期刊
SENSORS
卷 23, 期 10, 页码 -出版社
MDPI
DOI: 10.3390/s23104593
关键词
mechanoreceptor; tactile sensation; thermal sensation; gustation; olfaction; auditory sensation; firing rate; electrochemical impedance spectroscopy (EIS)
In order to develop versatile sensors capable of multiple responses to different sensations, researchers investigated mechanoreceptors fabricated as a single platform with an electric circuit. The proposed hybrid fluid rubber mechanoreceptors mimicking bio-inspired senses proved to be useful for resolving the complicated structure. Through electrochemical impedance spectroscopy, the intrinsic structure and physical mechanisms of firing rates of the mechanoreceptors were elucidated, with findings revealing the adaptions in different sensations.
In order to advance the development of sensors fabricated with monofunctional sensation systems capable of a versatile response to tactile, thermal, gustatory, olfactory, and auditory sensations, mechanoreceptors fabricated as a single platform with an electric circuit require investigation. In addition, it is essential to resolve the complicated structure of the sensor. In order to realize the single platform, our proposed hybrid fluid (HF) rubber mechanoreceptors of free nerve endings, Merkel cells, Krause end bulbs, Meissner corpuscles, Ruffini endings, and Pacinian corpuscles mimicking the bio-inspired five senses are useful enough to facilitate the fabrication process for the resolution of the complicated structure. This study used electrochemical impedance spectroscopy (EIS) to elucidate the intrinsic structure of the single platform and the physical mechanisms of the firing rate such as slow adaption (SA) and fast adaption (FA), which were induced from the structure and involved the capacitance, inductance, reactance, etc. of the HF rubber mechanoreceptors. In addition, the relations among the firing rates of the various sensations were clarified. The adaption of the firing rate in the thermal sensation is the opposite of that in the tactile sensation. The firing rates in the gustation, olfaction, and auditory sensations at frequencies of less than 1 kHz have the same adaption as in the tactile sensation. The present findings are useful not only in the field of neurophysiology, to research the biochemical reactions of neurons and brain perceptions of stimuli, but also in the field of sensors, to advance salient developments in sensors mimicking bio-inspired sensations.
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