Making Environments Work for People

A Novel Approach towards Personal Lifestyle Management Informatics

Eleni Kaldoudi

School of Medicine, Democritus University of Thrace, Dragana, Alexandroupoli, Greece

Keywords: eHealth, Personal Health Systems, Healthy Behaviour, Lifestyle Related Disease, Self-engagement,

Self-management.

Abstract: This paper introduces a new paradigm for personalized systems used by the citizen for self-management of

health and disease: using smart technologies to exploit the health potential of surrounding environments and

to support the citizen in decisions related to a healthy lifestyle. This approach proposes meshing the

citizen’s specific needs for healthier behaviours with what is available to meet these needs in the

surrounding environment. Rather than focusing on health monitoring alone, the aim should be to create a

healthy digital envelope – a Healthy Place – around the citizen as they move through their everyday lives.

The implementation of this approach needs to integrate existing systems for health assessment and

environmental predictions; collect personal private data from mobile personal sensors and public data on

health content of the environment; design dynamic testable models of behaviour change, that situate the

individual within their environment; develop advanced analytics for context understanding and situational

awareness that will couple the current goals of the person with what his or her environment can offer; and

create personalized decision support services for behaviour change that exploit the current match between a

person’s needs and the opportunities offered by his or her environment.

1 INTRODUCTION

Information and communication technologies have

conventionally been used to support disease

management. A second generation of interventions

addresses personal patient informatics, building the

‘quantified self’ to increase self-knowledge and

autonomy via (large scale) personal data collection.

The current trend is for personal devices and

applications whose primary purpose is less to

enlighten users with information than to urge them

to change (Singer, 2015). However, broadcasting

generic health messages (e.g. ‘do this, don’t do that’)

has relatively modest effects unless the

context/environment makes the advocated changes

very easy to carry out. Technology today cannot

significantly alter physical environments in this

respect, but it can alter something equally or even

more important: the perceived environment.

In this paper, we propose an innovative

approach of meshing the citizen’s specific needs and

goals for healthier behaviours with what is available

to meet these needs in the surrounding environment.

Rather than focusing on health monitoring alone or

individual medical and behaviour change plans, the

proposed approach aims to create a healthy digital

envelope – a Healthy Place – around the citizens as

they move through their everyday lives.

2 BACKGROUND

Lifestyle-related diseases are defined as non-

communicable diseases and are caused by non-

physiological lifestyle factors such as unhealthy diet,

physical inactivity, tobacco use, excessive use of

alcohol and psychosocial factors e.g. chronic stress

and depression, are leading causes of death globally.

Chronic non-communicable diseases such as

cardiovascular disease, cancer, diabetes and chronic

respiratory disease, were responsible for 36 million

deaths (67% of all deaths) in a single year (WHO,

2010). All these diseases are profoundly impacted

by lifestyle options including dietary intake,

exercise, stress, sleep, and use of alcohol.

Lifestyle changes in these patients can prevent

the progress of the disease more successfully than

418

Kaldoudi E.

Making Environments Work for People - A Novel Approach towards Personal Lifestyle Management Informatics.

DOI: 10.5220/0006235904180423

In Proceedings of the 10th International Joint Conference on Biomedical Engineering Systems and Technologies (BIOSTEC 2017), pages 418-423

ISBN: 978-989-758-213-4

any drug treatment (Spruijt-Metz, 2014; Wilson,

2014; Williamson, 2005; Li, 2014)

During the last decade, different forms of health

care delivery have also been considered, based on

the specific needs of patients with chronic diseases,

such as patient empowerment. Environmental

information as provided by smart cities

infrastructure has been proposed to augment

personal health applications and help citizens choose

wisely their whereabouts in the urban environment

(Solanas, 2014). Furthermore, the WHO, among

others, has promoted the idea of preventing disease

through healthy environments (Pruss-Ustun, 2006).

To ensure sustainable healthy behavioural change,

we must foster and promote environments that can

support people in healthier lifestyle habits.

As it is difficult to radically change the

environments of developed societies, we propose to

change how the environment is perceived. This will

be achieved by highlighting, on an individual basis,

those aspects of the environment that are most

conducive to encouraging and maintaining

personalized healthy behaviours. Thus, the aim is to

‘change’ the place around the citizen into a

‘perceived’ Healthy Place. For the rest of this

document, therefore, the term Healthy Place is used

to refer to a place whose health-related aspects have

been highlighted by the proposed technological

framework.

3 HEALTHY PLACES CONCEPT

For any place of everyday life to turn into a

perceived Healthy Place, its objects and concepts

must be semantically described and linked to healthy

habits and values, thus creating an augmented

environment for individuals to manage health,

lifestyle and disease. To be relevant, this needs to

relate to the individual’s every day, real world

context and be coupled to the personal lifestyle and

the medical/behavioural goals of the individual in

question.

There are three different types of data that

pertain to this approach: private personal data,

public data on the ambient surroundings, and health

related scientific evidence including predictive

models and risk assessment (Figure 1).

Private, individual-level data includes: (a)

personal information on health issues, e.g.

demographics, allergies, risk factors, etc. as

available from a personal health record; (b) real-time

information on physical activity, location, and

dietary choices; (c) lifestyle related information

from the person’s social media presence, including

attitudes, intention and relations to the community;

and (d) via analysis of the above, information on the

motivational and emotional state of the person.

Public data includes data on healthy aspects of

resources and activities of a place, incorporating

commerce, retail, leisure, workplace and community

aspects, or the ambient environment. Aggregating

public data on life contexts can be driven by

stakeholders in commerce, retail, leisure, workplace,

community who will publish key data; it can also

use participatory sensing approaches.

Major lifestyle related contexts include:

 Food: the ingredients and calorific content of

food items are an obvious and important source

of data when considering one’s health. This data

can be used in relation to: managing weight,

ensuring an appropriate balance of nutrients is

consumed and coping with food allergies.

Additional information includes meal

preparation processes, e.g. the type of fat used

for frying, whether menu items have been in the

proximity of nuts and other common allergens.

 Recreational activities: rich description of

activities in terms of their work load, difficulty,

special requirements, indications and contra-

indications for the healthy person at different

ages and capacities and when suffering from

different health conditions and disease.

 Public Transport: with the emergence of ‘Smart

Cities’ and public Open Data there is a growing

tendency for data concerned with transport

routes, stop and station locations, timetables and

vehicle locations to be publicly available. This

data can be used to help with maintaining a

certain level of exercise and energy

consumption.

 Ambient environment: temperature,

meteorological conditions, noise level, air

pollution, airborne allergens, etc. pollen counts,

as well as meteorological conditions can affect

health.

Ground medical evidence and health prediction

models can serve as the basis on which the current

environment is analysed for the opportunities it

offers and threats it presents for the individual. The

goal is to dynamically highlight the most suitable

attribute of each environment for the individual and

deter from any threats this environment may hold,

based on the needs of each person. Thus, the same

environment is presented differently according to the

health condition and requirements of each

individual.

Making Environments Work for People - A Novel Approach towards Personal Lifestyle Management Informatics

419

medicalevidence&

healthpredictivemodels

personal

healthdata

healthcontent

oftheenvironment

via

lif econtextdescriptions&

participatorysensing

quantifiedself

mindchange

model

decision

support

analytics

data

interlinking

healthylifestyle

virtualcoach

Figure 1: Data aggregation to realize the concept of a Healthy Place.

The coupling of public and personal data

projected against a behaviour and behaviour change

model to create personalized recommendation

services for the citizen via a personal application.

This can virtually coach individuals by supporting:

(a) advanced behaviour and environment awareness;

(b) self-monitoring, goal setting, and action

planning; and (c) motivational and sustained

behaviour change. Thus, individuals can explore

personal motives, competences, life goals,

preferences, social connections, and other internally-

driven motivational elements around physical

activity, healthy eating and healthy behaviours in

general. These can be coupled with opportunities

offered by the current environment. Social

intelligence tools can also be used to tap into

participants’ sense of volition and ownership (as

opposed to merely external pressure), confidence

and competence (as opposed to self-perceptions of

unpreparedness and even failure), and positive social

support for their activities and goals.

4 OPEN RESEARCH ISSUES

The proposed concept of combining health related

content with personal information to create an

optimum perceived Healthy Place for each

individual can be approached by a modular

architecture as shown in Figure 2.

Starting from top to bottom, data and knowledge

acquisition components acquire personal and public

data. Personal data is nowadays readily available via

a variety of commercially available wearable and

other personal sensors and systems (e.g. personal

health records). However, describing the health

content of the environment may prove challenging.

Participatory sensing can be employed to exploit the

crowds and their mobile devices to harvest and

enrich the information about the environment and

living spaces (e.g. the noise level and the

temperature of a place, photos of food items for

optical nutritional recognition, etc.).

Information a person creates on social networks

may prove to be a significant determinant of

behaviour: We are all individuals who are

interconnected with other individuals by personal,

social, economic and workplace relationships. These

connections facilitate communication, can motivate

us to different behaviours, and have the potential to

support shifts toward healthier lifestyles. Further

research is expected to adapt and develop the

necessary natural language processing, information

retrieval and machine learning methods, combining

data mining with semantic technologies and

expertise in social media sentiment analysis.

Data enriching and interlinking is of outmost

importance to bring up rich data relationships that

would help couple personal health requirements with

the opportunities in the environment. Thus, graph

data repositories (Angles, 2012) are chosen to

establish the middle layers of the proposed

architecture: a public one for the health context of

living spaces and a private for the personal

HEALTHINF 2017 - 10th International Conference on Health Informatics

420

www,LOD

sensors

LinkedOpenData

opendata

social networks

personal,private

LinkedData

repository

LinkedOpenData

repository

dataanalysis

visualization

existing

predictive

models

privatepersonaldata

profiling

users

decisionsupportservices

‒ realbehaviour tracking

‒ goalsetting,actionplanning

‒ motivationalsustained

behaviour change

personal

application

personalized

behaviour &

behaviour

change

model

integratedservicesplatformtorealizeapersonalperceivedhealthylivingspace

dataharvesting

andenrichment

information

extraction

harvesting

sentiment

analysis

data

extraction

sensorsdata

extraction

Figure 2: Overview of an abstract framework to realize personal perceived Healthy Places.

information. Although a lot of work has been put on

releasing semantically rich Open Data,

contemporary solutions often fall short of fully

exploiting the Semantic Web’s potential (d’Aquin,

2008). This shortcoming owes mainly to a) the

shortage of adequate knowledge acquisition

mechanisms, b) the lack of an environment-based,

life and health related semantically integrated

approach and c) the slow progress concerning the

linkage of user data with the Web of Data.

Despite the proliferation of semantic web data,

most published data remains semantically poor (e.g.

XHTML, XML, CSV files). To leverage this wealth,

research should focus on developing solutions that

enable knowledge acquisition, which can be

accommodated using different approaches, such as

data and information extraction, and sentiment

analysis. Applications that are based on traditional

database modelling principles suffer from difficulty

in capturing evolution of the data model, high

software maintenance cost and low reusability. The

semantic web achieves the translation of data across

boundaries that separate different domains and

overcomes these limitations (Feigenbaum, 2007).

Further research is required to define and analyse the

model and corresponding ontology/schema to

describe health context of living spaces. This entails

detailed examination and exploitation of existing

health and life vocabularies and development of the

appropriate Linked Services and service information

(Pedrinaci, 2010).

The emergence of social web has led to the

generation of user interaction and preferences traces

that are often distributed, fragmented and detached

(Rowe, 2009). This limitation not only complicates

efforts to gather relevant user information, but also

weakens the ties between personal data and the web

of data. However, it fails to safeguard privacy, given

the potential for a determined data-gatherer to

integrate diverse data sources to form a detailed

picture of an individual’s actions and preferences.

Concerning the linkage between personal data and

the web of data further research is required to

integrate personal data and web of data through a

single services interface, while ensuring the highest

level of privacy protection for individuals.

Support for analysis and visualization of large

data sets can in principle be done by aggregation

performed in either data space (data reduction) or in

visual space (visual aggregation). Scalability is a key

challenge in visual analytics as it determines the

ability to process large datasets by means of

computational overhead as well as appropriate

rendering techniques. Often, the huge amount of

Making Environments Work for People - A Novel Approach towards Personal Lifestyle Management Informatics

421

data that must be visualized exceeds the limited

number of pixels on a display by several orders of

magnitude. Currently existing techniques typically

focus on a single given data type, e.g., time series or

text data, so further research is required to address

multiple data perspectives simultaneously.

The wealth of available personal health devices

and applications, should be amended by novel

applications tracking real-time personalized lifestyle

to deduce the person’s current real behaviour and

how much this deviates from what is a healthy

behaviour for this person (especially as specified by

the individual in terms of his or her personal

behavioural goals) and to determine mind changing

actions (i.e., behaviour change through cognitive and

emotional determinants). Novel tools are also

required to support individuals to engage with self-

monitoring, goal setting, personal projects and

coping plans. New motivational and sustained

behaviour change decision support applications

should be devised to allow individuals to explore

personal motives, competences, life goals,

preferences, social connections, and other internally-

driven motivational elements around physical

activity, healthy eating and healthy behaviours in

general.

A major enabling factor for realizing the

personal healthy space via messing public and

private health related data lies in the challenge to

preserve privacy (Vayena, 2015). Although

healthcare data are customarily anonymised to

ensure a certain level anonymity (Gkoulalas-

Divanis, 2014), they remain susceptible to threats

caused by data linkage (e.g., with publicly available

data sources) or by background knowledge. Thus,

effective measures for preserving privacy must be

developed (Viceconti, 2015). Also, patient consent

(and its revocation) is recognized as a major

limitation in broadly re-using available healthcare

datasets for novel big data analytics (Barash, 2015).

Additionally, the recent agreement on Commission’s

EU Data Protection Reform (EU Regulation

2016/679) recognizes that practices have to respect

the citizens’ rights to (1) easily access their own

data, (2) transfer data among providers; (3) have

their data deleted when no longer needed; (4) know

when their own data have been hacked. Thus, new

research is required to extend anonymization

algorithms to work on a distributed setting, where

multiple parties hold different parts of the data that

cannot or are not willing to share in raw form.

develop and validate computationally efficient

algorithms for detecting complex events in

healthcare data streams. This research should also be

complemented by novel privacy preserving consent

management mechanisms and cryptography enabled

techniques for anonymous and unlikable feedback

and reward mechanisms to return useful service

output to the citizen (e.g. a health prediction or

personal health status) or reward the citizen for

contributing personal data.

5 DISCUSSION

In a radical departure from traditional eHealth, this

paper introduces a new paradigm for personalized

systems used by the citizen for self-management of

health and disease: smart technologies based on

existing predictive systems are used to exploit the

health potential of the surrounding environment and

support the citizen in his/her decisions related to a

healthy lifestyle. To achieve this, novel research

should address the following:

 integrate existing predictive systems from

different domains, namely (a) health risk

assessment models, calculating risks based on

current health condition; (b) health predictive

systems based on environmental factors; (c)

behavioural models; and (d) predictive models

of environmental parameters, e.g. weather

conditions, air pollution and noise levels;

 collect personal data from mobile personal

sensors but also collect data on health content of

the environment via citizen participatory

sensing;

 design dynamic testable models of behaviour

change, that situate the individual within their

environment and take full account of cognitive,

social and emotional aspects;

 develop technology that allows the semantic

description of health-related aspects of an

environment as well as of health-related aspects

of a person’s behaviour;

 perform advanced analytics for context

understanding and situational awareness that

will couple the current goals of the person with

what the current environment can offer; and

 deploy personalized recommendation services

for behaviour change that, based on

personalized predictions, exploit the current

match between a person’s needs and the

opportunities offered by his or her environment.

The goal is to: (a) help citizens manage actively

health and eventually adopt and maintain a healthy

behaviour, and thus prevent lifestyle related

diseases; and (b) make stakeholders in food,

commerce, retail, leisure, workplace and community

level aware of the healthy (or non-healthy) aspects

of the goods, opportunities and premises they offer

HEALTHINF 2017 - 10th International Conference on Health Informatics

422

to the public and provide them with technology to

promote what is healthier for each citizen.

Health cannot be successfully promoted and

sustained by health care systems alone – these are

naturally focussed on treatment much more than

prevention. At the same time, changing

environments with health-related goals in mind is

extremely difficult – it requires political will and

sometimes costly investments; health is a goal that

needs to be balanced alongside other priorities, such

as prosperity or efficiency.

Changing citizens’ awareness of their everyday

environment, in the light of their own priorities and

goals, creates a new possibility for the prevention of

lifestyle related diseases and, indeed, for the co-

production of health and reduction of potential

chronic, life quality reducing and costly health

conditions and complications.

ACKNOWLEDGEMENTS

The concept presented in this paper was inspired

mainly by work done in the FP7-ICT project

CARRE (No. 611140), funded by the European

Commission

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