Yuji Maruo

Fully automated two-dimensional electrophoresis system for high-throughput protein analysis.

We developed a fully automated electrophoresis system for rapid and highly reproducible protein analysis. All the two-dimensional (2D) electrophoresis procedures including isoelectric focusing (IEF), on-part protein staining, sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), and in situ protein detection were automatically completed. The system comprised Peltiert devices, high-voltage generating devices, electrodes, and three disposable polymethylmethacrylate (PMMA) parts for IEF, reaction chambers, and SDS-PAGE. Because of miniaturization of the IEF part, rapid IEF was achieved in 30 min. A gel with a tapered edge gel on the SDS-PAGE part realized a connection between the parts without use of a gluing material. A biaxial conveyer was employed for the part relocation, sample introduction, and washing processes to realize a low-maintenance and cost-effective automation system. Performances of the system and a commercial minigel system were compared in terms of detected number, resolution, and reproducibility of the protein spots. The system achieved high-resolution comparable to the minigel system despite shorter focusing time and smaller part dimensions. The resulting reproducibility was better or comparable to the performance of the minigel system. Complete 2D separation was achieved within 1.5 h. The system is practical, portable, and has automation capabilities.

Document scanner using polymer waveguides with a microlens array

A document scanner using polymer waveguides with a microlens array was developed. The waveguide grooves and the microlenses were fabricated simultaneously by injection molding. The cores of the waveguides were formed by squeegeeing. The waveguides have multiple sharp bends to minify the image and also to reduce the size of the scanner. The microlens had a root-mean-square wavefront aberration of 0.06 λ(λ = 633 nm), and the waveguide had a transmission loss of less than 0.1 dB/cm at 633 nm. The optical system was designed to be telecentric so that the scanner had a depth of field greater than 6.0 mm (at 4 lp/mm).

A capillary holder for scanning detection of capillary isoelectric focusing with laser-induced fluorescence

A holder for a 12 cm long capillary was designed for scanning LIF detection of CIEF. The polyimide coat of a fused-silica capillary has been removed, and 1.5 mm diameter flanges have been attached near both ends. The holder is fixed on the stage of a fluorescence microscope via a translational stage, and a capillary guide is directly fixed on the microscope stage. The guide has a groove and a pressure plate for the capillary to slide in. The holder has two pulling plates with slits of 1 mm to accept the capillary just inside the flanges. The slits and the groove of the guide have been aligned. The motion of the translational stage brings the pulling plate into contact with the flange at the pulled side, and slides the capillary through the guide. The other end of the capillary is free and produces no strain on the capillary. When the motion of the stage is reversed, an unstrained contact is achieved at the other end. The baseline noise from scanning was only 50% larger than that without scanning. The fluorescence-signal variation during scanning was about 4% of the total signal, which was about twice that without scanning.