Wearable sensors for telehealth based on emerging materials and nanoarchitectonics

Wearable sensors have made significant progress in sensing physiological and biochemical markers for telehealth.By monitoring vital signs like body temperature,arterial oxygen saturation,and breath rate,wearable sensors provide enormous potential for the early detection of diseases.In recent years,significant advancements have been achieved in the development of wearable sensors based on two-dimensional(2D)materials with flexibility,excellent mechanical stability,high sensitivity,and accuracy introducing a new approach to remote and real-time health monitoring.In this review,we outline 2D materials-based wearable sensors and biosensors for a remote health monitoring system.The review focused on five types of wearable sensors,which were classified according to their sensing mechanism,such as pressure,strain,electrochemical,optoelectronic,and temperature sensors.2D material capabilities and their impact on the performance and operation of the wearable sensor are outlined.The fundamental sensing principles and mechanism of wearable sensors,as well as their applications are explored.This review concludes by discussing the remaining obstacles and future opportunities for this emerging telehealth field.We hope that this report will be useful to individuals who want to design new wearable sensors based on 2D materials and it will generate new ideas.

Telemedicine platform for health assessment remotely by an integrated nanoarchitectonics FePS_(3)/rGO and Ti_(3)C_(2)-based wearable device

Due to the emergence of various new infectious(viral/bacteria)diseases,the remote surveillance of infected persons has become most important,especially if hospitals need to isolate infected patients to prevent the spreading of pathogens to health care personnel.Therefore,we develop a remote health monitoring system by integrating a stretchable asymmetric supercapacitor(SASC)as a portable power source with sensors that can monitor the human physical health condition in real-time and remotely.An abnormal body temperature and breathing rate could indicate a person’s sickness/infection status.Here we integrated FePS3@graphene-based strain sensor and SASC into an all-in-one textile system and wrapped it around the abdomen to continuously monitor the breathing cycle of the person.The real body temperature was recorded by integrating the temperature sensor with the SASC.The proposed system recorded physiological parameters in real-time and when monitored remotely could be employed as a screening tool for monitoring pathogen infection status.