Microtiter plate methods are commonly used for biofilm assessment. However, results obtained with these methods have often been difficult to reproduce. Hence, it is important to obtain a better understanding of the repeatability and reproducibility of these methods. An interlaboratory study was performed in five different laboratories to evaluate the reproducibility and responsiveness of three methods to quantify Staphylococcus aureus biofilm formation in 96-well microtiter plates: crystal violet, resazurin, and plate counts. An inter-lab protocol was developed for the study. The protocol was separated into three steps: biofilm growth, biofilm challenge, biofilm assessment. For control experiments participants performed the growth and assessment steps only. For treatment experiments, all three steps were performed and the efficacy of sodium hypochlorite (NaOCl) in killing S. aureus biofilms was evaluated. In control experiments, on the log10-scale, the reproducibility SD (SR) was 0.44 for crystal violet, 0.53 for resazurin, and 0.92 for the plate counts. In the treatment experiments, plate counts had the best responsiveness to different levels of efficacy and also the best reproducibility with respect to responsiveness (Slope/SR = 1.02), making it the more reliable method to use in an antimicrobial efficacy test. This study showed that the microtiter plate is a versatile and easy-to-use biofilm reactor, which exhibits good repeatability and reproducibility for different types of assessment methods, as long as a suitable experimental design and statistical analysis is applied.
Osteomyelitis is an inflammatory bone disease caused by an infecting microorganism leading to a gradual bone loss. Due to the difficulty in studying osteomyelitis directly in patients, animal models allow researchers to investigate the pathogenesis of the infection and the development of novel prophylactic, anti-inflammatory and antimicrobial treatment strategies. This review is specifically focused on the in vivo mouse osteomyelitis studies available in literature. Thus, a systematic search on Web of Science and PubMed was conducted using the query “(infection) AND (mice OR mouse OR murine) AND (model OR models) AND (arthroplasty OR fracture OR (internal fixator) OR (internal fixation OR prosthesis OR implant OR osteomyelitis)”. After critical assessment of the studies according to the inclusion and exclusion criteria, 135 studies were included in the detailed analysis. Based on the model characteristics, the studies were classified into five subject groups: haematogenous osteomyelitis, post-traumatic osteomyelitis, bone-implant-related infection, peri-prosthetic joint infection, fracture-related infection. In addition, the characteristics of the mice used, such as inbred strain, age or gender, the characteristics of the pathogens used, the inoculation methods, the type of anaesthesia and analgesia used during surgery and the procedures for evaluating the pathogenicity of the infecting micro-organism were described. Overall, the mouse is an excellent first step in vivo model to study the pathogenesis, inflammation and healing process of osteomyelitis and to evaluate novel prophylaxis and treatment strategies.
Nosocomial diseases represent a huge health and economic burden. A significant portion is associated with the use of medical devices, with 80% of these infections being caused by a bacterial biofilm. The insertion of a foreign material usually elicits inflammation, which can result in hampered antimicrobial capacity of the host immunity due to the effort of immune cells being directed to degrade the material. The ineffective clearance by immune cells is a perfect opportunity for bacteria to attach and form a biofilm. In this study, we analyzed the antibiofilm capacity of three naturally derived biofilm inhibitors when combined with immune cells in order to assess their applicability in implantable titanium devices and low-density polyethylene (LDPE) endotracheal tubes. To this end, we used a system based on the coculture of HL-60 cells differentiated into polymorphonuclear leukocytes (PMNs) and Staphylococcus aureus (laboratory and clinical strains) on titanium, as well as LDPE surfaces. Out of the three inhibitors, the one coded DHA1 showed the highest potential to be incorporated into implantable devices, as it displayed a combined activity with the immune cells, preventing bacterial attachment on the titanium and LDPE. The other two inhibitors seemed to also be good candidates for incorporation into LDPE endotracheal tubes.
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