Abstract: An electrochemical sensor measuring concentration of an analyte in a test fluid at 50° C. or above by voltammetry uses electrodes in contact with an electrolyte containing the analyte and a redox-active species electrochemically convertible between reduced and oxidised forms. At least one form of the redox active species is present within surfactant micelles. The surfactant micelles enhance thermal stability of the redox active species and may also solubilise a species with poor water solubility, such as t-butylferrocene. A downhole tool incorporating such a sensor comprises a barrier, permeable to the analyte, to separate the electrolyte from subterranean reservoir fluid, so that the sensor directly measures analyte which has passed through the barrier and thereby indirectly measures analyte in the test fluid.

Abstract: An analysis device for analysis of a sample on a test element is provided that comprises at least one component configured to make electrical contact with at least one other component for electrical transmission therebetween. The at least one component generally comprises an injection-molded circuit mount, also called an MID, or molded interconnect device.

Abstract: The present invention is generally directed to devices and methods for sensing a variety of biologically-related substances and/or chemical substances. In a device aspect, the present invention is directed to a multilayer device for sensing metal ions, non-biological molecules, biological molecules, or whole cells. In a method aspect, the present invention is directed to a method for sensing species such as ions, protons, metal ions, non-biological molecules, whole cells, and biological molecules, for example one or more biologically-related substances such as proteins, nucleic acids, DNA, RNA, enzymes, and chemical substances such as water contaminants.

Abstract: Fluid analyte sensors include a photoelectrocatalytic element that is configured to be exposed to the fluid, if present, and to respond to photoelectrocatalysis of at least one analyte in the fluid that occurs in response to impingement of optical radiation upon the photoelectrocatalytic element. A semiconductor light emitting source is also provided that is configured to impinge the optical radiation upon the photoelectrocatalytic element. Related solid state devices and sensing methods are also described.

Abstract: Synthesis of gold microtubes and nanotubes suspendable in solution is presented. The synthesis is accomplished using an AAO template route, wherein a polymer tube is used as a sacrificial core. The synthesis produces hollow structures that consist of only gold. These nanostructures exhibit two SPR modes, which correspond to both the transverse and longitudinal modes. The mode assignment was confirmed by measuring SPR behavior as both aligned arrays and in solution. The performance of gold nanotubes as refractive index detectors was quantified and determined to be more sensitive than analogous solid nanorods prepared under identical conditions, and are among the most sensitive nanostructured plasmon sensors to date. Due to their intense and sensitive resonances in the NIR spectrum, these solution-suspendable nanoparticles have potential to be used as in vitro or in vivo sensors.

Abstract: A dynamic and noninvasive method of monitoring the adhesion and proliferation of biological cells through multimode operation (acoustic and optical) using a ZnO nanostructure-modified quartz crystal microbalance (ZnOnano-QCM) biosensor is disclosed.

Abstract: The present invention is related to an electrochemical processor, which comprises two electrodes of different electrochemical potential, which are bridged via an electrolyte. Upon, completion of the electric circuit between the two electrodes, the second electrode is oxidized and therefore changed in at least one physical parameter, e.g. the second electrode becomes transparent. The electrochemical processor is characterized in that the surface of the second electrode, which is in contact with the electrolyte, is partially covered with an electrically insulating material, wherein this material is adjacent to the electrolyte. Moreover, the present invention relates to the use of this electrochemical processor and a method of composing such electrochemical processor.

Abstract: An apparatus, a control unit and a method are provided for detecting a concentration of chlorate-ions in an aqueous solution containing different types of chlorine oxidants. By applying energy to a defined volume of the aqueous solution to trigger a transformation of substantially all chlorine oxidants and/or chlorine therein to chloride and/or chlorate, and detecting the concentration of chlorate-ions contained in the defined volume, a solution can be provided that enables a simple and cheap measurement for a concentration of chlorate ions in an aqueous solution and that is capable for online measurement of such chlorate concentrations.

Abstract: A method and apparatus for pretreatment of a desired sample in a discrete fluid analyzing instrument comprises automated means for handling and analyzing the sample and means for performing a pretreatment step on the sample or a sub-sample of the sample. The means for pretreatment are used for immobilizing at least one substance or analyte from the sample or sub-sample wherein the substance or analyte is reversibly immobilized. Usually, the apparatus further comprises means for eluting the substance or analyte from the capture means prior to analysis.

Abstract: A new scanning electrochemical microscopy tip positioning method that allows topography and surface activity to be resolved independently is presented. A SECM tip is oscillated relative to the surface of interest. Changes in the oscillation amplitude, caused by the intermittent contact of the SECM tip with the surface of interest, are used to detect the surface of interest, and as a feedback signal for various types of imaging.

Abstract: Material transfer/interrogation devices (e.g. liquid handling workstations) have been designed in the past for transferring material from a source to a destination location or for interrogating a material at a location, where the locations remain fixed. The invention provides methods and apparatuses for transferring or interrogating materials by one or more carrier devices to one or more receiving devices, where the carrier and receiving devices move independently and simultaneously on multiple axes. In some embodiments, one or more of the carrier and receiving devices can move along an X, Z, Y, and Theta axis, which allows the source and destination locations to rotate and translate relative to each other. Due to this rotation and translation, containers can be positioned to minimize the distance traveled between a pick location from the source and a place location on the destination, greatly increasing the speed at which material transfer can occur.

Abstract: A wireless sensor unit and a maintenance method. The sensor unit includes a sensor capable of forming a measurement signal, electronics capable of receiving a measurement signal from the sensor and sending the signal wirelessly to a wireless network, and a power supply for providing supply voltage for the sensor and electronics. The unit is divided into two parts, a first part and a second part such that the first part includes the electronics and is may be mounted permanently to a fixed object like a wall, and second part including the power supply and the sensor. The second part is capable to be repeatedly mounted and detached to the first part.

Abstract: A tool for a sensor includes a first portion having an elongated channel that extends therealong for accommodating the sensor, and a second portion with an end slot that accommodates an end portion of the sensor, the sensor having one or more wire electrodes embedded between two substrates. One or both of the substrates has transaxial scoring for facilitating the snapping off of segments to expose a clean portions of the wire electrodes. One or both of the tool portions has a rounded end portion. The end slot of the second portion is dimensioned to correspond to an axial dimension of a segment that is to be snapped off from the sensor. The first tool portion has a shoulder and handle portions, the shoulder portion having a greater thickness than the handle portion, and the handle portion having a thickness that is less than the width of the sensor.

Abstract: The present invention relates to a sampling plate. In particular the invention relates to a sampling plate for measuring certain selected properties of a liquid sample, such as the glucose levels in a blood sample. Sampling plates of the present invention have a sample zone (20) for receiving a liquid sample which is surrounded by an air porous body (4). The air porous body (4) acts to receive air from the sample zone (20) as it is displaced by an incoming liquid sample, thereby allowing efficient spreading of the liquid sample.

Abstract: A measuring device is configured to measure a reaction of test objects suspended in a first liquid. The measuring device includes a base and a vibration generator. The base has a first cavity and second cavities provided therein. The first cavity is configured to store the first liquid. The vibration generator generates a standing wave in the first liquid stored in the first cavity. The base has through-holes provided therein. Each of the through-holes allows respective one of the second cavities to communicate with the first cavity. The through-holes have opening sections. The opening sections open to the first cavity and are configured to capture the test objects. This measuring device can measure a test objects with a high efficiency.

Abstract: Electrochemical sensors measure an amount or concentration of CO2, typically using catalysts that include at least one catalytically active element and one helper catalyst. The catalysts can be used to increase the rate, modify the selectivity or lower the overpotential of chemical reactions. These catalysts are useful for a variety of chemical reactions including electrochemical conversion of CO2. Chemical processes and devices employing the catalysts are also disclosed, including processes that produce CO, OH?, HCO?, H2CO, (HCO2)?, H2CO2, CH3OH, CH4, C2H4, CH3CH2OH, CH3COO?, CH3COOH, C2H6, O2, H2, (COOH)2, and (COO?)2.

Abstract: A sensor chip is a sensor device for measuring a property of a substance by adsorbing the substance on a surface of the sensor chip. The sensor chip includes a diaphragm having a first surface, a second surface, and at least one through hole penetrating from the first surface to the second surface. At least a part of the first surface, the second surface, and an inner wall surface of the through hole is covered with a noncrystalline solid layer including SiOX as a main component, in which substance X is an element having higher electronegativity than that of silicon.

Abstract: The present invention provides fluidic testing devices with fluidic flow channels for processing fluid samples.

Abstract: A simple and low cost device to detect the presence of mercury or other trace metals in the environment and quantify said concentration by spectrophotometric, colorimetric, or electrical conductivity is disclosed. Owing to its small size, it is suitable for portable mercury detectors or detectors that may be worn as badges in the breathing zone of workers.

Abstract: A layered electrocatalyst for oxidizing ammonia, ethanol, or combinations thereof, comprising: a carbon support integrated with a conductive metal; at least one first metal plating layer at least partially deposited on the carbon support, wherein the at least one first metal plating layer is active to OH adsorption and inactive to a target species, and wherein the at least one first metal plating layer has a thickness ranging from 10 nanometers to 10 microns; and at least one second metal plating layer at least partially deposited on the at least one first metal plating layer, wherein the at least one second metal plating layer is active to the target species, and wherein the at least one second metal plating layer has a thickness ranging from 10 nanometers to 10 microns, forming a layered electrocatalyst.

Abstract: A detection device that is used to detect a sample includes: a base component having on its surface a sample supply position to which the sample is supplied; an electrode system formed at a distance from the sample supply position on the surface of the base component; a sliding component having a slide body that performs a sliding movement over the surface of the base component, a sample receptacle portion provided in a portion of the slide body; and a supporting portion that is fixed to the base component and supports the sliding component such that it can perform the sliding movement relative to the base component. The base and the sliding components can perform the sliding movement within a range that includes an overlap position, where the sample receptacle portion overlaps with the electrode system, and the sample supply position.

Abstract: A system for in situ monitoring within a specified environment includes a housing with an intake inserted into the environment. A plurality of pumps are included in the housing with a number of test beds, each being separately coupled to one of the number of pumps, where each of the number of test beds holds material and where each of the plurality of pumps operate to separately push fluid through a coupled test bed. An effluent storage device is disposed to receive effluent from the number of test beds.

Abstract: A method and apparatus measures the presence of total residual oxidant species in aqueous environments. More specifically, the apparatus is operable to measure hypohalites (e.g., hypochlorite and hypobromite) in water containing halide salts using electrochemistry. The apparatus can be a sensor having four electrodes—a reference electrode, a working electrode, and two auxiliary electrodes. The fourth electrode, i.e., the second auxiliary electrode, can be used to generate ionized water near and in contact with the working electrode. The ionized water can clean the working electrode to minimize effects due to scaling or biofilm formation. As such, the working electrode does not need the capability to clean itself. Thus, other elements, originally believed to be unsuitable for use in saline aqueous environments, can be used for the electrodes, for example, gold.

Abstract: Methods and systems for measuring the oxidation-reduction potential of a fluid sample are provided. The system includes a test strip with a sample chamber adapted to receive a fluid sample. The sample chamber can be associated with a filter membrane. The test strip also includes a reference cell. The oxidation-reduction potential of a fluid sample placed in the sample chamber can be read by a readout device interconnected to a test lead that is in electrical contact with the sample chamber, and a reference lead that is in electrical contact with the reference cell. Electrical contact between a fluid sample placed in the sample chamber and the reference cell can be established by a bridge. The oxidation-reduction potential may be read as an electrical potential between the test lead and the reference lead of the test strip.

Abstract: Electrochemical test cells are made with precision and accuracy by adhering an electrically resistive sheet having a bound opening to a first electrically conductive sheet. A notching opening is then punched through the electrically resistive sheet and the first electrically conductive sheet. The notching opening intersects the first bound opening in the electrically resistive sheet, and transforms the first bound opening into a notch in the electrically resistive sheet. A second electrically conductive sheet is punched to have a notching opening corresponding to that of first electrically conductive sheet, and this is adhered to the other side of the electrically resistive sheet such that the notching openings are aligned. This structure is cleaved from surrounding material to form an electrochemical cell that has a sample space for receiving a sample defined by the first and second conductive sheets and the notch in the electrically resistive sheet.

Abstract: A three-dimensionally ordered macroporous sensor apparatus and method of forming the same. A direct opal film associated with a number of pores can be formed by vertical deposition of one or more nanospheres on a glass substrate. The thickness of the direct opal film can be controlled by concentration of the nanospheres. A mixture of a precursor/monomer of a sensing material and a complexing agent can be filled into the pores associated with the direct opal film, such that the mixture permeates the interstitial spaces between the pores. The nanospheres may then be removed in order to form a three dimensionally-ordered macroporous electrode with an inverse opal structure. Optionally, the sensing material can be coated on an inverse opal backbone structure formed from an external inactive material and utilizing a coating operation.

Abstract: The present invention allows simple and sensitive detection of microimpurities, microdefects, and corrosion starting points which may be present in a material. A probe microscope has a function to sense ions diffused from a specimen in a liquid. A probe is caused to scan over a predetermined range on a specimen. Then, the probe is fixed to a particular position in a liquid so as to set the distance between the specimen and the probe to a given value at which the microstructure of the specimen surface cannot be observed. Thereafter, one of the current between the probe and a counter electrode and the potential between the probe and a reference electrode is controlled, and the other of the current and potential which varies in accordance with the control is measured. Thus, ions diffused from the specimen are sensed.

Abstract: Electrochemical sensors for investigating a physiological sample and methods of manufacture are disclosed. The sensor includes a longitudinally extending reaction cell, having electrodes and a reagent, and laterally spaced electrical contact points for electrically communication with a meter. An array of such sensors is further disclosed including connective flaps for joining adjacent sensors. In use, the array of sensors can be stored in a folded configuration and dispensed individually.

Abstract: A cellular electrophysiological measurement device includes a thin plate and a frame. The thin plate has a first surface with a depression and a second surface with a through-hole. The frame is in contact with an outer periphery on the second surface of thin plate. The thin plate has a laminated structure of at least two layers including a first material layer on the first surface and a second material layer on the second surface. The frame is formed of a third material layer. The structure allows the cellular electrophysiological measurement device to be not so vulnerable to breakage of thin plate and other damages, thereby having high production yield.

Abstract: The present invention relates to improved electrochemical biosensor strips and methods for determining the concentration of an analyte in a sample. By selectively measuring a measurable species residing in a diffusion barrier layer, to the substantial exclusion of the measurable species residing exterior to the diffusion barrier layer, measurement errors introduced by sample constituents, such as red blood cells, and manufacturing variances may be reduced.

Abstract: The present invention relates to devices, systems, and methods for determination of ionizing radiation. In some embodiments, the devices comprise nanocomposite materials containing nanostructures (e.g., carbon nanotubes) dispersed in radiation sensitive polymers. In some cases, the device may include a conductive pathway that may be affected upon exposure to ionizing radiation. Embodiments described herein may provide inexpensive, large area, low power, and highly sensitive radiation detection materials/devices.

Abstract: Electrochemical transducer arrays are already known from the prior art. According to the invention, the transducer array is provided with at least one flexible, planar metal substrate on which at least one flexible insulator having a firm connection between the metal surface and the insulator surface is disposed. The metal substrate and the insulator disposed thereon are structured in such a manner as to give metal areas which are electrically insulated the one from the other and which serve as sensor areas. The metal substrate used is self-contained so that the structured metal areas can be contacted from the lower side.

Abstract: Methods and systems for screening for the effect of bath composition on the performance of electroplating, electroless-plating, electrochemical-etching, electropolishing, and chemical-etching processes are provided. The methods and systems use microfluidic channels that allow for etching or plating studies on an electrode exposed to a multitude of bath compositions at different positions on its surface. After deposition or etching, the electrode surface can be quickly and easily detached from the device for analysis of deposited or etched film properties.

Abstract: Provided herein is technology relating to testing biological samples and particularly, but not exclusively, to devices, systems, and kits for performing multiple, simultaneous real-time assays on a sample in a single-use disposable format. For example, the technology relates to an apparatus that finds use, for example, for point-of-care diagnostics, including use at accident sites, emergency rooms, in surgery, in intensive care units, as well as for non-medical applications.

Abstract: A sensor arrangement has first and second substrates arranged in juxtaposed relation to each other. A working electrode is interposed between the first and second substrates. At least one of the first and second substrates has transaxial scoring for facilitating the snapping off of segments of the first and second substrates to expose a clean portion of the working electrode. A further electrode, which may be a silver deposition, is disposed on the first substrate. A still further electrode, which may be a gold deposition, is disposed on the second substrate. The working electrode is a wire disposed axially in relation to the first and second substrates. The wire is formed of gold, indium, glassy carbon, copper, silver, or the like, and any of these can be used alone or as an amalgam with mercury. The working electrode may be printed or deposited on at least one of the substrates.

Abstract: Provided is an electrochemical sensor device capable of micromachining a channel while maintaining its measurement sensitivity and of reliably quantitating an analyte in a trace amount of a sample. An electrochemical sensor device includes: a channel portion formed in a substrate; and working electrodes for subjecting an analyte in a solution flowing in the channel portion to electrochemical measurement, the electrochemical sensor device includes a plurality of measuring portions individually provided with the working electrodes, and each of the working electrodes has a plurality of conductive protrusion portions formed to protrude from a bottom surface of each of the measuring portions.

Abstract: Systems and methods are provided herein for improving the selectivity and productivity of sensors via digital signal processing techniques. According to one illustrative embodiment, in an electrochemical method for monitoring of a select analyte in a mixed sample with an interfering analyte, an improvement is provided that includes applying a large amplitude potential stimulus waveform to the sample to generate a nonlinear current signal; and resolving a signal contribution from the select analyte in the generated signal by a vector projection method with an analyte vector comprising a plurality of real and imaginary parts of one or more Fourier coefficients at one or more frequencies of a reference current signal for the select analyte.

Abstract: The present invention relates to a method for producing a miniaturized separation column for chromatographic purposes including a porous stationary phase anchored in the column, including the following steps: (a) preparing a fiat substrate of silicon, glass, glass ceramic or ceramic; (b) etching at least one channel structure into the fiat substrate; (c) introducing a non-porous precursor material for the porous stationary phase into at least one portion of the channel structure(s); (d) forming a porous, three-dimensional network from the precursor material; and (e) fluid-tight covering of the channel structure(s) on the top side of the flat substrate.

Abstract: An analysis device is disclosed which includes an electron detection medium to obtain information needed for analyzing an analyte in correlation with an electron transfer level, and a reagent part which is disposed on the electron detection medium and includes an electron transporting substance to transport electrons between the analyte and the electron detection medium, the electron transporting substance including a water-soluble aromatic heterocycle compound, and being free of a metal complex. An analysis method using the analysis device is also disclosed.

Abstract: An amperometric sensor includes a first electrode, a second electrode and a reference electrode. The sensor further includes a switch to selectably electrically connect the first electrode as a working electrode and to electrically connecting the second electrode as an auxiliary electrode during a first time interval. During a second time interval, the switch electrically connects the first electrode as the auxiliary electrode and electrically connects the second electrode as the working electrode. The switching of the two electrodes is repeated continuously as amperometric measurements are performed. Preferably, the sensor includes an ultrasonic transducer proximate the working electrode and the auxiliary electrode to clean the electrodes.

Abstract: Disclosed is a method and apparatus for detecting the concentration of a lipophilic analyte of interest in a complex sample matrix. The method comprises extracting the analyte of interest from said sample into an organic solvent comprising a dissolved electrolyte; providing a free radical species, preferably a free oxygen radical species, in said organic solvent; reacting the Canalyte of interest with said free radical species; and performing a measurement to detect the concentration of the free radical-reacted analyte reaction product.

Abstract: An electrochemical sensing apparatus and methods are provided. In one embodiment, an apparatus is provided having a carrier that supports an electrochemical module and that communicates between electrodes on the electrochemical module and an analyte measurement device.

Abstract: An electrochemical sensor for the presence or concentration of an analyte has at least one electrode and at least one electrochemically active species able to undergo electrochemical reaction in response to electrical potential applied to the electrode, where the said reaction is modified by the presence of the analyte. This sensor has the novel characteristic that at least one said electrochemically active species is encapsulated within polymer particles. These particles are preferably formed from an amorphous polymer with a glass transition temperature above the temperature of the fluid to which the sensor is exposed. The encapsulating polymer protects the analyte species from degradation, but a small analyte such as a hydrogen or bisulfide ion can pass through the polymer and undergo reaction at the active species.

Abstract: Carbon nanotubes are formed on projections on a substrate. A metal, such as nickel is deposited on the substrate with optional platforms, and heated to form the projections. Carbon nanotubes are formed from the projections by heating in an ethylene, methane or CO atmosphere. A heat sensor is also formed proximate the carbon nanotubes. When exposed to IR radiation, the heat sensor detects changes in temperature representative of the IR radiation. In a gas sensor, a thermally isolated area, such as a pixel is formed on a substrate with an integrated heater. A pair of conductors each have a portion adjacent a portion of the other conductor with projections formed on the adjacent portions of the conductors. Multiple carbon nanotubes are formed between the conductors from one projection to another. IV characteristics of the nanotubes are measured between the conductors in the presence of a gas to be detected.

Abstract: Apparatus and method for detecting current or potential generated in a liquid sample suitable for use in a chromatography or other liquid sample analytical system. One embodiment is an electrolytic ion transfer device with a signal detector in communication with the electrodes of the transfer device. Another is a combination ion transfer device/electrolyte generator. Another substitutes a detector for the ion transfer device in the combination.

Abstract: This invention has two synergistic elements for simultaneous use in point-of-care or field analyses of diverse substances important to clinical medicine and other applications. The first element is a sample holder in which are stored the several reagents need for quantification of target molecules. The onboard storage of reagents in a water soluble plastic obviates the need for purchase, storage, measuring and mixing of the required reagents prior to analyses. The second part of the invention is a compact hand-held analyzer made of modern miniature optical components, into which the holder is inserted right after it is loaded with a sample by capillary action. The combination of the holder and analyzer permits analyses that are ten times faster than those done with current analyzers, and equally accurate. Analyses can be performed by diverse people, who require only a few minutes of training in the use of the entire invention.

Abstract: Certain embodiments of the present application describe a carbon-based electrode with graphene platelets. The addition of graphene platelets is intended to improve properties of the electrode. These properties include, but are not limited to, physical, electrical, and biochemical properties of the electrode. Enhanced reproducibility of these properties can also result from the addition of the graphene platelets.

Abstract: The electrode assembly is provided with: a rod-like body 1 that extends along a predetermined axis ; a substrate that is formed with a through-hole penetrating between a front surface and a back surface and attached to a fore end part of the body; and a sensor chip for electrochemical measurement, which is attached on the back surface of the substrate such that a sensing part is exposed outside from the through-hole, wherein: on the back surface of the substrate, a wiring for obtaining an output signal from the ISFET chip is formed, and the sensor chip is attached to the wiring directly or closely; and the substrate is attached with being inclined with respect to the predetermined axis of the body, and thereby the front surface of the substrate forms at least a part of a fore end surface that is inclined with respect to the predetermined axis.

Abstract: An electrochemical system with reduced limiting-current behavior is disclosed. The electrochemical system is useful for fuel cells and bio-sensors. In part, the invention relates a method of reducing or eliminating limiting-current behavior in the operation electrochemical systems, in particular those with ion-selective membrane or electrochemical electrodes, by spatially reducing the convection near the membrane or the electrode. The invention further relates to electrochemical systems in which micropores, microarrays or pillar arrays are used to reduce convection in comparison to conventional systems without microarrays, micropores or pillar arrays.

Abstract: The present invention relates to an electrochemical cell comprising a vibratile electrode (eg a vibratile microelectrode).