THE OPTIMAL SAMPLING STRATEGY IN PATIENTS SUSPECTED OF PROSTHETIC JOINT INFECTION: A MICROBIOLOGIST'S POINT OF VIEW

Optimal sampling for culture-based or molecular diagnosis remains highly contested for patients suspected of prosthetic joint infection (PJI). Most existing studies have a retrospective design without a standardized sampling strategy. Therefore, the results are difficult to translate into guidelines. We have conducted a 2-year prospective study with a sampling strategy adaptable to the specific procedure in patients with either hip or knee alloplasty. Thus, comparisons of results obtained with different specimen types and diagnostic methods are possible. The study enrolled patients with a painful hip or knee alloplasty. The sampling strategy for microbiological diagnosis included multiple specimens of each type (joint fluid, tissue biopsies, bone biopsies, and swabs taken from the prosthesis in situ), and prosthetic components (if removed). Prepacked boxes with containers and accessories for sampling, transport and storage were provided. Microbial culture and bacterial 16S rDNA screening were carried out for all specimen types. Whenever positive upon 16S rDNA screening, samples were analyzed further by sequencing. Peptide nucleic acid-fluorescence in situ hybridization (optimized using filtrations; Filter-PNA-FISH) was limited to a subset thereof. An overall completeness of ∼90% was obtained by the sampling strategy in 164 procedures (‘cases’) in 131 patients. In 58 cases PJI was suspected, and a revision was carried out. 42 cases were culture-positive, and 16 were culture-negative; one culture-negative case was positive by 16S rDNA sequencing of a corresponding specimen. The contribution to a microbiological diagnosis was high for periprosthetic tissue biopsies (≥ 3 positive out of 5) 90%, prosthetic component(s) 90%, and joint fluid 94%. Conversely, the contribution was sparse for prosthetic swabs 50% and bone biopsies 40%, respectively. Filter-PNA-FISH was used to confirm findings by culture and to demonstrate biofilm formation. With the described sampling strategy we reached high completeness of complex specimen sets. The sampling strategy may be adapted to other clinical settings with microbiological sampling of similar complexity. We found multiple periprosthetic tissue biopsies, prosthetic component(s) and joint fluid to form the optimal specimen set for culture-based diagnosis. The contribution by 16S rDNA sequencing is still under investigations but the contributions seems moderate probably because of a low rate of antibiotic therapy before the procedure, use of effective culture methods and prolonged incubation (14 days).