Creating miracles with polymeric fibers

“Polymers are very, very useful materials when it comes to modern applications.”

For applications ranging from scaffolding for tissue engineering and drug delivery to bacterial and viral air filtration, polymeric fibers can be woven into textilelike structures with the characteristics required for the task. Depending on the use, different fiber thicknesses may be necessary. But the ability to fabricate thin fibers with consistent characteristics is important.

“When you have thinner fibers, you use lesser material, and you can weave a web — whether it’s a tissue engineering scaffold or a filtration scaffold — much better,” said Edirisinghe. “You can put more fiber strands in what you weave.”

To study the effects of various parameters on fiber fabrication, the researchers compared the characteristics of fibers created in different ways. The conventional way of making fibers is by a process called centrifugal spinning. In centrifugal spinning, the polymer solution is placed in a reservoir. When the reservoir is rotated at high speeds, the polymer solution jets out in the form of fine fibers.

Edirisinghe and his team compared this to a method they invented and developed called pressure gyration. It functions broadly the same as centrifugal spinning, but with one key difference. High-pressure gas is applied inside the rotating vessel during the fabrication process.

They found increasing the rotational speed in both techniques and increasing the applied pressure in the pressure gyration technique both lead to thinner, more consistent fibers.

“The pressure makes a hell of a lot of difference,” Edirisinghe said.

For industrial applications, polymeric fibers need to be fabricated in larger quantities and in a way that ensures uniformity from pot to pot. To address these concerns, the researchers were also interested in seeing how the polymer was behaving inside the vessel while the fibers were being fabricated. For the first time, they fabricated the fibers in a transparent pot and used a high-speed camera to capture images during the process. They also compared the behavior to theoretical predictions.

In the future, the group plans to automate the fabrication process to make these nanofibers with optimal thickness and minimal waste. In addition, they are working on finding ways to make the material stronger and more suitable for biomedical applications by making fibers with a different interior and a bioactive exterior.

“If you take this technology to textiles where you can coat the fiber with some other smart sensing material, you can do miracles with them,” Edirisinghe said. “There are lots of possibilities!”

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