The present invention belongs to the field of nucleic acid detection, particularly in-vitro diagnostics. The invention concerns amongst others the amplification of at least one or more target nucleic acid that may be present in at least one sample using an inventive control, which comprises a particle comprising a polycationic compound and a nucleic acid. The present invention relates also to uses of the inventive controls, methods for the preparation, diagnostic tools and kits.

Disclosed are a kit for testing myocardial infarction rapidly and a preparation method and use thereof. The kit comprises a strip capable of detecting three markers, namely, human myeloperoxidase (MPO), heart-fatty acid binding protein (FABP3) and cardiac troponin I(cTnI) simultaneously. The strip comprises a sample pad, a conjugate pad, a chromatographic membrane coated with three test lines and a quality control line, and a sample absorption pad. Antibodies of the three markers are all marked on the conjugate pad. The chromatographic membrane has three test lines formed by coating paired antibodies of the three markers respectively, the paired antibodies of the three markers being able to specifically combine with the three markers, respectively. The kit has advantages such as convenient operation, rapid response, high sensitivity and high specificity, point of care test, and economical and practical etc.

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.

Devices for detecting a particle in a fluid sample are provided. The device includes a segmented microfluidic conduit configured to carry a flow of a fluid sample, where the conduit includes one or more nodes and two or more sections, and a node is positioned between adjacent sections of the conduit. The device also includes a detector configured to detect a change in current through the conduit. Also provided are methods of using the devices as well as systems and kits that include the devices. The devices, systems and methods find use in a variety of different applications, including diagnostic assays.

The invention relates to a method for detecting various analytes, characterized by the following steps: a) providing separation particles containing, on their surface, firstly means of binding the analyte to be identified and secondly means of separating the analyte bound to the particles; b) providing identification particles firstly having, on their surface, means for binding the analyte to be identified and secondly containing on their surface or enclosed therein, means which are capable, after they have been detached or released from the particles, by virtue of their labeling, of generating a signal which serves for identification of the analyte; c) combining analyte, separation particles and identification particles; d) removing and washing the identification particles bound via the analyte by means of the separation particles; e) releasing the means which serve to identify the analyte, characterized in that the means which serve to identify the analyte are coupled reversibly to the identification particles and in that the identification molecules serve simultaneously for identification of the analyte and for detection.

The present invention provides for a system and method to detect low levels of the anthrax protective antigen (PA) exotoxin in biological fluids, wherein the system uses a metal-enhanced fluorescence (MEF)-PA assay in combination with microwave-accelerated PA protein surface absorption. Microwave irradiation rapidly accelerates PA deposition onto the surface adjacent to deposited metallic particles and significantly speeding up the MEF-PA assay and resulting in a total assay run time of less than 40 min with an analytical sensitivity of less than 1 pg/ml PA.

According to an aspect, a server receives first and second transient (changing with time) locations of an entity, the first transient location being associated with a time instance until which the entity is physically present at the first transient location. The server accordingly provides the first transient location as the physical location of the entity prior to the time instance, and the second transient location as the physical location after the time instance. According to another aspect, a client device identifies that a search text (received from a user) is directed to searching for physical locations in view of the search text including an affix. The client device then parses the search text to determine an identifier, sends a location request containing the identifier, receives a response containing a transient location associated with the identifier, and then provides the transient location to the user as the response to the search.

The present disclosure relates to compositions, methods, and kits for the detection, separation and/or isolation of microorganisms. Specifically, the disclosure relates to compositions, methods, and kits for using polylysine-coated particles to capture microorganisms such as bacteria.

Analysis of a system and/or sample involves the use of absorption-encoded micro beads. Each type of micro bead is encoded with amounts of the k dyes in a proportional relationship that is different from proportional relationships of the k dyes of others of the n types of absorption-encoded micro beads. A system and/or a sample can be analyzed using information obtained from detecting the one or more types of absorption-encoded micro beads.

NT-proBNP can be determined in a biological sample using at least one antibody which recognizes an epitope of NT-proBNP in both a glycosylated and non-glycosylated form of NT-proBNP. Said antibody is preferably an isolated polyclonal antibody or a mixture of monoclonal antibodies coated onto a particle, preferably coated onto said particle in a coating ratio of 6-60%, forming a layer or multiple layers of antibodies on said particle. The assay, realized in the form of a nephelometric or turbidimetric assay, can be applied to a wide range of automated clinical analyzers.