RU90206U1 - OPTICAL CUVET - Google Patents

Abstract

1. An optical cuvette containing two plane-parallel plates tightly folded together, while in the first plate from the side facing the second plate of optically transparent material, a recess is made, characterized in that the recess is made in the form of a spherical segment, while the arrow of the spherical segment is not exceeds 30 microns, and the ratio of the boom of the spherical segment to the radius of its spherical surface does not exceed 10-4. ! 2. The cuvette according to claim 1, characterized in that the first plane-parallel plate is made of optically transparent material. ! 3. The cuvette according to claim 2, characterized in that a mirror coating is applied to the spherical surface of the recess. ! 4. The cuvette according to claim 2, characterized in that the plane-parallel plates are made of materials having a different spectral dependence of the transmittance.

Description

The utility model relates to biomedical measurement technology, and more specifically, to optical devices designed to study liquid samples in a thin layer.

As follows from the state of the art, optical studies of medical and biological liquid samples in a thin layer are given quite a lot of attention, because in this case, on the one hand, the measurement process is simplified (for example, studying the optical properties of blood allows you to determine blood oxygenation, hemoglobin concentration, hematocrit without laborious methods of its destruction and centrifugation), and on the other hand, the accuracy of determining the optical-luminescent characteristics, for example, microbes, is enhanced by a significant decrease in the effect of the substrate on the measurement results.

For optical studies of liquid in a thin layer, optical cuvettes of various designs are used. So known optical cuvette containing a base made of optically opaque material (metal), and a covering plane-parallel plate made of optically transparent material, while the base has a blind hole of a rectangular shape, the middle part of the bottom of which has a flat shape and is located at a depth of which is less than the depth of the bottom portions of the blind hole located on both sides relative to the above-mentioned middle portion of the bottom. The cover plate is located on top of the base with the formation of a measuring volume between the flat portion of the bottom of the blind hole and the surface portion of the cover plate opposite it, with through holes made for supplying and discharging the test fluid at the base (see application FR-A1-N2628531, 1989).

This optical cuvette has the following disadvantages, namely: the complex design of the base and limited functional capabilities due to the inability to conduct studies of samples in transmitted light.

An optical cuvette is also known, containing two plane-parallel plates of optically transparent material and an annular spacer of deformable material located between them, while the cuvette is placed in a housing made in the form of an annular capsule with a screw cap (see patent RV-C1-N2095787, 1997) . The undoubted advantage of this optical cuvette is the ability to smoothly change the distance between plane-parallel plates with a screw cap over a sufficiently large range. In other words, the well-known optical cuvette allows the study of fluid layers of various thicknesses. However, the absence in the description of the aforementioned patent of specific indications of the material used for the annular gasket does not allow us to consider reliable the statement that it is possible to study fluid layers from one micron. The disadvantages of this optical cuvette include the complexity of the housing design, as well as the complexity in determining the volume of the optical cuvette due to changes in the inner diameter of the gasket when changing its thickness.

An optical cuvette is also known, taken as a prototype and containing two plane-parallel plates of optically transparent material that are tightly stacked together, while in one of the plates, a recess (recess) is made in one of the plates facing the other plate, filled with the test liquid (see. Corporate Catalog German company "STARNA" 1993).

The prototype has a simple design. However, the shape of the notch in one of the plates, on the one hand, allows measurements of the optical parameters of the liquid layers having only a sufficiently large thickness of at least 0.1 mm, and on the other hand, complicates the cleaning and sterilization of the optical cell. In addition, to ensure the measurement of the dependence of the optical properties of a liquid on the thickness of its layer, it is necessary to have a set of optical cuvettes with different depths of recesses. This, on the one hand, complicates the measurement process, and on the other hand, does not allow the above measurements of liquid samples with a volume of 10 ^-1 ÷ 10 ^-3 ml.

This utility model is aimed at solving the technical problem of providing the possibility of measuring with only one optical cuvette the dependence of the optical parameters of liquid samples with a volume of 10 ^-1 to 10 ^-3 ml on the thickness of their layer while simplifying the manufacturing process of the recess, as well as the cleaning process and sterilization of the optical cell.

The problem is solved in that in the optical cuvette containing two plane-parallel plates tightly folded together, while in the first plate, a recess is made on the side facing the second plate of optically transparent material, according to the utility model, the recess is made in the form of a spherical segment, this boom of the spherical segment does not exceed 30 microns, and the ratio of the arrows of the spherical segment to the radius of its spherical surface does not exceed 10 ^-4 .

Due to the patented form of the recess in the first plane-parallel plate of the optical cell, the following technical results are achieved. The accuracy of measurements of the dependence of the optical parameters of the liquid on the thickness of its layer is increased in the case of samples having a small volume of 10 ^-1 to 10 ^-3 ml, since the measurement of the above dependence is carried out on the same sample. The range of variation in the thickness of the measured layer of the liquid sample expands due to the displacement of its lower boundary in the region of 3-4 μm. The process of making a recess with a given volume (in the range from 10 ^-1 to 10 ^-3 ml) is simplified, with a gradually varying depth from the maximum value (corresponding to the arrow of the spherical segment), lying in the range from 8 to 30 microns, and to zero, due to the possibility of using precision equipment well-known in the optical-mechanical industry for the manufacture of polished concave spherical surfaces. The process of cleaning and sterilizing the optical cell is simplified, since the notch is formed by one smooth surface, and, therefore, does not have hard-to-reach places for cleaning and sterilization.

In one preferred embodiment of the utility model, the first plane-parallel plate is made of optically transparent material. This makes it possible to study the properties of a liquid layer in transmitted light.

In another preferred embodiment of the utility model, a mirror coating is applied to the spherical surface of the recess. This ensures an increase in the signal due to the luminescence of the sample components.

In a further preferred embodiment of the utility model, plane-parallel plates are made of materials having different spectral dependences of the transmittance. Due to this, plane-parallel plates also perform the function of light filters, for example, to highlight the spectral components of luminescence or to cut off the spectral region corresponding to the excited luminescence radiation.

Other advantages of a patented optical cell will be described below.

Figure 1 shows a patented optical cuvette, a vertical section; figure 2 is the same, but with a mirror coating.

The optical cuvette (Fig. 1) contains the first plane-parallel plate 1, the second plane-parallel plate 2. The plane-parallel plates 1 and 2, in the preferred embodiment of the utility model, are made of both optically transparent material, namely glass, quartz, etc. However, in the same way as described above (see application FR-A1-N2628531, 1989), the first plate 1 can also be made of an optically opaque material, for example, metal. In assembled form, plane-parallel plates 1 and 2 are tightly folded together, while in the first plate 1 from the side facing the second plate 2, a recess 3 is made in the form of a spherical segment, while the arrow - h of the spherical segment does not exceed 30 μm, and the boom ratio - h to the radius - R of the spherical surface 4 of the spherical segment does not exceed 10 ^-4 .

When performing the above geometric parameters for the recess 3, the error in measuring the dependence of the optical parameters of the liquid on the thickness of its layer using commonly used optical probes with a light beam diameter of 1-2 mm is less than 5%. With an arrow - the h ball segment is greater than 30 μm and with the ratio h / R> 10 ^{-4, the} measurement error of the aforementioned dependence increases due to an increase in the curvature of the spherical surface 4. For current production capabilities, the lower boundary of the h / R ratio is 10 ^-6 . However, there are no fundamental factors preventing the decrease of this value.

In the case of using a patented optical cuvette to study the luminescent properties of a liquid, a mirror coating 5 is applied to the spherical surface 4 of the recess 3. It should be noted here that plane-parallel plates 1 and 2 can be made of materials having different spectral dependences of the transmittance, for example, to prevent passage exciting luminescence radiation through one of the plane-parallel plates. In the drawings, reference numeral 6 denotes the axis of symmetry of the recess 3 (spherical segment), and the distance from it in the horizontal direction is indicated by the letter X. In a plane-parallel plate 1, a groove 7 can be made to divert the excess amount of the liquid sample, shown by a dashed line (figure 2) . While the edge 8 of the groove 7 is adjacent to the upper edge of the spherical surface 4.

A patented optical cuvette of a given volume V and a given boom value h is made with geometric parameters satisfying the following relation. The diameter of the optical cell D is determined from the ratio: , and the radius R of its spherical surface 4 satisfies the relation:

For example, for V = 0.5 mm ² and h = 12.5 μm, we obtain R = 1 m, and D = 10 mm.

Patented cell is used as follows. In disassembled form (with the second plane-parallel plate 2 removed), a liquid sample is placed in the recess 3. Excess liquid due to surface tension forces flows into the groove 7. Then, on top of the plane-parallel plate 1, a second plane-parallel plate 2 is placed. The plates 1 and 2 tightly folded together form a ready-to-use optical cell with the studied liquid sample. The dependence of the optical parameters of liquid samples (with a small volume from 10 ^-1 to 10 ^-3 ml) on the thickness of the liquid layer is measured using an optical probe, which is moved from axis 6 along the radius of the optical cell equal to D / 2. The thickness Δ of the liquid layer at a distance X from axis 6 is determined from the following relationship:

Thus, the patented optical cuvette makes it possible to measure the dependence of the optical parameters of the liquid on the thickness of its layer using only one sample having a small volume, and very thin layers of liquid are measured without using any means for measuring the layer thickness (as in the patent RV-C1-N2095787).

It was found that in a patented optical cuvette with a spherical segment segment h h that is less than 13 μm, the microobjects in the liquid sample experience discrimination in the direction from axis 6 to the periphery of the recess 3. Due to the surface tension and capillary pressure in the patented optical cuvette, microparticles are “sorted” in size, namely, smaller particles are concentrated in the peripheral regions of the recess 3, and larger particles are concentrated in the center. For example, when a suspension of microorganisms containing both dead and living cells is introduced into an optical cuvette, living cells are collected in the center of the optical cuvette, and “fragments” of dead cells are collected along the edges of the cuvette. In addition, under the action of surface tension and capillary pressure, hydrophobic particles are displaced to the periphery, and hydrophilic particles are concentrated under the additional action of gravity in the center and at the bottom of the optical cell. Thus, the achievement of an additional technical result is provided, consisting in the possibility of studying microobjects of both living and non-living nature.

It should be noted here that it is possible to make an optical cell with two recesses made in the first 1 and second 2 plane-parallel plates and located opposite each other. In principle, a patented optical cuvette can be made flow-through. The industrial applicability of the patented utility model is also confirmed by the fame of the technical means used for its manufacture.

Claims (4)

1. An optical cuvette containing two plane-parallel plates tightly folded together, while in the first plate from the side facing the second plate of optically transparent material, a recess is made, characterized in that the recess is made in the form of a spherical segment, while the arrow of the spherical segment is not exceeds 30 microns, and the ratio of the boom of the spherical segment to the radius of its spherical surface does not exceed 10 ^-4 . 2. The cuvette according to claim 1, characterized in that the first plane-parallel plate is made of optically transparent material. 3. The cuvette according to claim 2, characterized in that a mirror coating is applied to the spherical surface of the recess. 4. The cuvette according to claim 2, characterized in that the plane-parallel plates are made of materials having a different spectral dependence of the transmittance.