Mats of polymer nanofibers show potential not only for surgery but also as biodegradable, drug-releasing implants or as scaffolds for tissue engineering, says Peter Kofinas, a bioengineer at the University of Maryland, College Park. Current methods for making the mats—such as electrospinning, which involves electric current—would damage living cells if the mats were made in situ. To devise a way to create the mats directly on the tissue, Kofinas and colleagues adapted a commercial airbrush, a tool more commonly used to apply paint.
They tinkered with different formulations of a biodegradable polymer, poly(lactic-co-glycolic acid), or PLGA, to find one that would work in the airbrush. By choosing a particular molecular weight of PLGA and concentration of acetone as the solvent, they could control the diameter of the resulting fibers. They ended up producing mats with fiber diameters of about 370 nm.
The researchers showed that the mats could seal diaphragm hernias and cuts to the lung, intestine, and liver in a pig. The acetone appears to evaporate before the nanofibers get deposited, suggesting that the solvent won’t pose toxicity problems, according to the paper. Cells sprayed with the PLGA nanofibers show no change in health after 24 hours. In lab tests, the nanofiber mats degraded completely over a 42-day period.
“Using an airbrush to deposit biomaterials directly onto tissue is quite enticing and has potential in many areas of medicine,” saysJeffrey M. Karp, a bioengineer and codirector of the Center for Regenerative Therapeutics at Brigham & Women’s Hospital, in Boston. Kofinas’s group is currently doing safety studies and improving the materials for surgical trials in laboratory animals.