A 10-V-Tolerant Dual-Mode Neural Stimulation System With Self-Sustaining Dynamic Supply and Error-Resilient Digital Stimulus Odometer

Kyeongho Eom; Han Sol Lee; Seung Beom Ku; Joonghoon Kang; Hyungjin Jung; Taewoo Kim; Jaesoon Joo; Taekyung Kim; Young Min Shon; Hyung Min Lee

doi:10.1109/JSSC.2025.3542022

A 10-V-Tolerant Dual-Mode Neural Stimulation System With Self-Sustaining Dynamic Supply and Error-Resilient Digital Stimulus Odometer

Kyeongho Eom
, Han Sol Lee
, Seung Beom Ku
, Joonghoon Kang
, Hyungjin Jung
, Taewoo Kim
, Jaesoon Joo
, Taekyung Kim
, Young Min Shon^*
, Hyung Min Lee^*

^*Corresponding author for this work

School of Electrical Engineering

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

Abstract

This article proposes the eight-channel 10-V-tolerant energy-optimizing dual-mode dynamic supplied stimulation (D²S² system for deep brain stimulation (DBS). The proposed D2S2 system can efficiently provide both current-controlled stimulation (CCS) and voltage-controlled stimulation (VCS) with 7-bit resolution, providing flexibility in stimulation modes. The system adopts the self-sustaining dynamic supply (SSDS) technique, which can be applied to multi-channel simultaneous stimulation, achieving stimulation efficiency of up to 74.8%. The proposed digital error-resilient stimulus odometer (ERSO) with the deglitching capacitor precisely balances the biphasic charge transfer while achieving energy savings of up to 83.6% in VCS. The stimulation channels of the proposed D2S2 system can simultaneously deliver stimuli with dynamic supplies while ensuring 10-V stimulation compliance only with 5-V transistors. In vivo animal experiments on a rat with the D2S2 system fabricated in 0.25-μm CMOS process verified the effectiveness of the D2S2 system in halting epileptic seizures.

Original language	English
Pages (from-to)	3268-3282
Number of pages	15
Journal	IEEE Journal of Solid-State Circuits
Volume	60
Issue number	9
DOIs	https://doi.org/10.1109/JSSC.2025.3542022
Publication status	Published - 2025

Bibliographical note

Publisher Copyright:
© 2025 IEEE. All rights reserved.

Keywords

Charge balancing (CB)
deep brain stimulation (DBS)
dual mode
dynamic supply
high voltage tolerant
multi-channel stimulation
neural stimulator
stimulation
voltage compliance

ASJC Scopus subject areas

Electrical and Electronic Engineering

Access to Document

10.1109/JSSC.2025.3542022

Cite this

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title = "A 10-V-Tolerant Dual-Mode Neural Stimulation System With Self-Sustaining Dynamic Supply and Error-Resilient Digital Stimulus Odometer",

abstract = "This article proposes the eight-channel 10-V-tolerant energy-optimizing dual-mode dynamic supplied stimulation (D2S2 system for deep brain stimulation (DBS). The proposed D2S2 system can efficiently provide both current-controlled stimulation (CCS) and voltage-controlled stimulation (VCS) with 7-bit resolution, providing flexibility in stimulation modes. The system adopts the self-sustaining dynamic supply (SSDS) technique, which can be applied to multi-channel simultaneous stimulation, achieving stimulation efficiency of up to 74.8\%. The proposed digital error-resilient stimulus odometer (ERSO) with the deglitching capacitor precisely balances the biphasic charge transfer while achieving energy savings of up to 83.6\% in VCS. The stimulation channels of the proposed D2S2 system can simultaneously deliver stimuli with dynamic supplies while ensuring 10-V stimulation compliance only with 5-V transistors. In vivo animal experiments on a rat with the D2S2 system fabricated in 0.25-μm CMOS process verified the effectiveness of the D2S2 system in halting epileptic seizures.",

keywords = "Charge balancing (CB), deep brain stimulation (DBS), dual mode, dynamic supply, high voltage tolerant, multi-channel stimulation, neural stimulator, stimulation, voltage compliance",

author = "Kyeongho Eom and Lee, \{Han Sol\} and Ku, \{Seung Beom\} and Joonghoon Kang and Hyungjin Jung and Taewoo Kim and Jaesoon Joo and Taekyung Kim and Shon, \{Young Min\} and Lee, \{Hyung Min\}",

year = "2025",

doi = "10.1109/JSSC.2025.3542022",

language = "English",

volume = "60",

pages = "3268--3282",

journal = "IEEE Journal of Solid-State Circuits",

issn = "0018-9200",

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AU - Eom, Kyeongho

AU - Lee, Han Sol

AU - Ku, Seung Beom

AU - Kang, Joonghoon

AU - Jung, Hyungjin

AU - Kim, Taewoo

AU - Joo, Jaesoon

AU - Kim, Taekyung

AU - Shon, Young Min

AU - Lee, Hyung Min

PY - 2025

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N2 - This article proposes the eight-channel 10-V-tolerant energy-optimizing dual-mode dynamic supplied stimulation (D2S2 system for deep brain stimulation (DBS). The proposed D2S2 system can efficiently provide both current-controlled stimulation (CCS) and voltage-controlled stimulation (VCS) with 7-bit resolution, providing flexibility in stimulation modes. The system adopts the self-sustaining dynamic supply (SSDS) technique, which can be applied to multi-channel simultaneous stimulation, achieving stimulation efficiency of up to 74.8%. The proposed digital error-resilient stimulus odometer (ERSO) with the deglitching capacitor precisely balances the biphasic charge transfer while achieving energy savings of up to 83.6% in VCS. The stimulation channels of the proposed D2S2 system can simultaneously deliver stimuli with dynamic supplies while ensuring 10-V stimulation compliance only with 5-V transistors. In vivo animal experiments on a rat with the D2S2 system fabricated in 0.25-μm CMOS process verified the effectiveness of the D2S2 system in halting epileptic seizures.

AB - This article proposes the eight-channel 10-V-tolerant energy-optimizing dual-mode dynamic supplied stimulation (D2S2 system for deep brain stimulation (DBS). The proposed D2S2 system can efficiently provide both current-controlled stimulation (CCS) and voltage-controlled stimulation (VCS) with 7-bit resolution, providing flexibility in stimulation modes. The system adopts the self-sustaining dynamic supply (SSDS) technique, which can be applied to multi-channel simultaneous stimulation, achieving stimulation efficiency of up to 74.8%. The proposed digital error-resilient stimulus odometer (ERSO) with the deglitching capacitor precisely balances the biphasic charge transfer while achieving energy savings of up to 83.6% in VCS. The stimulation channels of the proposed D2S2 system can simultaneously deliver stimuli with dynamic supplies while ensuring 10-V stimulation compliance only with 5-V transistors. In vivo animal experiments on a rat with the D2S2 system fabricated in 0.25-μm CMOS process verified the effectiveness of the D2S2 system in halting epileptic seizures.

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KW - deep brain stimulation (DBS)

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KW - dynamic supply

KW - high voltage tolerant

KW - multi-channel stimulation

KW - neural stimulator

KW - stimulation

KW - voltage compliance

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ER -

A 10-V-Tolerant Dual-Mode Neural Stimulation System With Self-Sustaining Dynamic Supply and Error-Resilient Digital Stimulus Odometer

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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