From the time Chet Moritz was a young boy, he was drawn to helping people with physical limitations. He attended a school in Seattle, WA, that accommodated children with disabilities.
At first, Dr. Moritz thought he wanted to be a physical therapist. But he got bitten by the research bug as an undergraduate when he began studying how large insects control the muscles used to flap their wings. “Once I got into the lab and started sticking electrodes in the muscles of these tiny insects, I was hooked,” Dr. Moritz says.
Becoming a Lab Rat
Trained as a biologist, Dr. Moritz’s initial interest focused on understanding the engineering aspects of movement control — how the brain and spinal cord coordinate movement over rocky versus slick terrain, for example.
Dr. Moritz and his colleagues started conducting studies on brain computer interfaces (devices), trying to figure out how to extract information from the brain about how animals intended to move. “We came up with this idea that maybe we could record neural messages from intact areas of the brain and reroute the signals below the spinal cord injury to stimulate paralyzed muscles electrically in real time,” Dr. Moritz says.
The approach worked and with that simple detour, scientists were able to hot-wire damaged nerves in animals and restore voluntary movement to paralyzed limbs. The logical next step: building neural prostheses, or neural prosthetic devices for humans with spinal cord injuries (SCIs).
From Bench to Bedside
“But dating back 40 years ago, Dr. Reggie Edgerton, a researcher and neurobiologist at UCLA, showed that if you stimulate the spinal cord below the level of injury, animals with no connection between their brain and their lower body could make stepping movements on a treadmill,” Dr. Moritz says. “That early research is now beginning to bear fruit and there have been tremendous breakthroughs in SCI research over the past 10 to 12 years.”