A nanotechnology platform developed by KAUST scientists could lead to new treatments for degenerative bone diseases.
The system takes advantage of tiny iron wires that bend in response to magnetic fields. Bone-forming stem cells grown on a mesh of these nanowires get a kind of physical workout on the moving substrate. They then transform into mature bone much faster than is typical of other culturing conditions, with a differentiation protocol that lasts just a few days instead of a few weeks.
“This is a remarkable finding,” says bioscientist, Jasmeen Merzaban. “We can achieve efficient bone cell formation in a shorter amount of time,” potentially paving the way for more efficient regeneration of bone. Merzaban co-led the study together with sensor scientist, Jürgen Kosel, and colleagues from their labs.
The researchers evaluated the bone-producing potential of their nanowire scaffold, both with and without magnetic signals. They patterned the tiny wires — each about the size of the tail-like appendage found on some bacteria — in an evenly spaced grid, and then layered bone marrow–derived human mesenchymal stem cells (MSCs) on top.
Adding a low-frequency magnetic field, the researchers found, dramatically accelerated the process of bone development. Genetic markers of bone development could be detected within two days of incubation under mechanical stimulation, while genes linked to stemness and self-renewal quickly became inactive. Under a microscope, the researchers could also see the cells remodeling themselves to become more bone-like at an accelerated pace.
The KAUST team next plans to test its system in mouse models of degenerative bone disease, with the expectation that stem cell–seeded nanowire scaffolds can be safely implanted at sites of injury and promote tissue repair. An externally applied magnetic field would be used to speed the healing process.
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