Abstract: The present invention relates to a process for producing a microfluidic device which involves providing a substrate with a surface and writing a first flowable material on the surface of the substrate. The first flowable material is then solidified to form spacer elements, each with a top surface distal from the surface of the substrate, and a second flowable material is written on the surface of the substrate. A cover having a surface is provided and applied to the substrate, with the surface of the cover contacting the top surfaces of the spacer elements. The second flowable material is solidified to form walls, where the walls, the surface of the substrate, and the surface of the cover form flow channels of a microfluidic device. The resulting microfluidic device is also disclosed.

Abstract: The present invention is directed to a thick film patterned resistor on a substrate and to a method of forming it. The method involves providing a substrate with opposed surfaces, where one surface is coated with a layer of a resistor composition. A photoresist is applied over the layer of the resistor composition, and a desired pattern in the photoresist is formed, where the pattern leaves certain regions of the resistor composition layer uncovered by the photoresist. The resistor composition layer which is uncovered by the photoresist is etched under conditions effective to leave a mass of loosely bound resistor particles at regions of the resistor composition which are not covered by photoresist. The mass of resistor particles is then removed from the substrate to produce a thick film patterned resistor on the substrate.

Abstract: The present invention is directed to a thick film patterned resistor on a substrate and to a method of forming it. The method involves providing a substrate with opposed surfaces, where one surface is coated with a layer of a resistor composition. A photoresist is applied over the layer of the resistor composition, and a desired pattern in the photoresist is formed, where the pattern leaves certain regions of the resistor composition layer uncovered by the photoresist. The resistor composition layer which is uncovered by the photoresist is etched under conditions effective to leave a mass of loosely bound resistor particles at regions of the resistor composition which are not covered by photoresist. The mass of resistor particles is then removed from the substrate to produce a thick film patterned resistor on the substrate.

Abstract: The present invention relates to a process for producing a microfluidic device which involves providing a substrate with a surface and writing a first flowable material on the surface of the substrate. The first flowable material is then solidified to form spacer elements, each with a top surface distal from the surface of the substrate, and a second flowable material is written on the surface of the substrate. A cover having a surface is provided and applied to the substrate, with the surface of the cover contacting the top surfaces of the spacer elements. The second flowable material is solidified to form walls, where the walls, the surface of the substrate, and the surface of the cover form flow channels of a microfluidic device. The resulting microfluidic device is also disclosed.

Abstract: A method for making an inductor comprising writing a conductive coil comprising resistive material onto an outer surface of a substrate, and inductors made therewith is disclosed.