The invention relates to a method for detecting a particle in a container filled with liquid, the method having the following steps: dispensing a liquid sample into the container, scanning a partial volume area of the container in order to detect a particle located in the liquid sample, characterized in that an upper limit and a lower limit of the partial volume area is determined in a calibration operation upstream of the dispensing process.

A point-of-care testing (POCT) fully-automatic chemiluminescence device based on a multi-channel parallel pretreatment technology includes a support. The support is provided thereon with a reaction chamber assembly, which reciprocates linearly relative to the support. A multi-channel parallel pretreatment assembly and a photomultiplier tube (PMT) assembly are arranged on the support and are located above the reaction chamber assembly. The multi-channel parallel pretreatment assembly is configured to transfer, clean, and separate reagents in reagent strips in the reaction chamber assembly. The PMT assembly is configured to detect a luminescence value of the cleaned and separated reagents. The device does not have a liquid passage, resulting in low maintenance costs and high reliability. This realizes automatic sample addition, supports whole blood testing, and avoids carry-over. The device solves the problems in the traditional POCT chemiluminescence device of manual sample addition, cumbersome steps, and human errors which are easily made.

[Solving Means] A sample liquid-sending apparatus includes a placement portion, a suction mechanism, and a vibrator. A sample container is placed in the placement portion, the sample container containing a suspension of a sample. The suction mechanism includes a nozzle configured to be inserted into the sample container placed in the placement portion, and suctions the sample through the nozzle. The vibrator vibrates the nozzle.

A method for mixing liquids using an automated liquid handling system includes: aspirating liquid volumes of a first liquid and a second liquid from alternating ones of a first liquid supply and a second liquid supply into a mixing volume such that the aspirated liquid volumes form a liquid stack including a series of alternating, interfacing layers of the first and second liquids in the mixing volume; permitting the interfacing layers of the first and second liquids to mix with one another by diffusion in the mixing volume to form a mixture liquid; and dispensing the mixture liquid from the mixing volume.

Disclosed are a water quality analyzer and a method for analyzing water quality. The water quality analyzer includes a first disc system, a second disc system, a colorimetric system, a cleaning system, a mechanical sampling system, an analysis system and a central control display. The first disc system and the second disc system are axially rotatable. A plurality of sample locating positions and a chemical locating positions are provided on the first disc system along a circumference of the first disc system. A plurality of colorimetric cuvette locating positions are provided on the second disc system, and the colorimetric system is arranged at a circumference edge of the second disc system. The cleaning system and the mechanical sampling system are provided between the first disc system and the second disc system. The method includes water sampling, water sample injection, cleaning, reagent extraction, reagent injection, cleaning and colorimetric analysis.

Aspects of this disclosure relate to systems, devices, and methods for the transfer of fluid to fluidic receptacles. In some embodiments, the fluid contains one or more molecules (e.g., one or more peptides, proteins, and/or nucleic acids) of interest, and the fluidic receptacle includes an integrated device. In certain embodiments, the one or more molecules can be immobilized on the integrated device for subsequent analysis (e.g., sequencing). Certain aspects of the present disclosure are directed towards systems and methods that can, in some instances, enhance the immobilization of the one or more molecules on the integrated device, e.g., by improving a rate of sample interaction with the integrated device. Through the use of systems, devices, and methods of the instant disclosure, target molecules may be more readily sequenced or prepared for sequencing. For example, in some embodiments, systems, devices, and methods of the instant disclosure allow automated loading of the fluidic receptacle using a fluidic device.

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.

The invention is related to a device for suspending particles in a fluid, wherein the mixing device includes a first magnet (1) rotating around a longitudinal axis (2), a mixing rod (4) attached to a mount (6), the mount including a second magnet (3), wherein the mount (6) moves in a substantially orthogonal motion to the longitudinal axis of the mixing rod (4) by the interaction of the rotating first magnet with the second magnet (3).

A control section causes one dispensing mechanism of either a reagent dispensing mechanism or a sample dispensing mechanism to first discharge a predetermined amount of a liquid into the reaction container, and then, with respect to the cases where the amount of a liquid to be discharged by the other dispensing mechanism is larger or smaller than the amount of the liquid in the reaction container, causes the other dispensing mechanism to discharge the liquid such that the discharge speed in the case where the amount of the liquid to be discharged is larger is decreased relative to the discharge speed in the case where the amount of the liquid to be discharged is smaller.

In some instances, an apparatus can include a light sensitive imaging sensor having a surface to receive a fluid sample, a body to be moved relative to the light sensitive imaging sensor and having a surface to touch a portion of the fluid sample, and a carrier to move the body toward the surface of the light sensitive imaging sensor to cause the surface of the body to touch the portion of the fluid sample, so that as the surface of the body touches the portion of the fluid, the surface of the body (i) is parallel to the surface of the light sensitive imaging sensor, and (ii) settles on top of the fluid sample independently of motion of the carrier.