Invention, relates to the field of supersensitive biomagnetometry under presence of external electromagnetic interferences. In order to perform passive compensation of said interferences, design of device at the magnetometer input is proposed, comprising compensation elements and means for their moving including shifting, holding, and fixation units. In the basic embodiment, three short-closed wire contours are used which are orthogonally placed in space and independently moved up-down relative to the magnetometer or its input antenna. Contours are fixed in positions where minimum of external interference amplitude is achieved according to given field projection. Variants are proposed with cooling of meter and/or contours, location of contours inside the cryostat and their manufacturing from superconductors.

A magnetic biosensor can include a magnetic stack comprising a free layer, a fixed layer, and a nonmagnetic layer between the free layer and the fixed layer. At least one of the free layer or the fixed layer may have a magnetic moment oriented out of a major plane of the free layer or the fixed layer, respectively, in an absence of an external magnetic field. The magnetic biosensor also may include a sample container disposed over the magnetic stack, a plurality of capture antibodies attached to a bottom surface of the sample container above the magnetic stack, and a magnetic field generator configured to generate a magnetic field substantially perpendicular to the major plane of the free layer or fixed layer.

A device includes an excitation coil, a detector coil, and a processing circuit. The excitation coil is aligned about a volume. The excitation coil is configured to carry a first and second biasing current and generate a magnetic field in the volume. The detector coil is configured to generate an electrical signal based on a detected field within the volume. The detected field is based on the magnetic field. The processing circuit is configured to generate data based on the electrical signal.

The present invention relates to systems and methods that utilize a combination of immunoassay and magnetic immunoassay techniques to detect an analyte within an extended range of specified concentrations. In particular, a device includes a housing, a heterogeneous surface capture immunosensor within the housing and configured to generate a first signal indicative of the concentration of the analyte in an upper concentration range, and a homogeneous magnetic bead capture immunosensor within the housing and configured to generate a second signal indicative of the concentration of the analyte in a lower concentration range.

The invention relates to a device for measuring a first parameter of a specimen, the device including a measuring volume configured to receive the specimen, a first control module and a measuring module, the first control module being configured to supply electricity to the measuring module with an electrical supply current, the measuring module including a magnetic field generator, a sensor and a second control module, the magnetic field generator being configured to generate a magnetic field in the measuring volume, the sensor being configured to measure values of a variable of the measuring volume during the generation of the magnetic field, the second measuring control module being configured to calculate a value of the parameter based on at least one value of the variable. The first control module is configured in order, following the generation of the magnetic field, to inhibit the power supply of the measuring module during a first predetermined length of time (dn).

A method of sensing molecules using a detection device, the detection device comprising a plurality of magnetoresistive (MR) sensors and at least one fluidic channel, comprising adding a plurality of molecules to be detected to the at least one fluidic channel, wherein at least some of the plurality of molecules to be detected are coupled to respective magnetic nanoparticles (MNPs), detecting a characteristic of a magnetic noise of a first MR sensor of the plurality of MR sensors, wherein the characteristic of the magnetic noise is influenced by a presence of one or more MNPs in a vicinity of the first MR sensor, and determining, based on the detected characteristic, whether the first MR sensor detected the presence of one or more MNPs in the vicinity of the first MR sensor.

A cartridge assembly, and method of using the same, is provided. The assembly includes a sample processing card and a substrate attached thereto. The card has an injection port for receiving a test sample; at least one metering chamber; a mixing material source for introducing mixing material(s) to the metering chamber; fluid communication channels fluidly connecting the injection port and the mixing material source to the metering chamber; and at least one output port for delivering the test sample to a sensor (e.g., GMR sensor). The substrate has associated therewith: the sensor for sensing analytes in the test sample; electrical contact portions for an electrical connection with a reader unit; and a memory chip. The assembly further includes a pneumatic interface with port(s) and corresponding communication channel(s) fluidly connected to card. The interface connects with an off-board pneumatic system and enables application of positive and negative pressurized fluid to the card to move the test sample and one or more mixing materials therein and to the sensor.

An electromagnetic sensing device comprising: a reference microfluidic reservoir to receive a reference substance with magnetic nanoparticles; an analyte microfluidic reservoir to receive an analyte and magnetic nanoparticles; a first excitation magnetic coil to subject the reference microfluidic reservoir to an alternating magnetic field at a first frequency; a second excitation magnetic coil to subject the analyte microfluidic reservoir to an alternating magnetic field at the first frequency; a third excitation magnetic coil to subject the reference microfluidic reservoir to an alternating magnetic field at a second frequency distinct from the first frequency; a fourth excitation magnetic coil to subject the analyte microfluidic reservoir to an alternating magnetic field at the second frequency; a first detection magnetic coil to detect a response magnetic field of the magnetic nanoparticles in the reference microfluidic reservoir; a second detection magnetic coil to detect a response magnetic field of the magnetic nanoparticles.

Methods for the detection of enzymatic activity, in particular, to in vivo methods. A non-invasive method for in vivo enzyme activity detection, such as activity of proteinases, to substrates specifically developed for these methods and to a device detecting product formation of the enzyme to be tested based on determination of signals produced by the substrates and/or its products.

Disclosed herein are devices, systems, and methods for monitoring single-molecule biological processes using magnetic sensors and magnetic particles (MNP). A MNP is attached to a biopolymer (e.g., a nucleic acid, protein, etc.), and motion of the MNP is detected and/or monitored using a magnetic sensor. Because the MNP is small (e.g., its size is comparable to the size of the molecule being monitored) and is tethered to a biopolymer, changes in the volume of Brownian motion of the MNP in a solution can be monitored to monitor the movement of the MNP and, by inference, the tethered biopolymer. The magnetic sensor is small (e.g., nanoscale or having a size on the order of the sizes of the MNP and the biopolymer) and can be used to detect even small changes in the position of the MNP within the sensing region of the magnetic sensor.