AI Article Synopsis
- Conventional gas plasma treatments are useful for functionalizing materials in biomedicine, but they face limitations like needing vacuum conditions and being unsuitable for aqueous environments and complex shapes.
- The study proposes using plasma polymer nanoparticles (PPN) as a new functionalization tool, which are compatible with aqueous systems and can easily modify complex geometries.
- The results show that PPN, especially those loaded with RGD, significantly improve cell attachment and spreading on various substrates, making this method a promising advancement for biomedical applications.
Article Abstract
Conventional gas plasma treatments are crucial for functionalizing materials in biomedical applications, but have limitations hindering their broader use. These methods require exposure to reactive media under vacuum conditions, rendering them unsuitable for substrates that demand aqueous environments, such as proteins and hydrogels. In addition, complex geometries are difficult to treat, necessitating extensive customization for each material and shape. To address these constraints, an innovative approach employing plasma polymer nanoparticles (PPN) as a versatile functionalization tool is proposed. PPN share similarities with traditional plasma polymer coatings (PPC) but offer unique advantages: compatibility with aqueous systems, the ability to modify complex geometries, and availability as off-the-shelf products. Robust immobilization of PPN on various substrates, including synthetic polymers, proteins, and complex hydrogel structures is demonstrated in this study. This results in substantial improvements in surface hydrophilicity. Materials functionalization with arginylglycylaspartic acid (RGD)-loaded PPN significantly enhances cell attachment, spreading, and substrate coverage on inert scaffolds compared to passive RGD coatings. Improved adhesion to complex geometries and subsequent differentiation following growth factor exposure is also demonstrated. This research introduces a novel substrate functionalization approach that mimics the outcomes of plasma coating technology but vastly expands its applicability, promising advancements in biomedical materials and devices.
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| http://dx.doi.org/10.1002/adma.202311313 | DOI Listing |
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