TY - JOUR
T1 - A self-powered wearable brain-machine-interface system for real-time monitoring and regulating body temperature
AU - Xu, Chengze
AU - Xie, Yan
AU - Zhong, Tianyan
AU - Liang, Shan
AU - Guan, Hongye
AU - Long, Zhihe
AU - Cao, Hanyu
AU - Xing, Lili
AU - Xue, Xinyu
AU - Zhan, Yang
PY - 2022/9/14
Y1 - 2022/9/14
N2 - Heat stroke that may cause acute central nervous system dysfunction, multiple organ dysfunction and even death has become a typical health problem in tropical developing countries. The primary goal of heat stroke treatment is to lower core body temperature, which necessitates physical or medical cooling in time. Here, we design a new self-powered wearable brain-machine-interface system for real-time monitoring and regulating body temperature. This system can monitor body temperature in real time and transmit neural electrical stimulation signals into specific brain regions to lower the body temperature. The whole system can work without an external power supply and be powered by the body itself through the piezoelectric effect. The system comprises a temperature detecting unit, a power supply unit, a data processing module, and a brain stimulator. Demonstration of the system with stimulation electrodes implanted in the median preoptic nucleus brain region in mice reveals an evident decrease in body temperature (1.0 °C within 15 min). This self-powered strategy provides a new concept for future treatment of heat stroke and can extend the application of brain-machine-interface systems in medical care.
AB - Heat stroke that may cause acute central nervous system dysfunction, multiple organ dysfunction and even death has become a typical health problem in tropical developing countries. The primary goal of heat stroke treatment is to lower core body temperature, which necessitates physical or medical cooling in time. Here, we design a new self-powered wearable brain-machine-interface system for real-time monitoring and regulating body temperature. This system can monitor body temperature in real time and transmit neural electrical stimulation signals into specific brain regions to lower the body temperature. The whole system can work without an external power supply and be powered by the body itself through the piezoelectric effect. The system comprises a temperature detecting unit, a power supply unit, a data processing module, and a brain stimulator. Demonstration of the system with stimulation electrodes implanted in the median preoptic nucleus brain region in mice reveals an evident decrease in body temperature (1.0 °C within 15 min). This self-powered strategy provides a new concept for future treatment of heat stroke and can extend the application of brain-machine-interface systems in medical care.
KW - RECEPTOR
KW - SENSOR
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U2 - 10.1039/d2nr03115a
DO - 10.1039/d2nr03115a
M3 - RGC 21 - Publication in refereed journal
C2 - 35983766
SN - 2040-3364
VL - 14
SP - 12483
EP - 12490
JO - Nanoscale
JF - Nanoscale
IS - 34
ER -
