Title :
Bio-electronic interaction: principle and applications
Author_Institution :
IMS, Univ. Bordeaux, Talence, France
Abstract :
Electrophysiology is at the basis of bio-electronic interaction. Excitable cells or tissues can communicate with electronics, either in experiments where the bio-signal is recorded and analyzed, or in experiments where the biological tissue is electrically stimulated. In the recording case, the action potentials of the bio-signal must be discriminated from noise, in order to measure the influence of a physical parameter or a pharmacological agent, and hence explore unknown mechanisms. In the stimulation case, a controlled amount of charge is delivered to the tissue, in order to restore or compensate a biological function.
Keywords :
bioelectric potentials; biological tissues; biomedical measurement; cellular biophysics; data acquisition; data analysis; drugs; medical signal processing; noise; patient treatment; bio-electronic interaction applications; bio-electronic interaction principle; biological function compensation; biological function restoration; biological tissue electrical stimulation; biosignal action potential; biosignal analysis; biosignal recording; charge delivery; controlled charge amount; electronic communication; electrophysiology; excitable cell communication; excitable tissue communication; noise; pharmacological agent influence measurement; physical parameter influence measurement; Biological tissues; Cells (biology); Context; Electric potential; Electrodes; Implants; Bio-electronic interfaces; Bio-signal processing; Biomedical circuits and systems; Biophysics; Electrophysiology;
Conference_Titel :
Design & Technology of Integrated Systems In Nanoscale Era (DTIS), 2014 9th IEEE International Conference On
Conference_Location :
Santorini
DOI :
10.1109/DTIS.2014.6850653
