Embodiments described herein may be useful in the detection of analytes. The systems and methods may allow for a relatively simple and rapid way for detecting analytes such as chemical and/or biological analytes and may be useful in numerous applications including sensing, food manufacturing, medical diagnostics, performance materials, dynamic lenses, water monitoring, environmental monitoring, detection of proteins, detection of DNA, among other applications. For example, the systems and methods described herein may be used for determining the presence of a contaminant such as bacteria (e.g., detecting pathogenic bacteria in food and water samples which helps to prevent widespread infection, illness, and even death). Advantageously, the systems and methods described herein may not have the drawbacks in current detection technologies including, for example, relatively high costs, long enrichment steps and analysis times, and/or the need for extensive user training. Another advantageous feature provided by the systems and methods described herein includes fabrication in a relatively large scale. In some embodiments, the systems and methods may be used in conjunction with a detector including handheld detectors incorporated with, for example, smartphones (e.g., for the on-site detection of analytes such as pathogenic bacteria).

A signal processing system used for GMR-based detection of a target analyte in a sample under test, comprising: a measurement circuit configuration unit configured to build a GMR sensor measurement circuit by routing in at least one GMR sensor, and to build a reference resistor measurement circuit by routing in at least one reference resistor; a magnetic field excitation unit configured to apply an AC magnetic field of frequency ω.sub.2 to the at least one GMR sensor; a carrier signal applying unit configured to apply a carrier signal of frequency ω.sub.1 to the GMR sensor measurement circuit, and apply carrier signals of frequency ω.sub.1, ω.sub.1+ω.sub.2, and ω.sub.1−ω.sub.2 to the reference resistor measurement circuit; a measurement signal pick-up unit coupled to the measurement circuits, configured to collect reference resistor measurement signals from the reference resistor measurement circuit and GMR sensor measurement signals from the GMR sensor measurement circuit; and a phase sensitive solution unit coupled to the measurement signal pick-up unit, configured to analytically solve for resistance change of the at least one GMR sensor based on both the reference resistor measurement signals from the reference resistor measurement circuit and the GMR sensor measurement signals from the GMR sensor measurement circuit.

Sensors having an advantageous design and methods for fabricating such sensors are generally provided. Some sensors described herein comprise pairs of electrodes having radial symmetry, pairs of nested electrodes, and/or nanowires. Some embodiments relate to fabricating electrodes by methods in which nanowires are deposited from a fluid contacted with a substrate in a manner such that it evaporates and is replenished.

A nanohole array (NHA)-based plasmonic sensor (e.g., gas/condensed phase sensor), their preparation, and their use to detect and analyze samples, especially mixtures of chemicals/bio-chemicals.

The disclosure relates to electronic reader devices, detection compositions and methods for detecting heavy metals (e.g., lead) in water samples using a simple, rapid and highly selective immunoassay system, including lateral and upward flow assay systems. The immunoassay is designed to detect very low levels of a contaminating analyte such as lead at less than 1 ppb with high specificity and selectivity from any common water source (e.g., tap or drinking water). Advantageously, implementation of the assay requires no formal technical training or expensive equipment or reagents and is provided with a multi-use reader that can be used for 50 samples or more. The immunoassay sample collector systems are consumable (single use) and can be purchased in any desired quantity. Assay results are wirelessly transmitted from the reader using a SafeSpout-designed app., which provides important information based on the test results.

Sensors having an advantageous design and methods for fabricating such sensors are generally provided. Some sensors described herein comprise pairs of electrodes having radial symmetry, pairs of nested electrodes, and/or nanowires. Some embodiments relate to fabricating electrodes by methods in which nanowires are deposited from a fluid contacted with a substrate in a manner such that it evaporates and is replenished.

Sensors having an advantageous design and methods for fabricating such sensors are generally provided. Some sensors described herein comprise pairs of electrodes having radial symmetry, pairs of nested electrodes, and/or nanowires. Some embodiments relate to fabricating electrodes by methods in which nanowires are deposited from a fluid contacted with a substrate in a manner such that it evaporates and is replenished.

A test container including: at least two accommodation portions each accommodating a liquid and internally provided; a flow path connecting the two accommodation portions to each other at respective upper end positions thereof internally provided; and a flexible film deformable inwards of at least one accommodation portion at a portion forming an upper wall surface of the one accommodation portion, in which the liquid accommodated in the one accommodation portion is fed to the other accommodation portion via the flow path due to deformation of the flexible film towards the one accommodation portion, and a breaking elongation of the flexible film is 100% or more and 600% or less.

The present system and method are useful for the removal of immune inhibitors such as soluble TNF receptors from the body fluid of cancer patients. In some embodiments, soluble TNF-Receptors 1 and 2 are selectively removed from plasma at 80% or more efficiency. In some embodiments, the system includes an immobilized capture ligand of a single chain TNFα. The system and method are useful for the treatment of different cancer types, stages and severity.

The biosensor platform is a rapid point-of-care (POC) device wherein detection of a target substance is performed in a single step using a fully integrated disposable biosensor test system. In one embodiment, the system comprises a horizontally oriented multi-strip test cassette. A user initiates the test by depositing an analyte onto an immunochromatographic test strip sandwiched between a (top) cassette lid and a (bottom) slotted cassette tray. The test strip is held in place by at least one horizontally extending self-adjusting flex plate. The system is structured so that as the analyte flows through the test strip, the analyte reacts with a reagent in the test strip to indicate a presence or absence of the targeted substance as the test strip is held in place by the self-adjusting flex plate.