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Biomedical engineers at Hopkins have caused stem cells from adult goats to grow into tissue that resembles cartilage, a key step toward creating a minimally invasive procedure that may one day be used to repair injured knees, noses and other body parts.
In this method, doctors inject a fluid filled with stem cells and nutrients into damaged tissue, then use light to harden the liquid into a stable gel. The researchers believe stem cells within the gel will multiply and form new bone or cartilage to replace the injured tissue.
Paving the way for this technique, the researchers have conducted lab experiments that turned stem cells within a gel into cartilage-like tissue. The team expects to begin testing the process on mice this fall, says Jennifer Elisseeff, Ph.D., an associate professor of biomedical engineering Elisseeff is leading a multi-disciplinary tissue engineering team that includes a plastic surgeon, an orthopedic surgeon, a polymer chemist and graduate students, all affiliated with the Whitaker Biomedical Engineering Institute at Johns Hopkins.
The team’s goal is to develop a new way to deliver and control the behavior of adult stem cells to restore bone and cartilage that has been damaged by disease or injury or is impaired by a genetic defect. Restoration of cartilage – the tough but elastic tissue in noses, ears and joints – would be particularly helpful because, unlike skin, cartilage does not naturally regenerate. Routine use of this procedure in humans may be many years away, Elisseeff says, but the potential benefits could be significant. For one thing, if the lab results can be replicated in humans, patients would end up with living tissue rather than metal or plastic replacement parts. “If this technique ultimately works the way we believe it will, doctors will have a new and possibly more effective option for treating severe joint injuries,” Elisseeff says. “This procedure would also help people avoid invasive surgery.”
Like many new research projects, this work uses stem cells because they have the ability to renew themselves and also to develop into many types of tissue. Elisseeff’s lab is using adult multipotent cells, meaning they can be stimulated to produce different types of musculoskeletal tissue. Ethical debates surrounding stem cell research have focused on material removed from human embryos and fetuses, not the adult cells used in Elisseeff’s experiments. Adult cells offer another advantage: In theory, patients preparing for cartilage or bone repairs will be able to donate their own stem cells prior to the procedure, reducing the likelihood of infection and tissue rejection.
MIT’s Technology Review magazine has recognized Elisseeff as one of the World's Top 100 Young Innovators in technology and business. Her current project, funded by the Arthritis Foundation, builds on work she began as a graduate student in the Harvard University-MIT Division of Health Sciences and Technology. Elisseeff was lead researcher in developing a polymer fluid–laced with cartilage cells called chondrocytes – that can be injected under the skin. The liquid is then hardened by shining an ultraviolet light or visible laser through the skin. The solid material, called a hydrogel, forms a scaffold or framework upon which cells can reproduce and form new tissue.
“Photopolymerizing hydrogels are very useful because they only harden when light is applied,” Elisseeff says. “Also, primary chondrocytes – cartilage cells – can be encapsulated in these hydrogels and will form cartilage-like tissue. The cells thrive because hydrogels contain plenty of water, which is needed to carry nutrients to these cells and move waste products away from them. The hydrogels also have enough space to allow the new tissue to form.”
Now, at Hopkins, Elisseeff and her colleagues are placing stem cells in her hydrogels and coaxing them to produce cartilage and an early form of bone within the polymer framework. Christopher Williams, a plastic surgery fellow in the lab, has conducted experiments with stem cells derived from the bone marrow of adult goats. By surrounding these cells with a specific growth factor that helps direct cellular differentiation, Williams has prodded the stem cells into forming what lab tests indicate are osteoblasts (cells that develop into bone) or chondrocytes. The cartilage samples show the proper gene expression and a cartilage-specific extracellular matrix. Lab tests show that the bone precursor cells are producing calcium, a first step toward osteogenesis, the formation of bone.
“This means that in the lab we’ve already used adult stem cells to create tissue resembling cartilage by composition and morphology in the photopolymerizing hydrogel, and early tests indicate this technique may work with bones, too,” Elisseeff says. “Other researchers have formed cartilage and bone from stem cells in the laboratory. But by applying this to the injectable hydrogel, we think we’ve come up with a clinically practical way to deliver the cells to the site of an injury, where they can grow to replace injured bone or cartilage. Some difficulties still exist in smoothly joining new cells to the recipient’s own tissue, but we’re working on these problems.”
Elisseeff’s team is now fine-tuning the technique. The researchers are synthesizing a new hydrogel that should degrade harmlessly in the body after the new tissue develops. Also, the team is refining its cell growth methods to more closely mimic the normal development of cartilage and bone cells.