Abstract
Orthopedic device-related infections remain a serious challenge to treat. Central to these infections are bacterial biofilms that form on the orthopedic implant itself. These biofilms shield the bacteria from the host immune system and most common antibiotic drugs, which renders them essentially antibiotic-tolerant. There is an urgent clinical need for novel strategies to prevent these serious infections that do not involve conventional antibiotics. Recently, a novel antibiofilm coating for titanium surfaces was developed based on 5-(4-bromophenyl)-N-cyclopentyl-1-octyl-1H-imidazol-2-amine as an active biofilm inhibitor. In the current study we present an optimized coating protocol that allowed for a 5-fold higher load of this active compound, whilst shortening the manufacturing process. When applied to titanium disks, the newly optimized coating was resilient to the most common sterilization procedures and it induced a 1 log reduction in biofilm cells of a clinical Staphylococcus aureus isolate (JAR060131) in vitro, without affecting the planktonic phase. Moreover, the antibiofilm effect of the coating in combination with the antibiotic cefuroxime was higher than cefuroxime treatment alone. Furthermore, the coating was successfully applied to a human-scale fracture fixation device resulting in a loading that was comparable to the titanium disk model. Finally, an in vivo biocompatibility and healing study in a rabbit osteotomy model indicated that these coated implants did not negatively affect fracture healing or osteointegration. These findings put our technology one step closer to clinical trials, confirming its potential in fighting orthopedic infections without compromising healing.
Highlights
Implanted devices are extensively used in orthopedic and trauma surgery to restore function and aid healing of broken bones
The first step of the coating procedure consisted in functionalizing the titanium surface with Fmoc-APTES
The active compound was detached from the titanium surface by hydrolysis and the resultant solutions were analyzed via fluorescence spectroscopy
Summary
Implanted devices are extensively used in orthopedic and trauma surgery to restore function and aid healing of broken bones. These interventions offer more rapid and accurate restoration of function and greatly improve the quality of life for the affected patient. Orthopedic device-related infection (ODRI) represents a major threat to the success of these surgical interventions. The surface of the implant serves as a substrate for bacterial attachment and the formation of biofilms, which are significantly more tolerant to antibiotics. Intravenous antibiotic therapy alone is rarely successful in treating biofilm infections. Exposure to low antibiotic concentrations exerts selective pressure which can lead to resistance development (Liu et al, 2011; Stanton et al, 2020)
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