Abstract: Various embodiments are directed to the electrochemical fabrication of multilayer mesoscale or microscale structures which are formed using at least one conductive structural material, at least one conductive sacrificial material, and at least one dielectric material. In some embodiments the dielectric material is a UV-curable photopolymer. In other embodiments, electrochemically fabricated structures are formed on dielectric substrates.

Abstract: Various embodiments are directed to the electrochemical fabrication of multilayer mesoscale or microscale structures which are formed using at least one conductive structural material, at least one conductive sacrificial material, and at least one dielectric material. In some embodiments the dielectric material is a UV-curable photopolymer. In other embodiments, electrochemically fabricated structures are formed on dielectric substrates.

Abstract: At least two Fresnel lenses are formed on a transparent substrate, and a set of parallel plates are established in an acute included angle (from 19° to 90°) with the transparent substrate by an inclined exposure process employing a thick film photoresist. The parallel plates are separately placed over the Fresnel lenses. Metal layers are separately deposited on the outside surfaces of the parallel plates far from the acute included angle, wherein one of the metal layers makes the parallel plates as mirrors reflect rays, and the other makes the parallel plates as beam splitters to simultaneously reflect and refract rays. A transparent polymeric material is overlaid on the surface of the transparent substrate till the parallel plates are immersed. Then, an An objective lens, placed over a photo detector, is formed on the surface of the transparent polymeric material.

Abstract: A microfluidic device has a plurality of H-shaped micro channels not connected to each other and formed on a substrate. Each of the H-shaped micro channels comprises two main channels separately placed on two opposite sides in parallel and a plurality of sub-channels perpendicularly connected to the two main channels. The present invention is designed in such a way that various reagents dropped into different H-shaped micro channels are immobilized on respective sub-channels because of the different widths of the main channel and sub-channel. Afterwards the reagents are coated with a layer of polymer. The polymer has a porous structure that allows the passage of any sample to be tested. Finally, a plurality of upper channels parallel to one another are directly fabricated in the polymer, or in another layer of polymer stacked on the previous polymer.

Abstract: A fabrication method of three-dimensional microstructures is to fabricate a real 3D microstructure. First, a substrate is coated with an anti-reflection layer to absorb reflected exposure light, and then the anti-reflection layer is overlaid with a first thick photoresist. After having been fully exposed by a first photo mask, a predetermined exposure depth of the first thick photoresist is achieved by a second photo mask and dosage-controlled UV exposure. If the unexposed areas of the first thick photoresist are released during a development step, a single-layer microstructure is created. Inversely, a multi-layered microstructure can be obtained simply by repeating the process described above. After all layers are laminated on the substrate, all unexposed areas of the all thick photoresist layers are released and connected to each other during a development step.

Abstract: The present invention discloses a micro-stamp array supported on a substrate. The micro array includes an array of micro-stamp sticks substantially of a same stick length extending vertically from a surface of the substrate. In a preferred embodiment, each of the micro-stamp sticks further includes a micro-channel for depositing a liquid sample with pre-defined volume therein.

Abstract: An apparatus and method for forming a bubble within a microchannel of a microinjector to function as a valve mechanism between the chamber and manifold, that provides for a high resistance to liquid exiting the chamber through the manifold during fluid ejection through an orifice and that also provides a low resistance to refilling of liquid into the chamber after ejection of fluid and collapse of the bubble. This effectively minimizes cross talk between adjacent chambers and increases injection frequency of the microinjector. The formation of a second bubble within the chamber coalesces with a first formed bubble between the chamber and manifold to abruptly terminate the ejection of fluid, thereby eliminating satellite droplets.

Abstract: An apparatus and method for forming a bubble within a microchannel of a microinjector to function as a valve mechanism between the chamber and manifold, that provides for a high resistance to liquid exiting the chamber through the manifold during fluid ejection through an orifice and that also provides a low resistance to refilling of liquid into the chamber after ejection of fluid and collapse of the bubble. This effectively minimizes cross talk between adjacent chambers and increases injection frequency of the microinjector. The formation of a second bubble within the chamber coalesces with a first formed bubble between the chamber and manifold to abruptly terminate the ejection of fluid, thereby eliminating satellite droplets.