An apparatus for detecting liquids or substances from liquids in spatially separate reaction zones using a plug-in module or a chip card for rapid immunological tests, for example, with the help of a reading device. The liquids or substances from liquids are detected by a sensor array and on which at least one diaphragm is arranged. Individual sensors are spatially separated from each other on a plane by means of walls. The diaphragm is filled with liquid that is to be analyzed. Sealed reaction chambers are created when pressure is applied to the diaphragm. Pores in the diaphragm are completely closed in the zone of the walls while the pores are merely reduced in size and liquid can continue to be exchanged in zones directly above the sensors. No liquid can be exchanged between adjacent reaction chambers as long as pressure is applied to and compresses the diaphragm.

An apparatus for detecting liquids or substances from liquids in spatially separate reaction zones using a plug-in module or a chip card for rapid immunological tests, for example, with the help of a reading device. The liquids or substances from liquids are detected by a sensor array and on which at least one diaphragm is arranged. Individual sensors are spatially separated from each other on a plane by means of walls. The diaphragm is filled with liquid that is to be analyzed. Sealed reaction chambers are created when pressure is applied to the diaphragm. Pores in the diaphragm are completely closed in the zone of the walls while the pores are merely reduced in size and liquid can continue to be exchanged in zones directly above the sensors. No liquid can be exchanged between adjacent reaction chambers as long as pressure is applied to and compresses the diaphragm.

According to one embodiment, a method for detecting a sample includes preparing a device for detecting a sample, the device including a measurement cassette, a first chamber formed by partitioning the cassette with a partition wall, a through-hole provided in the partition wall, a first electrode provided in the cassette, and a second electrode provided in the cassette, introducing a reagent and a sample containing a measuring object substance into the first chamber, introducing a conductive liquid into the second chamber, supplying current to the through-hole, allowing the measuring object substance whose surface is bound to and is covered by the tag particles via the capture substance in the first chamber to pass through the through-hole, and detecting presence of the measuring object substance.

According to one embodiment, a method for detecting a sample includes preparing a device for detecting a sample, the device including a measurement cassette, a first chamber formed by partitioning the cassette with a partition wall, a through-hole provided in the partition wall, a first electrode provided in the cassette, and a second electrode provided in the cassette, introducing a reagent and a sample containing a measuring object substance into the first chamber, introducing a conductive liquid into the second chamber, supplying current to the through-hole, allowing the measuring object substance whose surface is bound to and is covered by the tag particles via the capture substance in the first chamber to pass through the through-hole, and detecting presence of the measuring object substance.

Technologies are generally described for gas filtration and detection devices. Example devices may include a graphene membrane and a sensing device. The graphene membrane may be perforated with a plurality of discrete pores having a size-selective to enable one or more molecules to pass through the pores. A sensing device may be attached to a supporting permeable substrate and coupled with the graphene membrane. A fluid mixture including two or more molecules may be exposed to the graphene membrane. Molecules having a smaller diameter than the discrete pores may be directed through the graphene pores, and may be detected by the sensing device. Molecules having a larger size than the discrete pores may be prevented from crossing the graphene membrane. The sensing device may be configured to identify a presence of a selected molecule within the mixture without interference from contaminating factors.

Technologies are generally described for gas filtration and detection devices. Example devices may include a graphene membrane and a sensing device. The graphene membrane may be perforated with a plurality of discrete pores having a size-selective to enable one or more molecules to pass through the pores. A sensing device may be attached to a supporting permeable substrate and coupled with the graphene membrane. A fluid mixture including two or more molecules may be exposed to the graphene membrane. Molecules having a smaller diameter than the discrete pores may be directed through the graphene pores, and may be detected by the sensing device. Molecules having a larger size than the discrete pores may be prevented from crossing the graphene membrane. The sensing device may be configured to identify a presence of a selected molecule within the mixture without interference from contaminating factors.

Described are systems and methods for the simple and rapid measurement of an analyte, such as sulphur dioxide, in liquid samples, including beverages such as wine or beer. The systems and methods utilize voltammetry with a particulate carbon or copper electrode, and may be conducted outside of a laboratory in ten to sixty seconds using a small portable instrument or mobile device using, for example, 2nd harmonic Fourier Transform (FT) AC voltammetry.

Described are systems and methods for the simple and rapid measurement of an analyte, such as sulphur dioxide, in liquid samples, including beverages such as wine or beer. The systems and methods utilize voltammetry with a particulate carbon or copper electrode, and may be conducted outside of a laboratory in ten to sixty seconds using a small portable instrument or mobile device using, for example, 2nd harmonic Fourier Transform (FT) AC voltammetry.

Nanopore arrays are fabricated by controlled breakdown in solid-state membranes integrated within polydimethylsiloxane (PDMS) microfluidic devices. This technique enables the scalable production of independently addressable nanopores. By confining the electric field within the microfluidic architecture, nanopore fabrication is precisely localized and electrical noise is significantly reduced during sensing.

Nanopore arrays are fabricated by controlled breakdown in solid-state membranes integrated within polydimethylsiloxane (PDMS) microfluidic devices. This technique enables the scalable production of independently addressable nanopores. By confining the electric field within the microfluidic architecture, nanopore fabrication is precisely localized and electrical noise is significantly reduced during sensing.