Flexible implanted electronics are a step closer toward clinical applications thanks to a recent breakthrough technology developed by a research team from Griffith University and UNSW Sydney [both in Australia].
From: Griffith University
August 10, 2022 -- The
work was pioneered by Dr Tuan-Khoa Nguyen, Professor Nam-Trung Nguyen and Dr
Hoang-Phuong Phan (currently a senior lecturer at the University of New South
Wales) from Griffith University's Queensland Micro and Nanotechnology Centre
(QMNC) using in-house silicon carbide technology as a new platform for
long-term electronic biotissue interfaces.
The project was hosted
by the QMNC, which houses a part of the Queensland node of the Australian
National Nanofabrication Facility (ANFF-Q).
ANFF-Q is a company
established under the National Collaborative Research Infrastructure Strategy
to provide nano- and microfabrication facilities for Australia's researchers.
The QMNC offers unique
capabilities for the development and characterisation of wide band gap
material, a class of semiconductors that have electronic properties lying
between non-conducing materials such as glass and semi-conducting materials
such as silicon used for computer chips.
These properties allow
devices made of these materials to operate at extreme conditions such as high
voltage, high temperature, and corrosive environments.
The QMNC and ANFF-Q
provided this project with silicon carbide materials, the scalable
manufacturing capability, and advanced characterisation facilities for robust
micro/nanobioelectronic devices.
"Implantable and
flexible devices have enormous potential to treat chronic diseases such as
Parkinson's disease and injuries to the spinal cord," Dr Tuan-Khoa Nguyen
said.
"These devices
allow for direct diagnosis of disorders in internal organs and provide suitable
therapies and treatments.
"For instance,
such devices can offer electrical stimulations to targeted nerves to regulate
abnormal impulses and restore body functions."
Because of direct
contact requirement with biofluids, maintaining their long-term operation when
implanted is a daunting challenge.
The research team
developed a robust and functional material system that could break through this
bottleneck.
"The system
consists of silicon carbide nanomembranes as the contact surface and silicon
dioxide as the protective encapsulation, showing unrivalled stability and
maintaining its functionality in biofluids," Professor Nam-Trung Nguyen
said.
"For the first
time, our team has successfully developed a robust implantable electronic
system with an expected duration of a few decades."
The researchers
demonstrated multiple modalities of impedance and temperature sensors, and
neural stimulators together with effective peripheral nerve stimulation in
animal models.
Corresponding author Dr
Phan said implanted devices such as cardiac pace markers and deep brain
stimulators had powerful capabilities for timely treatment of several chronical
diseases.
"Traditional
implants are bulky and have a different mechanical stiffness from human tissues
that poses potential risks to patients. The development of mechanically soft
but chemically strong electronic devices is the key solution to this
long-standing problem," Dr Phan said.
The concept of the
silicon carbide flexible electronics provides promising avenues for
neuroscience and neural stimulation therapies, which could offer live-saving
treatments for chronic neurological diseases and stimulate patient recovery.
"To make this
platform a reality, we are fortunate to have a strong multidisciplinary
research team from Griffith University, UNSW, University of Queensland, Japan
Science and Technology Agency (JST) -- ERATO, with each bringing their
expertise in material science, mechanical/electrical engineering, and
biomedical engineering," said Dr Phan.
https://www.sciencedaily.com/releases/2022/08/220810105134.htm
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