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Article Abstract
Surface modification of polymer materials is crucial in the biomedical field, as it can endow materials with new properties, including high efficacy and durability and a low risk of infection. Here, we propose a simple, green, and reliable surface modification strategy using ovalbumin (OVA) and tannic acid (TA). The hydrogen bonds and hydrophobic interactions revealed between the OVA and TA molecules make the OVA/TA composite tenacious and stable. The subsequent OVA/TA coatings adhered firmly on five hydrophobic polymer materials using a two-step impregnation method and were highly hydrophilic and repellent to bacterial adhesion. Taking advantage of the reducing ability of OVA and TA, silver ions were reduced to form OVA/TA-AgNPs coatings, which could inhibit a broad spectrum of bacteria, especially some drug-resistant strains. In addition, both the OVA/TA and OVA/TA-AgNPs coatings exhibit good biocompatibility. This simple, reliable, stable, and biobased coating strategy holds great promise for enhancing the versatility of biomaterial surface modification.
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| http://dx.doi.org/10.1021/acsami.4c21624 | DOI Listing |
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