High‐Performing and Capacitive‐Matched Triboelectric Implants Driven by Ultrasound

High‐Performing and Capacitive‐Matched Triboelectric Implants Driven by Ultrasound

In implantable bioelectronics, which aim for semipermanent use of devices, biosafe energy sources and packaging materials to protect devices are essential elements. However, research so far has been conducted in a direction where they cannot coexist. Here, the development of capacitance‐matched trib...

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Bibliographic Details
Published in:Advanced materials (Weinheim) Vol. 36; no. 2; pp. e2307194 - n/a
Main Authors: Kim, Young‐Jun, Lee, Jiho, Hwang, Joon‐Ha, Chung, Youngwook, Park, Byung‐Joon, Kim, Junho, Kim, So‐Hee, Mun, Junseung, Yoon, Hong‐Joon, Park, Sung‐Min, Kim, Sang‐Woo
Format: Journal Article
Language:English
Published: Germany Wiley Subscription Services, Inc 01-01-2024
Subjects:
Animals
Electric Capacitance
Electric Power Supplies
Energy transmission
Humans
implantable devices
Implants
In vivo methods and tests
neurostimulation
overactive bladder
Packaging
Prostheses and Implants
Rats
Signs and symptoms
Transmission efficiency
Transplants & implants
triboelectric implants
Ultrasonic attenuation
Ultrasonic imaging
Ultrasonography
ultrasound energy harvesting
implantable devices
ultrasound energy harvesting
triboelectric implants
overactive bladder
neurostimulation
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Summary:In implantable bioelectronics, which aim for semipermanent use of devices, biosafe energy sources and packaging materials to protect devices are essential elements. However, research so far has been conducted in a direction where they cannot coexist. Here, the development of capacitance‐matched triboelectric implants driven is reported by ultrasound under 500 mW cm−2 safe intensity and realize a battery‐free, miniatured, and wireless neurostimulator with full titanium (Ti) packaging. The triboelectric implant with high dielectric composite, which has ultralow output impedance, can efficiently deliver sufficient power to generate the stimulation pulse without an energy‐storing battery, despite ultrasound attenuation due to the Ti, and has the highest energy transmission efficiency among those reported so far. In vivo study using a rat model demonstrated that the proposed device system is an effective solution for relieving urinary symptoms. These achievements provide a significant step toward permanently implantable devices for controlling human organs and treating various diseases. The ultrasound‐driven triboelectric nanogenerator using a high‐dielectric composite not only improves the output of the device, but also improves the connectivity between the energy harvester and the circuit, enabling the semipermanent use and miniaturization of implantable medical devices. These triboelectric implants provide a significant step toward permanently implantable devices for controlling human organs and treating various diseases.
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ISSN:0935-9648
1521-4095
DOI:10.1002/adma.202307194