An electrochemical biosensor based on magnetically coupled LC sensors for the rapid detection of microbial growth and sensitivity to microbials. The engineered LC sensors can be placed in 96 well plates and communicate the reading remotely with a receiver coil for signal analysis. The sensors were validated by testing the growth of Escherichia. coli, Staphylococcus. aureus, and Pseudomonas aeruginosa in the presence and absence of different antibiotics. Drug-resistant strains were used as controls. Bacterial growth was detected within 30 mins of culture inoculation, allowing rapid determination of antibiotic susceptibility at the phenotypic level. The pattern shown in the LC sensor AST is consistent with results collected with traditional optical density (OD) 600 nm measurement, additional validation was also performed with lysogeny broth (LB) dosed with fetal bovine serum (FBS). With the compatibility with 96-well plates, this rapid AST may be used for low-cost, point-of-care applications.

The present subject matter discloses various exemplary projective capacitive micro structured electrode arrays for measuring the impedance and action potential of living cells in particular induced pluripotent stem cells that are subsequently differentiated into cardiomyocytes and neurons. In one exemplary system a projective capacitive electrode array with cardiomyocytes attached onto the electrodes is formed and electrical measurements of live cell responses when exposed to external stimulants, such as small molecule drugs or biologically active compounds is recorded.

This invention relates to a capacitor comprising two electrical conductors separated by a dielectric, the dielectric comprising microorganisms. The dielectric may comprise a biological indicator. This invention relates to a process for determining whether the microorganisms are alive or dead. The number of microorganisms can be determined. This invention relates to a process for testing the efficacy of a sterilization process using the capacitor.

Provided is, in a sample of a cell or a micro region at a position designated in a microscope image of a tissue section, an apparatus and a method for analyzing a biomolecule, which are capable of collecting and analyzing a biomolecule in a single cell or in a micro region without damaging surrounding cells.

The invention provides a hydrogel network comprising a plurality of hydrogel objects, wherein each of said hydrogel objects comprises: a hydrogel body, and an outer layer of amphipathic molecules, on at least part of the surface of the hydrogel body, wherein each of said hydrogel objects contacts another of said hydrogel objects to form an interface between the contacting hydrogel objects. A process for producing the hydrogel networks is also provided. The invention also provides an electrochemical circuit and a hydrogel component for mechanical devices comprising a hydrogel network. Various uses of the hydrogel network are also described, including their use in synthetic biology and as components in electrochemical circuits and mechanical devices.

A cell stimulating apparatus for detaching adhesive cells adhered on a culture substrate from the culture substrate by stimulating the cells, comprising: an application unit configured to apply an alternating field between a first electrode and a second electrode opposing each other by sandwiching cells and a solution in which the cells are dipped, wherein at least one of the first electrode and the second electrode is not in contact with the cells and the solution, wherein the cells and the solution are contained in a vessel, and the first electrode and the second electrode are arranged outside the vessel.

The present subject matter discloses various exemplary projective capacitive micro structured electrode arrays for measuring the impedance and action potential of living cells in particular induced pluripotent stem cells that are subsequently differentiated into cardiomyocytes and neurons. In one exemplary system a projective capacitive electrode array with cardiomyocytes attached onto the electrodes is formed and electrical measurements of live cell responses when exposed to external stimulants, such as small molecule drugs or biologically active compounds is recorded.

Systems and methods for monitoring and tracking the behavior of cells and tissues in a culturing medium, for example, in a cell culture medium or an in vivo tissue environment, using a tissue scaffold system having one or more sensor arrays. Such monitoring systems include a tissue scaffold system and one or more sensor arrays on the tissue scaffold system in vertically stackable configurations. The sensor array(s) are configured to monitor electrical impedance and/or electrophysiological activities of cells or tissues which may be provided to an external data acquisition system for production of a three-dimensional (3D) map.

A multilayer electrode on a substrate (10) comprising titanium (20) and titanium-rich titanium nitride (30) and titanium-poor titanium nitride (40), particularly suitable for the application to thermoplastic substrates, in particular for the purpose of the impedance measurement in aqueous biological media, and method for the production thereof.

An electric reaction measuring apparatus measures a potential of each of measurement electrodes, which are respectively disposed in chambers in a culture vessel, with respect to at least one reference electrode. The electric reaction measuring apparatus includes at least one control circuit. A measurement object is disposed in each of the chambers. The at least one control circuit calculates at least one principal component for each of the measurement electrodes by performing principal component analysis of the potential of each of the measurement electrodes; estimates, for each of the measurement electrodes, a potential corresponding to the principal component from the principal component of the measurement electrode, and synthesizes the estimated potential; subtracts the synthesized potential of the measurement electrode from a potential measured at the measurement electrode; and outputs a potential after subtraction.