Abstract
Aim
The utilization of silver as an anti-infective agent is a subject of debate within the scientific community, with recurring discussions surrounding its biocompatibility. Presently, galvanic silver coating finds widespread clinical application in mitigating infection risks associated with large joint arthroplasties. While some instances have linked this coating to sporadic cases of localized argyria, these occurrences have not exhibited systematic or functional limitations. To address concerns regarding biocompatibility, a novel approach has been devised for anti-infective implant coatings: encapsulating silver nitrate within a biopolymer reservoir for non-articulating surfaces. This poly-L-lactic acid layer releases silver ions gradually, thereby circumventing biocompatibility concerns.
Method
Female C57BL/6 mice were utilized as an experimental model, with 6x2 mm Ti6Al4V discs, coated with or without the biopolymer-protected silver coating, implanted subcutaneously on both sides of the vertebrae. Daily blood samples were collected, and serum was analyzed for C-reactive protein (CRP) and silver concentration. After three days, histopathological analyses were conducted on the surrounding soft tissue pouch.
Results
Maximum CRP levels in the silver group (4.80 mg/L; Median: 3.29 mg/L; IQR: 2.38 to 3.73) did not significantly differ from the control group (4.58 mg/L; Median: 2.93 mg/L; IQR: 1.91 to 3.78) over the study period. Silver levels in serum 24 hours post-implantation were 64 µg/L (IQR: 35 to 78) and decreased subsequently over three days to 23 µg/L (IQR: 13 to 28). Histopathological examinations revealed a similarly strong expression of inflammation signs in tissue samples from the two groups.
Conclusions
Despite evidence of local inflammation indicated by CRP and histopathological analysis, no significant difference was observed between the coated and uncoated groups. This suggests that any inflammation may be attributed to the implantation procedure rather than silver influence. Furthermore, silver levels remained below the toxic limit, indicating the efficacy of the biopolymer-protected reservoir in aiding biocompatibility. This study underlines the potential of biopolymer-protected silver reservoirs in enhancing the safety profile of anti-infective silver implant coatings, warranting further investigation into their clinical application.
