Kevlar based artificial cartilage can benefit 850,000 patients in the U.S. who undergo surgeries removing or replacing cartilage in the knee.
Highlights
- The new Kevlar-based hydrogel recreates the magic of cartilage by combining a network of tough nanofibers from Kevlar with commonly used polyvinyl alcohol hydrogel cartilages
- In natural cartilage, the network of proteins and other biomolecules gets its strength by resisting the flow of water among its chambers.Water is released in the process, and the network recovers by absorbing water later.
- The pressure from the water reconfigures the network, enabling it to deform without breaking
- The synthetic cartilage such as that of Kevlar-based hydrogel boasts of the same mechanism, releasing water under stress and later recovering by absorbing water
Many people with joint injuries would benefit from a good replacement for cartilage, such as the 850,000 patients in the U.S. who undergo surgeries removing or replacing cartilage in the knee.
Synthetic cartilages, their properties and why they fail to achieve combination of strength and water content
While other varieties of synthetic cartilage are already undergoing clinical trials, these materials fall into two camps that choose between cartilage attributes, unable to achieve that unlikely combination of strength and water content.
The other synthetic materials that mimic the physical properties of cartilage don’t contain enough water to transport the nutrients that cells need to thrive, Kotov said.
The new Kevlar-based hydrogel recreates the magic of cartilage by combining a network of tough nanofibers from Kevlar, the "aramid" fibers best known for making bulletproof vests with a material commonly used in hydrogel cartilage replacements, called polyvinyl alcohol, or PVA.
This mechanism enables high impact joints, such as knees, to stand up to punishing forces. Running repeatedly pounds the cartilage between the bones, forcing water out and making the cartilage more pliable as a result. Then, when the runner rests, the cartilage absorbs water so that it provides strong resistance to compression again.
The synthetic cartilage boasts the same mechanism, releasing water under stress and later recovering by absorbing water like a sponge. The aramid nanofibers build the framework of the material, while the PVA traps water inside the network when the material is exposed to stretching or compression.
Even versions of the material that was 92 percent water were comparable in strength to cartilage, with the 70-percent version achieving the resilience of rubber.
As the aramid nanofibers and PVA don’t harm adjacent cells, Kotov anticipates that this synthetic cartilage may be a suitable implant for some situations, such as the deeper parts of the knee. He also wonders whether chondrocytes might be able to take up residence inside the synthetic network to produce a hybrid cartilage.
But his potential applications are not limited to cartilage. He suspects that similar networks, with different proportions of aramid nanofibers, PVA, and water, may be able to stand in for other soft tissues.
"We have a lot of membranes in the body that require the same properties. I would like to evaluate the space," Kotov said. "I will talk to doctors about where the acute need is and where this intersection of the properties will allow us to make best headway and biggest impact."
Kotov is a member of the Biointerfaces Institute, which provides shared space for researchers from U-M’s engineering and medical schools. He is also a professor of chemical engineering, materials science and engineering, and macromolecular science and engineering.
The study, recently published in Advanced Materials, is titled "Water-rich biomimetic composites with abiotic self-organizing nanofiber network." It was supported by the National Science Foundation, with additional funding from the Department of Defense. The university is seeking patent protection and partners to bring the technology to market.
Reference
- Lizhi Xu,Xueli Zhao,Chuanlai Xu,Nicholas A. Kotov. Water-Rich Biomimetic Composites with Abiotic Self-Organizing Nanofiber Network, Advanced Materials Journal (2017).DOI: 10.1002/adma.201703343
Source-Eurekalert