Project description
Wearable sensors detect hypothermia in elderly patients
Older adults are vulnerable to hypothermia. An exceptionally low body temperature for an older person can cause many health problems ranging from a heart attack to liver damage or worse. For this reason, it is important to monitor hypothermia in the elderly. Wearable sensors could help provide long-term continuous recordings of electrophysiological activity to detect hypothermia at early stages. The EU-funded WEARSENSNANO project will develop an integrated wearable temperature and pressure/strain sensor based on solution processable nanowires and cellulose hydrogel to monitor hypothermia in the elderly and improve patient outcomes.
Objective
One common influence of ageing is that it makes the individual susceptible to hypothermia, which is known to be death causing low body temperature (35°C). Hypothermia could be detected at early stages by monitoring various physiological parameters such as ECG signal, skin temperature and body movement. Owing to their flexibility and stretchability, wearable sensors could provide long term continuous recordings of electrophysiological activity for monitoring hypothermia in elder people.
Wearable temperature, pressure and strain sensors in forms were studied by many research groups. Those approaches utilized complex and high-cost photolithography techniques, which makes the devices far from commercialization. Besides, the poor processability and lack of skin compatibility of stretchable polymers used as substrates prevents the practical use of these materials. However, solution-processable nanomaterials offer a unique way to reduce the cost and complexity, while cellulose hydrogel is easy processable and skin friendly polymer.
Thus, in this project, we aim to develop an integrated wearable temperature and pressure/strain sensor based on solution processable nanowires, and cellulose hydrogel to monitor hypothermia in elder people via measuring pressure, strain and temperature. Pressure/Strain sensor will be prepared via laminating two silver nanowire printed cellulose hydrogels sandwiching a pressure sensitive dielectric layer. Temperature sensor will be fabricated via transfer printing of gold nanowires on the cellulose hydrogel substrate. Next, pressure/strain and temperature sensors will be laminated to form the integrated sensor. Finally, the sensors will be used in real patients.
In terms of research quality, infrastructure and services, Prof. Vapaavuori’s lab and Aalto University are quite appropriate for the proposed project. The training is believed to strongly contribute to the researcher’s academic, and scientific career.
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Funding Scheme
MSCA-IF - Marie Skłodowska-Curie Individual Fellowships (IF)Coordinator
02150 Espoo
Finland