The present invention relates to a method for the diagnosis of a disease comprising contacting a donor tissue section with a liquid capable of extracting an antibody from said donor tissue section and contacting said liquid with an acceptor material comprising an antigen, followed by detection of a complex comprising the antibody and the antigen, and a diagnostically useful carrier comprising a donor tissue section and an acceptor material comprising an antigen.

In biosciences and related fields, it can be useful to study cells in isolation so that cells having unique and desirable properties can be identified within a heterogenous mixture of cells. Processes and methods disclosed herein provide for encapsulating cells within a microfluidic device and assaying the encapsulated cells. Encapsulation can, among other benefits, facilitate analyses of cells that generate secretions of interest which would otherwise rapidly diffuse away or mix with the secretions of other cells.

A microfluidic diagnostic chip may comprise a microfluidic channel, a functionalizable enzymatic sensor in the microfluidic channel, the functionalizable enzymatic sensor comprising a binding surface to bind with a biomarker in a fluid, and a microfluidic pump to pass the fluid over the binding surface. A microfluidic device may comprise a number of pumps to pump a fluid though the number of microfluidic channels and a number of microfluidic channels comprising at least one sensor to detect a change in a chemical characteristic of the fluid in response to presence of the fluid on the sensor

Systems, methods, and kits are provided wherein a temperature-sensitive reagent that emits a luminescent signal is used to adjust the identification of the temperature of a sample or to control thermocycling. In various illustrative embodiments, the sample is a PCR mixture.

A microfluidic device includes a channel through which a reaction solution flows. The channel passes through a reaction section having a plurality of temperature zones set at predetermined different temperatures. The channel includes, at least in the reaction section, a region where a cross-sectional area decreases in a feeding direction of the reaction solution.

The pocket detection platform (PDP) detects pathogens, toxins and chemicals of interest simultaneously by way of a multi-channeled, soft see-through plastic pouch design that consists of inner and outer compartments that promote compartmentalization and/or unidirectional sample flow. The platform enables the concurrent running of multiple detection assay techniques such as lateral flow immunoassays (LFI), Isothermal molecular assays (i.e., Recombinase Polymerase Amplification, or RPA) and/or paper-based chemical assays (i.e., M8, pH paper) from a single wet or dry sample with minimal sample processing. The PDP reduces soldier overburden by decreasing size weight, and power (SWaP) as well as training time, electronic burden, while providing a flexible, customizable assay platform that can be rapidly produced, assembled, sustained, and when contaminated, easily to dispose of.

This invention relates generally to the field of nucleic acid detection. In particular, the invention provides a lab-on-chip system for analyzing a nucleic acid, which system comprises, inter alia, controllably closed space, and a target nucleic acid can be prepared and/or amplified, and hybridized to a nucleic acid probe, and the hybridization signal can be acquired if desirable, in the controllably closed space without any material exchange between the controllably closed space and the outside environment. Methods for analyzing a nucleic acid using the lab-on-chip system is also provided.

This invention relates generally to the field of analyte assays. In particular, the invention provides a device for analyzing an analyte, which device comprises, inter alia, various means for moving analytes and other items to facilitate binding between analytes and their binding reagents immobilized on a surface and to facilitate clearance of undesirable items away from analyte-binding reagent interaction area to reduce background noise in the assay. Methods for analyzing an analyte using the devices are also disclosed.

Embodiments of the present disclosure relate to a platform for at least one of capturing, identifying and studying biological materials, and more particularly, to microfluidic channel platforms (for example) for detecting and/or identifying samples containing sperm cells, and isolating and analyzing captured sperm cells for DNA analysis (for example). In some embodiments, such microfluidic platforms integrate imaging technology. Such embodiments provide the ability to at least one of rapidly isolate and quantitate sperm cells from biological mixtures as occur in sexual assault evidence, for example, thereby enhancing identification of suspects in these cases and contributing to the safety of society.

The present invention relates to systems 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 is provided for detecting an analyte in a biological sample. The device includes a first electrochemical sensor positioned on a substrate. The first electrochemical sensor includes an immobilized layer of antibody configured to bind to the analyte. The device further includes a second electrochemical sensor positioned adjacent to the first electrochemical sensor on the substrate, and a magnetic material that generates a magnetic field aligned with respect to the second electrochemical sensor. The magnetic field captures magnetic beads that have an immobilized layer of antibody configured to bind to the analyte, and concentrates the magnetic beads on or near a surface of the second electrochemical sensor.