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Posted on September 29, 2021 by  & 

Smart Textiles Powered by Body Movement for Remote Health Monitoring

New study to develop smart textiles powered by body movement for remote health monitoring
The global population recently reached 7.8 billion, among which almost 15% suffer from disabilities mainly caused by ageing and chronic diseases.
 
Lack of infrastructure and trained professionals in rehabilitation is a worldwide issue that has been intensified by the ongoing pandemic and, as a result, healthcare access has been significantly reduced. Upcoming technologies like telemedicine and telerehabilitation try to address these issues by providing remote and affordable access to healthcare using telecommunication devices, such as smartphones and tablets. This shift requires new methods that can gather inexpensive and accurate data on physiological parameters - such as heart rate, blood pressure, body temperature, and hormone levels - and body movements in real-life settings. For further information see the IDTechEx report on E-Textiles & Smart Clothing 2021-2031: Technologies, Markets and Players.
 
Existing motion detection techniques have numerous drawbacks, including limited range, restricted mobility (due to bulky, rigid components), high-cost, and the need of replacing/recharging batteries.
 
 
Dr Ishara Dharmasena, of the School of Mechanical, Electrical and Manufacturing Engineering (MEME), has been appointed a Research Fellow by the Royal Academy of Engineering and awarded funding of £500,000 to develop a new technology that overcomes these challenges. For the next five years, he will focus on creating sensor-containing super-smart textiles that can be used for remote health monitoring.
 
Dr Dharmasena will look to make this electronically-active clothing from textile yarns that capture energy from body movements and generate electricity using very small power generators known as 'Triboelectric Nanogenerators' (TENGs). Absorbing the movement from the body, these super-smart textiles will not only power electronic components, but also act as self-powered functional sensors that are able to accurately sense the movements of targeted body parts.
 
This futuristic textile system will then wirelessly communicate the data to a mobile device - resulting in a highly efficient, durable, light-weight, wearable, low-cost rehabilitation monitoring product.
 
Dr Dharmasena hopes to have two fully-functioning smart textile demonstrators at the end of the project: the first being a tight-fitting T-shirt/base layer, and the second being a bandage that can be worn like a normal support bandage. His research will receive input and support from a variety of industry partners plus academics across the School of MEME.
 
Of the importance of the project, Dr Dharmasena said: "It is an honour to have received the prestigious Research Fellowship from the Royal Academy of Engineering, which has been one of my aspirations since starting PhD studies. With this Fellowship, I will be able to address some of the key issues related to wearable health monitoring by creating innovative solutions through nanogenerator technology. These 'super-smart textiles' developed here will be able to monitor body movements and remotely transmit the sensor signals, while powering their own operations by absorbing energy from the natural motion of the wearer."He added: "In an era where healthcare access has become critically scarce, the Fellowship outcomes will benefit many people across the globe. In doing so, this work will support in the efforts in addressing global challenges and sustainable development goals in health and wellbeing, and clean energy areas."
 
 
Top image: Pixabay
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