The Unacceptance of a Self-Management Health System by Healthy
Older Adults
Ine D’Haeseleer
1 a
, Dries Oeyen
2
, Bart Vanrumste
1 b
, Dominique Schreurs
3 c
and Vero Vanden Abeele
1 d
1
KU Leuven, e-Media Research Lab, Belgium
2
BeWell Innovations, Belgium
3
KU Leuven, ESAT-TELEMIC, Belgium
Keywords:
Older Adults, Self-Management Health Systems, User-study, UTAUT Acceptance Model.
Abstract:
Self-Management Health Systems (SMHS) are defined as systems that combine data logging via multiple
sensors and/or self-reports, possibly enhanced with risk assessment and decision support. Research on SMHS
is booming, particularly as it is envisioned to support ageing in place for an increasingly greying population.
However, findings on what drives adoption of SMHS by healthy older adults is still lacking. Therefore, an
SMHS was tested for two weeks in a real world setting by 16 healthy participants aged 65+. We measured
acceptance towards the SMHS pre and post, combined with qualitative data , and usage logs. Results indicate
that at the start of the study, older adults perceived the system as easy to use, useful, and that participants had
access to supporting infrastructure. Notwithstanding, behavioural intention to use an SMHS was rather low.
Post usage, our findings show that, while perceived ease of use and confidence increased, perceived usefulness
and behavioural intention further decreased. These findings suggest that older adults are not yet ready to adopt
SMHS, and that design efforts should particularly be geared towards increasing perceived usefulness.
1 INTRODUCTION
The world’s population is ageing; it is predicted that
the number of people aged 65 years or older will dou-
ble to 160 millions by 2060 (Nations, 2015). There-
fore, many studies focus on older adults and tech-
nologies to support healthy ageing. In particular,
Self-Management Health Systems (SMHS), i.e., inte-
grated technical systems which combine data logging
via multiple sensors and/or self-reports, e.g., surveys,
logbooks, pain scales, with data visualisations, risk
assessment, and decision support, have been put for-
ward as a solution to support ageing in place (Queir
´
os
et al., 2017). Such systems are equally envisioned
to support a shift to preventive care, and to empower
older adults in the co-creation of their own health
(Vines et al., 2015).
Many R&D efforts are geared towards building
a
https://orcid.org/0000-0001-5455-3581
b
https://orcid.org/0000-0002-9409-935X
c
https://orcid.org/0000-0002-4018-7936
d
https://orcid.org/0000-0002-3031-9579
SMHS and solving technical challenges (Doyle et al.,
2014; Jim
´
enez-Mixco et al., 2013). Various com-
mercial and non-commercial actors are working on
increasingly efficient technological systems, varying
from memory training (Lumos Labs, 2020) to track-
ing of vital parameters (iHealth Labs Inc., 2019) e.g.,
blood pressure, glucose meters, or any combination.
Besides tracking information, also self-reported data,
e.g., (Ware and Sherbourne, 1992; Fougeyrollas and
Noreau, 2001) and risk assessments, e.g., (Bucking-
ham, 2016) are investigated and used in SMHS.
However, beyond solving technological chal-
lenges, there is also a need for further insight into
the actual use and acceptance of these systems, and
what drives adoption of SMHS by older adults. Stud-
ies on the adoption of related technologies for e.g.,
assisted living or telemonitoring show mixed results.
Some studies (Sintonen and Immonen, 2013; Wang
et al., 2019) show that older adults are open to the
idea of managing their own health. Other studies por-
tray a more nuanced image on acceptance of health-
related ICT among older adults (Heart and Kalderon,
2013; Peek et al., 2016; Young et al., 2013; Verdezoto
D’Haeseleer, I., Oeyen, D., Vanrumste, B., Schreurs, D. and Abeele, V.
The Unacceptance of a Self-Management Health System by Healthy Older Adults.
DOI: 10.5220/0009806402690280
In Proceedings of the 6th International Conference on Information and Communication Technologies for Ageing Well and e-Health (ICT4AWE 2020), pages 269-280
ISBN: 978-989-758-420-6
Copyright
c
2020 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
269
and Gr
¨
onvall, 2016; Jaschinski and Allouch, 2015;
Kononova et al., 2019; D’Haeseleer et al., 2019b).
These studies indicate a lack in perceived usefulness
and identify remaining barriers which needs to be ad-
dressed before adoption of SMHS by older adults.
These inconsistent findings may be due to different
operationalisations of what constitutes SMHS. They
may also be attributed to different inclusion criteria
for older adults, or different contexts-of-use – mun-
dane versus clinical contexts (Nunes et al., 2015).
Due to the inconsistent findings, designers may
lack insight into what drives the acceptance and use
of SMHS by older adults, and how to design for it.
In this study, we are particularly interested in com-
munity dwellers who aim to use SMHS in a mun-
dane setting, i.e., older adults aged over 65+, in good
health and still living at home. We deemed it impor-
tant to gain a deeper understanding of how this group
of older adults uses SMHS by combining quantitative,
qualitative, and usage data.
Therefore, we created a prototypical SMHS, in-
cluding a questionnaire on health and wellbeing, an
activity tracker, a blood pressure monitor, and a sleep
sensor. After designing and developing the SMHS,
the application was tested in a real world setting by
means of a user-study with 16 self-reported healthy
1
participants aged 65+, during two weeks. Acceptance
of the SMHS was both measured at the beginning and
at the end of the user-study, based on a questionnaire
informed by the Unified Theory of Acceptance and
Use of Technology (UTAUT) (Venkatesh et al., 2003).
Additionally, extra information was collected through
open-ended interviews and usage logs. The results
suggest a lack in intention to adopt the SMSH; older
adults aged 65+ are not yet waiting for these systems.
In Section 2, an overview of related work is given.
Section 3 describes the method. Section 4 presents
participants’ results: experience data, UTAUT evalu-
ation, and usage data. Further, in Section 5 results are
discussed and compared to findings in literature. Fi-
nally, section 6 concludes and addresses future work.
2 RELATED WORK
2.1 Self-Management Health Systems
SMHS are on the rise. Several researchers investi-
gated the acceptance and use of SMHS by older adults
(Sintonen and Immonen, 2013; Heart and Kalderon,
1
Older adults that perceive themselves as healthy, but
may experience mild cognitive and/or physical decline due
to their age.
2013; Peek et al., 2016; Wang et al., 2019). Often,
such studies include hundreds of participants, to al-
low generalising views and attitudes of the partici-
pants to a broader audience of ‘older adults’. Yet,
such survey studies most often remain hypothetical,
as participants are not offered a salient experience of
using an actual SMHS. On the other hand, studies
that do include hands-on experiences through work-
shops or prototypes, e.g., (Kononova et al., 2019;
D’Haeseleer et al., 2019b; Jaschinski, 2014; Verde-
zoto and Gr
¨
onvall, 2016; Young et al., 2013) are
mainly system evaluations that gauge technical pos-
sibilities, as well as usability issues. These studies
are highly important to overcome possible barriers in
developing and using SMHS, but not well suited to
understand and evaluate long-term adoption.
Adoption studies with older adults do exist, but
are typically not using SMHS, but rather a related
ICT technology, or rely on the support of a care-
giver. For example, Jim
´
enez-Mixco et al. investi-
gated a system to monitor health and promote ac-
tive ageing by including biomedical sensors in over
100 healthy older adults (Jim
´
enez-Mixco et al., 2013).
Results were promising regarding usability and use-
fulness, and moreover, most of the participants (68%)
wanted to use the application in the future. However,
older adults in this study were relatively young (aged
55+). Moreover, the study did not focus on the self-
managing of health, as they still relied on the support
of a caregiver. Another study from McMahon et al.
investigated the use and acceptance of older adults,
aged 70+, towards physical activity trackers (McMa-
hon et al., 2016). In total, 95 older adults participated
in an intervention study of 8 months. At the end of
the study, participants were asked about their experi-
ences. Ratings were twice positive, nevertheless, they
did decrease in the second measurement. Researchers
also found that the oldest older adults (80+) were less
positive than those aged between 70 and 80.
To the best of the authors’ knowledge, there is
only one adoption study on using SMHS by older
adults. Doyle et al. investigated attitudes and ad-
herence to wellness self-management in older adults
(Doyle et al., 2014). The sample was limited to seven
participants (mean age=70.6), who tested the applica-
tion. After two months the trial period was over and
participants were free to continue or quit using the
application (one person quit). After five months, par-
ticipants were interviewed to learn about their experi-
ences. Results showed that the application was found
user-friendly, and participants were intrinsically mo-
tivated to use it. Participants particularly emphasised
the importance of receiving feedback from the sys-
tem.
TEG 2020 - Special Session on Technology, Elderly Games
270
2.2 Technology Acceptance Theories
There are several psychological theories that inves-
tigate user acceptance and adoption of technologies,
e.g., (Champion et al., 2008; Fishbein, 1979; Deci
and Ryan, 2012; Davis, 1985; Venkatesh et al., 2003).
The model underlying this study is the “Unified the-
ory of acceptance and use of technology” (UTAUT)
(Venkatesh et al., 2003). This model has been put
forward as the gold standard of technology adoption
(Taiwo and Downe, 2013). UTAUT was first used in
general IT adoption within a work environment. Yet
since, several studies have used and extended UTAUT
to health care technologies, e.g., (Peek et al., 2019;
Vanneste et al., 2013; Khechine et al., 2016; Cimper-
man et al., 2016), and portrayed it as a fitting theory
also in a health care context. According to UTAUT,
four key constructs are used to assess behavioural in-
tention (i.e., acceptance) to use a system:
1. Performance Expectancy (PE) or “Do I find the
system useful?”
2. Effort Expectancy (EE) or “How difficult do I find
it to use the system?”
3. Social Influence (SI) or “What will others think
about me when using the system?”
4. and Facilitating Conditions (FC) or “Do I have the
facilities/technologies in order to use the system?”
The UTAUT model upholds that these constructs
are determinants of the behavioural intention to use
the system and can be used to predict the actual use
(see figure 1). In other words, by measuring these four
constructs, one can predict the Behavioural Intention
(BI) of the user to adopt, and use the system.
Figure 1: UTAUT model by (Venkatesh et al., 2003).
However, most recent studies focusing on adop-
tion of health care technologies that involve captur-
ing data from users, by means of sensors and/or self-
reports, showed that additional constructs such as
‘anxiety’ or ‘safety of data’ may also play an impor-
tant role in the use and acceptance of technologies
(Ebert et al., 2015; Baumeister et al., 2014). Hence,
in more recent UTAUT models for a health care con-
text, these constructs can be added (De Witte and
Van Daele, 2017).
3 METHOD
To explore the attitudes of older adults towards one
particular SMHS, we conducted a user evaluation
with 16 participants (ten women and six men) for a
two-week study. These studies took place between
July and November 2018.
3.1 SMHS Application with Sensors
For this study, an application was designed for older
adults to fill out questionnaires, view their answers to
the questionnaire’s items, along with results measured
by three different sensors: activity tracker, sleep mon-
itor, and blood pressure monitor.
The questionnaire used in this study is a combi-
nation of the RAND-36 (Ware and Sherbourne, 1992;
Van der Zee and Sanderman, 1993) and Life Habits
(Fougeyrollas and Noreau, 2001; Lemmens et al.,
2007). RAND-36 is an assessment for health-related
quality of life, divided over nine categories: physi-
cal functioning, physical role functioning, emotional
role functioning, energy/fatigue, emotional wellbe-
ing, social functioning, pain, general health, and
health change. The RAND questionnaire was vali-
dated with 8117 community dwellers, ages ranging
from 65-104 years old (Walters et al., 2001). Data
was reported and made it possible to filter for gender
and age-group, and therefore was used as an indica-
tion for ‘other’ participants. For our application, addi-
tionally, three categories were selected from the Life
Habits: meals, sleep, and personal care. Thus in total,
our SMHS consisted of 12 categories and 49 items.
The application was developed as a web-
application, optimised for tablet-use. The preferred
design needed to be as simple as possible, thus lim-
iting the amount of features available. When using
the application, the home screen gives an overview of
the results from the activity tracker and the question-
naires. Participants can select a topic from a question-
naire and fill out several questions. Once a category
is completed, results are shown on the results page,
where participants can also compare themselves to
normalised data from a previous study (Walters et al.,
2001). The results from the sensors are automatically
synchronised with the application and can be viewed
on a different screen. Different screenshots of the ap-
plication are shown in figure 2.
The sensors, which were integrated in the appli-
cation, consist of an activity monitor (Activ8, 2016),
a sleep monitor (Beddit, 2016), and a blood pressure
monitor (A&DCompany, 2016). The activity tracker
can be worn in a pocket of trousers and distinguishes
activities such as ‘lying down’, ‘standing’, ‘sitting’,
The Unacceptance of a Self-Management Health System by Healthy Older Adults
271
(a) Overview page.
(b) Question in questionnaire.
(c) Results from questionnaires.
(d) Results from sensors.
Figure 2: Screenshots of SMHS application.
‘walking’, ‘cycling’, and ‘running’. The sleep moni-
tor registers how long someone sleeps, as well as the
efficiency of the sleep represented by a sleep score.
The blood pressure monitor captures the systolic and
diastolic pressure as well as the pulse. Data from the
sensors were collected via BeWell Innovations (Inno-
vations, 2016) and automatically, through an API, in-
tegrated and visualised in the SMHS.
(a) Activ8
activity tracker.
(b) Beddit sleep
monitor.
(c) A&d blood
pressure monitor.
Figure 3: Integrated sensors in SMHS.
3.2 Measurement Instrument
To measure use and acceptance of the SMHS, we re-
lied on the Dutch variant of the questionnaire based
on Ebert et al. (Ebert et al., 2015), translated by De
Witte and Van Daele (De Witte and Van Daele, 2017).
This Dutch questionnaire polls for seven drivers: per-
formance expectancy (PE), effort expectancy (EE),
social influence (SI), facilitating conditions (FC),
anxiety (ANX), safety (SAF), and behavioural inten-
tion (BI). Minor adjustments were made to the items,
included changing ‘technology’ to ‘SMHS’, and ‘psy-
chological problems’ to ‘perceived self-reliance’. The
full list of all questions can be found in table 2. In to-
tal, the questionnaire consisted of 25 items to be an-
swered on a 5-point-Likert scale, were 1 represents
‘totally disagree’, and 5 represents ‘totally agree’,
thus 3 indicating ‘neither agree nor disagree’. All re-
sults were analysed via SPSS (IBM, 2017).
3.3 Participants
Participants were first contacted based on their indi-
cated interest in a previous study (D’Haeseleer et al.,
2019b). As only two of them were interested in par-
ticipating, further recruitment was carried out via the
snowball sampling method (Biernacki and Waldorf,
1981). Inclusion criteria stated that participants were
above 65 years old, living independently at home or
in a service flat, and not suffering from medical con-
ditions that required specific clinical supervision. The
study was approved by the Social and Societal Ethics
Committee (G-S60250).
3.4 Procedure
Before starting the study, the researcher (first author)
visited the older adults in their homes. She described
the study design, and explained the information in the
informed consent. Participants were able to ask ad-
ditional questions, and the researcher always had a
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272
Table 1: Demographic and experience information on participants. Information of the wearables are indicated as activity
(ACT), blood pressure monitor (BPM), and heart rate monitor (HRM).
Experiences with
code gender age living area tablet computer smartphone wearables owning wearables
P01 female 67 home with partner few few none none none
P02 male 69 home with partner little little none none none
P03 male 66 home with partner little little few a lot ACT, HRM
P04 male 80 home little little little none none
P05 female 82 flat few few few none BPM
P06 female 71 home with partner few little none none BPM
P07 female 84 flat few little little none BPM
P08 female 78 flat none few few none BPM
P09 female 66 home with partner a lot few a lot none BPM
P10 female 74 home with partner none little none none none
P11 male 76 home with partner none a lot none none none
P12 male 66 home with partner none little few little BPM, ACT
P13 female 75 home none none none little BPM
P14 female 86 flat little little little none BPM
P15 male 84 home with partner a lot a lot a lot none BPM, ACT
P16 female 71 home with partner few a lot a lot none BPM
tablet and one set of sensors with her, to show these
to the participants.
Once someone agreed on participating in this
study, a suitable starting date was chosen. This var-
ied from starting the same day to one month later, de-
pending on the availability of the participants and the
schedule of the researcher. On the starting day, par-
ticipants received a tablet with the web-application,
along with the sensors. The researcher installed ev-
erything and showed the participants how to interact
with the sensors and the application. Additionally,
every participant was asked to conduct each task at
least once, in order to get familiar with the technolo-
gies. Afterwards, participants were asked to fill out
the UTAUT questionnaire for the first time (PRE).
This evaluation polls for the users expectations of this
SMHS.
Participants were asked to fill out a questionnaire
at least every three days, and to use the sensors daily.
The experiment lasted for two weeks. The researcher
called the participant after one day, in order to check
up on their experiences. Depending on the needs of
the participant, the researcher made more frequent
visits (this varied from only at the start and end of the
study, to multiple times a week). Participants could
always call the researcher when they needed extra
support.
Finally, after two weeks had passed, the researcher
went back to the participant’s home, and a second
UTAUT questionnaire was taken (POST). In addition,
a semi-structured interview was conducted where par-
ticipants were asked about how they perceived using
wearable sensors, and whether they were interested in
using wearable sensors in the future. Moreover, the
researcher also briefly asked participant about their
overall experiences, what they liked and disliked.
4 RESULTS
In this section, we first present the results of the
UTAUT questionnaire, alongside relevant excerpts
from post-hoc interviews and observations. An
overview of all individual UTAUT items, along with
an overview of mean scores for each construct, Cron-
bach’s alpha, and mean difference can be found in ta-
ble 2. Next, we detail the data from the usage logs.
4.1 Participants and Experience Data
In total, 16 participants (median age = 74.5) were re-
cruited. Detailed information about the participants
can be found in table 1. As expected, participants had
never used an SMHS before. Five participants had
little to no experience with using a computer, ten par-
ticipants had little experience to no experience using a
tablet before, and six participants never used a smart-
phone.
4.2 Evaluation UTAUT Constructs
For each of the seven constructs, a reliability analysis
(by means of Chronbach’s alpha) was performed. Re-
sults of the average scores together with all individual
The Unacceptance of a Self-Management Health System by Healthy Older Adults
273
Table 2: UTAUT constructs and questions. All reversed items are marked with an asterix (
∗
).
Cronbach’s
Alpha
Mean (SD)
Code Construct and Item PRE POST PRE POST
EE Effort Expectancy .846 .789 3.18(.915) 3.79(.939)
EE
1
The SMHS was clear and easy to understand. 3.50(1.03) 4.06(1.29)
EE
2
Using the SMHS seems simple. 3.38(1.15) 4.00(1.16)
EE
∗
3
Using the SMHS seems complicated. 2.94(1.34) 3.62(1.50)
EE
∗
4
Before I can/could use the SMHS, I still need/had to
learn a lot.
2.13(1.09) 3.19(1.38)
EE
5
I have sufficient technological knowledge (turning on/off
and charging the devices) to use the SMHS.
3.94(1.18) 4.06(.998)
PE Performance Expectancy .891 .927 3.75(.957) 3.14(1.37)
PE
1
Using the SMHS would increase my perceived self-
reliance.
3.88(1.15) 3.19(1.38)
PE
2
Using the SMHS would increase my personal wellbeing. 3.63(1.03) 3.13(1.41)
PE
3
The SMHS would increase my confidence to live inde-
pendently.
3.63(1.20) 3.31(1.62)
PE
4
Using the SMHS would help me to age in place. 3.88(1.03) 2.94(1.61)
SI Social Influence .517 .574 3.72(.730) 3.28(.894)
SI
1
If people in my care networks would know this SMHS,
they would be positive about it.
3.87(.885) 3.38(1.15)
SI
2
It people in my care network would know this SMHS,
they would advise me to use it.
3.56(.892) 3.19(.981)
FC Facilitating Conditions .880 .679 4.06(1.29) 4.03(1.10)
FC
1
I own a computer or tablet, and could therefore use this
SMHS.
3.81(1.52) 3.88(1.41)
FC
2
I have a reliable internet connection. 4.31(1.20) 4.19(1.11)
ANX
∗
Anxiety .536 .877 3.31(1.34) 3.56(1.37)
ANX
∗
1
I am afraid to make an irrevocable mistake when using
the internet.
3.31(1.62) 3.88(1.31)
ANX
∗
2
The internet sometimes feels like something threatening. 3.31(1.62) 3.25(1.57)
SAF Safety .357 .774 4.31(.911) 3.66(1.30)
SAF
∗
1
I am afraid that confidential information will fall into the
wrong hands.
3.81(1.56) 3.13(1.71)
SAF
2
I am confident that when I use the SMHS, that all infor-
mation will be treated strictly confident.
4.81(.544) 4.19(1.11)
BI Behavioural Intention .828 .804 2.86(.992) 2.55(1.13)
BI
1
I would recommend the SMHS to others (older adults),
when they are still living independent at home.
3.87(.957) 3.75(1.29)
BI
2
I would like to use this SMHS in the future. 3.44(1.37) 2.50(1.367)
BI
3
I would purchase this SMHS, if this would be commer-
cially available.
3.00(1.21) 2.44(1.41)
BI
4
How often do you think you would use this SMHS in the
future. (1: never, 2: once a month, 3: once a week, 4:
twice or three times a week, 5: every day)
1.13(1.31) 1.50(1.59)
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274
items are pictured in table 2. Results indicate that be-
fore starting the experiment, participants were neutral
to positive towards using an SMHS. When analysing
the results after the study, scores slightly decreased
for all constructs, except for effort expectancy. Below,
all constructs and average ratings, along with quotes
from the interviews, are given.
Effort Expectancy. EE initially scored an average
of 3.18 (SD=0.92) (on a scale from 1 to 5), thus
close to neutral. After the study, this score increased
to 3.79 (SD=0.94), indicating that older adults’ per-
ceived ease of use increased after the two-week study.
These scores are in line with observations from the
researcher who made the house visits. It was often
noticed that at first, participants were afraid of hav-
ing to use the tablet. However, after going through
the application together, participants managed to use
it independently.
P05: “In the beginning it is a bit overwhelm-
ing, but once you use it, it all goes very well.”
(day 2)
Performance Expectancy. PE scored initially 3.75
(SD=0.96) out of 5, thus neutral to positive, but after
the study this construct scored only 3.14 (SD=1.4),
hence it decreased to a neutral score. This indicates
that older adults found the application more useful at
the beginning of the study compared to after using it
for two weeks. Overall, participants found it interest-
ing to follow up on their own health. Especially when
using the sensors, often participants mentioned they
gained new insights, and where happy to learn more
about their activity, blood pressure, and/or sleep.
P16: “It is striking to see how much you sit
down every day. Interesting to follow up on.”
(day 8)
Some participants were just curious, and did not feel
the need to keep on using these sensors for a longer
period.
P05: “I found it interesting to follow up on my
sleep patterns. I was already familiar with my
activities and blood pressure. But now I know,
so I would not keep on using it.” (day 14)
The blood pressure monitor was already used in ad-
vance by most participants. Others, who did not regu-
larly take their blood pressure also indicated that they
found it interesting to follow up. Although one person
also reported that ambivalence, since noticing your
blood pressure is too high can also make you worried.
P01: “I would find blood pressure measure-
ment interesting, but because I have had a
higher [cf. blood pressure] all day, it was
rather worrying me.” (day 13)
Social Influence. SI scored initially 3.72 (SD=0.73)
out of 5, thus neutral to positive, but after the
study this construct decreased to 3.28 (SD=0.89).
Participants often mentioned they did not really know
what their friends/family or physicians would think
about using such an SMHS, as this was never been
discussed.
Facilitating Conditions. FC scored initially
4.06 (SD=1.3) out of 5, thus positive, and after
the study this construct scored still positive with
4.03 (SD=1.1). This is normal as the facilities of
the person’s home have not changed during the
experiment. Almost every participant had access
to either a tablet or a computer, although many of
them did not use these. Also a wireless internet
connection was often available at the participants’
home, however, they had little knowledge on how this
could be accessed. Luckily, in this study, mobile data
cards were implemented in the tablets, so the tablet
and sensors did not need to be attached to the network.
Anxiety. ANX scored initially 3.31 (SD=1.3)
out of 5, thus neutral to positive, but after the study
this score increased to 3.56 (SD=1.4). Note that
items from this construct were reversed, thus a more
positive response indicates that participants were
less anxious towards using the internet. Overall,
participants did not reported anxiety towards using
the internet. However, we noticed that on the first
day, participants were often afraid when using the
tablet. Therefore, it was very important to take time
to comfort them and let them understand they cannot
do anything wrong.
P01: “So I just need to do this [cf. take blood
pressure with a blood pressure monitor] and
then I actually do not need to touch this [cf.
tablet]? [...] I am not going to use that [cf.
tablet].” (day 1)
P04: “I am afraid to do something wrong, or
to forget something.” (day 1)
Safety. SAF scored initially 4.13 (SD=0.91) out of 5,
thus positive, but after the study this construct scored
3.66 (SD=1.3) which is neutral to positive. Nobody
had problems with sharing this sensitive information,
as this was a research study. In this study, privacy
issues from commercial systems were not explicitly
discussed, but in one interview the participant men-
tioned that she had no problem in sharing information,
The Unacceptance of a Self-Management Health System by Healthy Older Adults
275
as this was already also the case with smartphones (cf.
Android from Google) and online advertising.
P09: “Privacy? I have no problems with pri-
vacy. Then you should look at Google and all
their advertising.” (day 15)
Behavioural Intention. BI scored initially 2.86
(SD=0.99) out of 5, thus negative to neutral, but after
the study this construct scored only 2.55 (SD=0.94),
meaning it further decreased. Participants did utter to
find the application useful, however, it was mentioned
multiple times that they would not (yet) need it them-
selves, as they were still in good health.
P09: “Those questionnaires in particular can
be of interest to single elderly people [cf. she
is still living together with her husband]. Cer-
tainly if that would be mandatory and the
physicians also support it.” (day 15)
Participants quickly got used to the application and
the sensors. Using the sensors became a habit for
most of them. At the same time, at the end of the
study, some mentioned they would “not be missing
the sensors”.
P05: “It went very quickly to get used to the
sensors. However, this system is not for me, I
do not need it yet. Moreover, I would rather
not become a ‘slave’ of all those devices.”
(day 14)
4.3 SMHS Usage Data
Each participant used the application during a two-
week study, varying from 13 to 16 days, depending on
the availability of the person. Participants were asked
to wear an activity tracker every day, to measure their
blood pressure at least once a day, and to use a sleep
monitor every night. Figure 4 gives an overview of
how participants interacted with the SMHS. Note that
all data has been rescaled to the same period, to in-
crease readability. In addition, for each person, a gray
line indicates the exact length of participation in the
study. For each participants, all sensor and/or ques-
tionnaire interactions are pictured.
Questionnaires. Since every participant was asked to
complete a full set of questionnaires (12 categories)
every three days, and to use the sensors daily, ide-
ally this would result in five complete sets, totaling
60 categories. This was only achieved by one par-
ticipant (P08). In contrast, participant P13 quit after
eight days, completing only nine categories. Four par-
ticipants stopped filling out questionnaires after seven
to ten days, the other twelve participants completed
between 36 and 52 categories throughout the entire
study period. Data results, aggregated over all partic-
ipants, show that each category was completed 53 to
68 times throughout the two week study period. In or-
der of importance, the following categories were an-
swered most frequently: emotional role functioning,
sleep, social functioning, mental health, and meals.
Activity Tracker. The activity tracker was used by
15 out of 16 participants. Figure 4 represents a time-
line of participants’ activities, i.e., walking, cycling,
running, sitting, or standing, where at least one ac-
tivity was measured during a five-minute block. The
gaps during the night indicate that participants were
not wearing their tracker when they were sleeping.
From all participants, one person (P01) did not wear
an activity tracker, as she felt her outfit did not al-
low to attach the sensor. Two participants (P02, P15)
stopped wearing the tracker for at least a week within
the study, and one participant (P13) only wore the
tracker for ten consecutive days. Presumable these
participants forgot to charge the battery. The other 12
participants wore the activity tracker daily.
Sleep Monitor. The sleep monitor was used by 14 out
of 16 participants. One participant (P13) was afraid
of using the sleep monitor during the night as she also
had an electrical blanket on top of the mattress and
therefore excluded this sensor. Another participant
(P16) preferred not to use the sleep monitor. The other
participants used the sleep monitor, if possible, as of-
ten participants reported troubles getting data out of
the sensor. Because the support for the type of sleep
monitor used in this study, ‘Beddit’ (Beddit, 2016),
was discontinued, problems occured when pairing the
device. For the first six participants, the sleep moni-
tor was either disfunctional or taken away for replace-
ment, indicating one to three nights without measure-
ments. For participant P07, 10 out of 14 nights, the
sleep monitor was disfunctional. For participant P09
to P12 the sleep was not registered during one to five
nights. While testing with participants P14 and P15,
the integration between the sensors and the platform
was disfunctional and therefore did not register for re-
spectively 11 and 14 days.
Blood Pressure Monitor. The blood pressure mon-
itor was used by all participants. Since some extra
measurements were due to an error in the syncing
process, the measurements that were taken within 5
min of each other were excluded in this analysis. One
participant (P13) only used the blood pressure mon-
itor eight times. This was due to the inability of the
person to attach the strap of the measurement device
TEG 2020 - Special Session on Technology, Elderly Games
276
Figure 4: Usage data from all participants during the two-week experiment.
The Unacceptance of a Self-Management Health System by Healthy Older Adults
277
by herself. Therefore, measurements were only taken
when an additional visitor came by. Participant P08
was an exception, as she took her blood pressure 69
times during the 15 days. In general, on average, par-
ticipants took their blood pressure one to two times a
day.
5 DISCUSSION
This study aimed to investigate whether healthy com-
munity dwellers, aged 65+, were ready to adopt an
SMHS in a real-world home environment. Prior to use
all determinants of use and acceptance of SMHS in
our study were neutral to positive: effort expectancy
(EE), performance expectancy (PE), social influence
(SI), facilitating conditions (FC), anxiety (ANX), and
safety (SAF). Post use, all values (except for EE and
FC) decreased. Moreover, post use, older adults’ be-
havioural intention (BI) scored only an average score
of 2.55 (SD=1.1).
Reflection on SMHS. Our findings contrasts with the
study from Doyle et al. (Doyle et al., 2014), which
is perhaps most akin to our study setup. Several hy-
potheses can be put forward. This may be due to the
specific SMHS design. This may also be attributed
to the use of a different methodology in polling for
adoption. Finally, the different results may also be
due to the fact that the average age of participants in
our study is older. Studies suggest the older the par-
ticipants, the less motivated they are to use interac-
tive health technologies such as a tracker (McMahon
et al., 2016). Similar to Doyle’s findings, however, we
found that older adults like to have freedom in per-
sonalisation, in our case determining which health-
related themes they find interesting.
Reflection on UTAUT Model. In this study, we
relied on the theoretical model of Venkatesh, et al.
(Venkatesh et al., 2003) in order to predict technology
acceptance. This UTAUT model suggests that mea-
surements on the constructs EE, PE, FC, and SI pre-
dict BI, in particular, positive scores on the aforemen-
tioned drivers should also result in a positive score for
BI. Surprisingly, this was not confirmed in our results.
Research from Peek et al. may provide extra insights,
as they investigated motivators for older adults in or-
der to use (new) technologies, as well as impact of
changes and stability of use (Peek et al., 2016; Peek
et al., 2017; Peek et al., 2019). This Cycle of Tech-
nology Acquirement by Independent-Living Seniors
(C-TAILS) model gives an overview of many differ-
ent influential factors in technology adoption by older
adults, including the importance of support by friends
or family, which is weighted strongly. This is in line
with our findings, as the construct social influence
from friends/family or physicians scored rather low
(neutral) post use.
Similar findings were also reported in
(D’Haeseleer et al., 2019a), where authors found
that older adults lack the perceived value of SMHS,
and did not welcome the accompanying shift from
curative to preventive care (Vines et al., 2015). Here,
authors emphasised that older adults will not use
SMHS, or interactive technologies in general, unless
they find it irrefutably useful. This finding is echoed
in this study, as older adults did mention to find the
SMHS useful (PE), but simply not for them. They did
not (yet) see the benefits of using SMHS themselves.
6 CONCLUSION
In this study, we report on the uses and attitudes of 16
healthy participants aged over 65. During a two week
study, participants used an SMHS in a real world set-
ting, at home. An adapted version of Unified The-
ory of Use and Acceptance for Technology (UTAUT)
was used to measure acceptance, both pre and post,
towards an SMHS (De Witte and Van Daele, 2017;
Venkatesh et al., 2003). In addition, usage data was
explored, as well as a post-hoc interview with the par-
ticipants. Results indicate that participants did find
the application user-friendly and felt confident in us-
ing the application. They also had access to a com-
puter or tablet with internet access. Despite these
positive aspects, they did not see the benefits of fol-
lowing up on their own health regularly, and their
behavioural intention decreased even more after the
two-week study.
However, only one SMHS was tested in this study,
with a limited sample. Therefore, future research is
needed to investigate whether these results can be
generalised to other SMHS, and a broader group of
older adults aged 65+.
ACKNOWLEDGEMENTS
We would like to thank all users for their participa-
tion. This research study was possible with the sup-
port of KIC EIT funding for GRACE-AGE.
TEG 2020 - Special Session on Technology, Elderly Games
278
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