An automatic analyzer which is capable of detecting a dispensing abnormality with a high degree of accuracy without causing the decrease in the determination performance or the increase in the calculation amount caused by the configuration balance of the reference database is implemented. A dispensing nozzle of a sample dispensing mechanism 50 is immersed in a dispensing target contained in a specimen container 11 and sucks the dispensing target, and internal pressure of the dispensing nozzle of the sample dispensing mechanism 50 of ejecting the sucked dispensing target to a reaction container 41 is detected through a pressure sensor 54. A plurality of feature quantities are extracted from a waveform of the detected pressure, and a determination result is output through a linear combination formula using an optimal coefficient for a determination function that receives a plurality of feature quantities and outputs one value. The determination result indicates whether or not dispensing of the sample dispensing mechanism 50 is performed normally in accordance with the magnitude of the output result of the determination function.

A blood component collection cassette of a blood component collection system, which is a biological component transfer system, includes a sheet-shaped cassette main body in which a blood line is formed. The blood line includes a second applied load measurement unit and line main body portions. A separation device includes a second load measurement unit that measures a load applied to a wall portion of the second applied load measurement unit in a cassette mounted state. The second applied load measurement unit is more easily deformed than the line main body portions, and is disposed at a location within the blood line on which only a positive pressure acts.

The present invention determines whether or not a mounted tip and a dispensing amount match with each other in order to prevent contamination in a dispensing device. The present invention is provided with a pipette mechanism 108, 109 that performs suction and discharge, a motor 102 that drives the pipette mechanism, and a pressure sensor 113 that detects a pressure of the pipette mechanism. A dispensing tip 110 is mounted to the pipette mechanism. A control computer 116 controls the motor 102, drives the pipette mechanism in a suction or discharge direction, and determines a type of the dispensing tip 110 on the basis of a difference in pressure waveform detected by the pressure sensor 113.

The present disclosure provides assay and method for using assay for streamlined assay preparation and testing. These assay are useful for pathogen (e.g., viral or bacterial) detection. The present disclosure also provides assay assemblies and means to prevent or minimize the formation of bubbles when using puncturing elements in fluidic devices or chambers.

The invention provides integrated Organ-on-Chip microphysiological systems representations of living Organs and support structures for such microphysiological systems.

A method of obtaining a numerical model is disclosed. The numerical model correlates estimated line width values to minimum pressure for gas bubble generation (MPGBG) values. An MPGBG value of each capillary tube in the reference group is measured for a liquid. A nanoparticle composition is deposited, under standard conditions, on substrate(s) from each respective reference capillary tube, to form nanoparticle lines. A line width of each of the nanoparticle lines deposited using each respective reference capillary tube is measured by a microscope apparatus. A numerical model that correlates estimated line width values to MPGBG values for the liquid is calculated.

Operations performed according to the example techniques described herein include controlling a probe to pierce a stopper of a container containing a substance, where the stopper provides an air-tight seal for the container, and where the air-tight seal supports an internal pressure in the container. The operations also include detecting the internal pressure based on information from a pressure sensor; determining that the internal pressure is not at a target pressure and, based on determining that the internal pressure is not at the target pressure, controlling the probe either to aspirate air from the container or to dispense air into the container in order to move the internal pressure toward the target pressure.

A cartridge reader controlled by processing means for carrying out a diagnostic test on a sample contained in a fluidic cartridge comprises a mechanical valve for isolating the sample with the cartridge. A system for actuating the mechanical valve comprises an actuation member configured to move the mechanical valve from an open position to a closed position and an armature connected to the actuation member. The armature is configured to engage an electromagnet, wherein the electromagnet can be switched between an active state in which it electromagnetically holds the armature and an inactive state in which it does not electromagnetically hold the armature. First biasing means are disposed between the actuation member and a bearing surface, wherein the first biasing means is configured to bias the actuation member into a first position in which it actuates a mechanical valve in a fluidic cartridge inserted into the reader.

The invention provides integrated Organ-on-Chip microphysiological systems representations of living Organs and support structures for such microphysiological systems.

An automated pipetting system includes a pipettor. The pipettor includes a pipetting channel, a first plunger mechanism operable to change a pressure in the pipetting channel to aspirate or dispense a liquid, and a second plunger mechanism operable to change the pressure in the pipetting channel to aspirate or dispense the liquid.