Development of microfluidic devices for on-site water quality testing using glass molding process.

The demand for multi-point water quality monitoring is increasing to solve the global problem of safe drinking water supply and environmental water contamination by industries. Therefore, compact devices are needed for on-site water quality analysis. On-site devices require low cost and high durability because they are placed outdoors, exposing them to strong ultraviolet rays and a wide range of temperatures.

Development of a Microfluidic System Comprising Dialysis and Secretion Components for a Bioassay of Renal Clearance.

We have developed a microfluidic bioassay system that mimics glomerular filtration and tubular secretion in the kidney. The system consists of a peristaltic micropump (heart), a dialysis component (renal corpuscle), and a secretion component (renal proximal tubule). Analytes were separated by size using a dialysis membrane in the dialysis component.

Development of a Multichannel Dialysis Microchip for Bioassay of Drug Efficacy and Retention.

Here, we developed a multichannel dialysis microchip having three sets of dialysis systems, which consisted of three independent circulation channels with a common micropump. Each dialysis system was composed of a pneumatic micropump (heart), dialysis unit (renal corpuscle), and cell culture chamber (drug target) as well as circulation and dialysate channels to mimic the circulation system. Small molecules were successfully separated in parallel from macromolecules at the dialysis components.