A minimally invasive approach to managing pain without opioids
Researchers at the University of Wisconsin (UW) are adopting a minimally invasive, safer approach to electrically treating pain directly at the source as part of the NIH Helping to End Addiction Long-term (HEAL) Initiative.
It is an advance from one of the National Institute of Biomedical Imaging and Bioengineering's (NIBIB's) first grants under the HEAL initiative, launched in 2018 to find solutions to the opioid crisis.
Neuromodulation therapies apply electrical stimulation to nerves to treat conditions like chronic lower back pain, paralysis, incontinence, migraines, sleep apnea, and obesity.
The UW technology was developed by the startup Neuronoff, Inc., primarily using private funding and Defense Advanced Research Projects Agency (DARPA) funding, and the infusion of NIH support will prepare the device for its first-in-human clinical trials.
The key innovation is a new type of electrode that may make neuromodulation therapies less invasive, less costly, less painful, more reliable, and much easier to scale for a larger number of patients.
Currently, the most effective neuromodulation treatments require intricate surgical procedures to implant a complex device that is invasive and expensive, making it a treatment of last resort.
In contrast, non-invasive neuromodulation devices apply stimulation through electrodes that are placed on the surface of the skin and use a specially crafted electrical waveform to block pain signals in nerves.
These electrical waveforms travel through tissue, muscle, and superficial nerves to achieve a therapeutic effect. Unfortunately, surface electrodes can result in uncomfortable sensations due to undesired stimulation of the superficial nerves. This approach has limited effectiveness for target nerves that are deeply buried under the skin.
By using an injectable liquid polymer that cures – like household epoxy -- next to or around the target nerve, the researchers say the device provides a localized stimulus that avoids the side effects of other types of neuromodulation therapy.
The new liquid polymer electrode named "Injectrode" is made of softer materials than traditional implantable devices, and is mechanically similar to human tissue, allowing it to integrate more easily, all while providing electrical conductivity similar to a metallic wire.
The UW-Madison team, led by Kip Ludwig, a professor of biomedical engineering and neurological surgery, presented their work in Advanced Healthcare Materials, showing that the Injectrode could form flexible structures around a variety of pig nerves and provide an electrical stimulus to a pig's vagus nerve.
The vagus nerve serves as the critical communication link between the brainstem and the rest of the body, particularly organs and tissues. Vagus nerve stimulation therapy has also been used for treating depression and epilepsy. The group reported that their technology had passed several preclinical safety standards recognized by the Food and Drug Administration for this type of device.
"This is an innovative approach to interfacing with the nervous system, and I'm excited to see their HEAL grant push hard towards first-in-human demonstrations," said Wolfson. "Even in the midst of a pandemic, the opioid crisis continues unabated, and this new technology offers hope to individuals suffering from debilitating back pain."
Collaborators at the University of Michigan are developing computational simulations to optimize the delivery of current to a cluster of neurons in the spinal nerve called the dorsal root ganglia. This cluster of nerves is a primary target for neuromodulation therapies Case Western Reserve University collaborators are characterizing and optimizing the mechanical properties of the Injectrode.
Lastly, tying it all together on the Ludwig team is the preclinical work conducted by the University of Pittsburgh researchers who are performing efficacy testing to aid in the translation process of bringing this pain treatment to market.
Neuronoff, Inc. and Ludwig's team will continue to develop the Injectrode with further safety and effectiveness experiments, as well as techniques to reliably administer it and power it with a wireless stimulator.
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