Electrically conductive catheter inhibits bacterial colonization

Suppression of Staphylococcus aureus biofilm formation under a short-term impact of low-intensity direct current in vitro and in a rat model of implant-associated osteomyelitis

Objectives

We investigated the effect of short-term low-intensity direct current (LIDC) on Staphylococcus aureus.

Materials and Methods

The reference strain of S. aureus was used. Experiments were performed in agar culture and on a model of rat's femur osteomyelitis. K-wires were used as electrodes. The exposure to LIDC of 150 μA continued for one minute. In vitro exposure was performed once. In vivo group 1 was a control group. Osteomyelitis was modeled in three groups but only groups 3 and 4 were exposed to LIDC four times: either from day 1 or from day 7 post-surgery. The effect was evaluated on day 21. Microbiological, histological, scanning electron, and light microscopy methods were used for evaluation of the LIDC effect.

Results

Bacteria diameter, oblongness, and division increased 15 min after LIDC exposure in the culture around the cathode. After 24 hr, the amount of exomatrix was lower than in the control test, and the cell diameter and roundness increased. Similar changes around the anode were less pronounced. In vivo, biofilm formation on the intramedullary wire cathode was suppressed in group 3. In group 4, detachment and destruction of the biofilm were observed. The formation of S. aureus microcolonies was suppressed, and the adhesion of fibroblasts and immune cells was activated. LIDC did not stop the development of the osteomyelitis process.

Conclusion

Short-term exposure to LIDC suppresses S. aureus biofilm formation on the implant cathode surface in the acute and early postoperative period but does not have an impact on the development of osteomyelitis.

Mapping Bacterial Biofilm on Features of Orthopedic Implants In Vitro

Implant-associated infection is a major complication of orthopedic surgery. One of the most common organisms identified in periprosthetic joint infections is Staphylococcus aureus, a biofilm-forming pathogen. Orthopedic implants are composed of a variety of materials, such as titanium, polyethylene and stainless steel, which are at risk for colonization by bacterial biofilms. Little is known about how larger surface features of orthopedic hardware (such as ridges, holes, edges, etc.) influence biofilm formation and attachment. To study how biofilms might form on actual components, we submerged multiple orthopedic implants of various shapes, sizes, roughness and material type in brain heart infusion broth inoculated with Staphylococcus aureus SAP231, a bioluminescent USA300 strain. Implants were incubated for 72 h with daily media exchanges. After incubation, implants were imaged using an in vitro imaging system (IVIS) and the metabolic signal produced by biofilms was quantified by image analysis. Scanning electron microscopy was then used to image different areas of the implants to complement the IVIS imaging. Rough surfaces had the greatest luminescence compared to edges or smooth surfaces on a single implant and across all implants when the images were merged. The luminescence of edges was also significantly greater than smooth surfaces. These data suggest implant roughness, as well as large-scale surface features, may be at greater risk of biofilm colonization.

Antibiofilm Activity of Electrical Current in a Catheter Model

Catheter-associated infections are difficult to treat with available antimicrobial agents because of their biofilm etiology. We examined the effect of low-amperage direct electrical current (DC) exposure on established bacterial and fungal biofilms in a novel experimental in vitro catheter model. Staphylococcus epidermidis, Staphylococcus aureus, Escherichia coli, Pseudomonas aeruginosa, and Candida parapsilosis biofilms were grown on the inside surfaces of polyvinyl chloride (PVC) catheters, after which 0, 100, 200, or 500 μA of DC was delivered via intraluminally placed platinum electrodes. Catheter biofilms and intraluminal fluid were quantitatively cultured after 24 h and 4 days of DC exposure. Time- and dose-dependent biofilm killing was observed with all amperages and durations of DC administration. Twenty-four hours of 500 μA of DC sterilized the intraluminal fluid for all bacterial species studied; no viable bacteria were detected after treatment of S. epidermidis and S. aureus biofilms with 500 μA of DC for 4 days.