Staphylococcus aureus is a leading cause of catheter-related bloodstream infections and endocarditis. Both involve (i) biofilm formation, (ii) exposure to fluid shear, and (iii) high rates of dissemination. We found that viscoelasticity allowed S. aureus biofilms to resist detachment due to increased fluid shear by deformation, while remaining attached to a surface. Further, we report that S. aureus microcolonies moved downstream by rolling along the lumen walls of a glass flow cell, driven by the flow of the overlying fluid. The rolling appeared to be controlled by viscoelastic tethers. This tethered rolling may be important for the surface colonization of medical devices by nonmotile bacteria.Biofilm infections are increasingly associated with a variety of medical prostheses (e.g., vascular and orthopedic implants) and delivery devices (e.g., percutaneous catheters), as well as with diseases such as native-valve endocarditis and infectious kidney stones (1,2,3,13). Staphylococcus aureus is a key pathogen, feared for its high mortality rate and antibiotic resistance (10). Endovascular biofilm infections caused by S. aureus also carry a high risk of metastasis (4, 10). These biofilms are exposed to a broad range of fluid shears, ranging from the continuous, laminar flow in infected infusion lines to the highly variable, turbulent flow in the case of bacterial vegetations on a heart valve. Therefore, the continuous adaptation to mechanical stresses is an important feature of biofilm physiology (7). The responses of biofilms to shear stresses may determine biofilm dissemination in general and the rate of formation and size of biofilm emboli in particular. In previous work, we showed that S. aureus biofilm emboli ranged in size from single cells to microcolonies containing thousands of cells in an in vitro catheter infection model (6). Large emboli expressed antibiotic (oxacillin) tolerance similar to that observed in attached biofilms. In the present study, we used a glass capillary system previously used to mimic physiological shear in both catheter (6) and vascular (9) infection models to quantify the viscoelastic response and motion of S. aureus biofilm microcolonies in response to varying or steady fluid shear over short (seconds) and sustained (minutes) periods. Biofilms were grown from an S. aureus strain (ATTC 25923) on 1/10-strength brain heart infusion broth at 37°C. One milliliter of a 24-h broth culture was inoculated into a 1-mm 2 , 140-mm-long glass capillary flow cell (model FC91; BioSurface Technologies, Bozeman, Mont.) integrated into a once-through flow system. Biofilms were monitored with a Cohu (San Diego, Calif.) model 4910 camera mounted on an Olympus BH2 microscope using Scion Image software (Scion Inc., Frederick, Md.). After an attachment period of 30 min, a continuous laminar flow rate (Q) of 60 ml h Ϫ1 was established to approximate the hydrodynamic conditions typically used in a central venous catheter (6). The average velocity was 1.67 cm s Ϫ1 , the Reynolds number was 17, and the wall ...
