RU2110296C1 - Device for exposing biological liquids to radiation - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has container provided with inlet and outlet nipples, peristaltic pump connected to inlet nipple of the container, ultraviolet radiation source, reservoir for collecting irradiated biological liquid and oxygen supply source. The container is composed of hollow casing additionally provided with the second inlet nipple and flat wall manufactured from material transparent to ultraviolet radiation. The oxygen supply source is connected to the second inlet nipple of the container through additionally designed activation unit being reservoir manufactured from material transparent to ultraviolet radiation having oxygen spray unit and filled with disinfecting liquid solution. The ultraviolet radiation supply source is mounted between the activation unit and the container. EFFECT: uniform distribution of radiation; improved rheological and anticoagulation properties of blood; enhanced sterility; accelerated sanitary treatment. 1 dwg

Description

 The invention relates to medical equipment and can be used to irradiate biological fluids, mainly blood, in the treatment of cardiovascular diseases, toxic-septic conditions and other diseases.

 A device for irradiating blood is known, comprising a device for attaching a blood container made in the form of a hollow thick-walled cylinder, an electric reducer and a mixing device consisting of heating and cooling elements located respectively in the bottom and top of the cylinder [1].

 A disadvantage of the known device is that it does not create a sufficiently large temperature gradient, since an increase in the heating temperature worsens the safety of blood, and with insufficient heating, the intensity of blood mixing and uniformity of its irradiation are not ensured.

 It is also known a device for ultraviolet irradiation of blood, containing a source of ultraviolet radiation, a flat cuvette, the end faces of which are provided with olives with holes, made of quartz glass and located in front of the ultraviolet radiation source, two hoses connected to olives, an injection needle connected to one of the hoses , a curtain made of a material opaque to ultraviolet rays, mounted on a cuvette in front of a source of ultraviolet radiation with the possibility of moving I, capacitance, connected with a hose, and a peristaltic pump with an adjustable pumping rate, connected to a hose connected to the injection needle and the olive on the end faces of the cell [2].

 A disadvantage of the known device is that at the rates of blood pumping provided in it, its flow in the cuvette is laminar in nature. The gap thickness in the cuvette is at least 1 mm, while almost the entire dose of ultraviolet radiation is absorbed in the near-surface blood layer on the order of tenths of a millimeter, as a result of which there is a significant non-uniformity in the distribution of the radiation dose over the volume of the processed blood. In addition, the design of the quartz cell, namely its small bore, makes it difficult to sanitize.

 Of the known closest in technical essence to the proposed device is an ultraviolet blood irradiation device containing an ultraviolet radiation source, a flat flowing quartz cuvette, a blood supply unit with a pipe made of a polymeric material and a flow regulator, an oxygen source, a mixing device and sources of constant and alternating magnetic fields moreover, the source of a constant magnetic field is installed in front of the cell and is made with the axis of magnetization perpendicular to the axis of the pipeline, an AC magnetic field formed in the form of a coil embracing the conduit, - for the cuvette, wherein the mixing device is installed between the node and the source of blood supply of a constant magnetic field [3].

 The disadvantages of the known device are the complexity of its design, as well as the fact that the mixing of blood with oxygen occurs before blood enters the cell, as a result of which the mixture manages to separate into gaseous and liquid phases, and this significantly reduces the uniformity of exposure.

 The technical task of the invention is to ensure uniform distribution of the radiation dose, increase sterility, reduce sanitation time, improve the rheological and anticoagulation properties of blood due to the simultaneous exposure to ultraviolet radiation and activated oxygen.

 This technical problem is solved due to the fact that in the device for ultraviolet irradiation of biological fluids, mainly blood, including a cuvette equipped with inlet and outlet fittings, a peristaltic pump connected to the inlet of the cuvette, an ultraviolet radiation source, a container for collecting irradiated biological fluid and a source oxygen, in accordance with the invention, the cuvette is made composite and is additionally equipped with a second inlet fitting, the oxygen source is connected to the second input fitting the cell-stand inputted through an additional oxygen treatment unit adapted as a container of material transparent to UV light, oxygen supply and filled with a disinfecting spray liquid, wherein the ultraviolet radiation source is set between the node and the oxygen treatment cuvette.

 The drawing shows a diagram of the proposed device for ultraviolet irradiation of biological fluids, mainly blood.

 The device contains a vertically arranged cell, made up of a hollow body 1, in the lower part of which there are two inlet fittings 2, 3, and in the upper part there is an outlet fitting 4, and from a flat wall 5 made of a material transparent to ultraviolet radiation. The flat wall 5 of the cuvette is located on the side facing the source of ultraviolet radiation 6. The housing 1 and the flat wall 5 form a sealed cavity in which the biological fluid, mainly blood, is supplied by means of a peristaltic pump 7 via a flexible pipe 8 connected to the first input fitting 2 and with an injection needle 9 inserted into the vein of the patient. The second inlet fitting 3 is connected by a pipe 10 to an oxygen source 11, and between the oxygen source 11 and the second inlet fitting 3, an oxygen flow regulator 12 and an oxygen treatment unit 13 are connected in series. The oxygen activation unit 13 consists of a housing 14 made of a material transparent to ultraviolet radiation, and an oxygen atomizer 15 immersed in the disinfectant liquid 16. The outlet nozzle 4 of the cell body 1 is connected by a pipe 17 to a vessel 18 for collecting the irradiated biological fluid. The tank 18 is equipped with a drainage tube 19, the end of which is located at the bottom of the tank 18. Flexible piping 8, 10, 17 are made of a material similar to that used in disposable blood sampling systems. A source of ultraviolet radiation 6 is installed between the activation site of oxygen 13 and the flat wall 5 of the cell.

 The device operates as follows.

 The estimated volume of the blood anticoagulant, for example, physiological saline with heparin through the nozzle 4, is introduced into the storage tank 18, an anticoagulant, such as saline with heparin, is also introduced into the cuvette, then the container 18 is turned downside down, and the peristaltic pump 7 is turned on, fill the pipeline 8 and the injection needle 9. while the oxygen flow regulator 12 remains closed. Then the peristaltic pump 7 is turned off, and the container 18 is returned to its original position (tube up), after which the source of ultraviolet radiation 6 is turned on and the patient's vein is punctured with an injection needle 9. After that, the peristaltic pump 7 is again turned on for blood sampling. At the moment of blood flow through the pipe 8 connected to the first inlet fitting 2, the valve of the oxygen flow regulator 12 is opened into the cavity of the casing 1 of the cuvette. In this case, oxygen from the source 11 through the pipeline 10 enters the cavity of the casing 14 of the processing unit 13, filled with disinfectant liquid 16 ( e.g. ethanol). In the volume of the disinfectant liquid 16, oxygen is sprayed using an oxygen atomizer 15, simultaneously being irradiated with an ultraviolet radiation source 6, and then through the output section of the pipe 10 connected to the second inlet fitting 3, enters the cavity of the cell body 1 at the same time as blood enters there through the first inlet nipple 2. Blood sparging with oxygen bubbles leads to its active mixing, as a result of which uniformity of irradiation through the flat wall 5 of the cuvette of the whole blood volume and its efficiency are ensured projective oxygenation. Oxygen consumption is set in such a way as to ensure intensive mixing of the blood, while avoiding excessive foaming. The mixture of blood and oxygen through a pipe 17 enters from the hollow body 1 of the cell through the outlet fitting 4 into the storage tank 18, where it is divided into liquid and gaseous fractions. Excess gas is discharged from the reservoir 18 through the drainage tube 19, and the blood is mixed with the anticoagulant located in the reservoir 18. After irradiation of the calculated amount of blood, the ultraviolet radiation source 6 is turned off, the oxygen supply is stopped by stopping the peristaltic pump 7, the container 18 is turned upside down and the treated and oxygen-enriched blood is returned to the patient's vein, turning the pump 7 into the blood return mode.

 The dose of blood irradiation is determined by the density of the radiation flux from the source of ultraviolet radiation 6, the area of the flat wall 5 of the cell and the exposure time. Since the first two quantities are constant, the dose of radiation depends on the time of exposure, i.e. of the volume of irradiated blood and the performance of the peristaltic pump 7. Typically, the volume of irradiated blood is determined by the patient’s weight based on 1 ml of blood per 1 kg of weight. Thus, the radiation dose is determined in each case by the rate of blood sampling from the patient's vein, i.e. performance peristaltic pump 7, which is installed before the procedure. The amount of anticoagulant in the tank 18 is determined by the volume of blood taken, based on a ratio of 1: 5.

 The technical advantages of the invention are to ensure uniform distribution of the radiation dose over the entire blood volume, to increase sterility and reduce sanitation time due to the design features of the cell, as well as to improve the rheological and anticoagulation properties of blood due to the simultaneous exposure to ultraviolet radiation and activated oxygen.

Claims (1)

 A device for ultraviolet irradiation of biological fluids, mainly blood, including a cuvette with inlet and outlet fittings, a peristaltic pump with a flexible pipe connected to the inlet fitting, an ultraviolet radiation source, a container for collecting the irradiated liquid and an oxygen source, characterized in that the connected with an oxygen source, an oxygen treatment unit, including one made of a material transparent to ultraviolet radiation, a container filled with a disinfectant with a solution and equipped with a sprayer, while the cuvette is made integral and has an additional inlet fitting connected to the oxygen processing unit, and the radiation source is located between the cuvette and the oxygen processing unit.