Improving the electrochemical imaging sensitivity of scanning electrochemical microscopy-scanning ion conductance microscopy by using electrochemical Pt deposition.

We fabricated a platinum-based double barrel probe for scanning electrochemical microscopy-scanning ion conductance microscopy (SECM-SICM) by electrodepositing platinum onto the carbon nanoelectrode of the double barrel probe. The deposition conditions were optimized to attain highly sensitive electrochemical measurements and imaging. Simultaneous SECM-SICM imaging of electrochemical features and noncontact topography by using the optimized probe afforded high-resolution images of epidermal growth factor receptors (EGFR) on the membrane surface of the A431 cells.

Noninvasively measuring respiratory activity of rat primary hepatocyte spheroids by scanning electrochemical microscopy.

Construction of an in vitro drug screening method for evaluating drug metabolism and toxicity by using cells is required instead of the conventional in vivo one that uses animals. In order to realize the in vitro study, analyzing the cellular activity or viability noninvasively in advance of the screening is essential. The aim of the current study is to establish a method that can evaluate the cellular activity depending on spheroid sizes by means of oxygen consumption and to determine the valid diameter of hepatocyte spheroids. To measure the respiratory activity of the spheroids, which were formed on a nanopillar sheet, we applied scanning electrochemical microscopy (SECM). From the viewpoint of high respiratory activity and its small variation, we determined that spheroids with 70 µm in diameter were adequate. We then performed a gene expression analysis by using a real-time PCR to evaluate the correlation with respiratory activity. As a result, a higher expression level of Hnf4α, which is essential for hepatocytes to fulfill many liver functions and is the indicator of well-differentiated hepatocytes, showed relatively higher respiratory activity. We concluded that the noninvasive SECM technique could evaluate the cellular activity of a single spheroid. Noninvasively measuring cellular activity by SECM makes it possible to evaluate the cellular activity prior to a nonclinical test and enables the continued monitoring of the drug response by using single spheroid. SECM becomes a powerful tool to satisfying the increasing demand for an in vitro system in the course of new drug development.

Noninvasive measurement of respiratory activity of mouse embryoid bodies and its correlation with mRNA levels of undifferentiation/differentiation markers.

Mouse embryoid bodies (mEBs) were evaluated in detail on the basis of respiratory activity and high-throughput quantitative reverse transcription-PCR (RT-qPCR) analysis. The hanging drop culture method was applied to prepare various sizes of mEBs ranging from 100 to 250 µm in radius by causing the aggregation of embryonic cells. The respiratory activity of individual mEBs was noninvasively measured using scanning electrochemical microscopy in a cone-shaped microwell. For gene expression analysis, we used 48.48 Dynamic Array chips (Fluidigm) integrating microfluidic circuits, which allowed high-throughput qPCR analysis in parallel. The respiratory activity of the mEBs that were cultured for 1 to 6 days could predict the mRNA levels of undifferentiation and differentiation markers. However, the sizes of the mEBs could also predict the gene expression of the undifferentiation/differentiation markers because the radii of the mEBs increased by more than 2-fold after incubation in hanging drop culture for 6 days. Next, mEBs with identical sample sizes were evaluated for respiratory activity and gene expression. For mEBs cultured at 1500 cells per droplet for 3 days, the respiratory activity was negatively correlated with the mRNA levels of pluripotent markers such as Nanog and Sox2. Many differentiation markers were positively correlated with the respiratory activity. However, there was no significant difference in respiration activity between the beating and nonbeating samples on day 3. Finally, principal component analysis (PCA) confirmed the relationship between respiratory activity and the mRNA levels of undifferentiation/differentiation markers.

Multiparameter analyses of three-dimensionally cultured tumor spheroids based on respiratory activity and comprehensive gene expression profiles.

Multicellular spheroids of human breast cancer cells (MCF-7) formed with two different three-dimensional (3D) culture methods were evaluated in detail on the basis of respiratory activity and high-throughput gene expression analysis. The spheroids formed with poly(dimethylsiloxane) (PDMS) microwell arrays indicated significant restriction of the spheroid size, whereas their respiratory activity was 2-fold greater than that formed with the hanging drop culture method. Fluidigm BioMark dynamic array was used for comprehensive and quantitative real-time polymerase chain reaction (qRT-PCR) analysis on the samples whose respiratory activity had been measured. Genes involved in cellular senescence and glucose metabolism indicated significantly higher values for the PDMS microwell culture method than for the hanging drop culture method (P<0.05). Interestingly, samples formed with the PDMS microwell culture method showed stronger responses for glycolysis than those formed with the hanging drop method. These results illustrate the power of multiparameter analysis to characterize multicellular spheroids cultured in different microenvironments even if they have the same morphology.

A Pt layer/Pt disk electrode configuration to evaluate respiration and alkaline phosphatase activities of mouse embryoid bodies.

A Pt layer/Pt disk electrode configuration was used as a scanning electrochemical microscopy (SECM) probe. The glass seal part of the insulator was covered with a Pt layer to form an exposed pseudo reference electrode. In a HEPES-based medium at pH 7.5, the half-wave potential (E(1/2)) for [Fe(CN)(6)](4-) oxidation and O(2) reduction measured versus the internal Pt pseudo reference was shifted by about -0.2V, compared with the E(1/2) measured versus the external Ag/AgCl reference electrode. The shape and the current of the cyclic voltammograms (CVs) did not change notably over time, indicating that the Pt layer is sufficiently stable to be used as an integrated pseudo reference for voltammetric measurements. To demonstrate the suitability for SECM applications, the Pt/Pt probe configuration was used for measuring the oxygen consumption and the alkaline phosphatase (ALP) activity of a single mouse embryoid body (mEB). Ten individual mEB samples were characterized to monitor the oxygen concentration profile. Oxygen reduction currents were monitored at -0.7 V versus the Pt pseudo reference and compared with those monitored at -0.5 V versus Ag/AgCl. The respiration rate of mEBs becomes greater with increasing cultivation dates. We have plotted the oxygen consumption rate (F(O(2))) of each mEB sample, measured versus the Pt layer and versus Ag/AgCl. The linearity of the plot was excellent (coefficient of determination R(2)=0.90). The slope of the least squares method was 1. In a 1.0mM p-aminophenylphospate (PAPP) HEPES buffer (pH 9.5) solution, APL activity of mEBs can be characterized, to monitor the p-aminophenol (PAP) oxidation current. ALP catalyzes the hydrolysis of PAPP to PAP. The E(1/2) for PAP oxidation measured versus the Pt layer was not shifted, compared with the E(1/2) versus Ag/AgCl. The mEB samples were characterized to monitor the PAP concentration profile. PAP oxidation currents were monitored at +0.3 V versus the Pt layer and compared with those monitored at +0.3 V versus Ag/AgCl. We have plotted the PAP production rate (F(PAP)) of each mEB sample, measured versus the Pt layer and versus Ag/AgCl. In this case, the linearity of the plot became slightly scattered, but it was found to be possible to evaluate ALP activities of mEB samples utilizing the Pt/Pt probe configuration. This type of probe is very useful because it is not necessary to insert a reference electrode into the measuring solution to obtain an electrical connection, and thus electrochemical measurement in a small volume becomes much easier.

Microfluidic devices for electrochemical measurement of photosynthetic activity of cyanobacteria microcystis cells.

A microfluidic device with analytical chambers for electrochemical measurements has been employed to detect photosynthetic activity at single cell level. The flowing cells (Microcystis viridis) in a main channel are individually guided to the chamber with microelectrodes by an electrophoretic manipulation. The reduction current of oxygen was continuously monitored to determine the photosynthetic activity upon light irradiation. The average rates for oxygen generation were estimated and found to be 10(-18) mol/s level.

Electrophoretic cell manipulation and electrochemical gene-function analysis based on a yeast two-hybrid system in a microfluidic device.

A novel microfluidic device with an array of analytical chambers was developed in order to perform single-cell-based gene-function analysis. A series of analytical processes was carried out using the device, including electrophoretic manipulation of single cells and electrochemical measurement of gene function. A poly(dimethylsiloxane) microstructure with a microfluidic channel (150 microm in width, 10 microm in height) and an analytical chamber (100 x 20 x 10 microm (3)) were fabricated and aligned on a glass substrate with an array of Au microelectrodes. Two microelectrodes positioned in the analytical chamber were employed as a working electrode for the electrophoretic manipulation of cells and electrochemical measurements. A yeast strain ( Saccharomyces cerevisiae Y190) carrying the beta-galactosidase reporter gene was used to demonstrate that the device could detect the enzyme. Target cells flowing through the main channel were introduced into the chamber by electrophoresis using the ground electrode laid on the main channel. When the cell was treated with 17beta-estradiol, gene expression was triggered to produce beta-galactosidase, catalyzing the hydrolysis of p-aminophenyl-beta- D-galactopyranoside to form p-aminophenol (PAP). The enzymatically generated PAP was detected by cyclic voltammetry and amperometry at the single-cell level in the chamber of the device. Generator-collector mode amperometry was also applied to amplify the current response originating from gene expression in the trapped single cells. After electrochemical measurement, the trapped cells were easily released from the chamber using electrophoretic force.