Aim

Multispecies biofilms are associated with difficult periprosthetic joint infections (PJI), particularly if they have different antibiotic sensitivities. We aimed to determine if we could generate and kill a multispecies biofilm consisting of a Gram negative and Gram positive pathogen in-vitro with antibiotic loaded calcium sulfate beads containing single or combination antibiotics.

Periprosthetic joint infection (PJI) is a difficult complication requiring a comprehensive eradication protocol. Cure rates have essentially stalled in the last two decades, using methods of antimicrobial cement joint spacers and parenteral antimicrobial agents. Functional spacers with higher-dose antimicrobial-loaded cement and antimicrobial-loaded calcium sulphate beads have emphasized local antimicrobial delivery on the premise that high-dose local antimicrobial delivery will enhance eradication. However, with increasing antimicrobial pressures, microbiota have responded with adaptive mechanisms beyond traditional antimicrobial resistance genes. In this review we describe adaptive resistance mechanisms that are relevant to the treatment of PJI. Some mechanisms are well known, but others are new. The objective of this review is to inform clinicians of the known adaptive resistance mechanisms of microbes relevant to PJI. We also discuss the implications of these adaptive mechanisms in the future treatment of PJI.

Cite this article: Bone Joint J 2022;104-B(5):575–580.

Aim

Carbapenem-resistant Enterobacteriaceae (CRE) and vancomycin resistant Enterococci (VRE) have emerged as multi-drug resistant Gram-negative pathogens associated with Periprosthetic Joint Infections (PJI). In this study, we evaluated the efficacy of antibiotic-loaded calcium sulfate beads (ABLCB) to inhibit bacterial growth, biofilm formation and eradicate preformed biofilms of K. pneumoniae and E. faecalis.

Aim

Bacterial biofilms play a key role in prosthetic infection (PI) pathogenesis. Establishment of the biofilm phenotype confers the bacteria with significant tolerance to systemic antibiotics and the host immune system meaning thorough debridement and prosthesis removal often remain the only possible course of treatment. Protection of the prosthesis and dead-space management may be achieved through the use of antibiotic loaded cements and beads to release high concentrations of antibiotics at the surgical site. The antibacterial and antibiofilm efficacy of these materials is poorly understood in the context of mixed species models, such as are often encountered clinically.

Post-operative surgical site infection following total joint arthroplasty occurs at rates between ~ 0.2–5 %, depending on the joint and the surgeon volume, as well as various patient risk factors. Given that an estimated over 700,000 knee and hip arthroplasties are performed in the US each year this translates to thousands of patients that are affected by this serious, costly and traumatic complication. In addition, it is now recognized that clinical culturing underestimates the infection rate and that a number of aseptic loosenings might actually have an infectious etiology. We have used a combination of non-culture based molecular methods to detect bacteria associated with hardware, antimicrobial impregnated cement, reactive tissue and pus collected during revision surgery in a total elbow arthroplasty (TEA) case and a total ankle revision (TAR) case. Confocal microscopy showed live cocci in biofilm cell clusters, and fluorescent in situ hybridization (FISH) demonstrated S. aureus biofilms. Reverse transcriptase (RT)-PCR, and multiplex PCR coupled with electrospray-ionization mass spectrometry (Ibis T5000) to identify S. aureus, S. epidermidis and genes for methicillin resistance. Together our complimentary techniques comprise compelling evidence that viable biofilm bacteria played an important role in the refractory infections in these cases.