Hydrogel Shows Promise as Treatment for Arthritic Joints

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By Pat Anson, PNN Editor

An experimental hydrogel that helps regenerate bone and cartilage tissue is showing promise as a treatment for arthritic joints, according to new research by Chinese and Canadian scientists. The gel is biodegradable and mimics the articular cartilage found in knee and hip joints.

In tests on laboratory animals, researchers say the gel showed signs of repairing articular cartilage 12 weeks after being implanted in rabbits, with no gel remaining and no rejection by the animals’ immune systems, according to findings published in the journal Nature.

Further animal testing is needed, but if the hydrogel proves useful in human trials, it could be used someday as an alternative to knee and hip replacement surgery. About one in four adults in the United States have some form of arthritis, which causes thinning of cartilage and progressive joint damage. Many resort to risky joint repair and replacement procedures.

“Cartilage is tricky,” says senior author Dr. Hongbin Li, a professor in the University of British Columbia’s department of chemistry. “Articular cartilage repair represents an important medical challenge because naturally speaking, it doesn’t repair itself.”

A delicate balance is needed to make biodegradable cartilage implants tough and stiff enough to support muscle-bearing tissues. They can’t be too stiff, or they’ll break when bent too far. Conversely, if they are too soft, they may not be useful in a joint.

In animal studies, researchers say a stiffer version of the gel had better results than a softer version, because it formed a scaffold that was more compatible with bone and cartilage tissue. That provided a physical cue to the body for tissue regeneration.

Dr. Linglan Fu holding the hydrogel

“This just shows how complex this area of research is, and the need to take into account the many different physical and biochemical cues and factors when designing these scaffolds,” says co-author Dr. Qing Jiang, a professor and surgeon at Nanjing University.

The research team used a new approach to stiffen biomaterials in the gel without sacrificing toughness, by physically entangling the chains of a protein.

“These entangled chains can move, which allows energy, for instance, the impact from jumping, to be dissipated, just like shock absorbers in bikes. In addition, we combined this with an existing method of folding and unfolding proteins, which also allows for energy dissipation,” says first author Dr. Linglan Fu, who conducted the research as a doctoral student at UBC’s department of chemistry.

The resulting gel is tough, able to resist slicing with a scalpel, and is more stiff than other protein-based hydrogels. Its ability to resist compression was among the highest achieved by any such gel, according to researchers, who say it compared favorably with actual articular cartilage. The gel was also able to rapidly recover its original shape after compression, as real cartilage does.

Researchers at Duke University are also working on an experimental hydrogel to replace damaged knee cartilage. The gel is made with thin sheets of cellulose fibers infused with a water absorbing polymer, creating a Jello-like material that is surprisingly strong. The cellulose fibers act like the collagen in natural cartilage, giving the gel strength when pulled or stretched.  

Experimental Gel Could Replace Damaged Knee Cartilage

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By Pat Anson, PNN Editor

Clinical trials on humans may begin as soon as next year on an experimental hydrogel designed to replace damaged cartilage in arthritic knees, according to researchers at Duke University, who say the gel is up to three times stronger than natural cartilage.   

Implants made of the material are currently being tested on sheep by Sparta Biomedical, a medical device company that is developing a line of synthetic cartilage.

“If everything goes according to plan, the clinical trial should start as soon as April 2023,”  Benjamin Wiley, PhD, Sparta’s chief technology officer and a Duke chemistry professor, said in a press release. “I think this will be a dramatic change in treatment for people.”

Wiley says hydrogel implants could someday be used as an alternative to total knee replacement surgery, one of the fastest growing elective procedures in the United States. About one in six adults suffer from knee osteoarthritis, a painful disorder that leads to thinning of cartilage and progressive joint damage.

Often considered the treatment of last resort, knee replacement surgery can be problematic. Studies have found that about a third of the patients who have their knees replaced continue to experience chronic pain. The artificial joints also have a limited life span and sometimes need to be replaced after a few years.   

“There's just not very good options out there,” said Wiley.

To make the hydrogel, Wiley and his team took thin sheets of cellulose fibers and infused them with a water absorbing polymer, creating a Jello-like material that is surprisingly strong. The cellulose fibers act like the collagen in natural cartilage, giving the gel strength when pulled or stretched.

Natural cartilage can withstand up to 8,500 pounds per inch of tugging and squishing before reaching a breaking point. The hydrogel can handle even more pressure and is 66% stronger than cartilage when compressed, the equivalent of parking a car on a postage stamp.

“It’s really off the charts in terms of hydrogel strength,” Wiley says.

Duke researchers first reported in 2020 that they had developed a hydrogel strong enough for knees, but using it to replace cartilage presented some design challenges. Hydrogels are difficult to attach directly to bone or cartilage to keep them from breaking loose or sliding off during intense activities.

They got around that problem by cementing and clamping the hydrogel to a titanium base, which is then anchored into a small hole where the damaged cartilage used to be. Tests showed the design stays fastened 68% more firmly than natural cartilage on bone.

In wear tests, the researchers took the hydrogel and natural cartilage and spun them against each other a million times, with a pressure similar to what the knee experiences during walking. Using high-resolution X-ray imaging, they found that the artificial cartilage held up three times better than the real thing.

DUKE UNIVERSITY IMAGE

And because the hydrogel mimics the smooth and cushiony nature of real cartilage, it protects other joint surfaces from being damaged as they slide against the implant. Other researchers have tried replacing cartilage with implants made of metal or polyethylene, but because those materials are stiffer than cartilage, they can chafe against other parts of the knee.

The research study, published in the journal Advanced Functional Materials, was funded by Sparta Biomedical and Duke University.

An experimental gel also shows promise as a treatment for low back pain caused by degenerative disc disease, according to a recent small study. Hydrafil – an injectable gel developed by ReGelTec – fills in cracks and tears in damaged discs, restoring the disc’s structural integrity. The injection procedure is minimally invasive and only takes about 30 minutes.

Injectable Gel Shows Promise as Treatment for Back Pain

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By Pat Anson, PNN Editor

An experimental gel shows promise as a treatment for low back pain caused by degenerative disc disease (DDD), according to the results of a small study being presented at the annual meeting of the Society of Interventional Radiology in Boston.

Hydrogels have been used for years to treat DDD, but this is the first time that Hydrafil – an injectable gel developed by ReGelTec – has been tested on humans.

Hydrafil was injected into the discs of 20 people in Colombia with chronic DDD, who had average pain levels of 7.1 on a 10-point pain scale. None of the participants had found more than temporary, mild relief from treatments such as rest, analgesics, physical therapy and back braces.

“We really have no good treatments for degenerative disc disease, aside from conservative care,” said lead investigator Douglas Beall, MD, a medical advisor to ReGelTec and chief of radiology services at Clinical Radiology of Oklahoma.

“Surgery is statistically no more effective than conservative care and can potentially make things worse; nerve ablation is appropriate for only a few patients; and existing hydrogels are inserted through an incision as a soft solid, which can pop out of place if you’re not highly skilled in placing it.”

Because Hydrafil is injectable, it requires no incision and is minimally invasive, although patients are sedated for the procedure. Researchers heat the gel to become a thick liquid and then use a 17-gauge needle to inject it directly into the affected discs, using fluoroscopic imaging to guide them. The gel fills in cracks and tears in the disc, and then hardens, restoring the disc’s structural integrity. The procedure takes about 30 minutes.

This promotional video by ReGelTec demonstrates how Hydrafil works:

Six months after the injection, all 20 participants in the study reported significantly less low back pain, with their pain levels declining to an average of 2.0 on the 10-point pain scale. They also reported significantly better physical function.

“If these findings are confirmed in further research, this procedure may be a very promising treatment for chronic low back pain in those who’ve found insufficient relief from conservative care,” said Beall. “The gel is easy to administer, requires no open surgery, and is an easy procedure for the patient.”

In 2020, Hydrafil received the FDA’s breakthrough device designation, which allows for an expedited review of an experimental product when there is evidence it provides more effective treatment than current options.

ReGelTec is currently recruiting 50 people with DDD in Canada for a new clinical trial of Hydrafil.

Degenerative disc disease is one of the leading causes of chronic low back pain. Healthy discs cushion the spine’s vertebrae, facilitating movement and flexibility. But with activity and normal aging, discs can wear out and cause the bones of the spine to rub together and pinch nerves, causing pain and numbness. By age 60, most people have at least some disc degeneration in their spines.