Taku Nishijo

LSI-based amperometric sensor for real-time monitoring of embryoid bodies

A large scale integration (LSI)-based amperometric sensor is used for electrochemical evaluation and real-time monitoring of the alkaline phosphatase (ALP) activity of mouse embryoid bodies (EBs). EBs were prepared by the hanging drop culture of embryonic stem (ES) cells. The ALP activity of EBs with various sizes was electrochemically detected at 400 measurement points on a Bio-LSI chip. The electrochemical measurements revealed that the relative ALP activity was low for large EBs and decreased with progress of the differentiation level of the ES cells. The ALP activity of the EBs was successfully monitored in real time for 3.5h, and their ALP activity in a glucose-free buffer decreased after 2h. To the best of our knowledge, this is the first report on the application of an LSI-based amperometric sensor for real-time cell monitoring over 3h. The chip is expected to be useful for the evaluation of cell activities.

Densified electrochemical sensors based on local redox cycling between vertically separated electrodes in substrate generation/chip collection and extended feedback modes.

A new local redox cycling-based electrochemical (LRC-EC) device integrated with many electrochemical sensors has been developed into a small chip device. The LRC-EC chip device was successfully applied for detection of alkaline phosphatase and horseradish peroxidase activity in substrate generation/chip collection (SG/CC) and extended feedback modes, respectively. The new imaging approach with extended feedback mode was particularly effective for sharpening of the image, because this mode uses feedback signals and minimizes the undesired influence of diffusion. The LRC-EC chip device is considered to be a useful tool for bioanalysis.

Noninvasive Measurement of Alkaline Phosphatase Activity in Embryoid Bodies and Coculture Spheroids with Scanning Electrochemical Microscopy

Alkaline phosphatase (ALP) is an enzyme commonly used as an undifferentiated marker of embryonic stem cells (ESCs). Although noninvasive ALP detection has long been desired for stem cell research and in cell transplantation therapy, little progress has been made in developing such techniques. In this study, we propose a noninvasive evaluation method for detecting ALP activity in mouse embryoid bodies (mEBs) using scanning electrochemical microscopy (SECM). SECM has several advantages, including being noninvasive, nonlabeled, quantitative, and highly sensitive. First, we found that SECM-based ALP evaluation permits the comparison of ALP activity among mEBs of different sizes by monitoring the p-aminophenol (PAP) production rate in aqueous solution containing p-aminophenylphosphate (PAPP) normal to the surface area of each sample. Second, coculture spheroids, consisting of mEB and MCF-7 cells for the core and the concentric outer layer, respectively, were prepared as model samples showing heterogeneous ALP activities. The overall PAP production rate dramatically declined in the presence of the MCF-7 cell outer layer, which blocked the mass transfer of PAPP to inner mEB. This result indicated that the SECM response mainly originated from ALP located at the surface of the cellular aggregate, including mEBs and coculture spheroids. Third, taking advantage of the noninvasive nature of SECM, we examined the relevance of ALP activity and cardiomyocyte differentiation. Collectively, these results suggested that noninvasive SECM-based ALP activity normalized by the sample surface enables the selection of EBs with a higher potential to differentiate into cardiomyocytes, which can contribute toward various types of stem cell research.

Comprehensive electrochemical imaging with local redox cycling-based electrochemical chip device for evaluation of three-dimensional culture cells

In this study, we have developed a novel electrochemical detection system containing many electrochemical sensors. The detection system is based on local redox cycling to incorporate many electrochemical sensors into small chip device. The density of the electrochemical sensors is the highest in the field of the electrochemical lab-on-a-chip devices. By using the chip device, comprehensive electrochemical imaging can be achieved. In this study, the chip device was applied for cell analysis of three-dimensional culture cells.