posted on 2017-07-21, 00:00authored byWenhao Zhou, Zhaojun Jia, Pan Xiong, Jianglong Yan, Yangyang Li, Ming Li, Yan Cheng, Yufeng Zheng
With
the progressively increasing demand for orthopedic Ti implants,
the balance between two primary complications restricting implant
applications is needed to be solved: the lack of bone tissue integration
and biomedical device-associated infections (BAI), where emergence
of multiresistance bacteria make it worse. Notably, a combination
of silver nanoparticles (AgNPs) and a kind of antibiotic can synergistically
inhibit bacterial growth, where a low concentration of AgNPs has been
confirmed to promote the proliferation and osteogenesis of osteoblasts.
In this work, we built AgNPs/gentamicin (Gen)-embedded silk fibroin
(SF)-based biomimetic coatings on orthopedic titanium by a facile
dipping–drying circular process and with the assistance of
polydopamine (PD). Ag+ was reduced to AgNPs by SF under
ultraviolet (UV) irradiation, and then they were detected by transmission
electron microscope (TEM) images and UV–visible (UV–vis)
analyses. Intriguingly, the addition of Gen highly improved the reduction
efficiency of Ag+. The antibacterial efficiency of SF-based
coatings was examined by challenging them with pathogenic Staphylococcus aureus (S. aureus) bacteria
which produced biofilms, and consequently, we found that low concentration
loading, durable release of Ag+ (28 days), and 10-fold
improvement of antibacterial efficiency were achieved for our novel
AgNPs- and Gen-embeded silk fibroin coatings. In bacteria and a cells
cocultured system, AgNPs/Gen-embedded coatings strongly inhibited
adhesion and proliferation of S. aureus, simultaneously
improving cell adhesion and growth. To investigate cytocompatibility
and osteogenic potential, different coatings were cultured with MC3T3
cells; AgNPs/Gen-embedded coatings showed generally acceptable biocompatibility
(cell adhesion, proliferation, and viability) and accelerated osteoblast
maturation (alkaline phosphatase production, matrix secretion, and
calcification). Expectantly, this novel biofunctional coating will
have promising applications in orthopedic and dental titanium implants
thanks to its excellently antibacterial, biocompatible, and osteogenic
activities.