Synchron Inc. announced the first successful clinical implantation of the Stentrode®, a minimally-invasive neural interface technology, a component of the Synchron Brain-Computer Interface. This is the first clinical feasibility trial evaluating this technology for its potential to restore communication in people with severe paralysis.

The Stentrode is the only investigational implantable device that does not require open brain surgery and is designed to record brain activity and stream thoughts wirelessly directly from the brain.

The technology relies on a revolutionary brain-controlled handsfree app platform called brainOS to translate the brain activity into a standardized digital language to control apps that restore communication and limb function. In addition, brainPort, a fully-internalized, wireless solution implanted in the chest provides high-resolution neural data transmission and is the final component of the Synchron Brain-Computer Interface.

“The commencement of human trials of a commercial brain-computer interface is a major milestone for the industry. By using veins as a naturally-existing highway into the brain, we have been able to reach the clinical stage significantly earlier than other more invasive approaches,” said Thomas Oxley, MD, Ph.D., CEO of Synchron.

The trial of the Stentrode in combination with brainOS software will evaluate the safety, as well as assess the stability of high-fidelity signals acquired from the brain to control external communications technologies. The trial is being conducted in Melbourne, Australia and will include patients with loss of motor function from paralysis due to a range of conditions including spinal cord injury, stroke, muscular dystrophy, or motor neuron disease (ALS) patients.

Pre-clinical studies have demonstrated the Stentrode’s long-term safety as well its ability to pick up specific electrical frequencies emitted by the brain. Synchron, in collaboration with the University of Melbourne, has published their scientific results in top-ranking journals including Nature Biotechnology, Nature Biomedical Engineering and the Journal of Neurosurgery.

Similar to the procedure utilized for implantation of cardiac pacemakers, implantation of the Stentrode is a minimally-invasive procedure during which the device is delivered to the brain through blood vessels. As the Stentrode system is small and flexible enough to safely pass through curving blood vessels, insertion of the device does not require open brain surgery. This may reduce the risk of brain tissue rejection of the device, which has been a significant problem for other techniques. Other neural interface devices, such as those being developed by Bryan Johnson’s Kernel, Elon Musk’s Neuralink and BrainGate, currently require drilling open the skull and direct puncture into the brain to achieve device implantation.

“By reimagining the concept of the operating system, we have designed our technology platform to enable a completely hands-free user experience. What we learn from the first-in-human clinical trial will be highly valuable in guiding our device design and the clinical protocol for a pivotal trial in the U.S.,” said Oxley.

The Stentrode utilizes brainOS, a modular training software that enables patients to control assistive technologies directly through thought. The brainOS platform is a suite of brain-controlled apps that aims to enable patients to restore lost speech and limb function. While current computer operating systems require pressing or tapping at least one button, typically on a mouse or a keyboard, brainOS offers handsfree control. The platform is designed to re-define the user experience for a large number of people who have trouble using a mouse or keyboards.