Your search keyword '"Guanglai Li"' showing total 2 results

1. Amplified effect of Brownian motion in bacterial near-surface swimming.

Author

Guanglai Li, Lick-Kong Tam, and Tang, Jay X.

Subjects

*WIENER processes, *HYDRODYNAMICS, *FLUORESCENCE microscopy, *ELECTROSTATICS, *VAN der Waals forces

Abstract

Brownian motion influences bacterial swimming by randomizing displacement and direction. Here, we report that the influence of Brownian motion is amplified when it is coupled to hydrodynamic interaction. We examine swimming trajectories of the singly flagellated bacterium Caulobacter crescentus near a glass surface with total internal reflection fluorescence microscopy and observe large fluctuations over time in the distance of the cell from the solid surface caused by Brownian motion. The observation is compared with computer simulation based on analysis of relevant physical factors, including electrostatics, van der Waals force, hydrodynamics, and Brownian motion. The simulation reproduces the experimental findings and reveals contribution from fluctuations of the cell orientation beyond the resolution of present observation. Coupled with hydrodynamic interaction between the bacterium and the boundary surface, the fluctuations in distance and orientation subsequently lead to variation of the swimming speed and local radius of curvature of swimming trajectory. These results shed light on the fundamental roles of Brownian motion in microbial motility, nutrient uptake, and adhesion. [ABSTRACT FROM AUTHOR]

Published

2008

2. Adhesion of single bacterial cells in the micronewton range.

Author

Tsang, Peter H., Guanglai Li, Brun, Yves V., Freund, L. Ben, and Tang, Jay X.

Subjects

*BACTERIAL adhesion, *CELLS, *FINITE element method, *ADHESION, *FUNGUS-bacterium relationships

Abstract

The adhesion of bacteria to surfaces plays critical roles in the environment, disease, and industry. In aquatic environments, CauIobacter crescentus is one of the first colonizers of submerged surfaces. Using a micromanipulation technique, we measured the adhesion force of single C. crescentus cells attached to borosilicate substrates through their adhesive holdfast. The detachment forces measured for 14 cells ranged over 0.11 to 2.26 µN, averaging 0.59 ± 0.62 µN. Based on the calculation of stress distribution with the finite element analysis method (dividing an object into small grids and calculating relevant parameters for all of the elements), the adhesion strength between the holdfast and the substrate is >68 N/mm² in the central region of contact. To our knowledge, this strength of adhesion is the strongest ever measured for biological adhesives. [ABSTRACT FROM AUTHOR]

Published

2006