Abstract: A method of quantifying cell migration of a cell population is provided. The method includes the step of patterning the cell population within a channel network in a first body. A first image of the cell population is obtained. Thereafter, a second image of the cell population is obtained after a first predetermined time period. The first and second images are compared in order to calculate a quantitative measure of the average directional migration of the cells population and a quantitative measure of the average motility of the cell population.

Abstract: A method is provided of controlling communication between multiple ports in a microfluidic device. The method includes the step of providing a channel network in a microfluidic device. The channel network including a first channel having a first input port and an output port. The first channel is filled with a fluid and a first output droplet is deposited on the output port. The first output droplet has a radius of curvature. The first output droplet flows toward the first input port in response to placement of a first input droplet having a radius of curvature greater than the radius of curvature of the first output droplet on the first input port. The first input droplet flows toward the output port in response to the first input droplet having a radius of curvature less than the radius of curvature of first output droplet.

Abstract: A method of self regulating a process of manufacturing a biological device which includes the steps of: choosing a first material and a second material based on a correlation of a parameter of the second material with a parameter of the first material; and merging the first material with the second material where the correlation of the parameter of the second material with the parameter of the first material self regulates the merging step to provide a distinct patterning of the first material and the second material.

Abstract: A method is provided of conducting cell chromatography with a group of cells. Each cell has a fluorescence intensity. The method includes the step of depositing the group of cells into a first chamber for a first predetermined time period such that a first portion of cells of the group of cells attaches to a first surface. The cells unattached to the first surface are removed from the first chamber and deposited into a second chamber for a second predetermined time period. A second portion of cells of the unattached cells attach to a second surface. The cells unattached to the second surface are removed from the second chamber. Thereafter, the fluorescence intensities of the cells attached to the first and second surfaces are compared to a standard.

Abstract: A method and apparatus are provided for regulating diffusive transport of particles between first and second portions of a channel network in a microfluidic device. The first and second portions of the channel network are in fluid communication. A first object is deposited in a first portion of the channel network and a second object is deposited in the second portion of the channel network. The diffusive transport of particles between the first and second portions of the channel network is controlled so as to allow for the study of reciprocal signaling between the objects.

Abstract: A device and method is provided for performing a high throughput assay. The device includes a plate structure having a plate and a plurality of microfluidic structures positioned thereon. Each microfluidic structure defines a channel having an input and an output. At least one of the input and the output of the channel of each of the plurality of mircofluidic structures includes a first plurality of ports. In operation, the channels are filled with fluid and pressure gradients are generated between the fluids at the inputs and the fluids at the outputs of the channels. As a result, fluid flows through the channels toward the outputs.