A solution for evaluating a sample gas for a presence of a trace gas, such as ozone, is provided. The solution uses an ultraviolet source and an ultraviolet detector mounted in a chamber. The chamber can include reflecting walls and/or structures configured to guide ultraviolet light. A computer system can operate the ultraviolet source in a high power pulse mode and acquire data corresponding to an intensity of the ultraviolet radiation detected by the ultraviolet detector while a sample gas is present in the chamber. Using the data, the computer system can determine a presence and/or an amount of the trace gas in the sample gas.

A solution for evaluating a sample gas for a presence of a trace gas, such as ozone, is provided. The solution uses an ultraviolet source and an ultraviolet detector mounted in a chamber. The chamber can include reflecting walls and/or structures configured to guide ultraviolet light. A computer system can operate the ultraviolet source in a high power pulse mode and acquire data corresponding to an intensity of the ultraviolet radiation detected by the ultraviolet detector while a sample gas is present in the chamber. Using the data, the computer system can determine a presence and/or an amount of the trace gas in the sample gas.

A capillary cell is described along with an arrangement and a method for receiving, positioning and examining a microscopic specimen, in particular a cleared fluorescent specimen with the help of a single-plane fluorescence microscope. The capillary cell is suitable for being positioned in a chamber volume and contains a capillary section, which comprises a wall. The wall encloses a specimen volume and is planar and transparent in at least some sections. In addition, the capillary cell includes an upper and a lower closure section, which are connected to the capillary section and which seal the capillary section. The specimen volume is separated from the chamber volume by the capillary section, the upper closure section and the lower closure section.

A capillary cell is described along with an arrangement and a method for receiving, positioning and examining a microscopic specimen, in particular a cleared fluorescent specimen with the help of a single-plane fluorescence microscope. The capillary cell is suitable for being positioned in a chamber volume and contains a capillary section, which comprises a wall. The wall encloses a specimen volume and is planar and transparent in at least some sections. In addition, the capillary cell includes an upper and a lower closure section, which are connected to the capillary section and which seal the capillary section. The specimen volume is separated from the chamber volume by the capillary section, the upper closure section and the lower closure section.

A calibration suspension unit has a container made of a flexible material that is filled with a calibration suspension for the calibration of a turbidity meter. There exists no air supernatant above the calibration suspension in the container. Further, a method for the manufacture of a calibration suspension unit is provided and its use for the calibration of a turbidity meter is described.

A calibration suspension unit has a container made of a flexible material that is filled with a calibration suspension for the calibration of a turbidity meter. There exists no air supernatant above the calibration suspension in the container. Further, a method for the manufacture of a calibration suspension unit is provided and its use for the calibration of a turbidity meter is described.

Embodiments for local and safe testing of injection fluids by drawing a sample of injection fluid into a local test chamber while drawing fluid to be tested into a syringe assembly and testing the sample of the injection fluid are disclosed. A fluid test device can include a syringe assembly, a plunger assembly, and a test module. The test module can determine information about fluid in a syringe assembly when the fluid enters a test chamber in the test module. Fluid may enter the test chamber through a one-way valve while a plunger in the plunger assembly is moved in a suction stroke to draw fluid into an interior of the syringe assembly. Fluid may not enter or be expelled from the test chamber when the plunger does not move or is moved in a compression stroke to expel fluid from the syringe assembly.

The present disclosure relates to a biochemical detection instrument. The technical solution is an automatic reactive oxygen species content detection system suitable for a cell microenvironment that includes: a sample transmission reaction system and a detection system which are communicated in sequence through a light avoiding pipeline. A washing system is in communication with the sample transmission reaction system through a water pipeline, and a purge system is in communication with the sample transmission reaction system through a gas pipeline. The sample transmission reaction system further includes a sample injector and a DCFH supply bin which are communicated with a reaction bin through light avoiding pipelines after being connected in parallel. Sample injection valves are respectively configured between the sample injection valve and the reaction bin and between the DCFH supply bin and the reaction bin.

The present disclosure relates to a biochemical detection instrument. The technical solution is an automatic reactive oxygen species content detection system suitable for a cell microenvironment that includes: a sample transmission reaction system and a detection system which are communicated in sequence through a light avoiding pipeline. A washing system is in communication with the sample transmission reaction system through a water pipeline, and a purge system is in communication with the sample transmission reaction system through a gas pipeline. The sample transmission reaction system further includes a sample injector and a DCFH supply bin which are communicated with a reaction bin through light avoiding pipelines after being connected in parallel. Sample injection valves are respectively configured between the sample injection valve and the reaction bin and between the DCFH supply bin and the reaction bin.

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.