The objective of the present disclosure is to provide a technique for reducing a quantity of magnetic particles remaining on a reaction vessel wall surface in a cleaning step for reducing, in a stepwise manner, an amount of a magnetic particle solution in the reaction vessel. The automated analysis device according to the present disclosure causes an agitating mechanism to operate in such a way that a magnetic substance remaining on the wall surface of the vessel in the previous cleaning step is captured by a cleaning solution in the next cleaning step (see FIG. 10).

Embodiments of automated assay processing systems and methods are disclosed. In an example, an assay automation system includes an assay processing tube, a magnet, and a controller. The assay processing tube has a right arm and a left arm, the right arm having an opening for receiving reagent transferred from a reagent tube being held in one of the tube-holding arms of the reagent tube holder, the assay processing tube being driven to rotate. The magnet is driven to move vertically. The controller is configured to control coordinated movements of the assay processing tube and the magnet to perform an assay processing sequence.

The degree of freedom in device configuration is increased. A BF separator includes: a holder configured to hold a container that stores therein a sample containing magnetic particles and a liquid component; a magnet provided to be movable relative to the holder in a direction approaching or separating from the holder, and configured to magnetically collect the magnetic particles; a movement mechanism configured to move the holder, and move the magnet in conjunction with movement of the holder, in a direction in which the holder and the magnet approach each other or separate from each other; an agitator configured to agitate the sample in the container held by the holder located in a separate position where the holder and the magnet are away from each other; and a suction tube configured to suck the liquid component in the container held by the holder located in an approach position where the holder and the magnet are close to each other.

A method and apparatus for the rapid and reliable preparation of a sample for use in testing for target analytes such as bacteria, viruses, toxins and pathogenic agents in various products. A sample for testing the target analyte is collected from various sources. The method for sample preparation provides for an express process for preparing collected samples for testing. The collected sample may be concentrated by centrifugation, filtration, or other means suitable for sample concentration, homogenized with the addition of a broth and enriched for specified period of time. Immunomagnetic separation of the sample occurs with receptor-coated magnetic microspheres in different test-specific formulations (singleplex or multiplex). An automatic testing system is disclosed which includes a biological testing cassette, in which testing of the sample occurs using liquid crystal diagnostic methodologies.

The present invention relates to a portable analyzer for detecting bisphenol A, which comprises an aptamer specifically binding to bisphenol A, and a method for detecting bisphenol A using the same. The analyzer of the present invention can analyze a small amount of a sample collected from a contaminated environment in a field at a level similar to a laboratory environment, thereby having an effect of enabling a more immediate and accurate detection and quantification of bisphenol A.

An automatic analysis apparatus and an operating method therefor. A temporary storage portion is introduced, a multi-component test project may be divided into new one-step test processes, or a multi-step test process may be divided into new one-step test processes, and test sequences and processes may be re-entered, so that each mechanism, unit and control time sequence may be designed according to one-step test processes in a standard and orderly manner, so as to solve the problem that multi-component test projects and multi-step test processes disturb normal processes, thereby effectively increasing the test speed and the test throughput of the whole machine.

The present invention relates to novel modules for transferring magnetic beads, an automated system comprising the same and a method for extracting nucleic acids using the same. The specifically designed magnet module and cover module of the present invention can be employed in the automated liquid handling apparatus by means of pre-existing moving modules (e.g., pipettor module) of the apparatus. The present invention enables a bead transfer-type method for extracting nucleic acids to be performed in an automated manner on the automated liquid handling apparatus. The present invention provides advantages of higher level of automation, more reduced cost and no need for another separate liquid handling apparatus compared to the conventional bead transfer-type method usually performed in the small apparatus designed to be used only for this bead transfer-type method. Also, the present method has the merits of more shortened reaction time compared to the conventional liquid transfer-type method.

This system takes in raw cellular material collected using a provided swab, blood collection device, urine collection device, or other sample collection device and transforms that biological material into a digital result, identifying the presence, absence and/or quantity of nucleic acids, proteins, and/or other molecules of interest.

Provided herein are apparatuses and systems for mixing liquids and suspensions that include vessels with structures that improve mixing while not contacting liquid delivery components. The apparatuses and systems can include a motor drive that allows speed and directional control of rotation of the vessel. The apparatuses and systems can include one or more magnets for separating magnetic beads in a suspension. Also provided are methods using said apparatuses and systems for mixing and separation processes.

Provided are nucleic acid extraction apparatuses and operation methods thereof. The apparatus may include at least one cyclically moveable annular structure, at least one pipetting mechanism, at least one injection mechanism and a driving mechanism. The annular structure may be provided with a plurality of cuvette positions and a plurality of operation positions. The pipetting mechanism and the injection operation may be arranged along the annular structure. The driving mechanism may drive the annular structure to move cyclically.