Abstract
Problems
Biofilm infections are increasingly associated with orthopedic implants. Bacteria form biofilms on the surfaces of orthopedic devices. The biofilm is considered to be a common cause of persistent infections at a surgical site. The growth and the maturation of biofilm are enhanced by the flow of broth in culture environment. In order to reduce the incidence of implant-associated infections, we developed a novel coating technology of hydroxyapatite (HA) containing silver (Ag). We previously reported that the Ag-HA coating inhibits biofilm formation under flow condition of Trypto Soy Broth + 0.25% glucose for 7 days. In this study, we evaluated whether the Ag-HA coating continuously inhibits the biofilm formation on its surface under flow condition of fetal bovine serum, which contains many in vivo substrates such as proteins.
Materials and Method
The commercial pure titanium disks were used as substrates. Ag-HA or HA powder was sprayed onto the substrates using a flame spraying system. The HA coating disks were used as negative control. The biofilm-forming methicillin resistant Staphylococcus aureus (BF-MRSA; UOEH6) strain was used. The bacterial suspension (about 105 colony forming units) was inoculated into 24-well sterile polystyrene tissue culture plates. The Ag-HA and HA coating disks were aseptically placed in the wells. After cultivation at 37°C for 1 hour, the disks were rinsed twice with 500 μL sterile PBS (−) to eliminate the non-adherent bacteria. After rinsing, the disks were transferred into petri-dish containing heat-inactivated FBS with a stirring bar on the magnetic stirrer and they were cultured at 37 °C for 24 hours, 7 and 14 days. In the meantime, the stirring bar was spun at 60 rounds per minute. Then, the disks were immersed in a fluorescent reagent to stain the biofilm. Finally, the biofilm on each disk was observed by a fluorescence microscope and the biofilm-covered rate (BCR) on the surfaces of them was calculated using the NIH image software.
Results
Biofilm was hardly observed on the Ag-HA coating. However, the biofilm on the HA coating was extensive and mature (Fig. 1). At 24h after cultivation, BCRs of BF-MRSA were 2.1% and 19.8% on the Ag-HA and HA coatings, respectively. Similarly, they were 6.3% and 12.4% on the Ag-HA and HA coatings at 7 days. At 14 days they were 20.6% and 39.4% on the Ag-HA and HA coatings, respectively. These results demonstrate that BCRs on the Ag-HA coating were significantly lower than those on the HA coating (Fig. 2).
Discussion
The Ag-HA coating continuously showed the inhibiting ability for biofilm formation under flow condition for 14 days. Ag ions inhibited the biofilm formation on the Ag-HA coating by killing adherent bacteria in the vicinity of the surface, although the release rate of Ag ions was high until 24h after immersion and decreased thereafter. The Ag-HA coating would be expected to contribute to reduction of implant-related biofilm infection.
