RU2636513C1 - Method of manufacturing cuvet for analysis of liquid samples - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: method of manufacturing a cuvet for the analysis of liquid samples includes the installation of cappings of a given thickness on the object parallel plate, placing on top of cappings of covering plane-parallel plate, fixing the resulting structure with the help of these devices, the introduction into the gap between the plates along the perimeter of adhesive composition and exposure in this state during the time required for its curing. Wherein in the subject plate two holes are made for pumping of analyzed samples, on the inner surface of the subject plate from the outside perimeter of the analytical zone closed-loopg groove is made, cappings are set adjacent outside to the groove, and the tightning of fastening device when fixing the structure is made taking into account the thickness of cappings.EFFECT: invention provides a cuvet with a predetermined volume of the measuring chamber, reduction in the time required for the analysis.2 cl, 1 dwg

Description

The invention relates to the field of medical and analytical technology and can be used in the manufacture of cuvettes for the analysis of liquid samples in thin layers, for example, samples of physiological fluids of humans, animals or plants, drinking and food products, water samples from various sources, other organic and inorganic liquids nature.

The trend towards miniaturization, acceleration and personalization of analysis and diagnostics has led to the creation of cuvettes that allow the analysis of very small amounts of fluid. For example, in analyzes using optical methods, the thickness of the liquid layer in the cuvettes is comparable, for example, with the size of blood cells and is only tens of microns. Moreover, the equipment allows you to automatically and accurately calculate the number of particles per unit volume of liquid. For such measurements, the requirement for the accuracy of maintaining the geometry of the cell (thickness of the liquid sample layer, its volume, etc.) increases. The very geometry of the cell for accurate rapid measurements is complicated and, as a rule, contains an input through which the sample enters the inner chamber, where the analysis takes place, and the output is to remove the sample after analysis. It is important that the fluid can move freely inside the cell and completely fill the measuring volume of the chamber in which the analysis takes place. If the fluid flow is difficult, it may be difficult to fill the chamber, the need for additional operations, which will complicate and lengthen the analysis procedure, reduce its accuracy (if the measuring volume of the chamber is incomplete with the sample material) or makes it completely impossible.

The most famous optical device designed to count the number of cells in a given volume of liquid is still the Goryaev’s camera (see, for example, https://cldtest.ru/hdbk/chamber), consisting of a thick glass slide having a rectangular recess ( camera) coated with a microscopic grid and a thin coverslip.

The main disadvantage of the known camera is the duration of the analysis with its help, associated with a certain sequence of preparation of the camera for use, requiring up to 30-40 minutes before each study.

Optical cuvettes are known (see, for example, patent RU 90206, IPC G01N 21/03, publ. 12/27/2009) formed by tightly folded together two plane-parallel plates, in one of which a recess of a certain shape is made from the side facing the second ( in the presented patent in the form of a spherical segment).

The manufacture of known cuvettes requires sophisticated equipment, and their use does not provide high accuracy of the results, since the actual thickness of the sample layer still depends on the contact density of the plates with each other (in fact, such cuvettes can in principle be considered as Goryaev’s camera options).

The closest to the claimed technical solution from the point of view of the result obtained is a method of connecting the elements of the transformer magnetic circuit with each other (see patent RU 2564441, IPC H01F 27/24, H01F 41/02, publ. 10.10.2015), including applying to the mating surface one from elements of an insulating adhesive composition containing powder, the particle sizes of which are equal to a given value of the gap between the elements of the magnetic circuit, the connection of the surfaces of the elements with each other, fixing the resulting structure using a tightening camping equipment and maintaining in this state for the time required to cure the adhesive.

Using this method provides a high-tech connection of the elements of the magnetic circuit with the same insulating gap over the entire surface of the connection between them with any given value, that is, provides constant parallelism of the surfaces of the elements of the device with a high degree of accuracy.

However, the use of this method is impossible for the manufacture of cuvettes for the analysis of liquid samples, since the adhesive composition, ensuring the parallelism of the inner surfaces of the connected elements of the cuvette, will occupy the entire internal volume and, accordingly, the studied liquid sample will have nowhere to put.

The task to which the claimed technical solution is directed is the possibility of simple and reliable manufacture of cuvettes with the same size of the gap between the elements forming the internal volume for the placement of samples.

The technical result of the invention is to obtain a cuvette with a given volume of the measuring chamber, which reduces the time for analysis.

The technical result is achieved due to the fact that in the method of manufacturing a cuvette for analyzing liquid samples, which includes installing gaskets of a given thickness on an object plane-parallel plate, placing the cover plane-parallel plates on top of the gaskets, securing the resulting structure with a contracting device, introducing the perimeter into the gap between the plates adhesive composition and keeping in this state for the time necessary for its curing, two holes are performed in the plate TIFA samples analyzed for pumping, operate closed loop groove laying mounted adjacent the outside of the groove and tightening the tightening device when attaching structure produced with respect to the predetermined thickness of the spacers on the inner surface of the subject outside the perimeter of the plate assay area.

Moreover, during the introduction into the gap between the plates along the perimeter of the adhesive composition through the holes for pumping the analyzed samples, it is possible to control the pressure in the internal volume between the plates.

The claimed technical solution is illustrated by the drawing, which shows the Assembly of the cell, side view.

The manufactured cell contains an object plane-parallel plate 1 with holes 2 and 3 for pumping the analyzed samples and a groove 4, a cover plane-parallel plate 5, gaskets 6, adhesive composition 7. The design of the cell is fixed using a tightening device 8.

The manufacture of the cell using the proposed method is as follows.

Initially, holes 2 and 3 are made in the subject plate 1 by any known method, intended for pumping a liquid sample through the analytical zone. The holes are positioned so that the sample pumped through them is guaranteed to occupy the entire volume of the analytical zone of the cell. Next, on the surface of the plate 1, which will be facing inward during assembly, a closed circuit groove 4 is made so that the analytical zone of the cuvette and holes 2 and 3 are placed inside the closed circuit of the groove 4. Then, gaskets 6 are mounted on the plate 1 so that they adjoin on the outside to the contour of the groove 4, on top of the gaskets 6 place a cover plate 5 and fix the resulting structure using a contracting device 8. Next, around the perimeter into the gap between the surfaces of the subject and cover plate stinki 1 and 5, the liquid adhesive composition is administered 7 in a definite quantity (based on the volume between the plates outside the grooves 4 circuit). Since the gap is of the order of 10 ^-4 -10 ^-5 m, the leakage of the adhesive composition 7 between the plates occurs under the action of capillary forces. At the same time, the presence of excess adhesive 7 in the volume of the analytical zone of the cell is prevented by the presence of a closed circuit groove 4, in which such excess (if any) remains. After the adhesive composition has hardened, the tightening device 8 is removed. The cuvette is ready for use. Its internal volume is completely sealed around the perimeter from the external environment (the presence of holes 2 and 3 is not taken into account, since they will be connected to the sample pumping system), the analytical zone of the cell is completely free of adhesive composition, and the gap between the inner surfaces of the subject and cover plates 1 and 5 is the same anywhere and equal to the known thickness of the gaskets 6.

It should be added that for better control of the leakage of the adhesive composition 7 between the subject and cover plates 1 and 5, it is possible to regulate the pressure in the internal volume of the cuvette by connecting to the openings 2 and 3, for example, a pump, which, if necessary, can create either excess pressure or vacuum .

Subsequently, during the operation of the cuvette, one of the holes (for example, 2) is connected to the sample feeder, and the other (respectively, 3) to the pumping device (for example, a vacuum pump). The sample, falling into the analytical zone of the cuvette, is examined using a microscope, then the sample is removed, the internal volume of the cuvette is cleaned, after which the next study can be carried out.

The volume of the test sample in each case is known, because it is equal to the product of the gap between the plates 1 and 5 by the microscope capture area (it can be from 1 to 5-6 mm). The deflection of the cover plate 5 can not be taken into account, since with the size of the analytical zone not more than 10 mm, it is practically absent.

The claimed technical solution allows the industrial production of simple and reliable in operation cuvettes for the analysis of liquid samples in thin layers ranging from 10 to 100 μm.

Claims (2)

1. A method of manufacturing a cuvette for analyzing liquid samples, including installing gaskets of a predetermined thickness on an object plane-parallel plate, placing the coating plane-parallel plates on top of the gaskets, securing the resulting structure with a tightening device, introducing the adhesive into the gap between the plates and keeping it in this state during the time necessary for its curing, characterized in that in the subject plate two holes for pumping analysis sampling samples, a closed loop groove is made on the inner surface of the plate outside the perimeter of the analytical zone, the gaskets are installed adjacent to the groove, and the tightening device is tightened when fixing the structure taking into account the specified thickness of the gaskets. 2. The method according to p. 1, characterized in that during the introduction into the gap between the subject and the coating plane-parallel plates around the perimeter of the adhesive composition through the holes for pumping the analyzed samples, the pressure in the internal volume between the plates is controlled.

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