The present invention relates to the use of a control marker for implementing analysis methods on spots, in particular in the context of multiplex analyses. The present invention thus relates to solid supports containing said control marker, their preparation method and their use in analysis methods. The present invention makes it possible to verify the presence, location and/or integrity of the spots at the end of the analysis method, and thus to secure the obtained results while guaranteeing that the yielded result indeed results from a present, intact and localized spot.

There are provided a urine testing apparatus and a urine testing method which can stabilize urine vitamins for several days and improve testing accuracy and convenience of a urine collection test of a subject. According to this urine testing apparatus, the inner wall surface of a urine collection storage container is coated with an aqueous citric acid solution or the like as a urine stabilizer. Alternatively, a dried or freeze-dried aqueous citric acid solution or the like as the urine stabilizer is stored in the urine collection storage container. On the other hand, according to the urine testing method of this invention, the aqueous citric acid solution or the like as the urine stabilizer is added to the collected urine sample, the vitamin concentration of at least 7 days after urine collection is stabilized to stabilize each urine vitamin for several days, thereby improving the convenience of the urine collection test of the subject. In particular, the urine concentrations of vitamins B can be stabilized to accurately test the nutrients lacking in the body of the subject.

There are provided a urine testing apparatus and a urine testing method which can stabilize urine vitamins for several days and improve testing accuracy and convenience of a urine collection test of a subject. According to this urine testing apparatus, the inner wall surface of a urine collection storage container is coated with an aqueous citric acid solution or the like as a urine stabilizer. Alternatively, a dried or freeze-dried aqueous citric acid solution or the like as the urine stabilizer is stored in the urine collection storage container. On the other hand, according to the urine testing method of this invention, the aqueous citric acid solution or the like as the urine stabilizer is added to the collected urine sample, the vitamin concentration of at least 7 days after urine collection is stabilized to stabilize each urine vitamin for several days, thereby improving the convenience of the urine collection test of the subject. In particular, the urine concentrations of vitamins B can be stabilized to accurately test the nutrients lacking in the body of the subject.

An insertion-type probe main body for insertion into a pipe transporting gas and a method for making such an insertion-type probe main body are provided. The probe main body includes: an elongate upper tubular portion; an elongate lower tubular portion which is integral with and having a diameter smaller than the upper tubular portion; a bore which extends between the upper and lower tubular portions; and helical fins integrally formed on the lower tubular portion and which wind along and around an outer surface of the lower tubular portion and which overlap each other. A radial extension of the lower tubular portion plus helical fins corresponds to an external radius of the upper tubular portion, so that the helical fins extend in a streamline fashion from the upper tubular portion. Numerous other aspects are provided.

An analytical system and method for detecting volatile organic chemicals in water including a coated SAW detector that provides for improved reduction of moisture at the coating of the SAW detector. A stabilized SAW sensitivity and long lasting calibration is achieved. The analytical system further includes an improved sample vessel and sparger that allow for easy grab sample analysis, while also providing efficient purging of the volatile organic compounds from the water sample. In addition, an improved preconcentrator provides a stabilized sorbent bed.

An analytical system and method for detecting volatile organic chemicals in water including a coated SAW detector that provides for improved reduction of moisture at the coating of the SAW detector. A stabilized SAW sensitivity and long lasting calibration is achieved. The analytical system further includes an improved sample vessel and sparger that allow for easy grab sample analysis, while also providing efficient purging of the volatile organic compounds from the water sample. In addition, an improved preconcentrator provides a stabilized sorbent bed.

A porous polymer monolith comprises a polymer body having macroporous through-pores that facilitate fluid flow through the body and an array of mesopores adapted to bind from the fluid flow molecules of a predetermined range of sizes, wherein the surface area of the monolith is predominantly provided by the mesopores. Also disclosed is a method of making a porous polymer monolith. The method includes forming a polymer body by phase separation out of a solution containing at least a monomer, a crosslinker and a primary porogen, whereby the body contains multiple macroporous through-pores, wherein the solution further contains a secondary porogen comprising oligomers inert with respect to the monomer and cross-linker but chemically compatible with the monomer so as to form mesostructures within the polymer body during said phase separation, and washing the mesostructures from the body to provide an array of mesopores such that the surface area of the monolith is predominantly provided by the mesopores.

A porous polymer monolith comprises a polymer body having macroporous through-pores that facilitate fluid flow through the body and an array of mesopores adapted to bind from the fluid flow molecules of a predetermined range of sizes, wherein the surface area of the monolith is predominantly provided by the mesopores. Also disclosed is a method of making a porous polymer monolith. The method includes forming a polymer body by phase separation out of a solution containing at least a monomer, a crosslinker and a primary porogen, whereby the body contains multiple macroporous through-pores, wherein the solution further contains a secondary porogen comprising oligomers inert with respect to the monomer and cross-linker but chemically compatible with the monomer so as to form mesostructures within the polymer body during said phase separation, and washing the mesostructures from the body to provide an array of mesopores such that the surface area of the monolith is predominantly provided by the mesopores.

A field flow fractionator (FFF device) 1 classifies particles in a liquid sample by applying a field to a liquid sample supplied from a sample injection device 5. A detector 6 detects the particles in the liquid sample classified by the FFF device 1. A bypass flow path 8 supplies the liquid sample from the sample injection device 5 to the detector 6 without via the FFF device 1. A rotary valve (flow path switching unit) 4 switches a flow path to guide the liquid sample from the sample injection device 5 to the FFF device 1 or a bypass flow path 8. The bypass flow path 8 is provided with a concentration adjusting device 9 for adjusting the concentration of the liquid sample from the sample injection device 5. In a case where a sample with the same quantity as the sample supplied to the FFF device 1 is supplied to the bypass flow path 8 at the time of analysis, the sample is diluted by the concentration adjusting device 9 such that a detection signal from the detector 6 falls within a dynamic range.

A field flow fractionator (FFF device) 1 classifies particles in a liquid sample by applying a field to a liquid sample supplied from a sample injection device 5. A detector 6 detects the particles in the liquid sample classified by the FFF device 1. A bypass flow path 8 supplies the liquid sample from the sample injection device 5 to the detector 6 without via the FFF device 1. A rotary valve (flow path switching unit) 4 switches a flow path to guide the liquid sample from the sample injection device 5 to the FFF device 1 or a bypass flow path 8. The bypass flow path 8 is provided with a concentration adjusting device 9 for adjusting the concentration of the liquid sample from the sample injection device 5. In a case where a sample with the same quantity as the sample supplied to the FFF device 1 is supplied to the bypass flow path 8 at the time of analysis, the sample is diluted by the concentration adjusting device 9 such that a detection signal from the detector 6 falls within a dynamic range.