performance expectancy was measured using the following statements: ‘The project helps me to be more physically active’, ‘The project helps me to eat healthier’ and ‘The project improved my health’. Effort expectancy is defined as ‘the degree of ease associated with the use of the system’ and was measured using the following statements: ‘Working with the television channel is easy’ and ‘It is easy to weigh myself/use the pedometer/use the remote control/use the tablet/use the sphygmomanometer’. Social influence is defined as ‘the degree to which important others believe he or she should use the new system’ and was measured with the following statements: ‘My partner/family/friends/others support me in participating in the project’ and ‘The support of my partner/family/friends/others is important to me’. Facilitating conditions are defined as ‘the degree to which an individual believes that an organisational and technical infrastructure exists to support the use of the system’ and was studied by several statements concerning the satisfaction about the helpdesk and the training. Behavioural intent was measured at T2 with one statement: ‘I would like to use the intervention more often’. Furthermore, semi-structured interviews with fifteen participants were performed to gain more in-depth insight into acceptability. The interviews took on average 30min, took place during T2 at the participants’ homes and were guided by an interview guide (Table 1). After verbal consent, all interviews were recorded and transcribed verbatim.

Table 1 Interview guide for interviews with participants (n 15) of the PhysioDom HDIM intervention† in the Netherlands

The PhysioDom Home Dietary Intake Monitoring (HDIM) intervention consisted of telemonitoring, nutrition education and follow-up by a nurse, implemented in a health-care setting among Dutch community-dwelling older adults from April 2016 to June 2017.

Acceptability of nurses was also assessed with help of the UTAUT model. Nurses filled out a paper questionnaire half-way during the project with statements that were answered on a five-point Likert scale ranging from ‘completely disagree’ to ‘completely agree’. The construct performance expectancy was divided into two sub-constructs, ‘gains for job performance’ and ‘gains for client’. Gains for job performance contained six statements concerning the added value of the intervention for the job performance of the health-care professional, for example: ‘Through the intervention I can do my work more efficiently’. Effort expectancy consisted of ten items concerning the ease of use of the project website. Social influence was assessed by two items concerning the support of colleagues. Behavioural intent contained the statement: ‘I would like to participate in a continuation of the project’. Furthermore, semi-structured interviews of 20–30min were held with each of the nurses including acceptability topics (Table 2). After verbal consent, interviews were recorded and transcribed verbatim.

Table 2 Interview guide for interviews with nurses (n 8) implementing the PhysioDom HDIM interventionFootnote in the Netherlands

The PhysioDom Home Dietary Intake Monitoring (HDIM) intervention consisted of telemonitoring, nutrition education and follow-up by a nurse, implemented in a health-care setting among Dutch community-dwelling older adults from April 2016 to June 2017.

Explaining mechanisms of impact

To study the mechanisms of impact, the associations of participant characteristics and the process indicator acceptability with intention to use the intervention were examined. Furthermore, the association of the process indicators acceptability and dose received with changes in the outcomes that were significantly affected by the intervention was examined. These were nutritional status and compliance to Dutch dietary guidelines for the intake of fruits, vegetables, dietary fibre and protein, and compliance to guidelines for physical activity( Reference Van Doorn-van Atten, Haveman-Nies and van Bakel 5 ). Nutritional status was measured using the MNA during a structured interview with participants at T0, T1 and T2( Reference Vellas, Villars and Abellan 21 ). Body weight was measured at T0, T1 and T2 by researchers using a weighing scale (brand A&D, type UC-411PBT-C). Participants were asked to take off their shoes and heavy clothes such as a jacket before weighing. Diet quality was assessed using the DHD-FFQ during a structured interview with participants at T0 and T2( Reference van Lee, Feskens and Meijboom 18 ). The DHD-FFQ contains twenty-eight items to evaluate compliance to Dutch dietary guidelines for vegetables, fruits, fish, alcohol, saturated fatty acids, trans-fatty acids, Na and dietary fibre, and compliance to Dutch guidelines for physical activity( Reference Gezondheidsraad 24 ).

Statistics

Data were analysed using the statistical software package IBM SPSS Statistics for Windows version 22. Baseline characteristics were analysed using descriptive statistics. Differences in baseline characteristics between completers and dropouts were analysed using independent t tests or χ 2 tests. The process indicators dose received and acceptability were analysed using descriptive statistics, showing percentages or means with standard deviations. Cronbach’s α was used to investigate whether acceptability items could be combined into the UTAUT constructs. If Cronbach’s α was lower than 0·70, items were presented separately. The association of participant characteristics and acceptability with intention to use the intervention was analysed using a nested linear regression analysis, including participant characteristics in the first block, then adding the four UTAUT constructs block-wise to the model. An F test revealed whether adding these constructs significantly increased the explained variance. Associations of process indicators and changes in health and behavioural outcomes were analysed using linear regression. Qualitative data were analysed using the software Atlas.ti version 7. Interview transcripts were coded deductively using codes from UTAUT constructs. New codes were generated for relevant sections that did not belong to any of the UTAUT constructs. Thematic analysis was used to study factors that influenced acceptance of the intervention. Interviews with the nurses were analysed by grouping relevant sections, phrases, sentences or words into themes.

Results

Reach

Table 3 shows the baseline characteristics of the study population. Twenty-one of ninety-seven participants dropped out of the study. They were significantly older, had a lower cognitive and physical functioning, and were more care-dependent than participants who completed the study. Reasons for dropout were health problems (n 10), difficulties with the technology (n 5), inability to install the telemonitoring technology properly due to technical problems (n 2), health problems of spouse (n 1), dislike of the intervention (n 1) or reason for dropout was unknown (n 2).

Table 3 Reach of the PhysioDom HDIM interventionFootnote in terms of baseline characteristics of the total group of participants, participants who completed the study and participants who dropped out

MMSE, Mini-Mental State Examination; SPPB, Short Physical Performance Battery.

The PhysioDom Home Dietary Intake Monitoring (HDIM) intervention consisted of telemonitoring, nutrition education and follow-up by a nurse, implemented in a health-care setting among Dutch community-dwelling older adults from April 2016 to June 2017.

One missing value.

§ Four missing values.

Low education level: primary school or less; intermediate level of education: secondary professional education or vocational school; high education level: higher vocational education, university.

Fidelity

Telemonitoring measurements

Adherence to telemonitoring measurements was high for body weight and lower for steps, nutritional status, appetite and diet quality (see ‘Dose’ subsection below). Half of the participants omitted to perform at least one of the telemonitoring questionnaires, so that researchers had to assist them with filling these out at T1. Furthermore, some participants needed nurses’ assistance with telemonitoring measurements, while it was the intention that participants would be able to perform these measurements independently.

Nutrition education

According to the intervention plan, participants received three television messages per week and two letters with computer-tailored advice about diet quality and physical activity.

Follow-up by the nurse

Nurses provided follow-up on the telemonitoring alerts according to the intervention plan. It was planned that this would take 0·75h/week. However, the project took nurses on average 1·26h/week (range 0·5–3·0h/week). It was not specified how this time was distributed over the different intervention tasks, but part of this time might have been spent on the additional help that was needed with telemonitoring measurements. Half of the nurses checked the project website less often than once per week as agreed upon with the researchers, mentioning a lack of time as reason for this.

Dose

Table 4 shows participants’ adherence to the telemonitoring measurements. Either with or without help from nurses or researchers, participants performed on average 70 % of the body weight measurements, 37 % of the step count measurements, and 100 % of the measurements of nutritional status, appetite and diet quality. A little under half of the participants indicated to have read the television messages on a weekly basis. Log data revealed that 37·2 % of the television messages were opened by participants. Regarding follow-up of telemonitoring measurements by a nurse, 36 % of the participants received on average 1·2 phone calls and 12 % were visited on average 2·8 times at home. These contact moments took on average 27·5min. Five participants were referred to a dietitian and another five were referred to their general practitioner.

Table 4 Dose of the PhysioDom HDIM interventionFootnote components received by the intervention group

T1, 4·5 months after the start of the study; T2, 6 months after the start of the study; n.e., not evaluated.

The PhysioDom Home Dietary Intake Monitoring (HDIM) intervention consisted of telemonitoring, nutrition education and follow-up by a nurse, implemented in a health-care setting among Dutch community-dwelling older adults from April 2016 to June 2017.

Acceptability

Table 5 shows that participants were satisfied about the project with an average score of 4·0 out of 5; this score was higher at T1 and slightly lower at T2. Almost all acceptability scores decreased slightly from T1 to T2, although these decreases were not statistically significant. Of the four UTAUT constructs, effort expectancy and facilitating conditions were rated highest with scores between 3·8 and 4·0 at T1 and T2, indicating that participants found that the intervention technology was easy to use and that the helpdesk supported the use of the technology. Interviews with participants revealed that they were generally positive about the technology. The intended use of it was understood well. Nevertheless, many interviewees struggled with some intervention tools, mainly the weighing scale and the television channel. Remarkably, nurses were more negative about the participants’ ease of use of the technology than participants themselves. Nurses were often asked to help with the telemonitoring measurements. Nurses mentioned that ‘this generation’ is not used to technology, that participants needed a lot of help, and that they easily became frustrated or stressed when technology was not working properly. With regards to facilitating conditions, interviewed participants perceived the helpdesk as friendly and helpful. However, participants also noticed that it was not always accessible, and some felt apprehension to approach the helpdesk: ‘I don’t want to be a nuisance to anyone’. Performance expectancy was rated 3·4 and 3·3 at T1 and T2, respectively, indicating that participants were neutral to positive about the contribution of the intervention to gains in a healthy diet, levels of physical activity, or health. All interviewees indicated that at least one intervention component gave new insight into their behaviour or health (e.g. the pedometer). However, the extent to which these insights impacted behaviour and health was highly variable among interviewees. Some interviewees indicated that the intervention helped to improve diet and physical activity and called the intervention ‘stimulating’, ‘increasing awareness of own habits’ and ‘providing useful insights for improving one’s diet’. Other interviewees mentioned that the intervention had little to no effect on them or their health and called the telemonitoring results and advices ‘unnecessary’, ‘not for me’ or ‘just for fun, nothing more’. They were already satisfied with their health, found that the supervision of a health-care professional was sufficient for them, or they already knew what they needed. While interviewees with a positive perspective appeared to be a majority, the distinction between the two points of view was not absolute. Most interviewees expressed both positive and negative sentiments regarding the performance of the intervention. Participants were neutral about social influence, with scores of 3·2 and 3·1 at T1 and T2, respectively. In the interviews, participants mentioned that they received positive feedback from their social environment about their participation, but that the social environment had little influence on their experience with the intervention. Participation was seen as a personal undertaking and the decision to participate was their own. Finally, participants were neutral about their intent to use the intervention more often. In the interviews, participants mentioned that it would be ‘just more of the same’, ‘too time/energy consuming’ or ‘[I] have already gotten everything out of this experience’. Only five interviewees preferred to continue participation, mentioning the stimulation to be physically active and the structure the intervention provided: ‘Yes, the project stimulates. Now, I’ll have to continue with it myself’ and ‘Like I said, it’s about structure in your life […]. This [intervention] is just a part of that’.

Table 5 Acceptability of the PhysioDom HDIM interventionFootnote as rated by participants and health-care professionals

T1, 4·5 months after the start of the study; T2, 6 months after the start of the study.

The PhysioDom Home Dietary Intake Monitoring (HDIM) intervention consisted of telemonitoring, nutrition education and follow-up by a nurse, implemented in a health-care setting among Dutch community-dwelling older adults from April 2016 to June 2017.

Acceptability scores of nurses were slightly lower than those of participants with an average satisfaction score of 3·5. Concerning performance expectancy, nurses were more positive about the gains of the intervention for their clients than the gains for their own job performance. Nurses called the project an addition to care, promising for the future, enabling ageing in place and possibly cost-saving. However, the intervention was difficult to fit in the nurses’ schedules as it took them a lot of time next to their normal working hours. Nurses made time for this when possible, but primary care needs of their clients had priority, sometimes resulting in postponing intervention-related tasks. Effort expectancy was rated neutral with a 3·2. Nurses found the layout of the project website not clear and intuitive, and they could not report follow-up of telemonitoring measurements on it. As a result, they had to keep their own administration next to the website. Nurses also reported interferences of the website. Finally, nurses found it difficult to provide follow-up of telemonitoring measurements of participants who did not receive home care. Nurses did not know the background or medical history of these participants and found it therefore difficult to assess telemonitoring results properly. With regards to social influence, nurses were neutral to slightly positive about support of their colleagues, while they indicated that support of colleagues is important to them. The interviews revealed that cooperation with colleagues within the project team was good, but that support of other colleagues and the management of the health-care organisation was lacking. Cooperation with researchers was experienced as pleasant, although some nurses preferred to have more personal meetings instead of telephone meetings. Finally, nurses were negative about participation in a possible continuation of the intervention, with lack of time as the main reason. Some nurses only wanted to continue if the project website would be improved including notifications via email and integration of the website with the clients’ electronic health records.

Intervention’s mechanisms of impact

Table 6 shows determinants of intention to use the intervention. The first model with the participant characteristics of age, sex, education, cognitive functioning and physical functioning explained only 9 % of the variation in intention to use PhysioDom HDIM. None of these characteristics was significantly associated with intention to use PhysioDom HDIM. The percentage of explained variance increased to 45 % after adding the UTAUT constructs to the model. Performance expectancy and social influence significantly increased explained variance by 26 and 5 %, respectively. Effort expectancy increased explained variance by 4 % (P=0·07). The final model showed that performance expectancy and social influence were significant predictors of intention to use PhysioDom HDIM.

Table 6 Determinants of intention to use the PhysioDom HDIM interventionFootnote (n 63)

Dependent variable: intention to use PhysioDom HDIM more often (range 1–5).

*P<0·05, **P<0·01, ***P<0·001.

The PhysioDom Home Dietary Intake Monitoring (HDIM) intervention consisted of telemonitoring, nutrition education and follow-up by a nurse, implemented in a health-care setting among Dutch community-dwelling older adults from April 2016 to June 2017.

Measured by Mini Mental State Examination.

§ Measured by Short Physical Performance Battery.

Table 7 shows the influence of the process indicators acceptability and dose received on effects of the intervention on nutritional status and DHD-FFQ scores for fruits, vegetables, fibre, protein, and physical activity. No significant associations of acceptability and dose received with effects of the intervention were observed.

Table 7 Influence of acceptability and dose received on effects of the PhysioDom HDIM interventionFootnote on nutritional status and diet quality

MNA, Mini Nutritional Assessment; DHD-FFQ, Dutch Healthy Diet Food Frequency Questionnaire; T0, baseline; T1, 4·5 months after the start of the study; T2, 6 months after the start of the study.

The PhysioDom Home Dietary Intake Monitoring (HDIM) intervention consisted of telemonitoring, nutrition education and follow-up by a nurse, implemented in a health-care setting among Dutch community-dwelling older adults from April 2016 to June 2017.

Constructs from the Unified Theory of Acceptance and Use of Technology are combined in one model and adjusted for age, sex, help from relatives, living situation and number of diagnoses.

§ Adjusted for age and education.

Discussion

The current process evaluation provided insight into how PhysioDom HDIM was implemented and received by participants and nurses. The intervention was largely implemented as intended with higher satisfaction rates among participants than among nurses. Both participants and nurses mentioned concerns regarding performance and effort expectancy of the intervention. Furthermore, participants’ intention to use the intervention was predicted by performance expectancy and social influence. Acceptability and dose received were not associated with intervention effects.

Concerning the reach of this intervention, about 20 % of the participants dropped out. Dropouts were older, less healthy and more care-dependent than completers. This is similar to the experience of another eHealth study among older adults in which dropouts were older and participants dropped out due to health deterioration( Reference Hirani, Beynon and Cartwright 25 ). In two other studies, having one or more chronic conditions was associated with lower adherence to an eHealth intervention( Reference Guzman-Clark, van Servellen and Chang 26 , Reference Kelders, Van Gemert-Pijnen and Werkman 27 ). This has implications for the expectation that eHealth improves health-care access and health equity, as the present study and other studies show that older age and poorer health are related to higher dropout or lower adherence. Therefore, health disparities may still remain for persons who are less able or willing to keep up with eHealth( Reference Eysenbach 28 ). For future generations of older adults with higher computer literacy this issue might be less problematic. Nevertheless, research should focus on how the reach towards these groups can be improved or by considering other modalities than eHealth to promote health in non-adopters of eHealth( Reference Zbib, Hodgson and Calderwood 29 ).

In general, participants were satisfied about the intervention. When looking at the UTAUT constructs, we found that participants rated effort expectancy and facilitating conditions the highest. Participants were more neutral about performance expectancy and social influence. The results for effort expectancy and social influence seem contradictory to the nurses’ views. The nurses were more negative about the participants’ ease of use of the intervention than participants themselves. Furthermore, nurses supported many participants in performing the telemonitoring measurements, but participants were neutral about the role of social influence. This could be partly due to the operationalisation of social influence, as participants might not see their nurses as ‘important others’ but rather think of relatives. Another explanation might be that the nurses especially observed participants who frequently needed help. All in all, taking account of the views of both participants and nurses is relevant as both have an essential role in successful implementation.

However, social influence was a predictor for intention to use the intervention, together with performance expectancy. Performance expectancy has been identified as an important predictor of use( Reference Peek, Wouters and van Hoof 10 Reference de Veer, Peeters and Brabers 12 , Reference Lee and Coughlin 30 , Reference Peeters, de Veer and van der Hoek 31 ). The literature is divided about the role of social influence in eHealth adoption. According UTAUT, social influence is a significant predictor in mandatory settings only and studies did not find an association between social influence and intention to use eHealth among older adults( Reference Venkatesh, Morris and Davis 11 , Reference de Veer, Peeters and Brabers 12 , Reference Cimperman, Makovec Brencic and Trkman 14 ). However, our study and others did find an association( Reference Peek, Wouters and van Hoof 10 , Reference Hsu, Tsai and Kuo 32 Reference Chen and Chan 35 ). This might be explained by the way social influence is operationalised in studies, or by the suggestion that the role of social influence is dependent on the context( Reference de Veer, Peeters and Brabers 12 , Reference Cimperman, Makovec Brencic and Trkman 14 ). Many technology acceptance models have reduced social influence to the construct of subjective norm (i.e. perception that important others think he/she should or should not use technology), but social influence also encompasses the influence of technology suppliers, health-care professionals and the help of relatives( Reference Peek, Wouters and van Hoof 10 , Reference Gramstad, Storli and Hamran 36 ). Models concerning technology acceptance by older adults should pay attention to this more complex role of social influence.

Unexpectedly, no associations of the process indicators dose received and acceptability with effects of the intervention were found. Previous research suggests that intervention adherence is related to better outcomes( Reference Couper, Alexander and Zhang 37 Reference Neve, Morgan and Jones 40 ). However, other studies did not find such an association or presented mixed results( Reference Kelders, Van Gemert-Pijnen and Werkman 27 , Reference Wildeboer, Kelders and van Gemert-Pijnen 41 Reference Dane and Schneider 43 ). It could be that the process indicators in the present study and the way they were measured did not capture implementation sufficiently. For example, self-report could have introduced recall bias. Another explanation might be that the relationship between process indicators and outcomes is more complex, for example not following a linear relationship or influenced by sociodemographic factors or personality traits( Reference Wildeboer, Kelders and van Gemert-Pijnen 41 , Reference Donkin, Hickie and Christensen 42 ). Future studies should continue to include process measures to unravel interventions’ mechanisms of impact and to unveil successful intervention elements.

The current study made use of evaluation frameworks to underpin the evaluation strategy. The Medical Research Council and UTAUT frameworks have been widely used for process evaluation and technology acceptance, respectively. One of the objections concerning UTAUT, however, is that this model lacks important determinants of technology use that are specific to community-dwelling older adults, such as cognitive and physical functioning and several contextual factors( Reference Peek, Wouters and van Hoof 10 ). This was taken into account by including cognitive and physical functioning in the analyses, together with the UTAUT constructs. Furthermore, both quantitative and qualitative data were used to capture an in-depth overview of how the intervention was implemented and received. Collecting data from both participants and nurses resulted in two complementary perspectives on the intervention. A limitation of the study might be recall bias among nurses concerning their implementation of the intervention. Nurses were asked about their frequency and duration of intervention activities half-way during the intervention and were reminded at the end of the intervention to record the contact moments with participants. This might have obscured the association between intervention dose and effects.

Based on the present study, some implications for future research and practice are presented. First, nurses found it difficult to perform follow-up of telemonitoring results of participants who did not receive home care. This suggests that telemonitoring can better be implemented within a care context in which nurses know the telemonitoring recipients. Second, telemonitoring has the purpose to partly replace care from health-care professionals. However, some of our participants needed much guidance from nurses in performing telemonitoring measurements, suggesting that the current intervention, implemented among the current generation, requires more guidance from nurses than desired. Improved usability may reduce the need for guidance, as well as the expectation that future generations have better computer literacy. Third, the study underlines the importance of user-centred design in developing eHealth intervention for older adults. This process evaluation revealed several aspects that would hinder long-term use of the intervention, such as the usability and interoperability of the nurses’ website, the perceived need for the intervention, and the usability and attractiveness of the television channel. Although we have pre-tested the telemonitoring technology in a pilot study, it is recommended that end users and other relevant stakeholders are even more involved in iterative development cycles of eHealth applications( Reference Matthew-Maich, Harris and Ploeg 44 , Reference Gustafson, Maus and Judkins 45 ).

Conclusion

To conclude, the PhysioDom HDIM intervention was feasible to implement with good satisfaction among participants, but lower satisfaction among nurses. Nutritional telemonitoring interventions should be user-friendly so that telemonitoring measurements can be performed without guidance from nurses; and should fit with working procedures from nurses for successful adoption and implementation. The perceived benefits of the intervention and social influence predicted the participants’ intention to use the intervention, which can be used as strategies for future intervention design and implementation. Future research should focus on how to enlarge the reach of eHealth interventions to more frail older adults and on unravelling mechanisms of impact.

Acknowledgements

Acknowledgements: The authors would like to thank all participants, health-care professionals and the boards of Zorggroep Noordwest-Veluwe and Opella. Furthermore, they would like to thank Iris Geigenmüller and Joline Wierda for their contribution to the data collection and data analysis of this study. Financial support: This work was supported by the European Union (grant number CIP-ICT-PSP-2013-7). The European Union had no role in the design, analysis or writing of this article. Conflict of interest: None. Authorship: M.N.v.D.-v.A. coordinated implementation of the study, analysed the data and drafted the article. S.S. and A.C.R. contributed to the study design. L.C.P.G.M.d.G., J.H.M.d.V., A.H.-N., S.S. and A.C.R. critically read and revised the manuscript. Ethics of human subject participation: This study was conducted according to the guidelines laid down in the Declaration of Helsinki and all procedures involving human subjects were approved by the ethics committee of Wageningen University. Written informed consent was obtained from all subjects.

References

1. Norman, K, Pichard, C, Lochs, H et al. (2008) Prognostic impact of disease-related malnutrition. Clin Nutr 27, 515.Google Scholar
2. Kaiser, MJ, Bauer, JM, Ramsch, C et al. (2010) Frequency of malnutrition in older adults: a multinational perspective using the mini nutritional assessment. J Am Geriatr Soc 58, 17341738.Google Scholar
3. Schilp, J, Kruizenga, HM, Wijnhoven, HA et al. (2012) High prevalence of undernutrition in Dutch community-dwelling older individuals. Nutrition 28, 11511156.Google Scholar
4. Elia, M, Zellipour, L & Stratton, RJ (2005) To screen or not to screen for adult malnutrition? Clin Nutr 24, 867884.Google Scholar
5. Van Doorn-van Atten, MN, Haveman-Nies, A, van Bakel, M et al. (2018) Effects of a multi-component nutritional telemonitoring intervention on nutritional status, diet quality, physical functioning, and quality of life of community-dwelling older adults. Br J Nutr 119, 11851194.Google Scholar
6. Saunders, RP, Evans, MH & Joshi, P (2005) Developing a process-evaluation plan for assessing health promotion program implementation: a how-to guide. Health Promot Pract 6, 134147.Google Scholar
7. Moore, GF, Audrey, S, Barker, M et al. (2015) Process evaluation of complex interventions: Medical Research Council guidance. BMJ 350, h1258.Google Scholar
8. World Health Organization (2016) Global Diffusion of eHealth: Making Universal Health Coverage Achievable . Report of the Third Global Survey on eHealth. Geneva: WHO.Google Scholar
9. Peek, ST, Wouters, EJ, Luijkx, KG et al. (2016) What it takes to successfully implement technology for aging in place: focus groups with stakeholders. J Med Internet Res 18, e98.Google Scholar
10. Peek, ST, Wouters, EJ, van Hoof, J et al. (2014) Factors influencing acceptance of technology for aging in place: a systematic review. Int J Med Inform 83, 235248.Google Scholar
11. Venkatesh, V, Morris, MG, Davis, GB et al. (2003) User acceptance of information technology: toward a unified view. MIS Q 27, 425478.Google Scholar
12. de Veer, AJE, Peeters, JM, Brabers, AEM et al. (2015) Determinants of the intention to use e-Health by community dwelling older people. BMC Health Serv Res 15, 103.Google Scholar
13. Kohnke, A, Cole, M & Bush, R (2014) Incorporating UTAUT predictors for understanding home care patients’ and clinician’s acceptance of healthcare telemedicine equipment. J Technol Manag Innovat 9, 2941.Google Scholar
14. Cimperman, M, Makovec Brencic, M & Trkman, P (2016) Analyzing older users’ home telehealth services acceptance behaviour – applying an Extended UTAUT model. Int J Med Inform 90, 2231.Google Scholar
15. van Doorn-van Atten, MN, Haveman-Nies, A, Pilichowski, P et al. (2018) Telemonitoring to improve nutritional status in community-dwelling elderly: design and methods for process and effect evaluation. BMC Geriatr (In the Press).Google Scholar
16. Kaiser, MJ, Bauer, JM, Ramsch, C et al. (2009) Validation of the Mini Nutritional Assessment Short-Form (MNA-SF): a practical tool for identification of nutritional status. J Nutr Health Aging 13, 782788.Google Scholar
17. Wilson, MM, Thomas, DR, Rubenstein, LZ et al. (2005) Appetite assessment: simple appetite questionnaire predicts weight loss in community-dwelling adults and nursing home residents. Am J Clin Nutr 82, 10741081.Google Scholar
18. van Lee, L, Feskens, EJ, Meijboom, S et al. (2016) Evaluation of a screener to assess diet quality in the Netherlands. Br J Nutr 115, 517526.Google Scholar
19. Voedingscentrum (2017) Ondervoeding. Eten bij ondervoeding en bij herstel na ziekte, vol. D752-20. https://webshop.voedingscentrum.nl/pdf/D752-20.pdf (accessed August 2018).Google Scholar
20. Folstein, MF, Folstein, SE & McHugh, PR (1975) ‘Mini-mental state’. A practical method for grading the cognitive state of patients for the clinician. J Psychiatr Res 12, 189198.Google Scholar
21. Vellas, B, Villars, H, Abellan, G et al. (2006) Overview of the MNA – its history and challenges. J Nutr Health Aging 10, 456463.Google Scholar
22. Guralnik, JM, Simonsick, EM, Ferrucci, L et al. (1994) A short physical performance battery assessing lower extremity function: association with self-reported disability and prediction of mortality and nursing home admission. J Gerontol 49, M85M94.Google Scholar
23. Laan, W, Zuithoff, NP, Drubbel, I et al. (2014) Validity and reliability of the Katz-15 scale to measure unfavorable health outcomes in community-dwelling older people. J Nutr Health Aging 18, 848854.Google Scholar
24. Gezondheidsraad, (2006 ) Richtlijnen Goede Voeding 2006 . Den Haag: Gezondheidsraad.Google Scholar
25. Hirani, SP, Beynon, M, Cartwright, M et al. (2014) The effect of telecare on the quality of life and psychological well-being of elderly recipients of social care over a 12-month period: the Whole Systems Demonstrator cluster randomised trial. Age Ageing 43, 334341.Google Scholar
26. Guzman-Clark, JR, van Servellen, G, Chang, B et al. (2013) Predictors and outcomes of early adherence to the use of a home telehealth device by older veterans with heart failure. Telemed J E Health 19, 217223.Google Scholar
27. Kelders, MS, Van Gemert-Pijnen, EWCJ, Werkman, A et al. (2011) Effectiveness of a web-based intervention aimed at healthy dietary and physical activity behavior: a randomized controlled trial about users and usage. J Med Internet Res 13, e32.Google Scholar
28. Eysenbach, G (2001) What is e-health? J Med Internet Res 3, E20.Google Scholar
29. Zbib, A, Hodgson, C & Calderwood, S (2011) Can eHealth tools enable health organizations to reach their target audience? Healthc Manage Forum 24, 155159.Google Scholar
30. Lee, C & Coughlin, J (2014) PERSPECTIVE: Older adults’ adoption of technology: an integrated approach to identifying determinants and barriers. J Prod Innovat Manag 32, 747759.Google Scholar
31. Peeters, JM, de Veer, AJ, van der Hoek, L et al. (2012) Factors influencing the adoption of home telecare by elderly or chronically ill people: a national survey. J Clin Nurs 21, 31833193.Google Scholar
32. Hsu, YC, Tsai, CH, Kuo, YM et al. (2016) Telecare services for elderly: predictive factors of continued use intention. Open Biomed Eng J 10, 8290.Google Scholar
33. Kijsanayotin, B, Pannarunothai, S & Speedie, SM (2009) Factors influencing health information technology adoption in Thailand’s community health centers: applying the UTAUT model. Int J Med Inform 78, 404416.Google Scholar
34. Or, CKL, Karsh, B-T, Severtson, DJ et al. (2011) Factors affecting home care patients’ acceptance of a web-based interactive self-management technology. J Am Med Inform Assoc 18, 5159.Google Scholar
35. Chen, K & Chan, AH-S (2013) Use or non-use of gerontechnology – a qualitative study. Int J Environ Res Public Health 10, 46454666.Google Scholar
36. Gramstad, A, Storli, SL & Hamran, T (2014) Older individuals’ experiences during the assistive technology device service delivery process. Scand J Occup Ther 21, 305312.Google Scholar
37. Couper, MP, Alexander, GL, Zhang, N et al. (2010) Engagement and retention: measuring breadth and depth of participant use of an online intervention. J Med Internet Res 12, e52.Google Scholar
38. Norman, GJ, Zabinski, MF, Adams, MA et al. (2007) A review of eHealth interventions for physical activity and dietary behavior change. Am J Prev Med 33, 336345.e316.Google Scholar
39. Mattila, E, Orsama, AL, Ahtinen, A et al. (2013) Personal health technologies in employee health promotion: usage activity, usefulness, and health-related outcomes in a 1-year randomized controlled trial. JMIR Mhealth Uhealth 1, e16.Google Scholar
40. Neve, M, Morgan, PJ, Jones, PR et al. (2010) Effectiveness of web-based interventions in achieving weight loss and weight loss maintenance in overweight and obese adults: a systematic review with meta-analysis. Obes Rev 11, 306321.Google Scholar
41. Wildeboer, G, Kelders, SM & van Gemert-Pijnen, JEWC (2016) The relationship between persuasive technology principles, adherence and effect of web-based interventions for mental health: a meta-analysis. Int J Med Inform 96, 7185.Google Scholar
42. Donkin, L, Hickie, BI, Christensen, H et al. (2013) Rethinking the dose–response relationship between usage and outcome in an online intervention for depression: randomized controlled trial. J Med Internet Res 15, e231.Google Scholar
43. Dane, AV & Schneider, BH (1998) Program integrity in primary and early secondary prevention: are implementation effects out of control? Clin Psychol Rev 18, 2345.Google Scholar
44. Matthew-Maich, N, Harris, L, Ploeg, J et al. (2016) Designing, implementing, and evaluating mobile health technologies for managing chronic conditions in older adults: a scoping review. JMIR Mhealth Uhealth 4, e29.Google Scholar
45. Gustafson, DH Jr, Maus, A, Judkins, J et al. (2016) Using the NIATx model to implement user-centered design of technology for older adults. JMIR Hum Factors 3, e2.Google Scholar
Figure 0

Table 1 Interview guide for interviews with participants (n 15) of the PhysioDom HDIM intervention† in the Netherlands

Figure 1

Table 2 Interview guide for interviews with nurses (n 8) implementing the PhysioDom HDIM intervention† in the Netherlands

Figure 2

Table 3 Reach of the PhysioDom HDIM intervention† in terms of baseline characteristics of the total group of participants, participants who completed the study and participants who dropped out

Figure 3

Table 4 Dose of the PhysioDom HDIM intervention† components received by the intervention group

Figure 4

Table 5 Acceptability of the PhysioDom HDIM intervention† as rated by participants and health-care professionals

Figure 5

Table 6 Determinants of intention to use the PhysioDom HDIM intervention† (n 63)

Figure 6

Table 7 Influence of acceptability and dose received on effects of the PhysioDom HDIM intervention† on nutritional status and diet quality