An Implantable Neural Stimulator IC With Anodic Current Pulse Modulation Based Active Charge Balancing

An Implantable Neural Stimulator IC With Anodic Current Pulse Modulation Based Active Charge Balancing

Implantable electrical stimulators can be used to treat a variety of neurological disorders and restore paralyzed body functions. In electrical neural stimulation, the stimulator circuit with safe charge balancing is essential to minimize damage to electrodes and biological tissue. In this paper, an...

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Bibliographic Details
Main Authors: Jin-Young Son, Hyouk-Kyu Cha
Format: Article
Language:English
Published: IEEE 2020-01-01
Series:IEEE Access
Subjects:
Neural stimulation
electrical stimulator
charge balancing
Online Access:https://ieeexplore.ieee.org/document/9149602/
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spelling doaj-a8777589644c497ab0ac1f132f959f772021-03-30T03:23:48ZengIEEEIEEE Access2169-35362020-01-01813644913645810.1109/ACCESS.2020.30120289149602An Implantable Neural Stimulator IC With Anodic Current Pulse Modulation Based Active Charge BalancingJin-Young Son0Hyouk-Kyu Cha1https://orcid.org/0000-0003-4193-9180Department of Electrical and Information Engineering, Seoul National University of Science and Technology, Seoul, South KoreaDepartment of Electrical and Information Engineering, Seoul National University of Science and Technology, Seoul, South KoreaImplantable electrical stimulators can be used to treat a variety of neurological disorders and restore paralyzed body functions. In electrical neural stimulation, the stimulator circuit with safe charge balancing is essential to minimize damage to electrodes and biological tissue. In this paper, an implantable current-mode neural stimulator for long-term safe electrical stimulation is presented. Anodic current pulse modulation active charge balancing technique is proposed to keep the residual voltage on the electrode within the safe window, which enables long-term safe stimulation. To ensure more complete charge balancing, the proposed active charge balancing technique can also be used with passive electrode shorting. Transistor stacking and dynamic gate biasing techniques can prevent the breakdown of standard MOSFET devices from high supply voltages, which enable the implementation of output current driver and charge balancing circuits without using HV process. The stimulator IC designed with 0.18-&#x03BC;m standard CMOS process can generate up to 1 mA of stimulation current and only consumes an area of 0.11 mm<sup>2</sup>. Since all functions are implemented on-chip without using external components, the proposed stimulator IC is suitable for high-density implantable stimulation applications.https://ieeexplore.ieee.org/document/9149602/Neural stimulationelectrical stimulatorcharge balancing
collection DOAJ
language English
format Article
sources DOAJ
author Jin-Young Son
Hyouk-Kyu Cha
spellingShingle Jin-Young Son
Hyouk-Kyu Cha
An Implantable Neural Stimulator IC With Anodic Current Pulse Modulation Based Active Charge Balancing
IEEE Access
Neural stimulation
electrical stimulator
charge balancing
author_facet Jin-Young Son
Hyouk-Kyu Cha
author_sort Jin-Young Son
title An Implantable Neural Stimulator IC With Anodic Current Pulse Modulation Based Active Charge Balancing
title_short An Implantable Neural Stimulator IC With Anodic Current Pulse Modulation Based Active Charge Balancing
title_full An Implantable Neural Stimulator IC With Anodic Current Pulse Modulation Based Active Charge Balancing
title_fullStr An Implantable Neural Stimulator IC With Anodic Current Pulse Modulation Based Active Charge Balancing
title_full_unstemmed An Implantable Neural Stimulator IC With Anodic Current Pulse Modulation Based Active Charge Balancing
title_sort implantable neural stimulator ic with anodic current pulse modulation based active charge balancing
publisher IEEE
series IEEE Access
issn 2169-3536
publishDate 2020-01-01
description Implantable electrical stimulators can be used to treat a variety of neurological disorders and restore paralyzed body functions. In electrical neural stimulation, the stimulator circuit with safe charge balancing is essential to minimize damage to electrodes and biological tissue. In this paper, an implantable current-mode neural stimulator for long-term safe electrical stimulation is presented. Anodic current pulse modulation active charge balancing technique is proposed to keep the residual voltage on the electrode within the safe window, which enables long-term safe stimulation. To ensure more complete charge balancing, the proposed active charge balancing technique can also be used with passive electrode shorting. Transistor stacking and dynamic gate biasing techniques can prevent the breakdown of standard MOSFET devices from high supply voltages, which enable the implementation of output current driver and charge balancing circuits without using HV process. The stimulator IC designed with 0.18-&#x03BC;m standard CMOS process can generate up to 1 mA of stimulation current and only consumes an area of 0.11 mm<sup>2</sup>. Since all functions are implemented on-chip without using external components, the proposed stimulator IC is suitable for high-density implantable stimulation applications.
topic Neural stimulation
electrical stimulator
charge balancing
url https://ieeexplore.ieee.org/document/9149602/
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