More Web Proxy on the site http://driver.im/

research-article

Remote health monitoring of elderly through wearable sensors

Authors:

Mohammed Al-khafajiy,

Hoshang Kolivand,

Muhammad Fahim,

Atif WaraichAuthors Info & Claims

Volume 78, Issue 17

Pages 24681 - 24706

https://doi.org/10.1007/s11042-018-7134-7

Published: 01 September 2019 Publication History

Abstract

Due to a rapidly increasing aging population and its associated challenges in health and social care, Ambient Assistive Living has become the focal point for both researchers and industry alike. The need to manage or even reduce healthcare costs while improving the quality of service is high government agendas. Although, technology has a major role to play in achieving these aspirations, any solution must be designed, implemented and validated using appropriate domain knowledge. In order to overcome these challenges, the remote real-time monitoring of a person’s health can be used to identify relapses in conditions, therefore, enabling early intervention. Thus, the development of a smart healthcare monitoring system, which is capable of observing elderly people remotely, is the focus of the research presented in this paper. The technology outlined in this paper focuses on the ability to track a person’s physiological data to detect specific disorders which can aid in Early Intervention Practices. This is achieved by accurately processing and analysing the acquired sensory data while transmitting the detection of a disorder to an appropriate career. The finding reveals that the proposed system can improve clinical decision supports while facilitating Early Intervention Practices. Our extensive simulation results indicate a superior performance of the proposed system: low latency (96% of the packets are received with less than 1 millisecond) and low packets-lost (only 2.2% of total packets are dropped). Thus, the system runs efficiently and is cost-effective in terms of data acquisition and manipulation.

References

[1]

Adlam T, Faulkner R, Orpwood R, Jones K, Macijauskiene J, Budraitiene A (2004) The installation and support of internationally distributed equipment for people with dementia. IEEE Transactions on Information Technology in Biomedicine

[2]

Ali A, Ming Y, Chakraborty S, Iram S (2017) A comprehensive survey on real-time applications of WSN. Fut Internet 9(4):77

[3]

Alsina-Pagès RM, Navarro J, Alías F, Hervás M (2017) homeSound: Real-Time Audio Event Detection Based on High Performance Computing for Behaviour and Surveillance Remote Monitoring. Sensors

[4]

Angelini L, Carrino S, Abou Khaled O, Riva-Mossman S, Mugellini E (2016) Senior living lab: an ecological approach to foster social innovation in an ageing society. Fut Internet 8(4):50

[5]

Barnes NM, Edwards NH, Rose DA, Garner P (1998) Lifestyle monitoring-technology for supported independence. Computing & Control Engineering Journal

[6]

Bonato P (2010) Wearable sensors and systems. IEEE Eng Med Biol Mag 29 (3):25–36

[7]

Bouchard B, Giroux S, Bouzouane A (2007) A keyhole plan recognition model for Alzheimer’s patients: first results, vol 21

[8]

Catarinucci L, De Donno D, Mainetti L, Palano L, Patrono L, Stefanizzi ML, Tarricone L (2015) An IoT-aware architecture for smart healthcare systems. IEEE Internet Things J 2(6):515–26

[9]

Chauhan J, Bojewar S (2016) Sensor networks based healthcare monitoring system. In: International conference on inventive computation technologies (ICICT). IEEE, Vol 2, pp 1–6

[10]

Chen TL, King CH, Thomaz AL, Kemp CC (2011) Touched by a robot: an investigation of subjective responses to robot-initiated touch. In: 2011 6th ACM/IEEE international conference human-robot interaction (HRI)

[11]

Chouvarda I, Antony R, Torabi A, Weston J, Caffarel J, van Gils M, Cleland J, Maglaveras N (2013) Temporal Variation in telemonitoring data: on the Effect of Medication and Lifestyle Compliance. International Journal of Bioelectromagnetism

[12]

Cook D, Das SK (2004) Smart environments: technology, protocols and applications. Wiley, New York

Digital Library

[13]

Dall TM, Gallo PD, Chakrabarti R, West T, Semilla AP, Storm MV (2013) An aging population and growing disease burden will require alarge and specialized health care workforce by 2025. Health affairs

[14]

Dohr A, Modre-Opsrian R, Drobics M, Hayn D, Schreier G (2010) The internet of things for ambient assisted living. In: 2010 seventh international conference on information technology: new generations (ITNG), pp 804–809

[15]

Dudakiya S, Galani H, Shaikh A, Thanki D, Late RA, Pawar SE (2016) Monitoring mobile patients using predictive analysis by data from wearable sensors. In: International conference on electrical, electronics, and optimization techniques (ICEEOT). IEEE, pp 332–335)

[16]

El-Darzi E, Vasilakis C, Chaussalet T, Millard PH (1998) A simulation modelling approach to evaluating length of stay, occupancy, emptiness and bed blocking in a hospital geriatric department. Health Care Manag Sci 1(2):143

[17]

Gupta MS, Patchava V, Menezes V (2015) Healthcare based on IoT using Raspberry Pi. In: 2015 international conference on green computing and internet of things (ICGCIoT). IEEE, pp 796–799)

Digital Library

[18]

Hassanalieragh M, Page A, Soyata T, Sharma G, Aktas M, Mateos G, Kantarci B, Andreescu S (2015) Health monitoring and management using Internet-of-Things (IoT) sensing with cloud-based processing: opportunities and challenges. In: 2015 IEEE international conference on services computing (SCC). IEEE, pp 285–292)

[19]

Islam SR, Kwak D, Kabir MH, Hossain M, Kwak KS (2015) The internet of things for health care: a comprehensive survey. IEEE Access 3:678–708

[20]

Kumar R, Rajasekaran MP (2016) An IoT based patient monitoring system using raspberry Pi. In: International conference on computing technologies and intelligent data engineering (ICCTIDE). IEEE, pp 1–4

[21]

LeBellego G, Noury N, Virone G, Mousseau M, Demongeot J (2006) A model for the measurement of patient activity in a hospital suite. IEEE Transactions on information technology in biomedicine

[22]

Lee C, Kim T, Hyun SJ (2016) A data acquisition architecture for healthcare services in mobile sensor networks. In: 2016 International conference on big data and smart computing (BigComp). IEEE, pp 439–442

[23]

Lin CT, Ko LW, Chang MH, Duann JR, Chen JY, Su TP, Jung TP (2010) Review of wireless and wearable electroencephalogram systems and brain-computer interfaces–a mini-review. Gerontology 56(1):112–9

[24]

Luprano J, De Carvalho P, Eilebrecht B, Kortelainen J, Muehlsteff J, Sipila A, Solà J, Teichmann D, Ulbrich M (2013) HeartCycle: advanced sensors for telehealth applications. In: 2013 35th annual international conference of the IEEE engineering in medicine and biology society (EMBC)

[25]

Luprano J, Solà J, Dasen S, Koller JM, Chételat O (2016) Combination of body sensor networks and on-body signal processing algorithms: the practical case of MyHeart project. In: null. IEEE, pp 76–79

[26]

Madden SR, Franklin MJ, Hellerstein JM, Hong W (2005) TinyDB: an acquisitional query processing system for sensor networks. ACM Trans Database Syst (TODS) 30(1):122–73

Digital Library

[27]

Manzano-Santaella A (2010) From bed-blocking to delayed discharges: precursors and interpretations of a contested concept Health services management research

[28]

Mégret R, Dovgalecs V, Wannous H, Karaman S, Benois-Pineau J, El Khoury E, Pinquier J, Joly P, André-Obrecht R, Gaëstel Y, Dartigues JF (2010) The IMMED project: wearable video monitoring of people with age dementia. In: Proceedings of the 18th ACM international conference on multimedia

[29]

Mottola L, Picco GP (2011) Programming wireless sensor networks: fundamental concepts and state of the art. ACM Comput Surv (CSUR) 43(3):19

Digital Library

[30]

Navarro J, Vidaña-Vila E, Alsina-Pagès R M, Hervás M (2018) Real-Time Distributed architecture for remote acoustic elderly monitoring in Residential-Scale ambient assisted living scenarios. Sensors (Basel Switzerland) 18(8):1

[31]

Nienhold D, Dornberger R, Korkut S (2016) Sensor-Based Tracking and Big Data Processing of Patient Activities in Ambient Assisted Living. In: 2016 IEEE international conference on healthcare informatics (ICHI). IEEE, pp 473–482

[32]

Oresko JJ, Jin Z, Cheng J, Huang S, Sun Y, Duschl H, Cheng AC (2010) A wearable smartphone-based platform for real-time cardiovascular disease detection via electrocardiogram processing. IEEE Trans Inf Technol Biomed 14(3):734–40

Digital Library

[33]

Palumbo F, Ullberg J, timec A, Furfari F, Karlsson L, Coradeschi S (2014) Sensor network infrastructure for a home care monitoring system. Sensors

[34]

Pantelopoulos A, Bourbakis NG (2010) A survey on wearable sensor-based systems for health monitoring and prognosis. IEEE Trans Syst Man Cybern Part C (Appl Rev) 40(1):1–2

Digital Library

[35]

Patel S, Park H, Bonato P, Chan L, Rodgers M (2012) A review of wearable sensors and systems with application in rehabilitation. J Neuroeng Rehabil 9 (1):21

[36]

Pham M, Mengistu Y, Do HM, Sheng W (2016) Cloud-Based Smart Home Environment (CoSHE) for home healthcare. In: 2016 IEEE international conference on automation science and engineering (CASE). IEEE, pp 483–488

[37]

Rahmani AM, Thanigaivelan NK, Gia TN, Granados J, Negash B, Liljeberg P, Tenhunen H (2015) Smart e-health gateway: bringing intelligence to internet-of-things based ubiquitous healthcare systems. In: 2015 12th annual IEEE consumer communications and networking conference (CCNC). IEEE, pp 826–834

[38]

Rantz MJ, Skubic M, Koopman RJ, Phillips L, Alexander GL, Miller SJ, Guevara RD (2011) Using sensor networks to detect urinary tract infections in older adults. In: 2011 13th IEEE international conference e-health networking applications and services (Healthcom)

[39]

Rashidi P, Cook DJ (2009) Keeping the resident in the loop: Adapting the smart home to the user. IEEE Transactions on systems, man, and cybernetics-part A: systems and humans

[40]

Rubin SG, Davies GH (1975) Bed blocking by elderly patients in general-hospital wards. Age and Ageing

[41]

Shnayder V, Chen BR, Lorincz K, Fulford-Jones TR, Welsh M Sensor networks for medical care

[42]

Suhonen J, Hämäläinen TD, Hännikäinen M (2009) Availability and end-to-end reliability in low duty cycle multihopwireless sensor networks. Sensors 9 (3):2088–116

[43]

Tamura T, Kawarada A, Nambu M, Tsukada A, Sasaki K, Yamakoshi KI (2007) E-healthcare at an experimental welfare techno house in Japan. The Open Medical Informatics Journal

[44]

Wartena F, Muskens J, Schmitt L, Petkovic M (2010) Continua: The Reference Architecture of a Personal Telehealth Ecosystem. In: proceedings of 12th IEEE international conference on e-health networking applications and services (Healthcom), Lyon, France

[45]

Yamazaki T (2007) The ubiquitous home. Int J Smart Home 1(1):17–22

[46]

Zhou Y, Vongsa D, Zhou Y, Cheng Z, Jing L (2015) A Healthcare System for Detection and Analysis of Daily Activity Based on Wearable Sensor and Smartphone. In: 2015 IEEE 12th international conference on ubiquitous intelligence and Computing and 2015 IEEE 12th international conference on autonomic and trusted computing and 2015 IEEE 15th international conference on scalable computing and communications and its associated workshops (UIC-ATC-ScalCom). IEEE, pp 1109–1114

Cited By

Comas-González ZMardini JButt SSanchez-Comas ASynnes KJoliet ADelahoz-Franco EMolina-Estren DPiñeres-Espitia GNaz SOspino-Balcázar D(2024)Sensors and Machine Learning Algorithms for Location and POSTURE Activity Recognition in Smart EnvironmentsAutomatic Control and Computer Sciences10.3103/S014641162401004858:1(33-42)Online publication date: 1-Feb-2024
https://dl.acm.org/doi/10.3103/S0146411624010048
De Vito G(2024)Assessing healthcare software built using IoT and LLM technologiesProceedings of the 28th International Conference on Evaluation and Assessment in Software Engineering10.1145/3661167.3661202(476-481)Online publication date: 18-Jun-2024
https://dl.acm.org/doi/10.1145/3661167.3661202
Protopapadakis EGallos PKalogridis SKarali TMarinou ESardis EBaki SKatsorida EIoannis R(2024)Quantifying the Impact of Nature based Interventions on Citizen Health and Well-beingProceedings of the 17th International Conference on PErvasive Technologies Related to Assistive Environments10.1145/3652037.3663917(428-434)Online publication date: 26-Jun-2024
https://dl.acm.org/doi/10.1145/3652037.3663917
Show More Cited By

Recommendations

Mobile and wearable sensors for data-driven health monitoring system: State-of-the-art and future prospect
Highlights
- Comprehensive review of health monitoring based sensors.
- Categorize the sensors ...
Abstract
Mobile and wearable devices embedded with multiple sensors for health monitoring and disease diagnosis are growing fields with the potential to provide efficient means for remote health management. A sensor-based health monitoring ...
Home-based health monitoring of the elderly through gait recognition
Home-based Health and Wellness Measurement and Monitoring

In Europe, in particular, growing numbers of elderly people need sustainable elderly care, which the young are not able to provide. As an alternative, elderly care can be provided through home-based, automatic, health-monitoring systems. Here we propose ...
Personalized Health Monitoring System for Managing Well-Being in Rural Areas

Rural India lacks easy access to health practitioners and medical centers, depending instead on community health workers. In these areas, common ailments that are easy to manage with medicines, often lead to medical escalations and even fatalities due ...

Comments

Please enable JavaScript to view thecomments powered by Disqus.

Information & Contributors

Information

Published In

cover image Multimedia Tools and Applications

Multimedia Tools and Applications Volume 78, Issue 17

Sep 2019

1379 pages

ISSN:1380-7501

Issue’s Table of Contents

Copyright © 2019 Springer Science+Business Media, LLC, part of Springer Nature.

Publisher

Kluwer Academic Publishers

United States

Publication History

Published: 01 September 2019

Author Tags

Qualifiers

Research-article

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

30
Total Citations
View Citations
0
Total Downloads

Downloads (Last 12 months)0
Downloads (Last 6 weeks)0

Reflects downloads up to 20 Jan 2025

Other Metrics

View Author Metrics

Citations

Cited By

Comas-González ZMardini JButt SSanchez-Comas ASynnes KJoliet ADelahoz-Franco EMolina-Estren DPiñeres-Espitia GNaz SOspino-Balcázar D(2024)Sensors and Machine Learning Algorithms for Location and POSTURE Activity Recognition in Smart EnvironmentsAutomatic Control and Computer Sciences10.3103/S014641162401004858:1(33-42)Online publication date: 1-Feb-2024
https://dl.acm.org/doi/10.3103/S0146411624010048
De Vito G(2024)Assessing healthcare software built using IoT and LLM technologiesProceedings of the 28th International Conference on Evaluation and Assessment in Software Engineering10.1145/3661167.3661202(476-481)Online publication date: 18-Jun-2024
https://dl.acm.org/doi/10.1145/3661167.3661202
Protopapadakis EGallos PKalogridis SKarali TMarinou ESardis EBaki SKatsorida EIoannis R(2024)Quantifying the Impact of Nature based Interventions on Citizen Health and Well-beingProceedings of the 17th International Conference on PErvasive Technologies Related to Assistive Environments10.1145/3652037.3663917(428-434)Online publication date: 26-Jun-2024
https://dl.acm.org/doi/10.1145/3652037.3663917
Caballero POrtiz GMedina-Bulo I(2024)Systematic literature review of ambient assisted living systems supported by the Internet of ThingsUniversal Access in the Information Society10.1007/s10209-023-01022-w23:4(1631-1656)Online publication date: 1-Nov-2024
https://dl.acm.org/doi/10.1007/s10209-023-01022-w
Pavitra BSingh DSharma SHashmi MKhan MDhiman GVE S(2023)Dementia prediction using novel IOTM (Internet of Things in Medical) architecture frameworkIntelligent Data Analysis10.3233/IDA-23743127:S1(29-45)Online publication date: 3-Nov-2023
https://dl.acm.org/doi/10.3233/IDA-237431
Baucum MKhojandi AVasudevan RRamdhani R(2023)Optimizing Patient-Specific Medication Regimen Policies Using Wearable Sensors in Parkinson’s DiseaseManagement Science10.1287/mnsc.2023.474769:10(5964-5982)Online publication date: 10-Apr-2023
https://dl.acm.org/doi/10.1287/mnsc.2023.4747
Radeta MRodrigues CSilva FAbreu PPestana JNguyen NZuniga AFlores HNurmi P(2023)Lost in the Deep?Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/35962457:2(1-27)Online publication date: 12-Jun-2023
https://dl.acm.org/doi/10.1145/3596245
Gao HZhou LKim JLi YHuang W(2023)Applying Probabilistic Model Checking to the Behavior Guidance and Abnormality Detection for A-MCI Patients under Wireless Sensor NetworkACM Transactions on Sensor Networks10.1145/349942619:3(1-24)Online publication date: 2-Mar-2023
https://dl.acm.org/doi/10.1145/3499426
Shilpi GRajesh Kumar KNaveen KAnshul V(2023)Effective Tools and Technologies for IoT and Blockchain-Based Remote Patient Monitoring: A Comparative AnalysisSN Computer Science10.1007/s42979-023-02288-w4:6Online publication date: 3-Nov-2023
https://dl.acm.org/doi/10.1007/s42979-023-02288-w
Bhattacharjee PBiswas SChattopadhyay SRoy SChakraborty S(2023)Smart Assistance to Reduce the Fear of Falling in Parkinson Patients Using IoTWireless Personal Communications: An International Journal10.1007/s11277-023-10285-8130:1(281-302)Online publication date: 23-Mar-2023
https://dl.acm.org/doi/10.1007/s11277-023-10285-8
Show More Cited By

View Options

View options

Media

Figures

Other

Tables

View Issue’s Table of Contents