Kaneshiro, Alma; Jordan, Adam; Crompton, Rhees; Brailsford, Samantha; Spencer, Jonathan (Weber State University)
Faculty Advisor: Clark, Daniel (Science, Microbiology Department and Neuroscience Center); Chaston, John (Life Sciences, Plant & Wildlife Sciences)
Antibiotic resistance is of great concern in the medical community, with bacterial resistance increasing proportional to their use. Staphylococcus aureus, such as methicillin resistant S. aureus (MRSA), can cause fatal infections. Problems due to this resistance are compounded when the infecting bacteria form a biofilm, thick sticky layers of bacterial secretions, which are difficult for antibiotics to penetrate. Biofilm formation is common in hospital settings on stents, catheters, and IV lines. Biofilms make antibiotic treatment risky due to incomplete killing—the most resistant survive exposure. There is evidence that bacteriophage can break up biofilms, possibly making them more susceptible to antibiotics. We induced a S. aureus biofilm formation using chemicals that mimic a skin wound. Using bacteriophage K, we inoculated the biofilm and observed clearance. Samples of cell pellets and liquid supernatant were collected, and DNA was extracted. Real-time PCR was used to quantify the levels of bacteriophage K replication, representing clearance of the bacteria. This research can be used to find efficient ways to treat an infection caused by a S. aureus biofilm. Bacteriophage used in combination with antibiotics may be able to better clear a biofilm infection and reduce antibiotic resistance risk due to more complete infection clearance.