A team of international researchers, led by Charles M Lieber, the Mark Hyman, Jr Professor of Chemistry, has 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. The study is described in Nature Nanotechnology.
“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 his lab demonstrated that the scaffolds could be used to create “cyborg” tissue—when cardiac or nerve cells were grown with embedded scaffolds. 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 did not 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 are wired up.”
Though this does not represent 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 is 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 is as if it is 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 are what I call ‘neuro-philic’—they actually like to interact with neurons.”
Despite their enormous potential, the fabrication of the injectable scaffolds is relatively simple. That’s the beauty of this—it is 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 types of things have never been done before, from both a fundamental neuroscience and medical perspective,” Lieber said. “It is 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.
Harvard’s Office of Technology Development has filed for a provisional patent on the technology and is actively seeking commercialisation opportunities.
“Having those results can prove that this is really a viable technology,” Lieber said. “The idea of being able to precisely position and record from very specific areas, or even from specific neurons over an extended period of time—this could, I think, make a huge impact on neuroscience.”