A method for reading a lateral flow assay test strip comprises providing a microwave antenna in proximity of a stain line region of the test strip. The method includes causing a chemical compound to travel to the stain line region, an amount of the chemical compound varying in accordance with a quantity of an analyte. The method comprises connecting an instrumentation to the microwave antenna. The method includes measuring a feed impedance of the microwave antenna using the instrumentation, the feed impedance of the microwave antenna varying with the amount of the chemical compound. The method comprises determining the quantity of the analyte based on the feed impedance of the microwave antenna.

A magnetic sensor includes a substrate having a first surface and a second surface, which is opposite the first surface, and a detection unit provided on the first surface. The detection unit includes a magnetoresistive effect element, the resistance value of which changes in accordance with an input magnetic field, provided on the first surface, and a protective layer that covers at least the magnetoresistive effect element. The magnetoresistive effect element is configured in a linear shape extending in a first direction on the first surface. The detection unit has a first width, which is a length in a second direction, orthogonal to the first direction, and a second length, which is greater than the first width. The first width is the length of the detection unit on the first surface, and the second width is the length of the top surface of the detection unit.

The present invention is directed to a method of identifying, isolating, and enabling downstream analysis of circulating tumor cells comprising contacting a blood or blood serum sample of a subject with a composition comprising a phospholipid ether analog bound to a luminescent molecule or a magnetic bead and subjecting the blood or blood serum sample of the subject to fluorescent microscopy, flow cytometry or magnetic isolation.

Described is a method and device for detecting an analyte in a sample, comprising bringing a sample comprising a target analyte into contact with magnetisable particles, the particles being coated with binding molecules complementary to the target analyte, resulting in bound and unbound binder complexes, positioning the magnetisable particles, comprising both bound and unbound binder complexes, in proximity to a magnetic field sensor, changing the magnetic field sufficient to release at least a portion of the magnetisable particles, comprising both bound and unbound binder complexes, from their proximity to the magnetic field sensor, and measuring changes in a magnetic signal detected from the net movement, being either translational or rotational movement, of the magnetisable particles relative to the magnetic sensor.

The present invention is directed to a method of identifying, isolating, and enabling downstream analysis of circulating tumor cells comprising contacting a blood or blood serum sample of a subject with a composition comprising a phospholipid ether analog bound to a luminescent molecule or a magnetic bead and subjecting the blood or blood serum sample of the subject to fluorescent microscopy, flow cytometry or magnetic isolation.

A sample is added to a chamber (12) in which magnetic particles (P) are provided. The sample includes a target component (T) and the chamber (12) has a detection surface (122). A magnetic force is exerted on the magnetic particles (P) to attract the magnetic particles (P) to the detection surface (122). The bound magnetic particles that captured the target component (T) in the magnetic particles (P) and the unbound magnetic particles that captured no target component (T) in the magnetic particles (P) are held at the detection surface (122). At least part of the sample is drained out of the chamber (12) and a new sample added to the chamber (12). The magnetic force exerted on the magnetic particles (P) is altered to release the unbound magnetic particles from the detection surface (122). An amount of the bound magnetic particles that are held at the detection surface (122) are measured. The target component (T) is preconcentrated by repeating the steps of magnetically binding the target component (T) from the newly added sample and washing the detection surface (122) from unbound magnetic particles.

Disclosed herein are detection methods that use magnetic nanoparticles (MNPs) to allow molecules to be identified. Embodiments of this disclosure include methods of using magnetic sensors (e.g., magnetoresistive sensors) to detect temperature-dependent magnetic fields (or changes in magnetic fields) emitted by MNPs, and, specifically to distinguish between the presence and absence of magnetic fields emitted, or not emitted, by MNPs at different temperatures selected to take advantage of knowledge of how the MNPs' magnetic properties change with temperature. Embodiments disclosed herein may be used for nucleic acid sequencing, such as deoxyribonucleic acid (DNA) sequencing.

In an approach to magnetic flux density based DNA sequencing, a static magnetic field is provided. A chain of nucleotides is passed through the magnetic field. A change in magnetic flux density of the static magnetic field due to an ionic voltage associated with an individual nucleotide or base pair of the chain of nucleotides is measured. An identity of the nucleotide is determined based on the change in magnetic flux density.

A system and method for locating magnetic material. In one embodiment the system includes a magnetic probe; a power module in electrical communication with the magnetic probe to supply current to the magnetic probe; a sense module in electrical communication with the magnetic probe to receive signals from the magnetic probe; and a computer in electrical communication with the power module and the sense module. The computer generates a waveform that controls the supply of current from the power module and receives a signal from the sense module that indicates the presence of magnetic material. The magnetic probe is constructed from a material having a coefficient of thermal expansion of substantially 10.sup.−6/° C. or less and a Young's modulus of substantially 50 GPa or greater. In one embodiment magnetic nanoparticles are injected into a breast and the lymph nodes collecting the particles are detected with the probe and deemed sentinel nodes.

A system for measuring analyte concentrations has porous-walled nanocontainers containing multiple magnetic nanoparticles, the magnetic nanoparticles coated with a selective binder that is analyte-responsive and binds a the analyte, an indicator substance releasable from the selective binder by the analyte, or an indicator substance cleavable by the analyte, apparatus for exposing the nanocontainers to a fluid potentially containing the analyte, and magnetic spectroscopy of Brownian motion sensing apparatus for detecting agglutination of the nanoparticles or binding of analyte to the nanoparticles. The system is used in a method comprising coating magnetic nanoparticles with a selective binder, encapsulating the magnetic nanoparticles in porous nanocontainers, exposing the nanocontainers to a fluid potentially containing analyte, using magnetic spectroscopy of Brownian motion sensing apparatus to detect agglutination or binding of the nanoparticles, and translating Brownian motion spectra to analyte concentrations.