Campus News

Published by Communications and Public Affairs 519 824-4120, Ext. 56982 or 53338

News Release

January 25, 2007

Stem Cells May Help Heal Joint Injuries, Say Researchers

As anyone who’s ever injured a knee or elbow will tell you, recovery can be a long and painful process. Cartilage is an exceptionally slow-healing tissue, and, until now, the missing or damaged tissue is often irreplaceable. Researchers at the University of Guelph are hoping stem cells might provide the needed tissue replacements.

Biomedical sciences professor Dean Betts and doctoral candidate Thomas Koch are hoping to use stem cells to improve cartilage healing after joint injuries. They’re working with horses, where joint injuries are both common and costly, and say the research could be a model for helping human joint injuries.

“Equine joints are similar to human joints in aspects such as joint thickness and spontaneous athletic injuries, so the research may be transferable,” said Koch.

Much of the team’s research focuses on perfecting the technique for isolating, expanding and differentiating adult stem cells. They’re using blood from the umbilical cord of horses as a source of stem cells. Because most horses are observed when foaling, it’s relatively easy to collect the cord blood at that time.

Obtaining cord blood samples is non-invasive and much easier than obtaining stem cells from an embryo. Koch said there’s evidence that stem cells from cord blood are “younger” than bone marrow stem cells, which means they’re capable of more divisions, and creating more diverse tissue types. The younger stem cells may also be less prone to rejection when used to help heal cartilage in another body.

Because there are no other reports on isolating stem cells from equine cord blood, Betts and Koch are eager to gather as much information as possible. Already, they’ve succeeded in differentiating the cord blood stem cells into three different cell types including chondrocytes – the building blocks of cartilage.

Betts said the three-dimensional structure of cartilage and its attachment to the underlying bone is difficult to reproduce. Despite this, there have been encouraging results using osteochondral grafts – pieces of bone and cartilage grafted to the site of the injury. He hopes further research will reveal more ways to reconstruct the tissue either at the injury site, or as a graft that can be surgically implanted.

Prof. Dean Betts
Department of Biomedical Sciences
(519) 824-4120, Ext. 54480

For media questions, contact Communications and Public Affairs: Lori Bona Hunt (519) 824-4120, Ext. 53338, or Rachelle Cooper, (519) 824-4120, Ext. 56982.

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