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Magnetic-Driven Torque-Induced Electrical Stimulation for Millisecond-Scale Wireless Neuromodulation.


ABSTRACT: Wireless neuromodulation using nanoparticles, offering minimally invasive alternatives to conventional deep brain stimulation (DBS) while reducing the risks associated with hardware implants, has gained significant traction over the past decade. Nevertheless, ensuring millisecond-scale wireless DBS for the precise temporal control of neuronal activity remains challenging. This study reports magnetic-driven torque-induced electrical stimulation (MagTIES), a torque-based magnetoelectric neuromodulation method. By utilizing magnetic nanodiscs to generate torque under alternating magnetic fields (AMFs), the MagTIES induces a piezoelectric effect in piezoelectric nanoparticles, thereby overcoming the limitations of traditional magnetostriction-based systems. With an AMF (50 mT at ≈10 Hz), the proposed approach triggers neuronal activity both in vitro and in vivo, specifically in the deep brain region of the amygdala, within milliseconds. Furthermore, MagTIES enables the fine-tuning of amygdala brain oscillations through the precise modulation of the AMF frequency. By combining high spatial and temporal precision with minimal invasiveness, MagTIES provides an innovative approach for advancing neuroscience research with potential applications in understanding neural circuits and developing innovative therapies.

SUBMITTER: Cheng CC 

PROVIDER: S-EPMC12333473 | biostudies-literature | 2025 Aug

REPOSITORIES: biostudies-literature

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Magnetic-Driven Torque-Induced Electrical Stimulation for Millisecond-Scale Wireless Neuromodulation.

Cheng Chao-Chun CC   Chen Li-Ling LL   Tseng Guan-Jhong GJ   Huang Jun-Xuan JX   Ting Yen-Jing YJ   Chiang Po-Han PH  

Advanced healthcare materials 20250616 20


Wireless neuromodulation using nanoparticles, offering minimally invasive alternatives to conventional deep brain stimulation (DBS) while reducing the risks associated with hardware implants, has gained significant traction over the past decade. Nevertheless, ensuring millisecond-scale wireless DBS for the precise temporal control of neuronal activity remains challenging. This study reports magnetic-driven torque-induced electrical stimulation (MagTIES), a torque-based magnetoelectric neuromodul  ...[more]

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