Biophysical properties and phenotypes of cell clusters detached from Staphylococcus epidermidis biofilms after matrix-targeted disruption

Bacterial cells detached from Staphylococcus epidermidis biofilms are found to release predominantly as small oblate clusters ([~]1.9 {micro}m) in both untreated biofilms and biofilms treated with matrix-targeted disruptors. Quantitative image analysis common to colloidal science was applied to quantitatively evaluate the physical properties of 9,147 bacterial clusters detached from S. epidermidis biofilms with and without targeted disruption of individual matrix components (polysaccharides, proteins, extracellular DNA) or solubilization of the extracellular polymeric substances (EPS). Concentrations of S. epidermidis biofilm-detached cells are highest after matrix-targeted disruption of polysaccharides. K-means clustering, an unsupervised machine learning technique, was used to reveal that S. epidermidis biofilm-detached cells are released in five distinct phenotypes: small oblate, mid-sized oblate, large oblate, small spherical, and mid-sized prolate clusters. S. epidermidis biofilm detached cell clusters are predominantly oblate across three size groups (79.5%), with the small oblate phenotype representing 60.1% of cell clusters that have 3.1 {+/-} 1.2 cells per cluster, Euclidean diameters of 1.9 {+/-} 0.4 {micro}m, anisotropy indices of 0.98 {+/-} 0.05, and asphericities of -1.75 {+/-} 0.31 on average. The proportion of S. epidermidis cell clusters within each biofilm-detached cell phenotype differs between matrix-targeted disruptors. There are also variations in the abundance of S. epidermidis biofilm detached cells after matrix-targeted disruption between growth conditions and strains. Evaluating the physical properties of biofilm-detached cells after matrix-targeted disruption is critical to understanding their translocation in fluid flow and susceptibility to the host immune response as well as in evaluating matrix-targeted disruption for biofilm control.