Making implants safer with a nanoparticle-modified biomedical implant material


Jul 22, 2022

(Nanowerk News) An interdisciplinary team of researchers at the University of Alabama at Birmingham have developed a new plasma-enabled process that could limit the proliferation of toxins from implants into a patient’s bloodstream. The team, led by Vinoy Thomas, Ph.D., associate professor in the UAB School of Engineering’s Department of Mechanical and Materials Engineering, recently published findings in the ACS Applied Materials & Interfaces journal (“Plasma Electroless Reduction: A Green Process for Designing Metallic Nanostructure Interfaces onto Polymeric Surfaces and 3D Scaffolds”). In the article, the authors explain that a major challenge of developing nanoparticle-modified biomedical implant material is to stably attach metallic nanoparticles on different surfaces — particularly polymer surfaces. “For years, scientists have achieved synthesis of metallic nanoparticles in aqueous solutions using both chemical and biological (plant extracts) reducing agents,” Thomas said. “The challenge of attaching metallic nanoparticles is especially difficult in cases involving hydrophobic polymeric biomaterials, which most polymeric biomaterials fall under.” To address this challenge, Thomas and his team developed a plasma-enabled process called plasma electroless reduction. The PER process allows researchers to deposit gold and silver nanostructures on different 2D and 3D polymer material surfaces, such as cellulose paper, polypropylene-based facemasks and 3D printed polymer scaffolds. Design of metal nanoparticle-modified polymer surfaces in a green and scalable way Design of metal nanoparticle-modified polymer surfaces in a green and scalable way. (© American Chemical Society) “It is well known that there are toxicity issues offered by the rapid and premature release of the metallic nanostructures from the implant material into the bloodstream,” Thomas said. “This issue could be addressed only by ensuring the stable anchoring of the metallic nanostructures on implant surfaces. This has inspired us to optimize our PER process by conducting systematic and in-depth investigation of concentration of the metallic precursor followed by sonication wash before cell culture in vitro.” In Thomas’ study, his team was able to successfully anchor silver nanoparticles on the surface of 3D printed polymers without any rapid release into the surroundings. The team’s additive manufacturing expertise also allowed them to design smaller 3D scaffold wafers that will fit into the well of a 96-well plate. “We anticipate that design of such consistent smaller 3D scaffold design would ensure large-scale and more reliable in vitro testing of 3D scaffolds,” Thomas said. “This systematic optimization of making uniform metal nanostructures on 3D scaffolds with cytocompatibility and potential antibacterial properties will be highly relevant and can potentially make an impact on the future development of biocompatible scaffolds, especially for osteomyelitis disease.” It took two years for the team to develop the PER process, but the process is just one of several aspects Thomas is studying with regard to plasma. “Plasma, the fourth state of matter, is a partially ionized gas that represents one of the greener methods of synthesizing metallic nanoparticles in a liquid phase,” he said. “It has enormous capability in materials processing and to decontaminate surfaces for preventing the spread of COVID-19 and other communicable diseases.” Thomas is currently developing a materials engineering course on Plasma Processing of Materials to be offered in fall 2022.



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