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Printed soft-electronics for remote body monitoring

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Printed soft-electronics for remote body monitoring. / Mäntysalo, Matti; Vuorinen, Tiina; Jeyhani, Vala; Vehkaoja, Antti.

Hybrid Memory Devices and Printed Circuits 2017: SPIE Organic Photonics + Electronics | 6-10 August 2017. SPIE, 2017. (SPIE Conference Proceedings; Vuosikerta 10366).

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Harvard

Mäntysalo, M, Vuorinen, T, Jeyhani, V & Vehkaoja, A 2017, Printed soft-electronics for remote body monitoring. julkaisussa Hybrid Memory Devices and Printed Circuits 2017: SPIE Organic Photonics + Electronics | 6-10 August 2017. SPIE Conference Proceedings, Vuosikerta. 10366, SPIE, 1/01/00. https://doi.org/10.1117/12.2275606

APA

Mäntysalo, M., Vuorinen, T., Jeyhani, V., & Vehkaoja, A. (2017). Printed soft-electronics for remote body monitoring. teoksessa Hybrid Memory Devices and Printed Circuits 2017: SPIE Organic Photonics + Electronics | 6-10 August 2017 (SPIE Conference Proceedings; Vuosikerta 10366). SPIE. https://doi.org/10.1117/12.2275606

Vancouver

Mäntysalo M, Vuorinen T, Jeyhani V, Vehkaoja A. Printed soft-electronics for remote body monitoring. julkaisussa Hybrid Memory Devices and Printed Circuits 2017: SPIE Organic Photonics + Electronics | 6-10 August 2017. SPIE. 2017. (SPIE Conference Proceedings). https://doi.org/10.1117/12.2275606

Author

Mäntysalo, Matti ; Vuorinen, Tiina ; Jeyhani, Vala ; Vehkaoja, Antti. / Printed soft-electronics for remote body monitoring. Hybrid Memory Devices and Printed Circuits 2017: SPIE Organic Photonics + Electronics | 6-10 August 2017. SPIE, 2017. (SPIE Conference Proceedings).

Bibtex - Lataa

@inproceedings{07f21b84aadf484bb0c150a4d7dda9c1,
title = "Printed soft-electronics for remote body monitoring",
abstract = "Wearable electronics has emerged into the consumer markets over the past few years. Wrist worn and textile integrated devices are the most common apparatuses for unobtrusive monitoring in sports and wellness sectors. Disposable patches and bandages, however, represent the new era of wearable electronics. Soft and stretchable electronics is the enabling technology of this paradigm shift. It can conform to temporary transfer tattoo and deform with the skin without detachment or fracture. In this paper, we focus on screen-printed soft-electronics for remote body monitoring. We will present a fabrication process of a skin conformable electrode bandage designed for long-term outpatient electrocardiography (ECG) monitoring. The soft bandage is designed to be attached to the patient chest and miniaturized data collection device is connected to the bandage via Micro-USB connector. The fabricated bandage is tested in short exercise as well as continued long-term (72 hours) monitoring during normal daily activities. The attained quality of the measured ECG signals is fully satisfactory for rhythm-based cardiac analysis also during moderate-intensity exercise. After pre-processing, the signals could be used also for more profound morphological analysis of ECG wave shapes.",
author = "Matti M{\"a}ntysalo and Tiina Vuorinen and Vala Jeyhani and Antti Vehkaoja",
note = "jufoid=71479",
year = "2017",
month = "8",
doi = "10.1117/12.2275606",
language = "English",
series = "SPIE Conference Proceedings",
publisher = "SPIE",
booktitle = "Hybrid Memory Devices and Printed Circuits 2017",
address = "United States",

}

RIS (suitable for import to EndNote) - Lataa

TY - GEN

T1 - Printed soft-electronics for remote body monitoring

AU - Mäntysalo, Matti

AU - Vuorinen, Tiina

AU - Jeyhani, Vala

AU - Vehkaoja, Antti

N1 - jufoid=71479

PY - 2017/8

Y1 - 2017/8

N2 - Wearable electronics has emerged into the consumer markets over the past few years. Wrist worn and textile integrated devices are the most common apparatuses for unobtrusive monitoring in sports and wellness sectors. Disposable patches and bandages, however, represent the new era of wearable electronics. Soft and stretchable electronics is the enabling technology of this paradigm shift. It can conform to temporary transfer tattoo and deform with the skin without detachment or fracture. In this paper, we focus on screen-printed soft-electronics for remote body monitoring. We will present a fabrication process of a skin conformable electrode bandage designed for long-term outpatient electrocardiography (ECG) monitoring. The soft bandage is designed to be attached to the patient chest and miniaturized data collection device is connected to the bandage via Micro-USB connector. The fabricated bandage is tested in short exercise as well as continued long-term (72 hours) monitoring during normal daily activities. The attained quality of the measured ECG signals is fully satisfactory for rhythm-based cardiac analysis also during moderate-intensity exercise. After pre-processing, the signals could be used also for more profound morphological analysis of ECG wave shapes.

AB - Wearable electronics has emerged into the consumer markets over the past few years. Wrist worn and textile integrated devices are the most common apparatuses for unobtrusive monitoring in sports and wellness sectors. Disposable patches and bandages, however, represent the new era of wearable electronics. Soft and stretchable electronics is the enabling technology of this paradigm shift. It can conform to temporary transfer tattoo and deform with the skin without detachment or fracture. In this paper, we focus on screen-printed soft-electronics for remote body monitoring. We will present a fabrication process of a skin conformable electrode bandage designed for long-term outpatient electrocardiography (ECG) monitoring. The soft bandage is designed to be attached to the patient chest and miniaturized data collection device is connected to the bandage via Micro-USB connector. The fabricated bandage is tested in short exercise as well as continued long-term (72 hours) monitoring during normal daily activities. The attained quality of the measured ECG signals is fully satisfactory for rhythm-based cardiac analysis also during moderate-intensity exercise. After pre-processing, the signals could be used also for more profound morphological analysis of ECG wave shapes.

U2 - 10.1117/12.2275606

DO - 10.1117/12.2275606

M3 - Conference contribution

T3 - SPIE Conference Proceedings

BT - Hybrid Memory Devices and Printed Circuits 2017

PB - SPIE

ER -