Nanotechnology may help end cartilage lossJune 4th, 2008 - 1:03 pm ICT by ANI
Washington, June 4 (ANI): For a long time, scientists have been trying to find a long-term aid those who suffer cartilage damage and loss. And now, it looks like Brown University researchers are close to finding it through nanotechnology.
Brown University nanotechnology specialist Thomas Webster has found a way to regenerate cartilage naturally by creating a synthetic surface that attracts cartilage-forming cells.
These cells are then coaxed to multiply through electrical pulses.
Cartilage regeneration is a big problem, said Webster, an associate professor in the Division of Engineering and the Department of Orthopaedics at Brown.
You dont feel pain until significant cartilage damage has occurred and its bone rubbing on bone. Thats why research into how to regenerate cartilage is so important, he added.
Websters work involves carbon nanotubes, which are molecular-scale tubes of graphitic carbon that are among the stiffest and strongest fibers known and are great conductors of electrons.
Webster and his team, including Brown researcher Dongwoo Khang and Grace Park from Purdue University, found that the tubes, due to their unique surface properties, work well for stimulating cartilage-forming cells, known scientifically as chondrocytes.
The nanotubes surface is rough; viewed under a microscope, it looks like a bumpy landscape. Yet that uneven surface closely resembles the contours of natural tissue, so cartilage cells see it as a natural environment to colonize.
Were tricking the body, so to speak. It all goes back to the fact that the nanotubes are mimicking the natural roughness of tissues in the first place, Webster said.
The study is published in the current issue of the Journal of Biomedical Materials Research, Part A. (ANI)
Tags: biomedical materials research, brown university researchers, carbon nanotubes, cartilage cells, cartilage damage, cartilage regeneration, conductors, contours, electrons, grace park, khang, natural environment, natural tissue, orthopaedics, purdue university, surface properties, synthetic surface, thomas webster, time scientists, uneven surface