In what could be a breakthrough for technical textiles, bioengineers have determined textile manufacturing processes ideal for engineering tissues needed for organ and tissue repair, the University of Missouri has said in a press release.
Tissue engineering is a process that uses novel biomaterials seeded with stem cells to grow and replace missing tissues. When certain types of materials are used, the “scaffolds” that are created to hold stem cells eventually degrade, leaving natural tissue in its place. The challenge is creating enough of the material on a scale that clinicians need to treat patients. Elizabeth Loboa, dean of the University's College of Engineering, and her team recently tested new methods to make the process of tissue engineering more cost effective and producible in larger quantities. Tissues could help patients suffering from wounds caused by diabetes and circulation disorders, patients in need of cartilage or bone repair and to women who have had mastectomies by replacing their breast tissue.In what could be a breakthrough for technical textiles, bioengineers have determined textile manufacturing processes ideal for engineering tissues#
In typical tissue engineering approaches that use fibres as scaffolds, nonwoven materials are often bonded together using an electrostatic field. This process, called electrospinning, creates the scaffolds needed to attach to stem cells; however, large-scale production is not cost-effective.
“Electrospinning produces weak fibers, scaffolds that are not consistent and have pores that are too small,” Loboa said. “We can run our system for hours and create about a ten-inch diameter of scaffold material. Therefore, we sought to test methods that could standardize the process. The goal of 'scaling up' is to produce hundreds of meters of material that look the same, have the same properties and can be used in clinical settings. So, we investigated the processes that create textiles, such as clothing and window furnishings like drapery, to scale up the manufacturing process.”
Loboa worked with Stephen A. Tuin, a recent doctoral graduate from her research group at the Joint Department of Biomedical Engineering at the University of North Carolina and N.C. State University (NCSU), and Behnam Pourdeyhimi of the NCSU College of Textiles. The group published a pair of papers using three common textile creation methods — meltblowing, spunbonding and carding — to determine if these methods would create the materials needed to mimic native tissue.
Meltblowing is a technique during which nonwoven materials are created using a molten polymer to create continuous fibers. Spunbond materials are made much the same way but the fibers are drawn into a web while in a solid state instead of a molten one. Carding involves the separation of fibers through the use of rollers, forming the web needed to hold stem cells in place.