The present disclosure relates to a semiconductor device and a cell potential measuring apparatus capable of amplifying and reading a potential of solution with high accuracy. A reading electrode reads the potential of the solution. A differential amplifier includes a current mirror circuit. The reading electrode is connected to a first input terminal of the differential amplifier which is connected to a gate of a first input transistor connected to a diode-connected pMOS transistor of the current mirror circuit. An output terminal of the differential amplifier is connected to a second input terminal of the differential amplifier, which is connected to a gate of a second input transistor connected to a pMOS transistor of the current mirror circuit which is not diode-connected, via a capacitor. For example, the present disclosure is applied to the cell potential measuring apparatus and the like.

The effectiveness and efficiency of wastewater treatments is computed on a real-time basis

The present invention relates to a bio-electrode for current measurement including silicon carbide (SiC) doped at least partially with nitrogen (N). The bio-electrode for current measurement according to an embodiment of the present invention is a bio-electrode for a current measurement which is contact with an object to be analyzed, which generates a current signal by an electrochemical reaction, and includes silicon carbide (SiC) doped at least partially with nitrogen (N). The electrode may be used in a high-sensitive bio-quantification kit, a high-sensitive bio-quantification device, and an immunoassay device.

Embodiments described herein relate generally to compositions that include a synthetic redox-active receptor, and in particular to compositions that include a boronic acid based synthetic redox-active receptor which can electrochemically sense a target analyte in a sample solution. In some embodiments, a synthetic redox-active receptor can have a composition of formula I:

##STR00001##

wherein the variables L, R, R, n and X.sup. are described herein.

An electronic component includes a field effect transistor that functions as a working electrode of an ion sensor and a driving circuit that causes a potential difference between a source electrode and a drain electrode of the field effect transistor. A reference electrode potential of the field effect transistor is fixed.

A method for determining a narcotic in a mixture comprising at least one interferant. The method comprises: (a) determining a voltage at which, in absence of the interferant, a voltammetric signal of the narcotic can be detected; (b) contacting an electrode with the mixture comprising the at least one interferant and potentially comprising the narcotic; (c) applying a pretreatment potential to the electrode for a duration of at least 5 seconds, the pretreatment potential measuring between 0.4 V and 2 V versus Ag/AgCl; (d) measuring a voltammetric response of the mixture, the measurement comprising at least the determined voltage; and (e) determining whether the narcotic is present in the mixture by analyzing whether the voltammetric signal of the narcotic, resolved from a voltammetric signal of the interferant, can be detected in the measured voltammetric response.

A method for determining a narcotic in a mixture comprising at least one interferant. The method comprises: (a) determining a voltage at which, in absence of the interferant, a voltammetric signal of the narcotic can be detected; (b) contacting an electrode with the mixture comprising the at least one interferant and potentially comprising the narcotic; (c) applying a pretreatment potential to the electrode for a duration of at least 5 seconds, the pretreatment potential measuring between 0.4 V and 2 V versus Ag/AgCl; (d) measuring a voltammetric response of the mixture, the measurement comprising at least the determined voltage; and (e) determining whether the narcotic is present in the mixture by analyzing whether the voltammetric signal of the narcotic, resolved from a voltammetric signal of the interferant, can be detected in the measured voltammetric response.

A liquid analyzer is one that performs analysis in a state of being immersed in a flowing analysis target liquid, and in order to simply make a good/bad determination and increase reliability, includes: a sensor adapted to, in a state where a responsive membrane is immersed in the flowing analysis target liquid, sense a predetermined component contained in the analysis target liquid; an analysis mechanism adapted to analyze the analysis target liquid with use of voltage generated in the sensor; and a resistance measurement mechanism adapted to, in the state where the responsive membrane is immersed in the flowing analysis target liquid, apply DC voltage to the responsive membrane to measure the resistance of the responsive membrane.

Embodiments described herein relate generally to compositions that include a synthetic redox-active receptor, and in particular to compositions that include a boronic acid based synthetic redox-active receptor which can electrochemically sense a target analyte in a sample solution. In some embodiments, a synthetic redox-active receptor can have a composition of formula I: ##STR00001##
wherein the variables L, L, R, R, n and X.sup. are described herein.

A continuous monitoring device for detecting defects in a section of piping and a monitoring system that includes at least two monitoring devices. The monitoring device includes injection means that are capable of generating an electric current at a first end of the section of piping, at least one withdrawal point at the second end of the section of piping, allowing the injected current to be removed via grounding, and a control housing with means for measuring at least one component of the current received by the withdrawal point and analysis means for detecting, on the basis of the measurements obtained by the measurement means, a variation in the received component corresponding to a type of defect in the piping.