, 1998). However, often the rate of positive samples is so high that suspicion has been raised that PCR might produce a high rate of false positive results by detecting contaminant bacteria or remnant bacterial DNA. Therefore, direct microscopic examination of recovered prosthesis components and associated tissue using viability stains and FISH to identify targeted
pathogens has been used to corroborate PCR-based methods (Stoodley et al., 2008, 2011; Gallo et al., 2011). These studies have demonstrated that PCR and FISH show similar trends to presonication and culture and indicate a much higher proportion of orthopedic device failures may have an infectious etiology than currently considered (Costerton et al., 2011). Better guidance outlining sampling protocols for obtaining clinical samples for microbiological testing and how to treat the samples for releasing Selleck GDC-0449 the biofilm bacteria may therefore improve culture outcomes, including sampling of multiple aspirate or effusion samples. Tissue biopsies that
allow histological work-up or homogenization before culture are also more likely to detect biofilm bacteria than swabs, which may miss microorganisms in a niche, encased in a matrix, or within the INK 128 clinical trial tissue. Furthermore, multiple or successive biopsies might also reduce the sampling error, taking into account that BAI may be surface-associated or localized. The following samples are therefore recommended in BAI: (1) swabs (e.g. nasal, throat, and genital), (2) liquid samples (e.g. blood, sputum, ear effusion, purulent discharge—particularly from wounds, and synovial fluid), (3) solid samples however (native tissue biopsies, e.g. bone fragments or heart valves), and (4) implant samples (e.g. sutures, meshes, catheters, stents, and prostheses). As discussed previously, in some cases, an ultrasonication step may increase sensitivity. Once the sample has been taken and processed, it remains to be seen from blinded clinical studies, which diagnostic samples are best for the determination of a course of treatment, culture, PCR, or
a combination of the both. Culture (plate counts with colony forming units (CFU) to determine viable bacteria) has been shown by many researchers to not necessarily accurately reflect viable bacteria. To assess antimicrobial effects, culture was directly compared in vitro with the bacterial Live/Dead kit, which uses membrane permeability/patency to assess in situ viability and a metabolic stain (CTC: 5-cyano-2,3,-ditolyl tetrazolium chloride) to measure bacterial respiratory activity in biofilms (Kim et al., 2008a). This study found that although nearly half of cells within the biofilm were not cultured (compared with direct microscopic analysis), 90% retained respiratory activity and 70% demonstrated membrane patency.