A new biomedical device to surgically treat chronic back pain – an artificial spinal disc that duplicates the natural motion of the spine – has been licensed from Brigham Young University to a Utah-based company.
In between the vertebrae of the human spine are 23 Oreo-sized, cartilage-filled discs that hold the vertebrae together and allow for spine movement.
While the discs are critical for movement, they can become the source of back pain when they degenerate or herniate – a significant health problem that affects 85% of Americans and drains the U.S. economy to the tune of $100 billion every year.
A new biomedical device to surgically treat chronic back pain – an artificial spinal disc that duplicates the natural motion of the spine – has been licensed from Brigham Young University to a Utah-based company.
The artificial disc was conceived by engineering professors Anton Bowden, Larry Howell, and BYU alum Peter Halverson. It will be developed for the market by Crocker Spinal Technologies, a company founded by BYU President’s Leadership Council member Gary Crocker and headed by BYU MBA graduate David Hawkes.
The BYU researchers report on the mechanism’s ability to facilitate natural spine movement in a study published in a forthcoming International Journal of Spine Surgery issue.
“Low back pain has been described as the most severe pain you can experience that won’t kill you,” said Bowden, a BYU biomechanics and spine expert. “This device has the potential to alleviate that pain and restore the natural motion of the spine – something current procedures can’t replicate.”
Currently, the most common surgical treatment for chronic low back pain is spinal fusion surgery. Fusion replaces the degenerative disc with a bone to fuse the adjacent segments to prevent motion-generated pain.
Unfortunately, patient satisfaction with fusion surgery is less than 50 per cent.
The solution researched by the BYU team and now being developed by Crocker Spinal Technologies consists of a compliant mechanism that facilitates natural spine movement and is aimed at restoring the function of a healthy spinal disc.
Compliant mechanisms are jointless, elastic structures that use flexibility to create movement. Examples include tweezers, fingernail clippers or a bow-and-arrow. Howell is a leading expert in compliant mechanism research.
“To mimic the spine's response is very difficult because of the constrained space and the sophistication of the spine and its parts,” Howell said. “A compliant mechanism is more human-like, more natural, and the one we’ve created behaves like a healthy disc.”
Under Howell’s and Bowden’s tutelage, BYU student engineers built prototypes, machine-tested the disc, and then the device in cadaveric spines. The test results show the artificial replacement disc behaves similarly to a healthy human disc.
“Putting it in a cadaver and having it do what we engineered it was gratifying,” Howell said. “It has a lot of promise for eventually making a difference in many people’s lives.”
Halverson, lead author of the International Journal of Spine Surgery study, earned his PhD from BYU and took a position at Crocker Spinal Technologies, which will likely begin international sales distribution as early as next year.
“Fusion, which is the current standard of care for back pain, leaves much to be desired,” said President Hawkes of Crocker Spinal Technologies. “Disc replacement is an emerging alternative to fusion that has the potential to make a significant difference in the lives of millions.
“BYU’s innovation is a radical step forward in advancing disc replacement technology. It is exciting to be a part of this effort and a delight to work with such talented, wonderful people,” he said.
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Courtesy BrighamYoung University
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