RU141657U1 - URINE ANALYZER - Google Patents

Abstract

1. Urine analyzer, characterized in that it includes a housing with receptacles located on the front part with analyzed samples, controls and data output devices, radiation sources located inside the housing, a directing optical system with flow-conducting channels, diaphragms and deflecting elements, radiation detectors , an analytical module with devices for fixing containers with liquid samples, allowing radiation to pass through liquid samples, an integrated microprocessor that serves to control phenomena by the analyzer, input and output of data, calculations and processing of measurement results, a device for outputting data, characterized in that at least two diaphragms are used in the guiding optical system, which allow generating a radiation flux with a given width and angle of divergence. 2. The urine analyzer according to claim 1, characterized in that the design of the nests for fixing the containers with samples in the analytical module is solved in such a way that the radiation flux passed through the liquid samples passes through the middle part of the liquid sample column, without falling into the rounding area of the tank bottom and the meniscus area liquid samples, which are areas of optical distortion. 3. The urine analyzer according to claim 1, characterized in that the design of the nests for fixing the containers with samples in the analytical module ensures that the containers are fixed in the horizontal plane with the help of fixing elements of a triangular profile with springing. 4. The urine analyzer according to claim 1, characterized in that the design of the nests for fixing the containers with samples in the analytical module is solved in such a way

Description

The patented utility model relates to measuring equipment, in particular, to urine analyzers.

Diagnostic testing of urine is used in the following main areas of medicine: hematology, molecular biology, microbiology.

There are three main types of analyzers used in the laboratory practice of small hospitals: 1) analyzers for hematology; 2) analyzers for immunology; 3) analyzers for clinical biochemistry.

For conducting microbiological analyzes at present, special tools are not required, because they are usually carried out using visualization of microbial cultures.

The most common types of clinical tests are based on the use of photometry. They include procedures such as adding reagents to the test sample; incubation after addition of reagents; measuring the absorption of the resulting mixture at different frequency ranges of transmitted radiation; calculations of the concentration of components based on the construction of calibration curves. However, the accuracy of such measurements will strongly depend on the optical lengths and properties of the walls of the containers containing the test sample. The dependence of measurements on the accuracy of manufacturing containers is a factor that significantly increases the cost of photometric analyzes.

The next type of analysis is based on the use of fluorescence of the analyzed mixture, the intensity of which is proportional to the concentration of the component. To do this, instead of the reagent - a chromogenic substrate - use the corresponding fluorogenic substrate. As a rule, this type of analysis is more often used in scientific research, less often in clinical laboratories. This is due to the fact that the high accuracy and breadth of the range of such measurements are more in demand both in scientific research and important in clinical research.

There is a large list of types of clinical tests that use an enzyme that acts either as an analyte component or as a reaction catalyst. The reaction using the enzyme as a catalyst changes the structure of the substrate molecule, which leads to a change in its absorption characteristics. Depending on the concentration of the analyzed component in the sample, the photometry result for a given frequency of transmitted radiation changes. If the analyzed component is a substrate, and the enzyme acts as a reagent, then, at the end of the reaction, the measurement can be carried out at the end point. If the enzyme serves as an analyte, the measurement can be carried out kinetically. In these cases, a quantitative assessment of the sample is performed at given time points, followed by calculation of the concentration based on the kinetics equations embedded in the program. (Programs are described in the literature).

In the health systems of developed countries, much attention is paid to improving the cost-effectiveness of analytical equipment, in particular, analyzers. In light of this, not only the reduction in the cost of analytical procedures, but also the increase in the number of analyzes is of particular importance. In fact, these measures are not feasible in small towns, or for conditions of rapid diagnosis, therapy in emergency situations or outpatient duty. In this regard, there is growing interest in finding ways to reduce the cost of production and operation of such equipment.

A device for analysis (RU 2282196, WO 02/090995 11/14/2002, G01N 35/00), comprising a cartridge for analysis, comprising at least one cell and a pipette that can be placed in at least one of these cells; a holder configured to place a specified cartridge therein; a moving mechanism configured to place said pipette into selected cells of said cartridge; gas pressure application means configured to attach to said pipette in order to cause fluid to flow through said membrane; and a radiation sensor for detecting radiation from a cell of said cartridge or from said pipette. The declared technical result is an increase in the accuracy of quantitative analysis for conducting a wide range of studies. However, despite the fact that this device uses the same principle of transmitting radiation through the analyzed samples, there are a large number of structural elements and moving units that complicate the device itself, as well as its manufacture and operation, which reduces its technical reliability and increases the cost of manufacture and operation .

A useful model of the biochemical analyzer Blood, urine measuring biochemical analyzer (CN 201043970 (Y) - 2008-04-02, G01N 33/50, G01N 21/00), for analysis of blood and urine, including a light source control circuit, an optical a system for measuring blood and urine parameters that converts a light signal into an electrical signal; signal amplification system; drive circuitry that converts electrical signals into a digital system; electronic analytical and control system that calculates and compares the measured values; and a data delivery system. The systems are connected by transmitting electrical and electronic signals. The declared technical results are due to the fact that using such a system of hardware and software for measuring blood and urine samples, respectively, a biochemical analyzer helps to reduce costs to a level acceptable for the popularization of biochemical analytical devices in medical institutions at all levels. However, the design features leave it possible to propose simpler solutions, in particular, to exclude the light source control system.

A useful model of the Dry-type urine / blood biochemical analyzer for one-step determination of urine biochemical index (CN 202133608 (U) - 2012-02-01, G01N 21/27) is disclosed, which discloses a dry-type dry blood / urine analyzer for single-stage determination of biochemical parameters of urine. The analyzer includes an optical detection system capable of converting a light signal into an electrical signal, an amplifier circuit, an analog-to-digital circuit for converting an electrical signal into a digital signal, a single-processor analytical control system for calculating and comparing the determined values, a result output system, a frequency control signal output circuit, and a light source control circuit in which an end of an output signal of an optical determination system is connected to an end of an input signal of a circuit y silitel; the end of the signal output of the amplifier circuit is connected to the end of the signal input of the analog-to-digital converter circuit; the output of the analog-to-digital converter circuit is connected to the receiving end of a single-processor analytical control system; the output end of a single-processor analytical control system is connected to the receiving end of the output system; and a specific signal is input to the output system and a specific result is output, depending on the result of the output system. The declared accuracy of the measurement is achieved due to the rather complex device, which reduces the reliability, significantly increases the cost of the device and its operation. The device leaves room for new technical solutions that simplify the device and operation, shorten the analysis process, and reduce cost performance.

As the closest analogue, a useful model of the Blood1 biochemical analyzer, urine measuring biochemical analyzer (CN 201043970 (Y) - 2008-04-02, G01N 33/50, G01N 21/00) is considered.

The task to which the claimed technical solution is directed is to realize the following advantages:

- in expanding the arsenal of technical means in this area,

- to increase the accuracy and stability of the analyzer,

- ensuring low cost of production of the analyzer.

This problem is solved by implementing a new design of the urine analyzer, which is a portable device designed to determine the protein and creatinine content in the urine, as well as to calculate the protein / creatinine ratio. The analyzer includes: a case with receptacles for analyzing samples located on the front part, control elements and data output devices, radiation sources located inside the case, a directing optical system with flow channels, diaphragms and deflecting elements, radiation receivers, an analytical module with capacitor fixing devices with liquid samples, allowing radiation to pass through liquid samples, an integrated microprocessor used to control the analyzer, input and output house data, calculation and processing of the measurement results, the device for data output. In the patented urine analyzer, in the guide optical system, at least two diaphragms are used, which make it possible to form a radiation flux with a given width and angle of divergence. The design of the nests for fixing containers with samples in the analytical module is solved in such a way that radiation fluxes passing through liquid samples pass through the middle part of the column of liquid sample, without falling into the region of curvature of the bottom of the container and the meniscus region of the liquid sample, which are regions of optical distortions. The design of the sockets for fixing containers with samples in the analytical module ensures the fixing of containers in the horizontal plane with the help of fixing elements of a triangular profile with spring-loaded. The design of the sockets for fixing the containers with samples in the analytical module is solved in such a way that when the containers are installed, their bottom parts are pressed on the microswitches that supply the signal to the microprocessor, including radiation sources.

The technical result provided by the given set of features is the absence of the need for alignment of the optical system, which allows the use of radiation sources of any quality, the absence of measurement errors due to optical distortions in the areas of the bottom of containers with liquid samples and menisci in liquid samples, increasing the reliability and efficiency of the device for due to the use of microswitches, including the control system of the device at the moment of touching the bottom of the cells with containers with liquid samples.

Patented utility model is as follows. It is known that proteinuria is a diagnostically important symptom of kidney and urinary tract diseases. The concentration of protein in the urine and the ratio of protein / creatinine concentrations are important indicators for the diagnosis of diseases of the urinary system of the patient's body and for monitoring treatment. During the day, fluctuations in the level of proteinuria occur, depending on diuresis, the concentration of protein in the urine changes. The severity of proteinuria is usually estimated by the daily amount of protein excretion in the urine. In cases where it is not possible to collect all daily urine, it is recommended to determine the concentrations of creatinine and protein in a “random” urine sample.

The rates of creatinine and protein excretion during the day are quite stable and do not depend on changes in the rate of urination. In this case, the ratio of protein concentration to creatinine concentration is constant and does not depend on the time of collection of the urine sample. The protein / creatinine ratio reflects the protein content in daily urine quite well.

The advantage of protein / creatinine evaluation methods is the elimination of errors associated with the inability to receive or incomplete collection of daily urine. Since the rate of creatinine release strongly depends on the gender, age and physical condition of people, in this case, it is proposed to use the reduced concentration of protein to creatinine to bring the protein / creatinine ratio to a single standard.

Determination of protein concentration in urine using an analyzer is based on a method that uses the formation of complexes of protein molecules with molecules of sodium molybdate and pyrogallol red dye. Determination of creatinine concentration in urine is based on the use of the reaction of creatinine molecules with picric acid molecules in an alkaline solution (Yaffe method). Determination of protein and creatinine concentrations is carried out using reagents introduced into liquid urine samples. The given concentration of protein to creatinine is equal to the product of the protein / creatinine ratio and the standard creatinine concentration corresponding to the daily creatinine excretion in this patient. The reduced protein concentration for creatinine has the same protein concentration dimension (g / l) and expresses its daily excretion for a given patient.

The analyzer uses a bichromatic measurement technique: the difference in the optical densities of the measured samples (relative to the blank samples) at the primary and auxiliary wavelengths is measured. Based on this difference, the concentration of protein and creatinine in the sample is calculated.

During operation of the analyzer, the fluxes from the radiation sources enter the directive optical system, which is formed by a set of flux-conducting channels, directing the fluxes of radiation to the deflecting elements, from which they are sent to the containers with liquid samples installed in the sockets of the analytical module. The streams that have passed capacities with liquid samples get to the radiation receiver, the signals from which, through the conversion circuit, are fed to the built-in microprocessor.

The measurement of the characteristics of liquid samples is as follows. Tanks with liquid samples are installed in the sockets of the analytical module. At the same time, microswitches installed at the bottom of the sockets are triggered, as a result of which the microprocessor that controls the radiation sources and analyzer organs is turned on.

After measuring the characteristics of the liquid samples, the built-in display shows the measurement results, which are automatically printed by the printer. The following parameter data is printed:

- the concentration of total protein in the sample in g / l;

- concentration of creatinine in the sample in g / l;

- the ratio of the concentration of total protein to the concentration of creatinine in the sample;

- reduced protein concentration to creatinine concentration in g / l.

The operation procedure on the analyzer consists of the following steps:

- inclusion of the analyzer;

- preparation of blank samples, calibration samples and patient samples.

- Measurement of the characteristics of blank samples.

- Measurement of calibration sample characteristics.

- Measurement of patient sample characteristics.

- Shutdown the analyzer.

Performance and Results

The range of measurements of protein concentration is 0 ÷ 8 g / l. The limit of permissible random error in measuring protein concentration, not more than:

Protein concentration, g / l Error 0.00-0.04 0.008 g / l 0.04-0.30 10% 0.3-1.0 8% 1-8 four%

The range of measurements of creatinine concentration is 0 ÷ 10 g / l. The limit of permissible random error in the measurement of creatinine concentration, not more than:

Creatinine concentration, g / l Error 0,0-0,1 0.006 g / l 0.1-0.4 10% 0.4-1.0 four% 1-10 1.2%

The analyzer is made in the form of a small desktop portable device. The analyzer case material is chemically resistant plastic. The urine analyzer can be equipped with a connector or a wireless computer connection system. The analyzer device is illustrated in FIG. 1, 2, 3, 4, which depict the analyzer of urine and its subsystems in a disassembled state.

The urine analyzer (Fig. 1) includes a housing 1 with slots 2 located on the front for containers with analyzed samples, controls 3, an LCD display 4, an output device 5, as well as a protective cover for slots 6 and a plug for socket 7.

The measuring unit (Fig. 2, 3) includes: an analytical module 8, containers with analyzed samples 9, radiation sources 10, radiation receivers 11, microswitch 12 (optical sensor).

The optical system (Fig. 4) includes: sockets for containers with analyzed samples 2, radiation sources 10, radiation receivers 11, diaphragms 13, flow channels 14, deflecting elements 15.

The principle of operation of the analyzer is based on the fact that when the analyzer is turned on, the radiation flux from several sources 10 enters the guiding optical system (Fig. 4), which is formed by the current-conducting channels 14, directing the radiation flux to the deflecting elements 15 of the system, and then to the liquid sample containers 9, installed in the sockets 2 of the analytical module, then to the radiation receivers 11. In the radiation receivers 11, radiation fluxes are converted into electrical signals that are transmitted to the amplifier input, then to the input d analog-digital converter, the output of which the digitized values of the signals received in the embedded microprocessor. The microprocessor performs the functions of controlling the analyzer, calculating and processing data, outputting the results to the built-in LCD 4, printer 5 or an external computer.

As features that distinguish this utility model from analogues, the following can be distinguished:

- the design of the guide optical system is solved in such a way that radiation from each source, due to the design of the flow-conducting channel, is formed so that it does not depend on the geometry or optical defects of the radiation sources, which eliminates the need for alignment and allows the use of radiation sources of any quality;

- the design of the nests for fixing the containers with liquid samples in the analytical module is solved in such a way that the radiation flux incident on the samples passes through the middle part of the column of liquid sample, without falling into the region of curvature of the bottom of the container and the meniscus of the liquid sample, which eliminates optical distortions that affect accuracy of measurements;

- the design of sockets for fixing containers with liquid samples in the analytical module provides fixation in the horizontal plane with the help of fixing elements of a triangular profile with spring-loaded;

- the design of the sockets for fixing the containers with liquid samples in the analytical module is solved in such a way that the bottom of the tanks rests on the levers of the microswitches, so that when pressed, the microswitches are activated by supplying signals to the microprocessor that controls the inclusion of radiation sources, which increases the consistency of operations, reduces the level of optical distortion, increases the accuracy of measurements.

Claims (4)

1. Urine analyzer, characterized in that it includes a housing with receptacles located on the front part with analyzed samples, controls and data output devices, radiation sources located inside the housing, a directing optical system with flow-conducting channels, diaphragms and deflecting elements, radiation detectors , an analytical module with devices for fixing containers with liquid samples, allowing radiation to pass through liquid samples, an integrated microprocessor that serves to control the analyzer, input and output of data, calculations and processing of measurement results, a device for outputting data, characterized in that at least two diaphragms are used in the guiding optical system, which make it possible to form a radiation flux with a given width and angle of divergence. 2. The urine analyzer according to claim 1, characterized in that the design of the nests for fixing the containers with samples in the analytical module is solved in such a way that the radiation flux passed through the liquid samples passes through the middle part of the liquid sample column, without falling into the rounding area of the container bottom and the meniscus region of the liquid sample, which are areas of optical distortion. 3. The urine analyzer according to claim 1, characterized in that the design of the nests for fixing the containers with samples in the analytical module ensures that the containers are fixed in the horizontal plane with the help of fixing elements of a triangular profile with spring-loaded. 4. The urine analyzer according to claim 1, characterized in that the design of the nests for fixing the containers with samples in the analytical module is solved in such a way that when the containers are installed, their bottom parts are pressed onto microswitches that supply a signal to the microprocessor, including radiation sources.

Images