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Biocompatibility assessment of wearable C/TPU/Tegaderm strain sensors

The rapid advancement of wearable technology has sparked significant interest in developing innovative sensors that can seamlessly integrate with the human body. Strain sensors have been widely used in wearable devices for human motion detection. The choice of materials for the substrate and electro...

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Bibliographic Details
Main Authors: Abu Hassan Zahri, Nur Nazihah, Nordin, Anis Nurashikin, Mohd Mansor, Ahmad Fairuzabadi, Ab. Rahim, Rosminazuin, Md Ralib @ Md Raghib, Aliza 'Aini, Suhaimi, Muhammad Irsyad, Lim, Lai Ming
Format: Proceeding Paper
Language:English
English
Published: IEEE 2023
Subjects:
TK Electrical engineering. Electronics Nuclear engineering
TK7800 Electronics. Computer engineering. Computer hardware. Photoelectronic devices
Online Access:http://irep.iium.edu.my/107317/1/107317_Biocompatibility%20assessment%20of%20wearable.pdf
http://irep.iium.edu.my/107317/7/107317_Biocompatibility%20Assessment%20of%20Wearable%20C_TPU_Tegaderm%20Strain%20Sensors_SCOPUS.pdf
http://irep.iium.edu.my/107317/
https://ieeexplore.ieee.org/abstract/document/10246041
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Summary:The rapid advancement of wearable technology has sparked significant interest in developing innovative sensors that can seamlessly integrate with the human body. Strain sensors have been widely used in wearable devices for human motion detection. The choice of materials for the substrate and electrodes of the strain sensors plays a crucial role in determining their biocompatibility. Existing wearable strain sensors commonly utilize polymeric films and planar structures, leading to restricted airflow in the area of attachment. Consequently, this limited ventilation can potentially elevate the risk of skin irritation, and bacterial infections, and cause discomfort for the users. In this paper, a biocompatible strain sensor for wearable technology is presented. The strain sensor design is discussed and fabricated using the printing technique. The biocompatibility of the sensor is assessed by conducting cell morphology and cell viability analysis. The finding shows that the C/TPU/Tegaderm strain sensor is noncytotoxic and highly biocompatible after being exposed to HFF-1 cells. These biocompatible sensors are promising for safe use on human skin.

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