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Journal of Medical Systems

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01.08.2010 | Original Paper

Towards Improved Healthcare Performance: Examining Technological Possibilities and Patient Satisfaction with Wireless Body Area Networks

verfasst von: Rune Fensli, Jan Gunnar Dale, Philip O’Reilly, John O’Donoghue, David Sammon, Torstein Gundersen

Erschienen in: Journal of Medical Systems | Ausgabe 4/2010

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Abstract

This paper investigates the benefits of using less intrusive wireless technologies for heart monitoring. By replacing well established heart monitoring devices (i.e. Holter) with wireless ECG based Body Area Networks (BAN), improved healthcare performance can be achieved, reflected in (1) high quality ECG recordings during physical activities and (2) increased patient satisfaction. A small scale clinical trial was conducted to compare both technologies and the results illustrate that the wireless ECG monitor was able to detect ECG signals intended for arrhythmia diagnostics. Furthermore, from a patient’s perspective, both technologies were evaluated using three dimensions, namely; hygienic aspects, physical activity, and skin reactions. Results demonstrate that the wireless ECG BAN showed better performance, especially regarding the hygienic aspects. It was also favourable for use during physical activities, and the signal quality of the wireless sensor system demonstrated good performance regarding signal noise and artefact disturbances. This paper concludes that wireless cardiac monitoring systems have significant benefits from a patient’s perspective, and further clinical trials should be conducted to further evaluate the new ECG based BAN system, to identify the possibility of widespread adoption and utilisation of wireless technology for arrhythmia diagnostics.

Al Khatib, I., Bertozzi, D., Poletti, F., Benini, L., Jantsch, A., Bechara, M., Khalifeh, H., Hajjar, M., Nabiev, R., and Jonsson, S., Hardware/software architecture for real-time ECG monitoring and analysis leveraging MPSoC technology. Transactions on HiPEAC I, LNCS. 4050:239–258, 2007.

Guler, N. F., and Ubeyli, E. D., Theory and applications of telemedicine. J. Med. Syst. 26:199–220, 2002.CrossRef

Jovanov, E., Raskovic, D., Price, J., Chapman, J., Moore, A., and Krishnamurthy, A., Patient monitoring using personal area networks of wireless intelligent sensors. Biomed. Sci. Instrum. 37:373–378, 2001.

Anliker, U., Ward, J. A., Lukowicz, P., Troster, G., Dolveck, F., Baer, M., et al., AMON: a wearable multiparameter medical monitoring and alert system. Information Technology in Biomedicine. IEEE Trans. 8 (4)415–427, 2004.

Rubel, P., Fayn, J., Nollo, G., Assanelli, D., Li, B., Restier, L., et al., Toward personal eHealth in cardiology. Results from the EPI-MEDICS telemedicine project. J. Electrocardiol. 38 Supplement 1 (4)100–106, 2005. doi:10.1016/j.jelectrocard.2005.06.011.CrossRef

Roth, A., Korb, H., Gadot, R., and Kalter, E., Telecardiology for patients with acute or chronic cardiac complaints: The ‘SHL’ experience in Israel and Germany. Int. J. Med. Inform. 75 (9)643–645, 2006. doi:10.1016/j.ijmedinf.2006.04.004.CrossRef

Marculescu, D., Marculescu, R., Zamora, N. H., Stanley-Marbell, P., Khosla, P. K., Park, S., et al., Electronic textiles: A platform for pervasive computing. Proc. IEEE. 91 (12)1995–2018, 2003. doi:10.1109/JPROC.2003.819612.CrossRef

Park, S., Jayaraman, S., On innovation, quality of life and technology of BodyNets’ Proceedings of the ICST 3rd international conference on Body area networks. Tempe, Arizona: ICST Institute for Computer Sciences, Social-Informatics and Telecommunications Engineering, 2008.

Demiris, G., Electronic home healthcare: concepts and challenges. Int. J. Electron. Healthc. 1 (1)4–16, 2004. doi:10.1504/IJEH.2004.004655.CrossRef

10.

Fenske, S., Challenges and Opportunities for Wireless Healthcare. www.wirelessdesignmag.com December, 2007.

11.

Williamson, P., Designing wireless products for the home healthcare market. www.wirelessdesignmag.com, 2007.

12.

Tan, J., E-Healthcare Information Systems: An Introduction for Students and Professionals, Wiley, 2005.

13.

Passanisi, C., Electrocardiography Essentials. Delmar Learning. 2001.

14.

Hopper, Telehealth and the diagnosis and management of cardiac disease. J. Telemed. Telecare. 7:249–256, 2001. doi:10.1258/1357633011936471.CrossRef

15.

Bunch, T., White, R., Gersh, B., Meverden, R., Hodge, D., Ballman, K., Hammill, S., Shen, W., and Packer, D., Long-term outcomes of out-of-hospital cardiac arrest after successful early defibrillation. N. Engl. J. Med. 348:2626–2633, 2003. doi:10.1056/NEJMoa023053.CrossRef

16.

Corrigan, D., and Paton, J., Pilot study of objective cough monitoring in Infants. Pediatr. Pulmonol. 35:350–357, 2003. doi:10.1002/ppul.10267.CrossRef

17.

Hoch, J. S., Rockx, M., and Krahn, A., Using the net benefit regression framework to construct cost-effectiveness acceptrability curves: an example using data from a trial of external loop recorders versus Holter monitoring for ambulatory monitoring of community acquired syncope. in BMC Health Service Results, June, 2006.

18.

Fensli, R., Pedersen, P. E., et al., Sensor Acceptance Model—Measuring patient acceptance of wearable sensors. Methods Inf. Med. 47 (1)89–95, 2008.

19.

Istepanian, R., Woodward, B., Gorilas, E., and Balos, P., Designing of mobile telemedicine systems using GSM and IS-54 cellular telephone standards. J. Telemed. Telecare. 4 (1)80–82, 1998. doi:10.1258/1357633981931579.CrossRef

20.

Andreasson, J., Ekstrom, M., Fard, A., Castano, J., Johnson, T., Remote system for patient monitoring using bluetooth. Sensors-02, Proceedings of the IEEE, 2002.

21.

Scherr, D., Dalal, D., Henrikson, C., Spragg, D., Berger, R., Calkins, H., and Cheng, A., Prospective comparison of the diagnostic utility of a standard event monitor versus a “leadless” portable ECG monitor in the evaluation of patients with palpitations. J. Interv. Card. Electrophysiol. 22:1, 2008. doi:10.1007/s10840-008-9251-0.CrossRef

22.

Huntleigh Healthcare: Medilog AR4 Digital Holter Recorder. http://www.medilogdarwin.com/Medilog_AR4.html

23.

Wireless Patient Recording Medical, A.S.: Wireless ECG sensor. http://www.wprmedical.com

24.

Fensli, R., and Boisen, E., Human factors affecting the patient’s acceptance of wireless biomedical sensors. In: Fred, A., Filipe, J., and Gamboa, H., (Eds.), BIOSTEC 2008, CCIS 25.402–12. Berlin Heidelberg: Springer, 2008.

25.

Giorgi, A., Aanstoos, C. M., and William, F. F., Phenomenology and psychological research. Duquesne University Press, Pittsburgh, 1985.

26.

Bland, J. M., and Altman, D. G., Statistical methods for assessing agreement between two methods of clinical measurement. Lancet. 1 (8476)307–310, 1986.

Titel: Towards Improved Healthcare Performance: Examining Technological Possibilities and Patient Satisfaction with Wireless Body Area Networks
verfasst von: Rune Fensli
Jan Gunnar Dale
Philip O’Reilly
John O’Donoghue
David Sammon
Torstein Gundersen
Publikationsdatum: 01.08.2010
Verlag: Springer US
Erschienen in: Journal of Medical Systems / Ausgabe 4/2010
Print ISSN: 0148-5598
Elektronische ISSN: 1573-689X
DOI: https://doi.org/10.1007/s10916-009-9291-8

Springer Medizin

Abstract

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