Analysis of wireless powering modes for nanotransducer-mediated neuromodulation

Prachi Kumari; Aleksandra Milojkovic; Kristen Kozielski

doi:10.1016/j.cobme.2024.100562

Analysis of wireless powering modes for nanotransducer-mediated neuromodulation

Prachi Kumari, Aleksandra Milojkovic, Kristen Kozielski

Assistant Professorship of Neuroengineering Materials

Technical University of Munich

Research output: Contribution to journal › Review article › peer-review

Abstract

Nanomaterials offer a promising approach for precise and minimally invasive modulation of neural activity versus traditional implants. This review explores recent advances in various nanotransducer systems that are powered by a remotely deliverable carrier signal (optical, mechanical, or magnetic) and output a neuromodulatory signal (optical, thermal, mechanical, or electrical). Key advantages of individual transduction methods have been highlighted, such as penetration to deeper brain regions, and potential for cell-specific targeting with or without genetic modification of the target tissue. Current challenges and advances are discussed in the context of considerations for clinical translation, which include optimizing transduction efficiency, reducing power requirements, and spatiotemporal stimulation control.

Original language	English
Article number	100562
Journal	Current Opinion in Biomedical Engineering
Volume	33
DOIs	https://doi.org/10.1016/j.cobme.2024.100562
State	Published - Mar 2025

Keywords

Bioelectronics
Nanotransducers
Neural engineering
Neural interfaces
Wireless power transfer

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10.1016/j.cobme.2024.100562

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title = "Analysis of wireless powering modes for nanotransducer-mediated neuromodulation",

abstract = "Nanomaterials offer a promising approach for precise and minimally invasive modulation of neural activity versus traditional implants. This review explores recent advances in various nanotransducer systems that are powered by a remotely deliverable carrier signal (optical, mechanical, or magnetic) and output a neuromodulatory signal (optical, thermal, mechanical, or electrical). Key advantages of individual transduction methods have been highlighted, such as penetration to deeper brain regions, and potential for cell-specific targeting with or without genetic modification of the target tissue. Current challenges and advances are discussed in the context of considerations for clinical translation, which include optimizing transduction efficiency, reducing power requirements, and spatiotemporal stimulation control.",

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AU - Milojkovic, Aleksandra

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N2 - Nanomaterials offer a promising approach for precise and minimally invasive modulation of neural activity versus traditional implants. This review explores recent advances in various nanotransducer systems that are powered by a remotely deliverable carrier signal (optical, mechanical, or magnetic) and output a neuromodulatory signal (optical, thermal, mechanical, or electrical). Key advantages of individual transduction methods have been highlighted, such as penetration to deeper brain regions, and potential for cell-specific targeting with or without genetic modification of the target tissue. Current challenges and advances are discussed in the context of considerations for clinical translation, which include optimizing transduction efficiency, reducing power requirements, and spatiotemporal stimulation control.

AB - Nanomaterials offer a promising approach for precise and minimally invasive modulation of neural activity versus traditional implants. This review explores recent advances in various nanotransducer systems that are powered by a remotely deliverable carrier signal (optical, mechanical, or magnetic) and output a neuromodulatory signal (optical, thermal, mechanical, or electrical). Key advantages of individual transduction methods have been highlighted, such as penetration to deeper brain regions, and potential for cell-specific targeting with or without genetic modification of the target tissue. Current challenges and advances are discussed in the context of considerations for clinical translation, which include optimizing transduction efficiency, reducing power requirements, and spatiotemporal stimulation control.

KW - Bioelectronics

KW - Nanotransducers

KW - Neural engineering

KW - Neural interfaces

KW - Wireless power transfer

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DO - 10.1016/j.cobme.2024.100562

M3 - Review article

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SN - 2468-4511

VL - 33

JO - Current Opinion in Biomedical Engineering

JF - Current Opinion in Biomedical Engineering

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ER -

Analysis of wireless powering modes for nanotransducer-mediated neuromodulation

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Keywords

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