Detection and Analysis of Targeted Biological Cells by Electrophoretic Coulter Method.

Combining the electrophoresis and conventional Coulter methods, we previously proposed the electrophoretic Coulter method (ECM), enabling simultaneous analysis of the size, number, and zeta potential of individual specimens. We validated the ECM experimentally using standard polystyrene particles and red blood cells (RBCs) from sheep; the latter was the first ECM application to biological particles in biotechnology research. However, specimens are prevented from passing through the ECM module aperture, which prevents accurate determination of the zeta potential of each specimen. This problem is caused by electro-osmotic flow (EOF) due to the high zeta potential at the ECM microchannel surfaces. To significantly improve ECM feasibility for biomedicine, we here propose a method to estimate the zeta potential at the ECM microchannel surfaces separate from the zeta potential of each specimen, by investigating the electric-field dependence of the specimen's experimental electrophoretic velocity. We minimize the zeta potential at the microchannel surfaces by applying an organic-molecule coating, and we suppress the surface zeta potential and its resultant EOF by optimizing the microchannel geometry. We demonstrate that the ECM can distinguish between different biological cells using the differences in zeta potential values and/or sizes. We also demonstrate that the ECM can determine the number of biomolecules attached to individual cells and identify whether the average cell state in an analyzed vial is alive or dead. The high-performance ECM can detect cellular morphology alterations, improve immunologic test sensitivity, and identify cell states (living, dying, and dead); this information is clinically useful for early diagnosis and its follow-up.

Encouragement of Enzyme Reaction Utilizing Heat Generation from Ferromagnetic Particles Subjected to an AC Magnetic Field.

We propose a method of activating an enzyme utilizing heat generation from ferromagnetic particles under an ac magnetic field. We immobilize α-amylase on the surface of ferromagnetic particles and analyze its activity. We find that when α-amylase/ferromagnetic particle hybrids, that is, ferromagnetic particles, on which α-amylase molecules are immobilized, are subjected to an ac magnetic field, the particles generate heat and as a result, α-amylase on the particles is heated up and activated. We next prepare a solution, in which α-amylase/ferromagnetic particle hybrids and free, nonimmobilized chitinase are dispersed, and analyze their activities. We find that when the solution is subjected to an ac magnetic field, the activity of α-amylase immobilized on the particles increases, whereas that of free chitinase hardly changes; in other words, only α-amylase immobilized on the particles is selectively activated due to heat generation from the particles.

Label-free determination of the number of biomolecules attached to cells by measurement of the cell's electrophoretic mobility in a microchannel.

We developed a label-free method for a determination of the number of biomolecules attached to individual cells by measuring the electrophoretic mobility of the cells in a microchannel. The surface of a biological cell, which is dispersed in aqueous solution, is normally electrically charged and the charge quantity at the cell's surface is slightly changed once antibody molecules are attached to the cell, based on which we detect the attachment of antibody molecules to the surface of individual red blood cells by electrophoretic mobility measurement. We also analyzed the number of antibody molecules attached to the cell's surface using a flow cytometer. We found that there is a clear correlation between the number of antibody molecules attached to the individual cells and the electrophoretic mobility of the cells. The present technique may well be utilized not only in the field of cell biology but also in the medical and pharmaceutical industries.