Abstract
Silk sericin has great potential as a biomaterial for biomedical applications due to its good hydrophilicity, reactivity, and biodegradability. To develop multifunctional sericin materials for potential antibacterial application, a one-step synthesis method for preparing silver nanoparticles (AgNPs) modified on polydopamine-coated sericin/polyvinyl alcohol (PVA) composite films was developed. Polydopamine (PDA) acted as both metal ion chelating and reducing agent to synthesize AgNPs in situ on the sericin/PVA composite film. Scanning electron microscopy and energy dispersive spectroscopy analysis revealed that polydopamine could effectively facilitate the high-density growth of AgNPs as a 3-D matrix. X-ray diffractometry studies suggested the synthesized AgNPs formed good face-centered cubic crystalline structures. Contact angle measurement and mechanical test indicated AgNPs modified PDA-sericin/PVA composite film had good hydrophilicity and mechanical property. The bacterial growth curve and inhibition zone assays showed the AgNPs modified PDA-sericin/PVA composite film had long-term antibacterial activities. This work develops a new method for the preparation of AgNPs modified PDA-sericin/PVA film with good hydrophilicity, mechanical performance and antibacterial activities for the potential antimicrobial application in biomedicine.
Highlights
Silk sericin (SS) is a natural macromolecular protein from silkworm cocoon, which makes up25% of the total silk protein [1]
The results suggested that the synthesized AgNPs formed good crystalline structures
The results suggested that AgNPs-modified PDA-SS/polyvinyl alcohol (PVA) film had PDA-sericin/polyvinyl alcohol film (SS/PVA)
Summary
Silk sericin (SS) is a natural macromolecular protein from silkworm cocoon, which makes up. Since dopamine has metal ion chelating ability and redox activity [43,44], it could directly reduce the adsorbed Ag+ on the dopamine-coated material surface to form AgNPs via a one-step reaction [45,46] These properties may facilitate the use of PDA as a 3D matrix to enhance the adsorption of Ag+ and promote the high-density growth of AgNPs. In addition, the presence of PDA could avoid direct exposure of AgNPs to oxygen and slow down the release of silver ions.
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