RU2373590C2 - Radionuclide generator - Google Patents

Abstract

FIELD: nuclear physics.

SUBSTANCE: invention relates to radionuclide sources, meant for medical purposes, and can be used for making visualisation agents, used in diagnostic recording systems. The radionuclide generator has a housing 1 with a cover 2, a three-way tap 3, pipes 4, 5, 6, 7 and an eluent source 8. Inside housing 1 there is a column 9 with sorbent and a radiation shield 10. The first 11 and second 12 connecting elements are placed on the cover 2 perpendicular its surface. The generator also has a waste unit 13, a pump 14 in form of syringe and a double-chamber protective-actuating cylinder 15, which has a first chamber 16 under the actuating medium and a second chamber 17 under the eluent. The first chamber 16 is separated from the second chamber 17 by a flexible membrane 18 and its inner volume is 1.2 to 1.8 times larger than the volume of the second chamber 17. The difference in length from ends of connecting elements 11 and 12 to the surface of cover 2 ranges from 3 to 5 mm. Pump 14 is connected by the first pipe 4 with the double-chamber protective-actuating cylinder 15, which is connected by the second pipe 5 with the three-way tap 3. The three-way tap 3 is connected to the eluent source 8 and by the third pipe 6 to the first connecting element 11. The waste unit 13 is connected to the second connecting element 12 by the fourth pipe 7. The invention is safe and simplifies operation of the device.

EFFECT: obtaining radionuclides which improve diagnosis, and therefore treatment results.

1 cl, 1 dwg

Description

The invention relates to radioactive sources intended for medical purposes, and can be used to obtain imaging agents used in diagnostic recording systems.

Generators for producing radionuclides are known. Known, for example, is a generator for producing sterile radioisotopes RU 20909949 C1, 09/20/1997, which, in particular, contains a column with a sorbent and a radioisotope located inside the radiation protection and the generator housing, a flange with sockets located above the radiation protection, flexible hoses and a four-way crane.

A disadvantage of the known generator is the complexity of operation.

Closer to our invention should be considered a device RU 2097857 C1, 11/27/1997, designed to receive sterile radionuclides and containing a housing with a cover, a column with a sorbent and radiation protection installed inside the housing, the first and second connecting elements placed on the cover perpendicular to it surfaces, three-way valve, pipelines and source of eluent.

A device for producing sterile radionuclides is convenient to use, but has limited functionality.

The problem solved by the invention is to create a safe, easy-to-use device that allows you to receive radionuclides that improve diagnosis and, as a result, treatment results.

The technical result of the invention is a technical effect, objectively manifested during its use and consisting in obtaining and implementing the above properties, i.e. the proposed generator provides:

a) higher image accuracy than when using isotopes of common radionuclides: thallium-201, technetium-99m;

b) the diagnosis of diseases of the coronary vessels of the heart and the selection of a treatment strategy for the disease at an early stage through the use, in particular, of the rubidium-82 radionuclide, which can be used as a quantitative marker of necrosis or viability of myocardial tissue;

c) reducing the time for sequential playback of the image during the examination of the patient; allows every 10 minutes to carry out sequential scanning of the investigated organ;

d) minimizing the dose of radiation received by the patient during the examination;

e) conducting clinical studies using positron emission tomography without the need for expensive cyclotrons.

The invention is expressed in the aggregate essential features, in which a generator for producing radionuclides, comprising a housing with a cover, a column with a sorbent and radiation protection installed inside the housing, first and second connecting elements placed on the cover perpendicular to its surface, a three-way valve, pipelines and a source eluent differs from the closest analogue in that it additionally contains a waste collector, a pump in the form of a syringe and a two-chamber safety-drive cylinder having a first a chamber for the working medium and a second chamber for the eluent, the first chamber being separated from the second chamber by a flexible membrane and having an internal volume that is 1.2-1.8 times larger than the volume of the second chamber, while the length difference from the ends of the connecting elements to the surface of the cover is 3-5 mm, the pump is connected by a first pipe to a safety-drive cylinder, connected by a second pipe with a three-way valve connected to the source of eluent, and a third pipe to the first connecting element, and the waste collector is connected a second connecting member of the fourth pipeline.

The relationship of the distinguishing features of the invention according to its technical results is manifested in the fact that the two-chamber safety-drive cylinder connected to the pump by the first pipeline allows the use of a pump of the simplest construction, i.e. syringe. The execution of the cylinder with the first chamber under the working medium and with the second chamber under the eluent with the separation of their flexible membrane provides minimal effort for the generator and at the same time protects the pump (syringe) from contact with the eluent. The magnitude of the efforts for the operation of the generator is determined by the ratio of the internal volume of the first and second chambers, in which the internal volume of the first chamber is 1.2-1.8 times the volume of the second chamber.

Placing the connecting elements on the cover perpendicular to its surface with a length difference from the ends of the connecting elements to the cover surface of 3-5 mm simplifies the preparation of the generator for operation, in particular, due to an easier approach to each connecting element and due to an easier determination of the desired connecting element.

Simplifies the work with the generator and makes it more convenient to connect its elements, i.e. connecting the waste collector to the second connecting element with a fourth pipeline, connecting the three-way valve connected to the source of eluent to the drive cylinder with the second pipeline, and connecting the three-way valve with the third pipeline to the first connecting element.

The invention is illustrated in the drawing, which shows a diagram of a generator for producing radionuclides.

The generator for producing radionuclides contains a housing 1 with a cover 2, a three-way valve 3, pipelines 4, 5, 6, 7 and an eluent source 8. A column 9 with a sorbent and radiation protection 10 is installed inside the housing 1. The first 11 and second 12 connecting elements are placed on the lid 2 perpendicular to its surface. Additionally, the generator contains a waste collector 13, a pump 14 in the form of a syringe and a two-chamber safety-drive cylinder 15. The two-chamber safety-drive cylinder 15 has a first chamber 16 for the working medium and a second chamber 17 for the eluent. The first chamber 16 is separated from the second chamber 17 by a flexible membrane 18 and has an internal volume that is 1.2-1.8 times larger than the volume of the second chamber 17. The length difference from the ends of the connecting elements 11 and 12 to the surface of the cover 2 is 3-5 mm . The pump 14 is connected by a first pipe 4 with a two-chamber safety-drive cylinder 15, connected by a second pipe 5 with a three-way valve 3. A three-way valve 3 is connected to the source of eluent 8 and a third pipe 6 to the first connecting element 11. The waste container 13 is connected to the second connecting element 12 the fourth pipeline 7.

The use of the generator began with the preparation of the working room and equipment. In particular, before starting work, the serviceability of all devices installed both in the protective chamber 19 and outside it (manipulators, a device for measuring volumetric activity, and weight gauge) is checked. Then, in the protective chamber 19, radioactive raw materials are placed in the source of eluent 8. As a source of eluent 8, a 20 ml penicillin bottle with a prepared ⁸² Sr solution (7) or another similar container with a similar solution can be used.

Ready for applying to column 9, a solution of radioactive strontium from the source of eluent 8 is fed into the second chamber 17 of the two-chamber safety-drive cylinder 15. The eluent is supplied by moving the rod of the pump 14, which provides a rarefaction of the working medium (air) in the first chamber 16. Since the pump 14, made in the form of a syringe, is connected to the two-chamber safety-drive cylinder 15 by the first pipe 4, the rod moves outside the protective chamber 19 and does not require an operator nachitelnyh effort. The rarefaction in the first chamber 16 of the two-chamber safety-drive cylinder 15 leads to the bending of the flexible membrane 18 and to the rarefaction in the second chamber 17, into which the eluent from the source 8 flows through the second pipe 5.

Then the position of the three-way valve 3 is changed and counter-movement of the rod of the pump 14 increases the pressure of the working medium in the first chamber 16, bends the flexible membrane 18 in the opposite direction and carries out the reverse movement of the eluent through the second pipe 5 to the first connecting element 11 through the three-way valve 3 and the third pipe 6 Through the connecting element 11, the solution enters the column 9 having a sorbent at a speed of 1-2 ml / hour, where it is absorbed. Waste through the second connecting element 12 through the fourth pipeline 7 fall into the waste collection 13.

Wash column 9 in the same manner using 200 ml of a 0.9% NaCl solution at a rate of 10 ml / min.

The generator can be used to produce a short-lived rubidium-82 radionuclide (half-life of 1.3 min). This radionuclide is introduced into the patient's circulatory system, and blood flow is analyzed by positron emission tomography. The method is most effective for non-contact study of myocardial perfusion in the diagnosis and prognosis of patients with suspected coronary artery disease. The use of rubidium-82 allows the assessment of myocardial perfusion with high sensitivity. Rubidium-82 can also be used to study the functions of the brain, gastrointestinal tract, liver and kidneys.

Claims (1)

A generator for producing radionuclides, comprising a housing with a cover, a column with a sorbent and radiation protection installed inside the housing, first and second connecting elements placed on the cover perpendicular to its surface, a three-way valve, pipelines and sources of eluent, characterized in that it further comprises a waste collector , a pump in the form of a syringe and a two-chamber safety-drive cylinder having a first chamber for a working medium and a second chamber for an eluent, the first chamber being separated from the second chamber with a diaphragm and has an internal volume that is 1.2-1.8 times larger than the volume of the second chamber, while the length difference from the ends of the connected elements to the surface of the cover is 3-5 mm, the pump is connected by a first pipe to a safety-drive cylinder connected a second pipeline with a three-way valve connected to the source of the eluent and a third pipeline to the first connecting element, and the waste collector is connected to the second connecting element by a fourth pipeline.

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