RU2161132C1 - Extraction generator for technetium 99m - Google Patents

Abstract

FIELD: isotope separation techniques. SUBSTANCE: invention is intended for preparing radiopharmaceutical medicinal preparations and focuses on developing high- efficiency small-size extraction generator for technetium 99m with autonomous portable extractor allowing running installation in radiological laboratories not provided with protection equipment. Invention aims at enabling self-regulation of location of aqueous/organic phase interface in extractant discharge extractor region thereby enabling operation of installation in "black box" mode, that is in closed form characterized by minimal loss of extracted radionuclide. This task is solved by manufacturing extractor column with holes in its lower section and placing this column coaxially in sealed cylindrical casing with two connection pipes for connecting to air-vacuum control system and for withdrawal of exhausted molybdenum 99, admission pipe being connected over single-pass cock with filtration column and extractant tank. Such structure of extractor permits placing it into protecting container with communication holes, which is suitable for repeated extraction in small-size extractor due to its coaxial arrangement and lack of liquid communications between column and internal section functioning as supplementary extractor. EFFECT: increased productivity of installation. 2 cl, 1 dwg

Description

например, при облучении солей молибдена нейтронами ядерного реактора. Он является дочерним продуктом β -распада материнского изотопа ⁹⁹Mo.The invention relates to the field of applied radiochemistry, in particular to the production of radiopharmaceuticals for medicine. Technetium-99m radionuclide is formed by a nuclear reaction:

for example, when molybdenum salts are irradiated with neutrons from a nuclear reactor. It is a daughter product of the β decay of the maternal isotope ⁹⁹ Mo.

The above reaction (1) characterizes a generator system in which ^99m Tc is accumulated at intervals of 22 hours. Various methods can be used to isolate and separate it from the parent radionuclide ⁹⁹ Mo: chromatographic, sublimation, extraction, etc. Based on the first two methods, designs have been developed for small-sized devices transported for subsequent use directly to medical institutions. In contrast to them, extraction generators are stationary units, allowing to obtain the activity of technetium-99m 10-20 Curie (Ci) or more (against 0.5-0.7 Ci for chromatographic generators) and to meet the needs of medical institutions in large cities.

 The large dimensions of the extraction devices of the EGTTs-30 type (manufactured by Czechoslovakia) are, as a rule, determined by the height of the extraction column, where the extractant reacts with the initial solution when it moves from bottom to top. The higher the column, the longer the contact time and, accordingly, the separation efficiency of the mixture of daughter and parent radionuclides.

Relatively small installations are known where mixers are used instead of extraction columns. An example of such an extraction generator is the device described in the book (V. A. Sokolov. Generators of short-lived radioactive isotopes. - M .: Atomizdat, 1975, pp. 12-13, 29). It consists of an extractor with a stirrer, to which an initial alkaline solution of ⁹⁹ Mo molybdate is fed and an extractant, for example methyl ethyl ketone (MEK). After mixing the mixture and exfoliating the organic phase containing technetium-99m, it is pumped to the evaporator through a tube, one end of which is at the interface between the aqueous and organic phases. From here, the extractant is distilled off, and the dry residue containing technetium-99m is dissolved in physiological saline (0.9% NaCl).

 The main disadvantage of the described generator is the impossibility of extracting the extract without significant losses, since the phase interface is large, and when the end of the intake tube is shifted directly to the interface, it is possible to capture the aqueous phase together with the parent isotope, which is not permissible.

 A known extraction generator of the authors of this application, selected as a prototype (see RF patent N 2118858 from 09/10/98, BI N 25, 1998), comprising an extractor, a filter column, an evaporator with a refrigerator and a pertechnetate extraction unit, an air-vacuum control system and auxiliary containers with liquid communications, in which the aforementioned drawback is eliminated by reducing the area of the phase separation boundary by narrowing the casing of the extractor columns in the region of this boundary. Unlike the analogs discussed above, this generator has an extractor in the form of two columns: the main and additional, in which phase mixing is carried out alternately and repeatedly by alternately creating air rarefaction in the columns through their upper nozzles connected to the air-vacuum system. Due to this, a reduction in the dimensions of the installation is achieved in comparison with other single-column direct-flow systems. The extract with technetium is taken through a sampling tube, one end of which is located in the narrowed part of the additional column, where the surface of the interface is minimal and, accordingly, the extractant is not large (about 2-3%). The other end of the intake pipe is connected to a filter column. The specified generator is designed for work in a heavy protective box with simultaneous visual control of the location of the phase boundary during extraction.

 Thus, the problem of creating a highly efficient small-sized extraction technetium-99m generator with an autonomous (portable) extractor for operating the installation in radiological laboratories that do not have powerful protective equipment remains unresolved.

 The technical result of the present invention consists in creating the possibility of self-regulation of the location of the interface between the aqueous and organic phases in the extractor in the area of narrowing of the extraction column, which will allow the unit to be operated as a black box, i.e. in closed form with minimal loss of extractant.

 The technical task is solved as follows. As in the prototype, the generator includes an extractor with a column having a suction pipe in the narrowed middle part, and a pipe for connecting to an air-vacuum control system, a filter column, an evaporator connected to the pertechnetate extraction unit and a refrigerator in the upper part, and also auxiliary capacities with liquid communications. Unlike the prototype, the extractor column is made with holes in the lower part, coaxially placed in a sealed cylindrical housing with two nozzles for connecting to an air-vacuum control system and for outputting the spent molybdenum-99, while the intake pipe is connected to the filter column through one-way valves and container with extractant.

 This embodiment of the extractor allows you to place it in a protective container with holes for connecting hoses and communications.

 To prevent liquids from entering the air-vacuum system, the volumes of the extractor column and its internal part (between the walls of the column and the housing) are approximately equal to each other and individually exceed the total volume of introduced reagents.

 As a result, as in the prototype, multiple extraction is achieved, but with smaller (about 3 times) dimensions of the extractor due to its coaxial layout and the absence of fluid connection between the column and the inner part acting as an additional extractor.

 The drawing shows a schematic diagram of a technetium-99m generator.

The extraction generator includes an extractor with a column 1 having two nozzles in the upper part. One of the nozzles is connected to an air-vacuum system controlled from an external control panel 2, and the other 3 through communication 4 and one-way valves B ₁ and B _{2 are} connected to a filter column with sorbent 5 and to a container 6 containing extractant. The cylindrical housing 10, where the column 1 is coaxially mounted, also has two nozzles in the upper part: one for connecting to the air-vacuum system with remote control 2, and the other, plugged with plug 7, for collecting the spent ⁹⁹ Mo solution. In the center of the column 1 above its narrowed part is placed a sampling tube 8. In the lower part of the column there are through holes 9 for free passage of liquid from the column into the gap between the outer walls of the column and the inner surface of the housing 10. The column with sorbent 5 is connected through the nozzle to the evaporator 11, in the casing 12 which is pumped with hot water. One of the evaporator pipes is connected through a one-way valve B ₃ to the tank for supplying physiological saline 13, the refrigerator 14 is connected to the other, which, in turn, is connected to the tank 15 for collecting spent extractant. The evaporator intake pipe 16 is connected through a two-way valve B ₄ to a bottle for collecting sodium pertechnetate solution, ^99m Tc, through which a needle 17 is inserted. Another needle 18 of this bottle is connected to the air-vacuum system of control panel 2. It is also connected to the air-vacuum system a pressure gauge 19 and a needle valve 20 mounted on the panel of the control panel. The control panel contains 6 solenoid valves, two of which (K ₂ and K ₆ ) are connected through air filter 21 to atmospheric air, and the rest are connected to a vacuum pump 22 (for example, water-jet). The generator is controlled using the command buttons displayed on the remote control panel. The extractor is placed in a protective container 23 having openings for connecting hoses and communications.

Example. A weighed portion of molybdenum oxide (MoO ₃ ) in an amount of 14 g is irradiated with reactor neutrons and dissolved in 36 ml of a 5 M KOH solution with the addition of 1 ml of hydrogen peroxide in a separate container located outside the generator and having an outlet tube. At the end, bring the volume of the solution to 85 ml with a 2.5 M solution of K ₂ CO ₃ . The resulting composition through the outlet pipe, pre-connected to the pipe 3 of the extractor, is fed through the intake pipe 8 and the holes 9 into the gap between the walls of the columns 1 and the housing 10 by creating in this area a vacuum through the valve K ₁ . The output tube is disconnected from the pipe 3, and in its place connect the communication 4 of the generator. Through valves K ₂ and K _6, atmospheric air is launched into the column and into the gap between the walls, which leads to equalization of the liquid level in these communicating volumes. The volume of the solution is determined as the sum of the volumes of the column 1 of the extractor and the housing 10 to the narrowing of the column 1. At the same time, the level of the aqueous phase in the column is at or 1-2 mm below its narrowed part.

At the end of the load, on the tank 4 containing the extractant methyl ethyl ketone (MEK) in the amount of 40 ml, open the valve B ₂ and turn on the valve K ₁ create a vacuum in the gap between the walls. The required rarefaction value (approximately 0.1 kgf / cm ² ) is set according to the pressure gauge 19 using a needle valve 20. According to this command, the extractant passes through the layer of the aqueous phase with molybdenum-99 through communication 4, intake pipe 8 and openings 9, captures technetium -99m and is collected in the upper part of the volume between the walls of the housing 10 and the extraction column 1. Then, through the valve K ₂ , a vacuum is created in the column 1 and at the same time air is introduced into the gap between the walls through the valve K ₂ . Under these conditions, the aqueous and organic phases through the openings 9 alternately pass into the column with simultaneous re-extraction. The described operations for transferring liquids from volume to volume are repeated 2-3 times. At the stage of the final completion of the extraction, the aqueous and organic phases are transferred to the column, the vacuum in the system is reduced to zero, and in this mode, they are stratified for 1-2 minutes, and then valves K ₂ and K ₆ are turned _on simultaneously to equalize the level of liquids in the column and in the volume between the walls.

The established equilibrium, based on the law of mass action, will be written:
M ₁ = M ₂ ,
where M ₁ = M _e + M _in is the total mass of the extractant and the aqueous phase in the column, and M ₂ is the mass of the aqueous phase in the volume between the walls, respectively.

Under the action of the mass of extractant, the mass of the aqueous phase Δ M = M ₂ - M _{c is} additionally displaced from the column. The height of the displaced column relative to its initial level h ₀ (until the introduction of the extractant) is
Δh = ΔM / 2S • d,
where d is the density of the aqueous phase, and S is the cross-sectional area of the column.

 During the subsequent extraction of the extractant, self-regulation of the phase boundary is ensured by the value of Δ M, which decreases in proportion to the decrease in the mass of the extractant. This eliminates the possibility of the molybdenum solution entering the evaporator.

To transfer the extractant through the intake pipe 8 and the filter column 5 into the evaporator, the valve B _{1 is} opened, and in the evaporator system 11 a vacuum is created through the valve K ₄ while the atmospheric air is supplied to the extractor through valves K ₂ and K ₆ . When selecting the extractant, the column of the aqueous phase in the generator column rises to the initial level h ₀ . At the same time, in the narrowed part of the column there remains the part of the IEC, the volume of which is equal to the volume of the neck to the tip of the intake pipe 8. With a neck cross section of 1 cm ² and its height of 1.5 cm, the losses amount to 1.5 ml or about 4% of the injected amount.

At the end of the extraction of extractant, the valve B ₁ close and turn off the valves K ₂ and K ₆ . In the casing of the evaporator 11 and the refrigerator 14 serves respectively hot (93-96 ^o C) and cold water. The process is carried out until the IEC is completely vaporized. Then, the evaporator is purged, for which a three-way valve B ₄ is opened for 3-5 minutes to the start position of atmospheric air. After that, the water supply systems are turned off. 10-12 ml of physiological saline (0.9% NaCl solution) is introduced into the container 13 and the B ₃ valve is opened. This solution washes technetium-99m from the walls of the evaporator, and a solution of sodium pertechnetate, ^99m Tc, is formed. Flushing is carried out in the same position of the valve B ₄ in the mode of bubbling. Then the tap B _{4 is} switched to the “feed” position, and in the collection vial a vacuum is created by turning on the valve K ₅ through the needle 18. By this command, the sodium pertechnetate solution, ^99m Tc, passes into the bottle through the needle 17. This completes the process of obtaining the drug. The bottle is disconnected from the needles using a remote device, and the resulting preparation is sent for sterilization.

 At the end of 1-2 weeks (the shelf life of the molybdenum-99 solution), the extractor is rebooted. To this end, the cork is removed from the pipe 7, a sampling tube is introduced into the extractor, and the spent aqueous phase is pumped through it into the waste collector.

 In the considered example, the technetium generator is located directly at the place of preparation of the initial molybdenum-99 solution. In the case when the main generator stand together with the remote control and auxiliary capacities is based in rooms remote from the place of irradiation, the container with the extractor after loading can be transported to the place of subsequent operation. In this case, all the outlet pipes of the extractor are drowned out by plugs.

 The inventive technetium generator provides high reliability in the selection of the extractant with its minimum losses, without resorting to visual monitoring of the progress of this process. The proposed design makes it possible to reduce the dimensions of the extractor several times, which allows you to create its mobile version.

Claims (2)

 1. The extraction technetium-99m generator, including an extractor with a column having a suction pipe in the narrowed middle part, and a pipe for connecting to an air-vacuum control system, a filter column, an evaporator connected to a pertechnetate extraction unit and a refrigerator in the upper part, and also auxiliary containers with liquid communications, characterized in that the extractor column is made with holes in the lower part, coaxially placed in a sealed cylindrical housing with two nozzles for connection to air-vacuum control system and for the withdrawal of spent molybdenum-99, while the intake pipe through one-way valves connected to a filter column and a container with extractant.  2. The extraction technetium-99m generator according to claim 1, characterized in that the extractor is placed in a protective container with holes for connecting hoses and communications.