RU2090949C1 - Sterile radioisotope generator - Google Patents

Abstract

FIELD: nuclear engineering. SUBSTANCE: generator has column holding sorbent and radioisotope inside radiation shield and generator case, flange with seats placed above radiation shield, eluent, eluate, and bacterial air filter needles connected through flexible hoses with column, bacterial air filter, eluent tank, and switch. The latter is tour-way cock placed in seat of flange with eluent and bactericidal air filter needles communicating through flexible hoses with filter, eluent tank bottom and cover, and column inlet. Slide valve of switch has three locked positions relative to cock body: neutral, eluent tank or column, and bacterial air filter or tank cover, bacterial air filter or column. Eluent tank in the form of annular space, such as torus or double-wall cylinder is placed around radiation shield. EFFECT: improved effectiveness of scrubbing of isotope obtained from sorbent during elution process. 3 cl, 5 dwg

Description

 The invention relates to the production of generators of radioactive elements used to produce radionuclides for medicine and technology.

 A device for the sterile preparation of radioactive isotopes [1] is known in which, to facilitate the operation of the device, the collectors and the generator are mounted on a tripod and placed in a shielding container made in the form of a cylinder with end flanges on both sides of it, on which axial removable bushings are mounted. The bushings are provided with internal jumpers, and the flanges and bushings have axial channels for placing hollow needles inside them. The disadvantages of the described construction of the isotope generator include the bulkiness and complexity of the design and the presence of eluent in the column after the elution process.

 In another isotope generator, a column placed in a lead shield is used to obtain sterile radionuclides [2, 3], which is connected to the vessels for the eluent and for the eluate, the column of the generator and the vessel for the eluent installed in the container. The generator column is placed between two centering devices with recesses motionless relative to the container and through one hollow needle is connected to an eluent vessel mounted motionless relative to the generator column in the recess of the centering device. Another hollow needle column is connected to the vessel for the eluate, which is installed in the recess of the second centering device. In addition, the centering devices have recesses for centering and fixing the hollow needles. The device of the generator includes a vessel with physiological solution of sodium chloride. The vessel, by means of a preferably double-sided hollow needle, is connected to a generator column having circular protection against radiation, for example, from lead. The centering device secures the eluent vessel, generator column, radiation protection and hollow needle in the correct position. The eluent vessel is installed in the recess of the centering device. Molybdenum-99 is fixed on the alumina matrix of the generator column. Preferably, a double-sided hollow needle is attached to the second end of the generator column, which is held by the centering device. The needle is closed by a protective element. The lid buries the packaging container for transporting the generator. In addition, centering devices ensure the correct position of the generator protection during transport. To elute the generator, the container lid is removed, the protective element of the hollow needle is removed, and the evacuated vessel for the eluate, which is in transparent protection from lead glass, is connected to the column of the generator using a hollow needle. In this case, the recess in the centering part of the device serves as a guide. At the end of the elution, the vessel with the eluate is removed and the protective element for the hollow needle is again put on. It serves to protect against contamination and to ensure sterility. The disadvantages of the described construction of the isotope generator include wetting the matrix of aluminum oxide with the isotope fixed by physiological saline due to capillary forces arising in the hollow needle, lowered into the vessel with the eluent and in the intergranular space of the column. As a result of this, the yield of technetium-99 is reduced and, to maintain it at a high level, additional oxidizing agents are introduced into the eluent, in some cases interfering with the normal course of the synthesis of radiopharmaceuticals from reagent kits in clinics.

 A generator of a radioactive element is also known, the case of which is installed in a detachable casing provided with a holder with containers for solvent and a product with a daughter radioactive element [4]. The casing consists of detachable vertical sections, each of which has internal recesses for accommodating the generator casing and tubes. The vertical sections on the inside are provided with ribs and grooves to set the sections in the desired position. A glass column with an aluminum oxide sorbent containing molybdenum-99 is placed in the cylindrical case of the generator. As seals in the upper part of the body, plugs are used that can be punctured with hypodermic needles. The outer ends of these tubes for supplying a washing solution and removing the finished product are sealed using caps containing a molded glass with bushings, inside which the upper segments of the tubes are enclosed. The open ends of the tubes are not blocked, but open and connected to the glass chamber. The glass has a punctured septum. The disadvantage of this device is its complexity and the need to work with two bottles - evacuated and a bottle with eluent.

 The closest technical solution is a generator for producing radioisotopes, which consists of a sealed glass column filled with an aluminum oxide sorbent with an isotope adsorbed on it [5]. The system includes an eluent container having an airtight stopper through which two needles are passed. One of the needles is lowered to the bottom of the container and connected via a flexible hose to the top of the column, and the second needle is located in the inner air space of the container and connected via a flexible hose to a bactericidal air filter. From the lower end of the column, a needle comes up, which is connected with a flexible hose to a working needle, on which a vacuum bottle is pierced. All of the above flexible hoses pass through a switch (tap), which during operation has a normally open position to ensure the functioning of the system. The system operates as follows. A vacuum bottle is pricked onto a working needle. The switch is moved to a normally open position, while due to the elasticity of the material of the flexible hoses, the flow areas of all three hoses are restored to normal diameters. Due to the vacuum in the bottle on the path "working needle flexible hose-column flexible hose capacity" creates a vacuum. The eluent in the tank is sucked into the needle, enters the upper part of the column along the path, flushes technetium-99m accumulated in the column, and enters the evacuated bottle. To compensate for the pressure in the tank due to the loss of eluent through the bactericidal filter, clean air is sucked into the tank through a flexible hose. The eluate is accumulated in the evacuated vial. Upon reaching the required volume of the eluate in the vial using the switch, cut off the eluent, eluate and air at the same time. Then, the bottle with the eluate is removed from the working needle. After a certain period of time, a new evacuated bottle is punctured on the working needle and the working process is repeated. A drawback of the described construction is the simultaneous clamping of all three flexible hoses with the passage cross-sections, as a result of which the column with the sorbent and communications are constantly filled with eluent, and therefore the specific activity of the eluate and the efficiency of the system when washing the technetium-99m isotope from the column are reduced.

 The authors were faced with the task of eliminating these shortcomings, increasing the yield of the target isotope in the elution process without introducing additional oxidizing agents into the eluent by blowing the column with air and maintaining a given amount of eluate during generator operation. To achieve this technical result, the authors proposed to introduce a switch into the device, made in the form of a four-way valve and placed on the lines of the eluent, filter and column.

 Structurally, the generator for producing sterile radioisotopes is made in the form of a device containing a column, radiation protection placed in the housing, a flange with sockets for the eluate and eluent needles, connected by flexible capillaries to the column, an air bactericidal filter, an elastic container with an eluate, a four-way switch a crane placed on the lines of the eluent, filter and column. The body of the four-way valve is connected by flexible hoses with an air bactericidal filter, a lid and the bottom of the tank with an eluent, the entrance to the column. A four-way valve is connected to a switching handle having three fixed positions relative to the valve body: neutral, container with eluent column, bactericidal filter column. The elastic container with the eluent is made in the form of an annular cavity and is placed around the protection.

The technical result of the invention is the creation of a generator to produce sterile radioisotopes with increased efficiency of the output of the accumulated isotopes from the sorbent in the elution process by purging the column with air and maintaining the specified quality of the eluate during operation of the generator. To do this, the switch is made in the form of a four-way valve, the casing of which is connected by flexible hoses with an air bactericidal filter, a lid and the bottom of the tank with an eluent and an entrance to the column. Such a connection allows you to switch the filter both to the container with the eluent, and to the column for purging it with air. Therefore, the four-way valve spool is connected to a shift knob having three fixed positions relative to the valve body:
neutral when the column is completely disconnected from the bactericidal filter and from the container with eluent. This position of the crane is necessary for transporting the generator to prevent leakage of the radioactive element;
capacity with eluent column. This is the first working position of the generator, when the eluent due to the difference in air pressure enters the column with the sorbent;
bactericidal filter column. This is the second working position. when the air flow from the bactericidal filter is disconnected from the container with the eluent and switched directly to the column. The air flow displaces the eluate from the column into the vial and at the same time dries it. The process of air drying the intergranular space of the column leads to the formation of an oxidizing atmosphere in it and stabilization of the yield of the target nuclide in the eluent at a high level with an increased quality of the eluate.

 In FIG. 1 shows a general view of a generator for producing sterile radioisotopes, where 1 column; 2 radiation protection; 3 generator housing; 4 flange of the generator; 5 and 6 sockets in the flange; 7 eluate needle; 8 eluent needle; 9 filter needle; 10 body four-way valve; 11 - spool four-way valve; 12 handle four-way tap; 13 - connecting sleeve; 14 bactericidal cap; 15 flexible eluate hose; 16 flexible eluent hose; 17 ring capacity with eluent; 18 flexible filter hose; 19 flexible hose cover ring capacity; 20 flexible hose bottom of the annular tank; 21 evacuated vials; 22 eluate; 23 - level of eluate; 24 bactericidal filter housing; 25 filter element; 26 lock nut.

 In FIG. 2 shows a fragment of a generator for producing sterile radioisotopes with a filter.

 In FIG. 3 shows a schematic hydraulic diagram of a generator for producing sterile radioisotopes with an airtight column-filter-capacity path (position "0").

 In FIG. 4 shows a schematic hydraulic diagram of a generator for producing sterile radioisotopes when a four-way valve is turned on to fill the column with eluent (position "I").

 In FIG. 5 is a schematic hydraulic diagram of a generator for producing sterile radioisotopes when switching a four-way valve to “dry” the column (position “II”).

 The inventive device operates as follows. Column 1 containing the sorbent is “charged” with a radionuclide, for example, molybdenum-99. To do this, in a special chamber, a bottle containing the molybdenum-99 isotope in solution is injected into two needles 8 and 9, and a vacuum bottle is injected onto the needle 7 (not shown in the figure). Due to the pressure difference in the two bottles, the solution moves through the column 1 into the evacuated bottle. In this case, the molybdenum-99 radionuclide is fixed on the sorbent, and the liquid accumulates in a vacuum bottle. Thus, the column is charged with molybdenum-99. Used vials are removed after charging. The bactericidal cap 14 is put on the needle 7, and the body 10 of the four-way valve with the slide valve 11 and the switching handle 12 is put on two needles 8 and 9 with the help of the coupling 13. The four-way valve is thus placed in the socket 6 of the flange 4. FIG. 3 shows a schematic diagram of an assembled generator. When transporting the generator, column 1 containing the radioactive isotope is hermetically closed on one side with a bactericidal cap 14, and on the other with a spool 11 of a four-way valve. To prepare the generator for operation, remove the cover (not shown in the figure). A vacuum bottle 21 is punctured on the needle 7 (Fig. 4). Using the handle 12, the spool 11 is moved to position “I”. In this case, the filter is connected to the lid of the container 17 with the eluent, and the bottom of the container 17 with the end face of column 1. Due to the pressure difference of the vacuum atmosphere, eluent enters the column 1, which washes out the accumulated daughter isotope of technetium-99m. As soon as the first drop of the eluate appears on the end of the needle 7, the slide valve is moved to position "II" (Fig. 5). In this case, the air line of the hose 18 of the bactericidal filter is connected to the column 1, and the container 17 with the eluate is turned off. Air transfers liquid from column 1 to vial 21. This process continues until air bubbles barb through the eluate 22 appear in the vial. Thus, column 1 is purged with clean sterile air and drained of residual liquid (eluate). After the process is completed, the spool 11 is moved to the “0” position (Fig. 3), and the bactericidal cap 14 is put on the needle 7. In the case of the technetium generator, in a day it is ready to learn a new portion of the eluate.

 An example of the design of the generator to obtain sterile radioisotopes. The activity of a column with a radionuclide, for example, molybdenum-99, is up to 1.5 Ci. About 50 mm thick lead was selected as the radiation protection material. Column height 80 mm. The capacity of the eluent in the case of a technetium generator is 100 cm3. designed for 14 or 15 elutions. The four-way valve has three switching positions "0-I-II". The mass of the generator is about 12 kg, height 250 mm.

 Using the invention will allow to obtain sterile radioisotopes with increased efficiency of washing the obtained isotope from the sorbent in the elution process and high quality of the eluate.

Claims (3)

 1. A generator for producing sterile radioisotopes, containing a column with a sorbent and a radioisotope, placed inside the radiation shield and the generator housing, a flange with sockets located above the radiation shield, an eluent needle, an eluate needle and an air bactericidal filter needle connected by flexible hoses to the air column bactericidal filter, a container with an eluent and a switch, characterized in that the switch is made in the form of a four-way valve located on the flange of the generator connected by flexible hose mi with an air bactericidal filter, a lid and the bottom of the tank with eluent, the entrance to the column, while the four-way valve is equipped with a shift knob having three fixed positions relative to the valve body: neutral; tank bottom with eluent column and air bactericidal filter tank cap; air bactericidal filter column.  2. The generator according to claim 1, characterized in that the four-way valve is made with a spool, which is connected to a shift knob.  3. The generator according to claim 1, characterized in that the container with the eluent is made in the form of an annular cavity, for example a torus or a cylinder with double walls, and is placed around the radiation protection.

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