Attachment characteristics and kinetics of biofilm formation by Staphylococcus aureus on ready‐to‐eat cooked beef contact surfaces

Abstract

AbstractStaphylococcus aureus is a food‐borne pathogen that quickly forms biofilm on meat contact surfaces and thus poses a serious threat to the safety of the meat industry. This study evaluated the attachment, survival, and growth of S. aureus biofilm with exposure to environmental factors in the meat industry by simulated ready‐to‐eat (RTE) cooked beef product contamination scenarios. The results indicated that the meat‐borne S. aureus biofilm formation dynamic could be divided into four different phases: initial adhesion (4–12 h), exponential (12–24 h), slow growth (1–3 days), and stationary (3–7 days). Meat‐borne S. aureus has strong adhesion and biofilm formation ability, and its biofilm exhibits persistence, high‐intensity metabolic activity, aerotaxis, and strain heterogeneity. This study has also demonstrated that in the long‐term existence of meat‐borne S. aureus biofilm on stainless steel and plexiglass surfaces (>7 days, 7.2–8.8 log CFU/cm2), expose to RTE cooked beef products, may cause it to become high‐risk contaminated food. Meat‐borne S. aureus that forms a dense and rough concave‐convex in the shape of biofilm architecture was observed by scanning electron microscopy, consisting of complex components and adhesion of living and dead cells. This was further confirmed by the meat‐borne S. aureus biofilm on the stainless steel surface by attenuated total reflectance Fourier transformed infrared spectroscopy, and the dominant peaks in biofilm spectra were mainly associated with proteins, polysaccharides, amino acid residues, and phospholipids (>50%). These findings may help in the identification of the main sources of contamination within the meat industry and the subsequent establishment of strategies for biofilm prevention and removal.Practical ApplicationThis study revealed the meat‐borne S. aureus biofilm formation mechanism and found that it exhibited strong colonization and biofilm‐forming ability, which can persist on the contact surfaces of ready‐to‐eat beef products. These initial findings could provide information on the behavior of meat‐borne S. aureus biofilm attached to meat contact surfaces under conditions commonly encountered in meat environments, which help to support the determination of the main sources of contamination within the meat industry and the subsequent establishment of strategies for biofilm prevention and removal. It was also helpful in controlling biofilm contamination and improving meat safety to minimize it.