Paired laser and electrokinetic separation, manipulation, and analysis device

What is claimed is: 1. A device comprising: a microfluidic channel configured to supply a linear or non-linear dielectrophoretic (DEP) field to an interior of the channel via a (1) DEP electrode system or (2) insulator DEP system, the channel having a region of shaped wall geometry or obstruction geometry configured to create at least one restriction in the channel, and a source of laser light focused by an optic into the microfluidic channel, wherein the laser light and DEP field operate jointly on particles in the microfluidic channel to trap the particles or modify their velocity, wherein the DEP field exists across a length of the channel and is generated by electrodes positioned beyond the region of shaped wall geometry or obstruction geometry at inlet and outlet ends of the channel. 2. A device comprising: a microfluidic channel configured to supply a linear or non-linear dielectrophoretic (DEP) field to an interior of the channel via a (1) DEP electrode system or (2) insulator DEP system, the channel having a region of shaped wall geometry or obstruction geometry configured to create at least one restriction in the channel, and a source of laser light focused by an optic into the microfluidic channel, wherein the laser light and DEP field operate jointly on particles in the microfluidic channel to trap the particles or modify their velocity, wherein the DEP field exists across a length of the channel and is generated by electrodes positioned beyond the region of shaped wall geometry or obstruction geometry at inlet and outlet ends of the channel; and an adjoining channel structure, wherein said DEP field is effective to operate on populations of particles based on their electrokinetic properties, and said laser light is focused orthogonally to a flow axis of said microfluidic channel and operates to elute one or more of the isolated populations into the adjoining channel structure, wherein the adjoining channel structure is a region open to the channel at only a single end. 3. The device of claim 1 , wherein the channel has said curved or triangular shaped wall geometry or round obstruction geometry. 4. A device comprising: a microfluidic channel configured to supply a linear or non-linear dielectrophoretic (DEP) field to an interior of the channel via a (1) DEP electrode system or (2) insulator DEP system, the channel having a region of shaped wall geometry or obstruction geometry configured to create at least one restriction in the channel, and a source of laser light focused by an optic into the microfluidic channel, wherein the laser light and DEP field operate jointly on particles in the microfluidic channel to trap the particles or modify their velocity, wherein the DEP field exists across a length of the channel and is generated by electrodes positioned beyond the region of shaped wall geometry or obstruction geometry at inlet and outlet ends of the channel , and wherein said laser light is configured to be adjustably angled via mirrors and focusing optics held in place with optomechanical components and configured with the necessary degrees of freedom to direct and align the laser into the microfluidic channel.