Design of intelligent wearable equipment based on real-time dynamic ECG-monitoring system.

Objectives: The coronavirus disease epidemic has largely restricted the traditional offline medical treatment model. With increasing requirements for virtual medical assistance, the design of smart medical apparel has received more attention.

Methods: In this study, we designed electrocardiography (ECG)-monitoring smart clothing based on the Holter system after identifying and analyzing the needs of patients and doctors. This clothing is a wearable device that integrates monitoring and remote diagnosis, building a general network platform to support remote data transfer and sharing and online interactive auxiliary diagnosis. Creating wearable smart clothing includes multiple dimensions, such as ECG module design, clothing structural design, and a real-time monitoring app. This innovative technology is achieved by intelligently integrating limb lead wires, conductive fiber fabrics, lead interfaces, and electrode signal storage receivers, all based on the human body's sensing conduction principle. Wearable clothing that can monitor ECG in real time is designed and developed by intelligently integrating limb lead wires, conductive fiber fabrics, lead interfaces, and electrode signal storage receivers by using the human body-sensing conduction principle of real-time ECG monitoring.

Results: Wearable real-time ECG-monitoring clothing can help patients achieve fast virtual medical care and auxiliary diagnosis and solve the design issues associated with electrode signal storage receivers. In addition, such clothing can be applied to automatically monitor groups at high risk of heart disease.

Conclusions: Our design not only meets the accuracy requirements of traditional medical diagnosis but also combines traditional real-time ECG monitoring and smart clothing, providing new options for the daily needs of patients and doctors.