Abstract
The role of biofilm in pathogenesis of several chronic human infections is widely accepted, as this structure leads pathogens to persist among the human body, being protected from the action of antibacterial molecules and drugs (1). It has been estimated that up to 65% of bacterial infections are caused by microorganisms growing in biofilms (2). Moreover, biofilm is involved in device-related orthopaedic bacterial infections, which are unaffected by vaccines and antibiotic therapies, constituting a serious problem for the human health care.
The aim of the present work was to evaluate the anti-biofilm action of a selected and patented lactobacillus strain (MD1) supernatant, both on the in-formation- biofilm and on mature biofilm produced by pathogenic bacteria.
MD1 was grown in BHI for 48 h at 37°C. After incubation, the sample was centrifuged for 5’ for 14,000 × g and the supernatant previously filtered and treated in order to obtain the anti-biofilm compounds (Special Supernatant – SS) was collected. Staphylococcus aureus and Pseudomonas aeruginosa strains were grown in BHI for 24h at 37°C. The anti-biofilm ability of the tested SS – lactobacillus strain was evaluated by a spectrophotometric method according to Christensen at al., following the incubation of pathogens and the “mature biofilm” with the lactobacillus supernatant. Confocal Laser Scanning Microscopy was used to confirm the data obtained from Crystal Violet Assay.
After the incubation of the SS with pathogens and mature biofilm, the formation of biofilm was inhibited and a significant disruption of the mature biofilm was observed. Interestingly, the same properties were observed also when the SS pH was neutralized to pH 6.5. In particular, the reduction of biofilm production and the disruption of mature biofilm was about 50–70% for all microorganisms.
The SS lactobacillus strain MD1 exhibited a relevant antibiofilm action against mature and in-formation-biofilm produced by S. aureus and P. aeruginosa strains tested in the study. Moreover, the antibiofilm action has been observed to be pH-independent, as when the supernatant was neutralized to pH 6.5, the reduction of pathogenic biofilm has been still observed. These promising results highlighted the possibility to use this SS-lactobacillus anti-biofilm property to develop a cost-effective and safety treatment able to reduce the impact of pathogenic biofilm on device-related orthopaedic bacterial infections.
