SU1149144A1 - Through-type tray for small-volume liquid samples - Google Patents

Abstract

FLOW CUVETS FOR LIQUID TESTS OF SMALL VOLUMES, having a body with annular grooves and holes for introducing and draining the sample with a cylindrical insert fitted with horizontal cylindrical measuring channel, inlet and outlet passages for the sample and optical glasses with adjacent sealing rings The housing axes and the liner coincide with the optical axis of the flow cell, characterized in that, with the aim of improving the measurement accuracy, the input and output passages are made on the outer cylindrical The liner surface has diametrically opposed longitudinal grooves made starting from the middle of the insert to its ends, while there is a through slit in the half of the groove of the entrance passage, passing at the end of the liner into the radial notch The liner on the side of the exit passage is cylindrical high (L tup with diametrically opposed slots of various sizes, the smaller of which is a continuation of the groove of the exit passage a, and the sealing rings are located in the annular grooves of the housing 4; SB hU

Description

eleven . The invention relates to medical laboratory technology and is intended for optical measurements of the reaction mixture during biochemical analyzes. A known flow cell for optical measurements of a fluid containing an insert with an optical channel installed in the housing, wherein a pneumatic-hydraulic ring is formed between the inner surface of the housing and the outer surface of the inlet. The cuvette has channels for inlet and outlet of liquid and a channel for diverting gas inclusions. Optical glasses and sealing rings are installed at both ends of the liner. However, although the cuvette provides for the removal of gas from the optical channel with a continuous flow of liquid through it, with a discrete fluid intake, this cuvette cannot provide good washing from the remnants of the previous bioassay. Closest to the invention to the technical essence and the achieved result is a flow cell for liquid samples of small volumes, having a body with annular grooves and holes for introducing and draining the sample with a cylindrical liner installed in it with a horizontal cylindrical measuring channel, inlet ports and output ports for the sample and optical glasses with adjacent sealing rings, with the axis of the housing and the contribution coinciding with the optical axis of the flow cell. The insert has a horizontal measuring channel, inlet and outlet passages for the length of the liquid sample, communicated with the corresponding channels in the cuvette body, and the channel dp for removing gas bubbles. The inlet passage has a form of chips and the diameter of its rear wall is less than the internal diameter of the inlet channel of the housing. The gap reaches the end of the liner, forming a path for the passage of fluid into the measuring channel of the insert. The output passage of the liner is formed by a C-shaped protrusion ending at the level of the bottom of the horizontal channel by a plug and a protrusion with a horizontal platform creating a transverse channel for discharging the gland. In the body of the cuvette, a four-ring annular groove encompasses the output end of the insert, with the ring covering part of the entrance slit at the input end, and part of the transverse channel at the output end. The inlet channel of the cuvette is connected to a test tube with the test liquid, and the outlet channel to a vacuum source and a receiver for the measured bioassay. The studied bioassay enters the cuvette from above, and is removed from it from below 2. A disadvantage of the known cuvette is that the fluid flow directed by the longitudinal inlet and transverse output passages does not cover the ends of the measuring channel of the cuvette. This contributes to the creation of stagnant zones with air bubbles at optical glasses, which reduces the reliability of the measurement. In addition, a sufficiently large volume of the measured liquid (more than 1 ml) is required for a high-quality washing of the measuring channel of the cuvette. The design of the cuvette and its manufacturing techniques (a special coating for the liner is required) are quite complex and time consuming. The purpose of the invention is to improve the measurement accuracy at the minimum flow rate of the measured liquid due to the removal of air bubbles and stagnant zones from the measuring channel. The goal is achieved by the fact that in a flow cell having a casing with annular grooves and holes for it has a cylindrical liner with a horizontal cylindrical measuring channel, inlet and outlet passages for the sample and optical glasses with adjacent sealing rings, with the housing axis and on the outer cylindrical surface of the insert in the form of diametrically opposed longitudinal sanavas, made from the middle of the insert to its ends, while half the length of the groove of the entrance passes through the passage, the junction at the end of the insert in the radial cut, the width of which corresponds to the diameter of the measuring channel, on the end of the insert, on the side 3 of the exit passage, there is a cylindrical protrusion with a diameter Differently sized slots are different, the smaller of which is the continuation of the groove of the output passage, and sealing, and the rings are located in the annular grooves of the housing. FIG. 1 shows a cuvette, general view, in section; in fig. 2, section A-A in FIG. one; in fig. 3 inserts, view from the entrance groove; pas figs. 4 - the same, view from the exit groove. The flow cell comprises a housing 1 with an inlet 2 for inlet and an opening 3 for draining the sample of the test liquid. An insert 4 is inserted into the cylindrical opening of the housing, equipped with a horizontal cylindrical measuring channel 5, and two passages for the liquid 6 and output 7. At the same time, the axis of the cylindrical measuring channel coincides with the optical axis of the flow cell. The entrance passage 6 is made on the external cylindrical surface of the insert in the form of a longitudinal groove 8, starting from the middle of the insert to its end, passing halfway through into the through slot 9, which is bounded on the end of the insert by the radial cut 10. The exit passage 7 has the shape of a longitudinal grooves 11, which are provided with an annular channel 12, an outer casing 1 of the cuvette and a cylindrical protrusion 13 at the end of the input 4 from the exit passage side. The protrusion 13 has two diametrically arranged slots 14 and 15 of different sizes, and The smaller slot is a continuation of the groove 11. In the cell body 1, annular grooves 16 and 17 are made to install sealing rings 18 and 19 in them, adjacent to the optical glasses 20 and 21. In the holes 2 and 3 of the body, tubes are inserted (not shown), connected to the intake spout (input) and the mechanism for filling the cuvette (output), the cuvette works as follows. Under the influence of the vacuum created by the cell filling mechanism, the reaction mixture enters the inlet 2, and from it into the inlet 6, from which 4 part of the liquid is directed through the radial cutout 10 towards the optical glass 20 and is subsequently directed along the measuring channel 5, . and the other part of the liquid passes through the slit 9 and is also directed along the measuring channel, creating a general flow of liquid in the channel, which displaces most of the air from the channel cavity-. A portion of the air in the form of bubbles rises into the upper part of the measuring channel and moves to the slot 14. The main part of the liquid from its flow in the measuring channel through the slot 15 and the annular groove 12 rushes into the outlet passage 7, As the fluid flows through the slot 14 then an injection phenomenon occurs above it, due to which air bubbles trapped before slot 14 are carried away by the flow of fluids through the slot and are removed from the measuring channel 5. After moving some flushing volume of liquid STI filling device halts liquid flow cell and bioassay is ready for measurement. The inlet passage 6, the radial cutout 10, the through slit 9 and the diametrically located slots 14 and 15 direct the fluid flow in the measuring channel so that the liquid actively flushes its entire cavity, providing the required washing of the measuring channel from the remnants of the previous bioprobe and active removal of air bubbles from its cavity. The measuring channel of the cuvette before the liquid enters it is filled with air. At the beginning of the filling, the flow of liquid displaces the main volume of air from the measuring channel, and its remaining bubbles are carried away by the active and uniform moment of measurement of the reaction mixture. The ibiM fluid flow created by the inlet 6 and outlet 7 passages, the through slot 9, the radial tube 10 and the slots 14 and 15. The proposed cuvette for small sample volumes has a simpler and more technological design, which improves the measurement accuracy by eliminating the formation of air bubbles in the measuring channel and stagnant zones.

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Claims (1)

FLOW CUVET FOR 'LIQUID SAMPLES OF SMALL VOLUMES, having a body with annular grooves and holes for input and discharge of the sample with a cylindrical insert with a horizontal cylindrical measuring channel, inlet and outlet passages for the sample and optical glasses with sealing rings adjacent to them, the axis of the body and the insert coincide with the optical axis of the flow cell, characterized in that, in order to increase the accuracy of measurements, the inlet and outlet passages are made on an external cylindrical the liner in the form of diametrically opposite longitudinal grooves made starting from the middle of the liner to its ends, while at the half of the groove of the inlet passage there is a through slot, passing at the end of the liner into a radial cutout, the width of which corresponds to the diameter of the measuring channel, at the end of the liner from the side of the exit passage made a cylindrical protrusion with diametrically opposed slots of different sizes, the smaller of which is a continuation of the groove of the exit passage, and sealing to rings are located in the annular grooves of the housing,