A new method for simulating the motion of individual ellipsoidal bacteria in microfluidic devices.

To successfully perform biological experiments on bacteria in microfluidic devices, control of micron-scale cell motion in the chip-sized environment is essential. Here we describe a new method for simulating the motion of individual bacterial cells in a microfluidic device using a one-way coupling Lagrangian approach combined with rigid body theory. The cell was assumed to be an elastic, solid ellipsoid, and interactions with solid wall boundaries were considered to occur in one of two collision modes, either a "standing" or "lying" collision mode on the surface. The ordinary differential equations were solved along the cell trajectory for the thirteen unknown variables of the translational cell velocity, cell location vector, rotational angular velocity, and four Euler parameters, using the Rosenbrock method based on an adaptive time-stepping technique. As selected applications, we show how this novel simulation method may be applied to the designs of efficient hydrodynamic cell traps in a microfluidic device for bacterial applications and for cell separations. Modeled designs include optimized U-shaped sieve arrays with a single aperture for the hydrodynamic cell trapping, and three kinds of staggered micropillars for cell separations.

[1]  Daniel A Fletcher,et al.  Chemotherapy exposure increases leukemia cell stiffness. , 2007, Blood.

[2]  L. Munn,et al.  Particulate nature of blood determines macroscopic rheology: a 2-D lattice Boltzmann analysis. , 2005, Biophysical journal.

[3]  Rustem F Ismagilov,et al.  Spatial localization of bacteria controls coagulation of human blood by 'quorum acting'. , 2008, Nature chemical biology.

[4]  M. Nobili,et al.  Brownian Motion of an Ellipsoid , 2006, Science.

[5]  Alex Groisman,et al.  A microfluidic chemostat for experiments with bacterial and yeast cells , 2005, Nature Methods.

[6]  David W Inglis,et al.  Critical particle size for fractionation by deterministic lateral displacement. , 2006, Lab on a chip.

[7]  Mattias Goksör,et al.  Optical tweezers applied to a microfluidic system. , 2004, Lab on a chip.

[8]  Roman Stocker,et al.  Microorganisms in vortices: a microfluidic setup , 2006 .

[9]  M. Solomon,et al.  Translational and rotational dynamics of colloidal rods by direct visualization with confocal microscopy. , 2007, Journal of colloid and interface science.

[10]  A. Ashkin,et al.  Optical trapping and manipulation of viruses and bacteria. , 1987, Science.

[11]  A. Neild,et al.  Directional Brownian diffusion dynamics with variable magnitudes , 2008 .

[12]  G. Ahmadi,et al.  Dispersion of Ellipsoidal Particles in an Isotropic Pseudo-Turbulent Flow Field , 1995 .

[13]  G. B. Jeffery The motion of ellipsoidal particles immersed in a viscous fluid , 1922 .

[14]  Roman Stocker,et al.  Separation of microscale chiral objects by shear flow. , 2009, Physical review letters.

[15]  Raymond H. W. Lam,et al.  Building a better cell trap: Applying Lagrangian modeling to the design of microfluidic devices for cell biology , 2008 .

[16]  Rashid Bashir,et al.  A multifunctional micro-fluidic system for dielectrophoretic concentration coupled with immuno-capture of low numbers of Listeria monocytogenes. , 2006, Lab on a chip.

[17]  J. Hubbell,et al.  Chemical tethering of motile bacteria to silicon surfaces. , 2009, BioTechniques.

[18]  I. Gallily,et al.  On the orderly nature of the motion of nonspherical aerosol particles. II. Inertial collision between a spherical large droplet and an axially symmetrical elongated particle , 1979 .

[19]  S. G. Mason,et al.  The flow of suspensions through tubes: V. Inertial effects , 1966 .

[20]  Jin Hyun Nam,et al.  Near-Wall Deposition Probability of Blood Elements as A New Hemodynamic Wall Parameter , 2006, Annals of Biomedical Engineering.

[21]  C. Y. Teo,et al.  Enhanced microfiltration devices configured with hydrodynamic trapping and a rain drop bypass filtering architecture for microbial cells detection. , 2008, Lab on a chip.

[22]  Raymond H. W. Lam,et al.  Culturing Aerobic and Anaerobic Bacteria and Mammalian Cells with a Microfluidic Differential Oxygenator , 2009, Analytical chemistry.

[23]  Howard Brenner,et al.  The Stokes resistance of an arbitrary particleIV Arbitrary fields of flow , 1964 .

[24]  Luke P. Lee,et al.  Dynamic single cell culture array. , 2006, Lab on a chip.

[25]  J. Wikswo,et al.  Effects of flow and diffusion on chemotaxis studies in a microfabricated gradient generator. , 2005, Lab on a chip.