Literature DB >> 20703570

Heart monitoring garments using textile electrodes for healthcare applications.

Hyun-Seung Cho1, Su-Min Koo, Joohyeon Lee, Hakyung Cho, Da-Hye Kang, Ha-Young Song, Jeong-Whan Lee, Kang-Hwi Lee, Young-Jae Lee.   

Abstract

We measured the electrical activity signals of the heart through vital signs monitoring garments that have textile electrodes in conductive yarns while the subject is in stable and dynamic motion conditions. To measure the electrical activity signals of the heart during daily activities, four types of monitoring garment were proposed. Two experiments were carried out as follows: the first experiment sought to discover which garment led to the least displacement of the textile electrode from its originally intended location on the wearer's body. In the second, we measured and compared the electrical activity signals of the heart between the wearer's stable and dynamic motion states. The results indicated that the most appropriate type of garment sensing-wise was the "cross-type", and it seems to stabilize the electrode's position more effectively. The value of SNR of ECG signals for the "cross-type" garment is the highest. Compared to the "chest-belt-type" garment, which has already been marketed commercially, the "cross-type" garment was more efficient and suitable for heart activity monitoring.

Mesh:

Year:  2009        PMID: 20703570     DOI: 10.1007/s10916-009-9356-8

Source DB:  PubMed          Journal:  J Med Syst        ISSN: 0148-5598            Impact factor:   4.460


  11 in total

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  9 in total

1.  The Effect of Electrode Designs Based on the Anatomical Heart Location for the Non-Contact Heart Activity Measurement.

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8.  Design and implementation of a BSN-based system for plantar health evaluation with exercise load quantification.

Authors:  Yang Wang; Zhiwen Liu; Jian Yang; Shaodong Ma
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Review 9.  Nanomaterials-patterned flexible electrodes for wearable health monitoring: a review.

Authors:  Md Mehdi Hasan; Md Milon Hossain
Journal:  J Mater Sci       Date:  2021-06-28       Impact factor: 4.220
  9 in total

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