Polypropylene (PPE) synthetic mesh is increasingly used in knee arthroplasty surgery to salvage a disrupted extensor mechanism. Despite its clinical success, it is associated with a high rate of periprosthetic joint infection (PJI), which is hypothesized to be caused by bacterial biofilm. The purpose of the current study is to describe the progression of PPE-based biofilm formation over time and to determine if intraoperative antiseptic solutions could be used to effectively remove biofilm when treating PJI. Commercially available knotted monofilament PPE mesh1 was cut into 10mm circular shape, immersed in tryptic soy broth (TSB) with methicillin-sensitive staphylococcus aureus and cultured individually in 48-well plates for 10 days to elucidate the biofilm grown on mesh over time. At every 24 hours, a triplicate of samples was retrieved and biofilm on the mesh was dislodged by sonicating at 52 kHz for 15 minutes and quantified by counting colony-forming units (CFUs) after overnight growth. The biofilm growth was also verified using scanning electron microscopy. The effect of saline and antiseptic solutions was verified by exposing 1) 0.05% chlorohexidine gluconate2, 2) acetic acid-based mixture3, 3) diluted povidone-iodine (0.35%), 4) undiluted povidone-iodine (10%)4, and 5) 1:1 combination of 10% povidone-iodine & 3% hydrogen peroxide on immature and mature biofilms for 3 minutes, created by culturing with bacteria for 24 hours and 72 hours respectively. All experiments were performed in quintuples and repeated. Antiseptic treatments that produced a three-log reduction in CFU counts compared to controls were considered clinically significant.Aim
Method
To test the hypothesis that: CERAMENT[™]|G (C-G) would improve new bone growth and decrease infection rate after debridement as compared with 1) CERAMENT|BONE VOID FILLER (CBVF) and 2) no void filler in a rat osteomyelitis model. 72 Sprague Dawley rats were injected with 1.5 × 10∧6 CFU of S. aureus into a drill hole in the right tibia. After 3 weeks, the osteomyelitic defect was debrided, and filled with either: 1) C-G (n=32), 2) CBVF (n=20), or 3) nothing (n=20). 6 weeks after the second surgery, 20 rats from each group were sacrificed and the right tibias were harvested. A long-term group (n=12) of C-G treated rats were also sacrificed at 6 months after the second surgery. The tissues were sonicated and the colony forming units in the sonicate were quantified by serial dilutions and culture. MicroCT was used to quantify the new bone growth (BV/TV) in the debrided osteomyelitic void. Histological samples were analyzed for the presence of a neutrophil response by a blinded pathologist. (*: p<0.05) Positive cultures in:
○ 30% of animals treated with CBVF ○ 25% of animals treated with no void filler ○ 0% of animals treated with C-G (*) Neutrophil reaction in:
○ 35% of animals treated with CBVF ○ 50% of animals treated with no void filler ○ 0% of animals treated with C-G (*) The BV/TV in:
○ C-G treated rats was 24% greater than CBVF treated rats (*) ○ C-G treated rats was 94% greater than rats treated with no void filler (*) ○ CBVF treated rats was 56% greater than rats treated with no void filler (*) Animals sacrificed at 6 months which were treated with C-G did not have any evidence of infection by culture or histology. The bone mass of the implanted limb was higher than the contralateral (non-operated) side. CERAMENT|G decreased the rate of infection and increased new bone growth as compared with both CBVF and no void filler in a debrided osteomyelitic environment. Animals treated with C-G at 6 months showed no evidence of infection and retained a higher bone mass relative to the contralateral (non-operated) side. This study supports the use of CERAMENT|G as a readily available void filler which could be used in osteomyelitic environments after debridement.
