The object of the invention is to avoid a decrease in dispensing accuracy of a sample, a reagent, or the like as a temperature changes. In an automatic analyzer, a dispensing nozzle sucks the sample from a sample container holding the sample and discharges the sample to a reaction container. A syringe pump controls an amount of change in a volume of water. A first pipe connects the dispensing nozzle and the syringe pump. An electromagnetic valve flows or stops the water. A second pipe connects the electromagnetic valve and the syringe pump. A branch pipe branches the water. A third pipe connects the electromagnetic valve and the branch pipe. A case accommodates at least the syringe pump, the first pipe, the electromagnetic valve, the second pipe, the branch pipe, and the third pipe. Further, the third pipe includes a heat exchange unit that performs heat exchange of the water.

A biological sample processing apparatus, including: a pipette block with which a plurality of pipettes for sucking or discharging a biological sample in a multi-well plate in which wells are arranged in a matrix shape along row and column directions are detachably coupled; a pipette block forward and backward transfer unit configured to move the pipette block along a forward and backward direction along a process direction; a pipette block top and bottom transfer unit configured to move the pipette block along a vertical direction; a magnetic field applying unit disposed below the multi-well plate for applying a magnetic field to a well of the multi-well plate; and a heating unit disposed below the multi-well plate so as to be spaced apart from the magnetic field applying unit, for heating a well of the multi-well plate.

The present invention relates to a heat preservation shell (4) for an analyzer. At least one liquid passage (402) for conveying the liquid is embedded in a shell wall of the heat preservation shell. The liquid passage (402) is embedded in the shell wall of the heat preservation shell (4), on one hand, the liquid transported or preserved in the liquid passage is subjected to the heat preservation function of the heat preservation shell, so that the liquid transported or preserved in the liquid passage (402) maintains the preset temperature, thereby avoiding the influence of the external environment temperature on the transported liquid; and on the other hand, the space of the shell wall of the heat preservation shell is effectively utilized, the situation that various liquid pipelines are intricately distributed inside or outside the heat preservation shell (4) is avoided, thereby increasing the space utilization rate.

An automatic analyzer for analyzing a medical probe includes an analysis cell for the probe, a piezo element, and an analysis device. The piezo element can be operated by applying a voltage and a frequency, and in the process an acoustic wave field is generated. A probe located in the analysis cell is located in the acoustic wave field when the piezo element is being operated.

Application of the present invention enables quantification of fractions of candidate pharmaceutical compounds (a parent compound and its metabolites), one excreted to the basolateral (Basal/Basolateral)-side via transporters and by diffusion, one excreted to the lumen (Apical)-side, and one remained in the cells. This enables determination of the total amount of the administered candidate pharmaceutical compounds and the distribution ratio of the fractions. The kinetics of the administered candidate pharmaceutical compounds can be evaluated, thereby enabling in vitro screening of an enormous number of candidate pharmaceutical compounds for drug candidates exhibiting the efficacy. The object of the present invention is to provide an apparatus and method for understanding a total picture of pharmacokinetics in vitro by quantifying a fraction of basolateral (Basal/Basolateral) efflux, a fraction of lumen (Apical)-side excretion, and a fraction remaining in a cell of a drug which has been administered to the cell to determine the distribution ratio of each fraction.

The object of the invention is to avoid a decrease in dispensing accuracy of a sample, a reagent, or the like as a temperature changes. In an automatic analyzer, a dispensing nozzle sucks the sample from a sample container holding the sample and discharges the sample to a reaction container. A syringe pump controls an amount of change in a volume of water. A first pipe connects the dispensing nozzle and the syringe pump. An electromagnetic valve flows or stops the water. A second pipe connects the electromagnetic valve and the syringe pump. A branch pipe branches the water. A third pipe connects the electromagnetic valve and the branch pipe. A case accommodates at least the syringe pump, the first pipe, the electromagnetic valve, the second pipe, the branch pipe, and the third pipe. Further, the third pipe includes a heat exchange unit that performs heat exchange of the water.

Reagent cartridges and related systems and methods for controlling reagent temperature are disclosed. In accordance with an implementation, an apparatus includes a system and a reagent cartridge. The system includes a reagent cartridge receptacle, a non-contact temperature controller, a processor operatively coupled to the temperature controller. The reagent cartridge is receivable within the reagent cartridge receptacle and includes a flow cell assembly, a plurality of reagent reservoirs, and a manifold assembly. The manifold assembly includes a common fluidic line and a plurality of reagent fluidic lines. Each of the plurality of reagent fluidic lines is adapted to be fluidically coupled to a corresponding reagent reservoir and selectively couplable to the common fluidic line. The processor is to cause the temperature controller to change a temperature of at least one of the common fluidic line or one or more of the reagent fluidic lines.

Means for determining whether or not a reagent necessary for a chemical reaction is normally discharged is provided for a liquid dispensing device that dispenses the reagent for the reaction. A liquid dispensing device as such means includes a temperature controller that controls a temperature of a reaction position to any appropriate temperature and a temperature monitor part that monitors the temperature of the reaction position, monitors with the temperature monitor part a change in the temperature of the reaction position when the dispensing device discharges a reagent, and when a temperature change amount deviates from a beforehand determined threshold range, determines abnormal dispensation.

According to one embodiment, an automatic analyzing apparatus includes a probe and a liquid level detector. The liquid level detector is electrically connected to the probe and detects contact between the probe and a liquid surface, wherein the liquid level detector comprises an adjuster configured to adjust electrostatic capacitance of one or more capacitors for circuitry for use in liquid level detection.

A high-throughput automatic analyzer integrates a biochemical analysis section and a blood coagulation analysis section. The analyzer is capable of achieving a reduction in size, system cost, and lifecycle cost. The automatic analyzer includes: a reaction disk; a first reagent dispensing mechanism that dispenses a reagent to reaction cells on the reaction disk; a photometer that irradiates a reaction solution in the reaction cell with light; a reaction cell cleaning mechanism; a reaction vessel supply unit that supplies a disposable reaction vessel for mixing and reacting a sample and a reagent with each other; a second reagent dispensing mechanism that dispenses a reagent to the disposable reaction vessel; a blood coagulation time measuring section that irradiates a reaction solution in the disposable reaction vessel with light to detect transmitted or scattered light; and a sample dispensing mechanism that dispenses a sample to the reaction cell and the disposable reaction vessel.