Flexible Charge Balanced Stimulator With 5.6 fC Accuracy for 140 nC Injections

Author

Nag, Sudip ; Xiaofeng Jia ; Thakor, Nitish ; Sharma, Divya

Author_Institution

Electr. Eng. Dept., Indian Inst. of Technol. Bombay, Mumbai, India

Volume

7

Issue

3

fYear

2013

fDate

Jun-13

Firstpage

266

Lastpage

275

Abstract

Electrical stimulations of neuronal structures must ensure net injected charges to be zero for biological safety and voltage compliance reasons. We present a novel architecture of general purpose biphasic constant current stimulator that exhibits less than 5.6 fC error while injecting 140 nC charges using 1.4 mA currents. The floating current sources and conveyor switch based system can operate in monopolar or bipolar modes. Anodic-first or cathodic-first pulses with optional inter-phase delays have been demonstrated with zero quiescent current requirements at the analog front-end. The architecture eliminates blocking capacitors, electrode shorting and complex feedbacks. Bench-top and in-vivo measurement results have been presented with emulated electrode impedances (resistor-capacitor network), Ag-AgCl electrodes in saline and in-vivo (acute) peripheral nerve stimulations in anesthetized rats.

Keywords

bioelectric potentials; biomedical electrodes; biomedical electronics; biomedical measurement; capacitors; delays; neuromuscular stimulation; resistors; silver; silver compounds; Ag-AgCl; analog front-end; anesthetized rats; anodic-first pulses; bench-top measurement; biological safety; biphasic constant current stimulator; bipolar modes; blocking capacitor elimination; cathodic-first pulses; charge balanced stimulator; complex feedback elimination; conveyor switch based system; current 1.4 mA; electrical stimulations; electrode impedances; electrode shorting elimination; floating current sources; in-vivo acute peripheral nerve stimulations; in-vivo measurement; inter-phase delays; monopolar modes; neuronal structures; resistor-capacitor network; saline; zero quiescent current requirements; Accuracy; Biomedical measurements; Capacitors; Current measurement; Electrodes; Voltage control; Voltage measurement; Charge balancing; electrical stimulation; floating current source; muscle evoked potentials (MEP); Algorithms; Animals; Computer Simulation; Electric Capacitance; Electric Impedance; Electric Stimulation Therapy; Electrodes; Electrodes, Implanted; Equipment Design; Evoked Potentials; Female; Muscle, Skeletal; Neurons; Peripheral Nervous System; Rats; Rats, Wistar; Reproducibility of Results; Transcutaneous Electric Nerve Stimulation;

fLanguage

English

Journal_Title

Biomedical Circuits and Systems, IEEE Transactions on

Publisher

ieee

ISSN

1932-4545

Type

jour

DOI

10.1109/TBCAS.2012.2205574

Filename

6302212