Tag Archives: injectable electronics

“Injectable tissue prosthesis coupled with closed-loop bioelectronic system” for damaged muscle/nerve regeneration and robot-assisted rehabilitation

A fascinating new use for hyaluronic acid (usually discussed in relation to cosmetic wrinkle-reduction) has been found according to a November 1, 2023 news item on ScienceDaily.

In a recent publication in the journal Nature, researchers from the Institute of Basic Science (IBS) in South Korea have made significant strides in biomaterial technology and rehabilitation medicine. They’ve developed a novel approach to healing muscle injury by employing “injectable tissue prosthesis” in the form of conductive hydrogels and combining it with a robot-assisted rehabilitation system.

Let’s imagine you are swimming in the ocean. A giant shark approaches and bites a huge chunk of meat out of your thigh, resulting in a complete loss of motor/sensor function in your leg.

If left untreated, such severe muscle damage would result in permanent loss of function and disability.

How on Earth will you be able to recover from this kind of injury?

Traditional rehabilitation methods for these kinds of muscle injuries have long sought an efficient closed-loop gait rehabilitation system that merges lightweight exoskeletons and wearable/implantable devices.

Such assistive prosthetic system is required to aid the patients through the process of recovering sensory and motor functions linked to nerve and muscle damage.

Unfortunately, the mechanical properties and rigid nature of existing electronic materials render them incompatible with soft tissues.

This leads to friction and potential inflammation, stalling patient rehabilitation.

To overcome these limitations, the IBS researchers turned to a material commonly used as a wrinkle-smoothing filler, called hyaluronic acid.

A November 2, 2023 Institute of Basic Science (IBS) press release (also on EurekAlert but published November 1, 2023), which originated the news item, explains how hyaluronic acid helps in tissue rehabilitation and regeneration,

Using this substance [hyaluronic acid], an injectable hydrogel was developed for “tissue prostheses”, which can temporarily fill the gap of the missing muscle/nerve tissues while it regenerates. The injectable nature of this material gives it a significant advantage over traditional bioelectronic devices, which are unsuitable for narrow, deep, or small areas, and necessitate invasive surgeries.

Thanks to its highly “tissue-like” properties, this hydrogel seamlessly interfaces with biological tissues and can be easily administered to hard-to-reach body areas without surgery. The reversible and irreversible crosslinks within the hydrogel adapt to high shear stress during injection, ensuring excellent mechanical stability. This hydrogel also incorporates gold nanoparticles, which gives it decent electrical properties. Its conductive nature allows for the effective transmission of electrophysiological signals between the two ends of injured tissues. In addition, the hydrogel is biodegrdable, meaning that the patients do not need to get surgery again.

With mechanical properties akin to natural tissues, exceptional tissue adhesion, and injectable characteristics, researchers believe this material offers a novel approach to rehabilitation.

Next, the researchers put this novel idea to the test in rodent models. To simulate volumetric muscle loss injury, a large chunk of muscle has been removed from the hind legs of these animals. By injecting the hydrogel and implanting the two kinds of stretchable tissue-interfacing devices for electrical sensing and stimulation, the researchers were able to improve the gait in the “injured” rodents. The hydrogel prosthetics were combined with robot assistance, guided by muscle electromyography signals. Together, the two helped enhance the animal’s gait without nerve stimulation. Furthermore, muscle tissue regeneration was effectively improved over the long term after the conductive hydrogel was used to fill muscle damage.

The injectable conductive hydrogel developed in this study excels in electrophysiological signal recording and stimulation performance, offering the potential to expand its applications. It presents a fresh approach to the field of bioelectronic devices and holds promise as a soft tissue prosthesis for rehabilitation support.

Emphasizing the significance of the research, Professor SHIN Mikyung notes, “We’ve created an injectable, mechanically tough, and electrically conductive soft tissue prosthesis ideal for addressing severe muscle damage requiring neuromusculoskeletal rehabilitation. The development of this injectable hydrogel, utilizing a novel cross-linking method, is a notable achievement. We believe it will be applicable not only in muscles and peripheral nerves but also in various organs like the brain and heart.”

Professor SON Donghee added, “In this study, the closed-loop gait rehabilitation system entailing tough injectable hydrogel and stretchable and self-healing sensors could significantly enhance the rehabilitation prospects for patients with neurological and musculoskeletal challenges. It could also play a vital role in precise diagnosis and treatment across various organs in the human body.”

The research team is currently pursuing further studies to develop new materials for nerve and muscle tissue regeneration that can be implanted in a minimally invasive manner. They are also exploring the potential for recovery in various tissue damages through the injection of the conductive hydrogel, eliminating the need for open surgery.

Here’s a link to and a citation for the paper,

Injectable tissue prosthesis for instantaneous closed-loop rehabilitation by Subin Jin, Heewon Choi, Duhwan Seong, Chang-Lim You, Jong-Sun Kang, Seunghyok Rho, Won Bo Lee, Donghee Son & Mikyung Shin. Nature volume 623, pages 58–65 (2023) DOI: https://doi.org/10.1038/s41586-023-06628-x Published: 01 November 2023 Issue Date: 02 November 2023

This paper is behind a paywall.

Long-term brain mapping with injectable electronics

Charles Lieber and his team at Harvard University announced a success with their work on injectable electronics last year (see my June 11, 2015 posting for more) and now they are reporting on their work with more extensive animal studies according to an Aug. 29, 2016 news item on psypost.org,

Scientists in recent years have made great strides in the quest to understand the brain by using implanted probes to explore how specific neural circuits work.

Though effective, those probes also come with their share of problems as a result of rigidity. The inflammation they produce induces chronic recording instability and means probes must be relocated every few days, leaving some of the central questions of neuroscience – like how the neural circuits are reorganized during development, learning and aging- beyond scientists’ reach.

But now, it seems, things are about to change.

Led by Charles Lieber, The Mark Hyman Jr. Professor of Chemistry and chair of the Department of Chemistry and Chemical Biology, a team of researchers that included graduate student Tian-Ming Fu, postdoctoral fellow Guosong Hong, graduate student Tao Zhou and others, has demonstrated that syringe-injectable mesh electronics can stably record neural activity in mice for eight months or more, with none of the inflammation

An Aug. 29, 2016 Harvard University press release, which originated the news item, provides more detail,

“With the ability to follow the same individual neurons in a circuit chronically…there’s a whole suite of things this opens up,” Lieber said. “The eight months we demonstrate in this paper is not a limit, but what this does show is that mesh electronics could be used…to investigate neuro-degenerative diseases like Alzheimer’s, or processes that occur over long time, like aging or learning.”

Lieber and colleagues also demonstrated that the syringe-injectable mesh electronics could be used to deliver electrical stimulation to the brain over three months or more.

“Ultimately, our aim is to create these with the goal of finding clinical applications,” Lieber said. “What we found is that, because of the lack of immune response (to the mesh electronics), which basically insulates neurons, we can deliver stimulation in a much more subtle way, using lower voltages that don’t damage tissue.”

The possibilities, however, don’t end there.

The seamless integration of the electronics and biology, Lieber said, could open the door to an entirely new class of brain-machine interfaces and vast improvements in prosthetics, among other fields.

“Today, brain-machine interfaces are based on traditional implanted probes, and there has been some impressive work that’s been done in that field,” Lieber said. “But all the interfaces rely on the same technique to decode neural signals.”

Because traditional rigid implanted probes are invariably unstable, he explained, researchers and clinicians rely on decoding what they call the “population average” – essentially taking a host of neural signals and applying complex computational tools to determine what they mean.

Using tissue-like mesh electronics, by comparison, researchers may be able to read signals from specific neurons over time, potentially allowing for the development of improved brain-machine interfaces for prosthetics.

“We think this is going to be very powerful, because we can identify circuits and both record and stimulate in a way that just hasn’t been possible before,” Lieber said. “So what I like to say is: I think therefore it happens.”

Lieber even held out the possibility that the syringe-injectable mesh electronics could one day be used to treat catastrophic injuries to the brain and spinal cord.

“I don’t think that’s science-fiction,” he said. “Other people may say that will be possible through, for example, regenerative medicine, but we are pursuing this from a different angle.

“My feeling is that this is about a seamless integration between the biological and the electronic systems, so they’re not distinct entities,” he continued. “If we can make the electronics look like the neural network, they will work together…and that’s where you want to be if you want to exploit the strengths of both.”

In the 2015 posting, Lieber was discussing cyborgs, here he broaches the concept without using the word, “… seamless integration between the biological and the electronic systems, so they’re not distinct entities.”

Here’s a link to and a citation for the paper,

Stable long-term chronic brain mapping at the single-neuron level by Tian-Ming Fu, Guosong Hong, Tao Zhou, Thomas G Schuhmann, Robert D Viveros, & Charles M Lieber. Nature Methods (2016) doi:10.1038/nmeth.3969 Published online 29 August 2016

This paper is behind a paywall.

Injectable electronics

Having taught a course on bioelectronics for Simon Fraser University’s (Vancouver, Canada) Continuing Studies Program, this  latest work from Harvard University (US) caught my attention. A Harvard research team has developed a technique which could allow doctors to inject us with electronics, should we need them. From a June 8, 2015 news item on phys.org,

It’s a notion that might be pulled from the pages of science-fiction novel – electronic devices that can be injected directly into the brain, or other body parts, and treat everything from neurodegenerative disorders to paralysis.

It sounds unlikely, until you visit Charles Lieber’s lab.

A team of international researchers, led by Lieber, the Mark Hyman, Jr. Professor of Chemistry, an international team of researchers developed a method for fabricating nano-scale electronic scaffolds that can be injected via syringe. Once connected to electronic devices, the scaffolds can be used to monitor neural activity, stimulate tissues and even promote regenerations of neurons. …

Here’s an image provided by the researchers,

Bright-field image showing the mesh electronics being injected through sub-100 micrometer inner diameter glass needle into aqueous solution. mage courtesy of Lieber Research Group, Harvard University

Bright-field image showing the mesh electronics being injected through sub-100 micrometer inner diameter glass needle into aqueous solution. mage courtesy of Lieber Research Group, Harvard University

A June 8, 2015 Harvard University new release by Peter Reuell (also on EurekAlert), which originated the news item, describes the work in more detail,

“I do feel that this has the potential to be revolutionary,” Lieber said. “This opens up a completely new frontier where we can explore the interface between electronic structures and biology. For the past thirty years, people have made incremental improvements in micro-fabrication techniques that have allowed us to make rigid probes smaller and smaller, but no one has addressed this issue – the electronics/cellular interface – at the level at which biology works.”

The idea of merging the biological with the electronic is not a new one for Lieber.

In an earlier study, scientists in Lieber’s lab demonstrated that the scaffolds could be used to create “cyborg” tissue – when cardiac or nerve cells were grown with embedded scaffolds. [emphasis mine] Researchers were then able to use the devices to record electrical signals generated by the tissues, and to measure changes in those signals as they administered cardio- or neuro-stimulating drugs.

“We were able to demonstrate that we could make this scaffold and culture cells within it, but we didn’t really have an idea how to insert that into pre-existing tissue,” Lieber said. “But if you want to study the brain or develop the tools to explore the brain-machine interface, you need to stick something into the body. When releasing the electronics scaffold completely from the fabrication substrate, we noticed that it was almost invisible and very flexible like a polymer and could literally be sucked into a glass needle or pipette. From there, we simply asked, would it be possible to deliver the mesh electronics by syringe needle injection, a process common to delivery of many species in biology and medicine – you could go to the doctor and you inject this and you’re wired up.'”

Though not the first attempts at implanting electronics into the brain – deep brain stimulation has been used to treat a variety of disorders for decades – the nano-fabricated scaffolds operate on a completely different scale.

“Existing techniques are crude relative to the way the brain is wired,” Lieber explained. “Whether it’s a silicon probe or flexible polymers…they cause inflammation in the tissue that requires periodically changing the position or the stimulation. But with our injectable electronics, it’s as if it’s not there at all. They are one million times more flexible than any state-of-the-art flexible electronics and have subcellular feature sizes. They’re what I call “neuro-philic” – they actually like to interact with neurons..”

Despite their enormous potential, the fabrication of the injectable scaffolds is surprisingly easy.

“That’s the beauty of this – it’s compatible with conventional manufacturing techniques,” Lieber said.

The process is similar to that used to etch microchips, and begins with a dissolvable layer deposited on a substrate. To create the scaffold, researchers lay out a mesh of nanowires sandwiched in layers of organic polymer. The first layer is then dissolved, leaving the flexible mesh, which can be drawn into a syringe needle and administered like any other injection.

After injection, the input/output of the mesh can be connected to standard measurement electronics so that the integrated devices can be addressed and used to stimulate or record neural activity.

“These type of things have never been done before, from both a fundamental neuroscience and medical perspective,” Lieber said. “It’s really exciting – there are a lot of potential applications.”

Going forward, Lieber said, researchers hope to better understand how the brain and other tissues react to the injectable electronics over longer periods.

Lieber’s earlier work on “cyborg tissue” was briefly mentioned here in a Feb. 20, 2014 posting.

Getting back to the most recent work, here’s a link to and a citation for the paper,

Syringe-injectable electronics by Jia Liu, Tian-Ming Fu, Zengguang Cheng, Guosong Hong, Tao Zhou, Lihua Jin, Madhavi Duvvuri, Zhe Jiang, Peter Kruskal, Chong Xie, Zhigang Suo, Ying Fang, & Charles M. Lieber. Nature Nanotechnology (2015) doi:10.1038/nnano.2015.115 Published online 08 June 2015

This paper is behind a paywall but there is a free preview via ReadCube Access.

One final note, the researchers have tested the injectable electronics (or mesh electronics) in vivo (live animals).