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In Vitro Testing of an Implantable Wireless Telemetry System for Long‐Term Electromyography Recordings in Large Animals
Author(s) -
Kneisz Lukas,
Unger Ewald,
Lanmüller Hermann,
Mayr Winfried
Publication year - 2015
Publication title -
artificial organs
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.684
H-Index - 76
eISSN - 1525-1594
pISSN - 0160-564X
DOI - 10.1111/aor.12626
Subject(s) - electromyography , telemetry , wireless , transmitter , signal (programming language) , computer science , biomedical engineering , functional electrical stimulation , transceiver , transmission (telecommunications) , neuroprosthetics , channel (broadcasting) , engineering , telecommunications , medicine , stimulation , psychiatry , physical medicine and rehabilitation , programming language
Multichannel bio‐signal recording in undisturbed in vivo conditions is a frequent demand in experimental work for development of methodology and associated equipment for functional electrical stimulation ( FES ) application, limb prosthesis, and diagnostic tools in contemporary rehabilitation efforts. Intramuscular electromyogram ( EMG ) recordings can provide comprehensive insight in complex interactions of agonistic and antagonistic muscles during movement tasks and in contrast act as reliable control signals for both neuroprosthesis and mechanical prosthesis. We fabricated a fully implantable device, which is capable of recording electromyography signals from inside a body and transmit these signals wirelessly to an external receiver. The developed analog front end uses only two electrodes per channel, provides a gain of 60 dB, and incorporates a band pass filter with lower cut‐off frequency of 4 Hz and upper cut‐off frequency of 480 Hz. The bidirectional wireless data link, which operates in the 2.4 GHz Industrial, Scientific and Medical band, is designed for transmission distances of 10 m using an application data rate of 1 kSps for each of the two channels. Performed in vitro tests with the devices coated in epoxy resin and inserted into a phantom with tissue‐equivalent characteristics confirmed the functionality of our concept and the measurement results are consistent with those from preceding simulations.