Embodiments of the present invention provide a portable bioelectrochemical electrical signal measuring device that may have at least one anode, at least one cathode, an anode-cathode connector between said at least one anode and said at least one cathode, a load connector between a load and said at least one anode and at least one cathode, and a data meter connected to said load connector wherein the device may measure an electrical signal of a matrix to perhaps determine the microbial activity in the matrix.

An all-electronic high-throughput detection system can perform multiple detections of one or more analyte in parallel. The detection system is modular, and can be easily integrated with existing microtiter plate technologies, automated test equipments and lab workflows (e.g., sample handling/distribution systems). The detection system includes multiple sensing modules that can perform separate analyte detection. A sensing module includes a platform configured to couple to a sample well. The sensing module also includes a sensor coupled to the platform. The sensing module further includes a first electrode coupled to the platform. The first electrode is configured to electrically connect with the sensor via a feedback circuit. The feedback circuit is configured to provide a feedback signal via the first electrode to a sample received in the sample well, the feedback signal based on a potential of the received sample detected via a second electrode.

A method of operating a gas detection device including a capillary-limited, electrochemical gas sensor includes operating the gas sensor in a sensing mode during which a signal from the gas sensor is representative of a concentration of the analyte gas measured by the gas sensor and in an interrogation mode during which the gas sensor is electronically interrogated by applying an electric signal to the gas sensor to generate a non-faradaic current flow between a working electrode and a counter electrode without the application of a test gas, periodically entering the interrogation mode, measuring a parameter of a gas sensor output during the interrogation mode, comparing the measured parameter to one or more previously measured parameters, determining an operational state from the comparison, and returning the gas sensor to the sensing mode if the operational state is determined to be within a predetermined range.

An embodiment provides an electrochemistry sensor, comprising; a sensor housing; an electrode, wherein the electrode is located within the sensor housing and is located within an orifice at the end of the sensor housing, thereby being exposed to outside the sensor housing and held within the sensor housing; and a rod coupled to an electrical connector, the rod being at least partially housed within the sensor housing, wherein the electrical connector contacts the electrode. Other aspects are described and claimed.

A combination pH sensor includes: a pH sensing composite electrode comprising a sample contact part and having metal oxide dispersed in the matrix material; a reference electrode; a wick of which one side is located on the same surface as the sample contact part of the pH sensing electrode and the other side is electrochemically connected to at least a part of the reference electrode through an electrolyte solution, and through which the electrolyte solution can move from the one side to the other side; and a sensing part including the sample contact part and a sample contact part of the wick located on the same surface as the sample contact part.

Embodiments of the present invention provide a portable bioelectrochemical electrical signal measuring device that may have at least one anode, at least one cathode, an anode-cathode connector between said at least one anode and said at least one cathode, a load connector between a load and said at least one anode and at least one cathode, and a data meter connected to said load connector wherein the device may measure an electrical signal of a matrix to perhaps determine the microbial activity in the matrix.

The present invention relates to an electroanalytical instrument for determining by amperometry (eg chronoamperometry) the presence or quantity (eg concentration) of an analyte in an aqueous sample, comprising a sealed housing, an elongate pivotal arm mounted on the sealed housing, wherein the elongate pivotal arm houses a potentiostat, and a pivotal forearm joined pivotally to the elongate pivotal arm, which is connectable to an electrochemical sensor. By flexing the pivotal forearm, the electrochemical sensor may be electrically connected to the potentiostat. By flexing the elongate pivotal arm, the electrochemical sensor is immersed in the aqueous sample in the sealed housing.

A sensor interface for interfacing with a sensor such as an electrochemical sensor, a temperature sensor or the like in which the interface comprises a memory configured to store data received at the interface from a sensor. The sensor interface is configured to assess the difference between data values in the memory, and to transmit advertising packets at a rate dependent on the difference between the values. The sensor interface includes a volatile memory and a non-volatile memory. The volatile memory is configured to store data received at the sensor interface from a sensor. The non-volatile memory is configured to store data stored in the volatile memory. The sensor interface is configured such that: data received at the sensor is stored in the volatile memory forming stored data until the volatile memory is substantially full and then at least some of the stored data is transferred to the non-volatile memory.

A sensing electrode, and an electrochemical system and method utilizing same for detecting peroxide-containing compounds in a sample, are provided. The sensing electrode is a carbon electrode having ions of a metal that promotes decomposition of a peroxide absorbed to its surface, optionally along with a solid electrolyte membrane.

The present disclosure relates to a sensor arrangement for use in process automation, having a sensor, comprising a first coupling body, having at least one sensor element for detecting a measurement value of the process automation, and a first interface for transmitting a signal dependent upon the measurement value, a connection element for transmitting the signal to a superordinate unit, comprising a second coupling body complementary to the first coupling body, having a second interface complementary to the first interface, wherein the first and second interfaces are designed for bi-directional communication between sensor and superordinate unit, where the sensor has at least one light source for transducing the signal dependent upon the measurement value into light of a color corresponding to the measurement value.