KR20180035317A - a continuously medical radioisotope injecting device to the column - Google Patents

Abstract

The present invention relates to an apparatus to manufacture a radioisotope solution (Mo-99, etc.) used for medical diagnosis and cure and, more specifically, relates to an apparatus to inject a medical radioisotope solution into a column, to correctly inject the total radioactivity required for medical purposes. According to the present invention, the apparatus (400) comprises: a dilute solution storage unit (410), a dilute solution radioactivity measurement unit (411) a first radioisotope creation column unit (420); a waste solution storage unit (470); a waste solution radioactivity measurement unit (471); and a saline solution injection unit (480). Accordingly, provided is an effect capable of continuously manufacturing a radioisotope column through control of a process to sequentially supply a dilute solution to an injection storage unit of each radioisotope creation column unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a continuous medical radioisotope injecting device to the column,

TECHNICAL FIELD The present invention relates to an apparatus for producing a radioactive isotope (Mo-99, etc.) solution used for medical diagnosis treatment, and more particularly, to an apparatus for preparing a radioactive isotope solution for medical use ≪ / RTI >

Technetium-99m ( ^99m Tc) is a medically important radioisotope and is used in various medical diagnoses. The ^99m Tc is a gamma ray emitter having a half-life of 6 hours. It is a self-emissive nuclide of molybdenum-99 ( ⁹⁹ Mo) produced by neutron absorption or fission products of molybdenum-98 ( ⁹⁸ Mo) It is used for various medical diagnosis of diseases.

In addition, there is a growing interest in the therapeutic radiopharmaceuticals following the diagnosis area, and ¹⁸⁸ Re has emerged as a promising therapeutic nuclide.

Such ^99m Tc or ¹⁸⁸ Re can be successively separated from the parent mixture by solvent extraction or chromatographic techniques. Chromatography methods are used more than other methods because of their smaller size, easier operation, and less time constraints. This chromatographic extraction system of ^99m Tc or ¹⁸⁸ Re is referred to as " ⁹⁹ Mo / ^99m Tc generator" or " ¹⁸⁸ W / ¹⁸⁸ Re generator." The convenience and portability of the generator makes it possible to extract ^99m Tc or ¹⁸⁸ Re It is becoming universal in the world of nuclear medicine as much as possible.

Many ^99m Tc generator for using the ⁹⁹ Mo produced by the fission of highly enriched ²³⁵ U, these fission ⁹⁹ Mo are extremely with a high specific activity (specific activity), also many Ci (Curie) amounts of ⁹⁹ Mo currently used Can be adsorbed onto a very small alumina column (alumina 1-1.5 g) that can yield high concentrations of ^99m Tc (greater than ^99m Tc 1Ci) by effectively eluting even small volumes (less than 2 to 5 ml) of eluent. However, the ²³⁵ U fission generates a lot of gaseous and solid radioactive material, which is a troublesome and costly waste disposal problem.

There are many methods for extracting ⁹⁹ Mo from various target materials investigated in a nuclear reactor. US Pat. No. 5,910,971 describes a method and apparatus for generating ⁹⁹ Mo in a uranyl sulfate nuclear fuel of a homogeneous liquid reactor. ^The fuel containing ⁹⁹ Mo is recovered by passing it through an organic adsorbent to extract ⁹⁹ Mo in a closed cycle system. US Patent No. 5,962,597 describes a specific organic adsorbent for extracting ⁹⁹ Mo from a solution reactor as disclosed in U.S. Patent No. 5,910,971.

Korean Patent Application No. 2002-7007625 discloses an inorganic adsorbent for efficiently and selectively extracting ⁹⁹ Mo from a radioactive solution of uranium. The sorbent has a high radiation resistance that allows it to be used in high radiation areas of the reactor, facilitating a closed cycle extraction method that maintains the uranium concentration of the fuel through many ⁹⁹ Mo extraction cycles while minimizing radioactive waste disposal problems.

In addition, US Pat. No. 4,280,053 discloses a ^99m Tc generator containing a zirconium molybdate (ZrOMoO ₄ ) gel produced from ⁹⁹ Mo. Where the gel is prepared by dissolving ⁹⁹ Mo in a somewhat excess aqueous ammonia solution or sodium hydroxide solution. Specifically, acid is added to adjust the pH to between 1.5 and 7, and the resulting solution is added to the stirred zirconium aqueous solution to form a molybdate precipitate. The precipitate is collected by filtration or liquid distillation, dried in air, To obtain a zirconium molybdate.

On the other hand, ⁹⁹ Mo is produced by irradiating neutrons with ⁹⁸ Mo (n, γ). In this reaction, ⁹⁹ Mo with low radioactivity can not be produced. Therefore, Columns should be used. As a result, the volume of the eluent is increased, and only ^99m Tc solution with low radioactivity concentration can be produced.

Current international supply of fission ⁹⁹ Mo is now largely dependent on South Africa or Canada, and it is therefore necessary to develop alternative technologies for technetium generators that use fission ⁹⁹ Mo as a raw material to avoid steady supply and long haul transport.

Recently, a generator system using a high capacity adsorbent for molybdenum was proposed by Kaken Co. in Japan. This generator system uses zirconium polymer (PZC) as the adsorbent and (n, γ) molybdenum (ie, low non-radioactive molybdenum) as a ^99m Tc source. However, in the production of a generator column using the above-mentioned materials, complicated radiation is required, such as not only preparing molybdenum in a batch system (batch system) but also heating a solution for a batch reaction for a long time, .

In addition, the conventional technique for producing a radioisotope column does not provide a technique capable of providing an accurate radioactivity amount for a medical radioisotope ( ⁹⁹ Mo / ^99m Tc) column, There is a problem that a technique for manufacturing a conventional radioisotope column can not be continuously produced for producing a medical radioisotope ( ⁹⁹ Mo / ^99m Tc) column.

The present invention provides an apparatus for column injection of a radioactive isotope solution for medical use that can provide an accurate radioactivity amount of a radioisotope column.

The present invention also provides a control process and apparatus for injecting a column of a medical radioisotope solution capable of continuously producing a radioisotope column.

The present invention has been made to solve the above-mentioned needs and problems,

The first radioactive isotope production column section 420, the waste liquid storage section 470, the waste liquid activity measurement section 471, and the saline infusion section 480. The dilution liquid storage section 410, dilution liquid activity measurement section 411, (400) for injecting a medical radioisotope solution, which is configured to include a medical radioisotope solution.

The first radioisotope producing column section 420 includes an injection storage section 422, an injection storage section pump section 422-1, a generation section 421, a generation section pump section 421-1, (400) for injecting a radioactive isotope solution for medical use, characterized in that the medical radioisotope solution is constituted by including the above-mentioned components.

The present invention provides an in-column injection device 400 for a medical radioisotope solution characterized in that the first radioisotope producing column section 420 is composed of two or more.

The present invention is characterized in that the diluent solution is introduced into the injection reservoir 422 using the injection reservoir pump section 422-1 of the first radioisotope producing column section 420 in the diluent reservoir 410 described above The diluent is introduced into the injection reservoir 432 of the second radioisotope generating column 430 from the diluent reservoir 410 at a predetermined time interval, (400) of a medical radioisotope solution in which a radioisotope column can be continuously produced through a process control of sequentially introducing a dilution liquid into the injection reservoir of the third, fourth, and fifth radioisotope producing columns do.

The apparatus for injecting a medical radioisotope solution according to the present invention has an effect of providing a radioisotope column containing a radioactivity required by a user.

In addition, the apparatus for injecting a radioactive isotope solution for medical use according to the present invention has the effect of continuously producing a radioisotope column.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a structural view of a device for injecting a medical radioisotope solution into a column according to the present invention. FIG.
Figure 1b is an external front view of a device for injecting a medical radioisotope solution in a column according to the present invention.
1C is a conceptual diagram of an in-column injection device for a medical radioisotope solution according to the present invention connected to a dilution and dispensing device for a radioisotope stock solution.
2 is a conceptual diagram of a radioisotope column in which a radioisotope is injected by a radioisotope generating column.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

The present invention is a device 400 for injecting a medical radioisotope solution into a dilution liquid (hereinafter referred to as a dilution liquid) of a radioisotope stock solution from a radioisotope stock solution dilution and dispensing apparatus 200.

The present invention includes a diluent reservoir 410, a diluent radioactivity measuring unit 411, a first radioactive isotope producing column unit 420, a waste liquid reservoir unit 470, a waste liquid radioactivity measuring unit 471, a physiological saline infusion unit 480) for injecting the medical radioisotope solution into the column.

As shown in FIG. 1, each component of the present invention is included in the second hot cell 401.

The second hot cell 401 of the present invention has a case shape and is formed of a material that shields radiation.

The diluent reservoir 410 of the present invention means a container or an apparatus for temporarily storing the radioactive isotope dilution and measuring the total radioactivity for the diluted radioisotope supplied from the feeder 200. [

The dilution liquid radioactivity measuring unit 411 of the present invention is added to the diluting liquid reservoir 410. The diluted radioactive isotope dilution liquid for the radioactive isotope solution column used for medical use is supplied to the diluted liquid reservoir 410, 1 radioisotope column section 420 to measure the total radioactivity of the radioactive isotope dilution solution.

The dilution liquid radioactivity measurement unit 411 of the present invention means an apparatus or means capable of measuring a normal radioactivity amount.

As described above, the present invention uses radionuclides using Mo-99 and Tc-99m, which are mainly diagnostic for medical use, as radioactive isotopes to be used.

Mo-99 has a half-life of 66 hours and is converted to Tc-99m. In addition, Tc-99m is converted to Tc-99 with a half-life of 6 hours.

Therefore, the diluted radioisotope diluted with the distilled water of the radioisotope stock solution was Mo-99, Tc-99m. 99 and Tc-99m are added to the first radioisotope-producing column section 420 as the radioactive isotope to be diagnosed uses Mo-99 and Tc-99m radionuclides, Absorbed and Tc-99 should be removed.

In general, the imported radioactive isotope solution is introduced during the continuous collapse of Mo-99, so that Tc-99 is about 2/3, which is about 2/3 of the total radioactivity, and Mo-99 / Tc- 99m is about 1/3.

Accordingly, the present invention provides a function of preparing a radioisotope dilution solution having a radioactivity of about 3 times the radioactivity amount when the required radioactivity for the radioisotope solution column used for medical use is, for example, 10 mci (milliCure) And it is possible to extract 10 mci which is about 1/3 of the amount of radioactivity provided to the first radioactive isotope column section 420.

The technical feature of the present invention is that the total radioactivity of the diluted radioisotope flowing into the diluent reservoir 410 is measured and stored so that a radioisotope solution column having a desired radioactivity can be manufactured .

The first radioisotope producing column section 420 of the present invention includes an injection storage section 422, an injection storage section pump section 422-1, a generation section 421, a generation section pump section 421-1, And the like.

The infusion reservoir 422 of the present invention may include a container or apparatus that temporarily stores a radioactive isotope diluent for injecting the radioisotope dilution liquid from the diluent reservoir 410 to the generation unit 421 it means.

Therefore, in the present invention, the diluted radioisotope diluted in the diluent reservoir 410 is measured by a radioactivity meter, and the total radioactivity is measured and the value is obtained. In addition, the diluted solution is stored in the diluent reservoir 410, The total radioactivity of the radioisotope diluent contained in the injection reservoir 422 becomes equal to the total radioactivity of the diluent reservoir 410 as the diluent is introduced into the injection reservoir 422. [

With this configuration and action, the effect of being able to know the total radioactivity of the radioisotope dilution liquid flowing into the generation section 421 is generated.

The injection storage part pump part 422-1 of the present invention means a pump or an apparatus that performs a function of injecting a radioactive isotope dilution solution from the diluent storage part 410 to the injection storage part 422 .

The above-mentioned generation unit 421 of the present invention means an apparatus or means for generating a medical-diagnostic and therapeutic radioisotope-adsorbed column.

Therefore, the above-mentioned generation unit 421 means that an apparatus or means for generating a column in which ordinary radioisotopes are adsorbed can be used.

The cancer diagnostic agent and the therapeutic agent-producing column of the radiopharmaceuticals described in the application No. 10-2014-0092963 filed by the applicant of the present invention in the section entitled "Column for the diagnosis of cancer drugs and therapeutic agents for radiopharmaceuticals and their assemblies" Quot; generation unit 421 ".

As shown in FIG. 2, the generating unit 421 includes a columnar glass container and an adsorbent for adsorbing the radioactive isotope therein, introducing a nuclide as a radioactive substance into the columnar glass container and adsorbing it, Means a device or means having a space for producing nuclides.

Therefore, as described above, the generating unit 421 is filled with an adsorbent to maintain the shape stability of the filter, and both ends of the glass container are connected to a diagnostic column And a column having an adsorbent and a filter adsorbed on an adsorbent A such as alumina filled with molybdenum (Mo-99) in the form of sodium molybdate inside the glass vessel, (B), which is a diagnostic form of sodium formate (Tc-99m), which reacts in the process of contact with the adsorbent by injecting a reagent made of NaCl or the like into the column. .

The generating part pump part 421-1 of the present invention performs a function of introducing the diluted radioisotope solution stored in the injection storage part 422 into the generating part 421 so that the radioisotope diluent contained in the radioisotope dilution solution And adsorbs the element to the adsorbent (A).

In the present invention, the radioactive isotope is adsorbed on the adsorbent by injecting the radioactive isotope diluent into the generator 421, and there is a radioactive isotope material that is not adsorbed on the adsorbent of the generated portion. The total radioactivity of the radioactive isotope material can be accurately determined by measuring the total radioactivity of the radioactive isotope material.

The technical feature of the present invention is that it has a configuration capable of measuring the amount of radioactivity that is exiting without being adsorbed by the generation unit 421 and is composed of a waste liquid storage unit 470 and a waste liquid radioactivity measurement unit 471 .

The waste solution reservoir 470 of the present invention may temporarily store the filtrate exiting from the generation section 421 or may mix the radioisotope column B (B) of the generation section in which the radioisotope is adsorbed by physiological saline (NaCl) Means a container or a device for temporarily holding washing water discharged from washing.

The present invention is capable of measuring the amount of radioactivity that the waste liquid reservoir 470 has been additionally provided with the waste liquid radioactivity measurement unit 471 so as to exit without being adsorbed by the generation unit 421. [

The above-described waste liquid radioactivity measuring unit 471 of the present invention is constituted by an apparatus or means for measuring ordinary radioactivity.

The physiological saline solution injecting part 480 of the present invention provides a physiological saline solution for washing unadsorbed radioisotope material including Tc-99 which has been reacted to the radioisotope column (B) of the generating part 421 Means a device or means that

The physiological saline solution injector 480 of the present invention stores 0.9% of physiological saline (NaCl), and the physiological saline solution pump portion 481-1 injects saline solution into the generator portion 421 .

In the present invention, the physiological saline solution is injected from the physiological saline solution injection pump part 481-1 into the diluent solution reservoir 410, and then the diluent solution reservoir 410 is injected into the injection reservoir pump part 422-1. The saline solution is introduced into the injection reservoir 422 and then introduced into the generator 421 by using the generator pump unit 421-1 to be cleaned.

The washing water is moved to the waste solution reservoir 470 and the total amount of radioactivity released from the washing solution can be measured by the waste solution radiation measuring unit 471,

The present invention is characterized in that the total radioactivity (a) of the above-described radioisotope dilution solution is measured, the total radioisotope capacity (b) of the filtrate of the radioisotope dilution solution passed through the generation section 421 is measured, (C) of the washing water washed with the radioisotope column (B), the action and effect of accurately recognizing the total radioactivity amount (T) contained in the radioisotope column (B) are exhibited.

In other words,

Total radioactivity (T) included in the radioisotope column (B) = total radioactivity of the radioisotope dilution (a) - total radioisotope of the filtrate of the radioisotope dilution (b) Total radioactivity (c)

.

1C, the waste liquid reservoir portion 470 of the present invention further includes a waste liquid reservoir portion pump portion 472 to transfer the radioactive waste liquid to the waste liquid storage portion 350 of the radioisotope stock solution diluter and feeder 200 .

The present invention includes an operation control unit 490 and is provided with the diluent reservoir 410, the diluent radioactivity measuring unit 411, the first radioisotope producing column unit 420, the waste liquid reservoir unit 470, It is possible to perform the operation control and the process control on the measurement unit 471 and the saline solution injection unit 480.

The operation control unit 490 of the present invention means a device or means equipped with a central processing unit such as an ordinary CPU or an MCU and equipped with a memory, a command control structure, an information input / output unit, and the like.

The operation control unit 490 of the present invention includes the dilution liquid storage unit 410, the dilution liquid activity measurement unit 411, the first radioisotope production column unit 420, the waste liquid storage unit 470, 471) and to control the action of opening and closing open lungs on each inflow tube and / or outflow tube added to the physiological saline infusion section 480.

The operation control unit 490 of the present invention further includes an injection storage unit 422 of the first radioisotope production column unit 420, an injection storage unit pump unit 422-1, a generation unit 421, Closing of the inlet pipe and / or the outlet pipe related to the operation and stoppage of various pump sections such as the pump section 421-1, the waste liquid storage section pump section 472, and the like.

Therefore, according to the present invention, the total amount of radioactivity contained in the medical radioisotope column (B) can be accurately known by the above-described constitution and operation, so that a user for medical use can perform diagnosis and treatment more accurately and precisely The effect of the

The technical feature of the present invention is that two or more first radioisotope producing columns 420 are provided to continuously generate the radioisotope columns B, thereby remarkably improving productivity.

As shown in FIG. 1, the first radioisotope generating column section 420 is formed by two or more than two.

Accordingly, the present invention is not limited to the above-described radioisotope producing column section 420, the second radioisotope producing column section 430, the third radioisotope producing column section 440, the fourth radioisotope producing column section 450 ), A fifth radioisotope generating column section (460), and the like.

The conventional radioisotope column apparatus is generally composed of only one radioisotope generating column section, and thus it has been difficult to supply a radioisotope column which is urgently required for medical use.

In particular, even when a conventional radioisotope column apparatus has a plurality of radioisotope column sections, it is necessary to measure the precise radioactivity amount of the radioisotope stock solution injected into each column section to simultaneously operate the plurality of radioisotope column sections It was difficult and more difficult to manufacture continuously.

The present invention is characterized in that the first radioisotope column (420) is formed by two or more than two, and that the radioisotope column (B) can be continuously produced through process control thereon. Feature.

As shown in FIG. 1 and as described above, the present invention is characterized in that the total radioactivity of the diluent is known in the diluent reservoir 410, which is known from the injection reservoir pump section 422-1 of the first radioisotope producing column section 420, The dilution liquid is introduced into the injection reservoir 422 using the process control.

The dilution liquid introduced into the injection storage section 422 of the first radioisotope production column section 420 flows into the generation section 421 as described above to generate the radioisotope column B, The process of measuring the total radioactivity of the filtrate, washing with physiological saline and controlling the process of measuring the total radioactivity of the waste liquid washed with physiological saline is performed to prepare the radioactive isotope column (B), and an accurate A process of measuring the total radioactivity is carried out.

The present invention is characterized in that the diluent solution is introduced into the injection reservoir 422 using the injection reservoir pump section 422-1 of the first radioisotope producing column section 420 in the diluent reservoir 410 described above (For example, intervals of 1 minute to 5 minutes), the diluent reservoir 410 is connected to the injection reservoir pump section 432 of the second radioisotope producing column section 430 -1) is used to control the process of introducing the diluent into the injection reservoir 432.

The diluent introduced into the injection storage section 432 of the second radioisotope producing column section 430 flows into the generation section 431 in the same manner as the first radioisotope producing column section 420 The steps of generating the radioisotope column (B), measuring the total amount of radioactivity of the filtrate, washing with physiological saline, and measuring the total radioactivity of the waste solution washed with physiological saline were carried out to obtain radioisotope columns B) is carried out and a process for measuring an accurate total radioactivity amount therefor is carried out.

The second radioisotope producing column section 430 of the present invention has the same construction as the first radioisotope producing column section 420 and thus the second radioisotope producing column section 430 has the same structure as the first radioisotope producing column section 420, An injection storage section pump section 432-1, a generation section 431, and a generation section pump section 431-1.

Similarly, other radioisotope producing column sections, such as the third radioisotope generating column section 440, the fourth radioisotope generating column section 450 and the first radioisotope producing column section 460, And has the same configuration as the generation column section 420.

As described above, in the present invention, the dilution liquid is injected into the first radioisotope producing column section 420 and injected into the second radioisotope producing column section 430 at a predetermined time interval, The radioactive isotope column B can be continuously manufactured through the process control in which the dilution liquid is injected into the third radioisotope producing column section 430 at a constant time interval and operated continuously.

In addition, the present invention is characterized in that the radioisotope column (B) can be continuously produced by continuously performing the above-described process on the remaining radioisotope producing column section (420).

Even when the time required to produce the radioisotope column (B) in the single radioisotope column (420) of the present invention takes a time of, for example, 5 to 20 minutes, the radioisotope column (420) The total radioactivity of the diluted solution injected into the radioactive isotope column portion 420 and the total radioactivity of the waste fluid are measured and calculated by the control unit 490 of the present invention, The total radioactivity of the elemental column (B) is measured.

The method of measuring the total amount of radioactivity is simply measured by the calculation formula and the application program installed in the control unit.

As shown in FIG. 1B, the second hot cell of the present invention is provided with the monitor unit 500, and the total radioactivity of the diluted solution injected into each of the radioisotope producing columns 420, the total radioactivity of the radioactive waste, And displays the total radioactivity of the radioisotope column (B).

In the second hot cell of the present invention, an observation window 402 is formed and functions to check processes and internal conditions of each of the radioisotope producing columns 420.

The present invention provides an in-column injection device for continuous production of a medical radioisotope solution having the above-described structure and function.

The present invention is very useful for an industrial columnarizing process using a radioactive isotope used for diagnostic or therapeutic purposes.

Further, the present invention is a very useful invention for industries handling radioactive isotopes used for diagnostic or therapeutic purposes.

A dilution liquid storage portion 410, a dilution liquid radioactivity measurement portion 411, a first radioisotope production column portion 420, a waste liquid storage portion 470, a waste liquid radioactivity measurement A portion 471, a physiological saline solution injecting portion 480,
The injection storage section 422, the injection storage section pump section 422-1, the generation section 421, the generation section pump section 421-1,

Claims (4)

The first radioactive isotope production column section 420, the waste liquid storage section 470, the waste liquid activity measurement section 471, and the saline infusion section 480. The dilution liquid storage section 410, dilution liquid activity measurement section 411, (400) for in-column medical radioisotope solution comprising a plurality of medical radioisotope solutions.
The method according to claim 1,
The first radioisotope producing column section 420 includes an injection storage section 422, an injection storage section pump section 422-1, a generation section 421, and a generation section pump section 421-1 (400) for injecting a medical radioisotope solution characterized in that it is constituted.
3. The method according to claim 1 or 2,
Characterized in that the first radioisotope producing column section (420) is composed of two or more than two.
The method of claim 3,
The dilution liquid is introduced into the injection storage section 422 by using the injection storage section pump section 422-1 of the first radioisotope production column section 420 in the dilution liquid storage section 410 The diluent is introduced into the injection reservoir 432 of the second radioisotope generating column 430 from the diluent reservoir 410 at a predetermined time interval, (400) for injecting a medical radioisotope solution into a column capable of continuously producing a radioisotope column through a process control of sequentially introducing a dilution liquid into an injection reservoir of a radioisotope production column of the column.

Images