JP2002214395A - Isotopic nuclide manufacturing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an isotopic nuclide manufacturing device allowing improvement of production efficiency of isotopic nuclide produced using neutrons. SOLUTION: Neutrons are multiplied by a neutron multiplication material 2, and then moderated by a neutron moderator 3. The neutrons moderated by the neutron moderator 3 are made incident on an isotopic nuclide producing material 5, thereby generating isotopic nuclide with nuclear reaction. The neutrons causing the nuclear reaction in the isotopic nuclide producing material 5 increase by multiplying and moderating the neutrons, so that the production efficiency of the isotopic nuclide is improved.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an isotope nuclide producing apparatus for producing isotope nuclides using neutrons.

[0002]

2. Description of the Related Art Radioisotopes (hereinafter referred to as RIs)
SPECT (SinglePhoton Emission C)
The omputed tomography is used for various radiological diagnoses such as cancer diagnosis, vascular disorder diagnosis, lung function diagnosis, bone disease diagnosis and the like. Among the RIs used in SPECT, technetium-99m ( ^99mTc ) is used for more than 60 types of drugs, and the proportion of technetium-99m in the amount of RI for SPECT is very large.

[0003] Technetium-99m is a daughter of the half-life of 66 hours molybdenum ⁹⁹ (99 Mo), if the use of molybdenum 99 as a technetium generator,
Technetium 99m can be easily eluted even in hospitals. As described above, technetium-99m occupies a very important position in medical care, and the importance of stable supply of molybdenum-99, a parent nuclide, to medical care is described in "Isotope news; Jan. '00. No. 548 Nippon Isotope. Association).

[0004]

In order to produce molybdenum 99, ⁹⁸ Mo (n, γ) ⁹⁹ Mo, ²³⁵ U (n, f) ⁹⁹ Mo,
Nuclear reactions such as ¹⁰⁰ Mo (p, pn) ⁹⁹ Mo are used,
²³⁵ U (n, f) ⁹⁹ Mo has a low operating rate because it uses a nuclear reactor, and ¹⁰⁰ Mo (p, pn) ⁹⁹ Mo requires a high-power proton source because of its small reaction cross section. For this reason, ⁹⁸ Mo (n, γ) ⁹⁹ Mo using neutrons has attracted attention,
It is desired to efficiently generate molybdenum 99 even at ⁹⁸ Mo (n, γ) ⁹⁹ Mo using neutrons.

[0005] An object of the present invention is to provide an isotope nuclide production apparatus capable of improving the generation efficiency of isotope nuclides produced using neutrons.

[0006]

A feature of the present invention to achieve the above object is that an isotope nuclide is produced by a nuclear reaction between a neutron moderator that slows down incident neutrons and a neutron moderated by the neutron moderator. And an isotope nuclide-producing material.

[0007] By slowing down neutrons with a neutron moderator, neutrons are more likely to cause a nuclear reaction with the isotope nuclide generator, and the amount of neutrons that cause a nuclear reaction is increased, thereby improving the RI generation efficiency.

[0008]

Embodiments of the present invention will be described below with reference to the drawings. (Embodiment 1) FIG. 1 is a structural view (cross-sectional view) of an isotope nuclide producing apparatus according to a preferred embodiment of the present invention. As shown in the figure, in the isotope nuclide production apparatus of the present embodiment, a neutron multiplier 2 and a neutron moderator 3 are contained in a cylindrical container 1, and a target 4 is provided at the bottom of the container 1. .
Further, an RI generating material 5 is provided so as to surround the container 1. The RI generating material 5 is filled in a container 6. The container 6 is provided with a recovered liquid inlet 7 at a lower part and a recovered liquid outlet 8 at an upper part.

[0009] In such an isotope nuclide production apparatus,
The target 4 is irradiated with a charged particle beam, and neutrons are generated by a nuclear reaction between the target 4 and the charged particle beam. In this embodiment, a neutron is generated by a D-T reaction between the deuterium beam and tritium by using a deuterium beam as the charged particle beam and using a titanium material (Ti) impregnated with tritium as the target 4. . The substance to be impregnated with tritium is not limited to a titanium material, but may be another hydrogen storage material or a metal (for example, copper).
May be used. When a DD reaction is used to generate neutrons, the titanium material impregnated with deuterium may be irradiated with a deuterium beam.

The neutrons generated in the target 4 pass through the container 1 and enter the neutron multiplier 2, where the neutrons are multiplied by the neutron multiplier 2. In this embodiment, the neutron multiplier 2
Is used as beryllium. The neutron multiplier 2
May be used as lead. The neutrons multiplied by the neutron multiplier 2 enter the neutron moderator 3, and the neutrons incident on the neutron moderator 3 are decelerated. In the present embodiment, water is used as the neutron moderator 3. The neutrons are desirably decelerated by the neutron moderator 3 to thermal neutrons.

The neutrons decelerated by the neutron moderator 3 pass through the vessel 6 and reach the RI generating material 5, where RI is generated by a nuclear reaction. In the present embodiment, molybdenum 98 is used as the RI generating material 5, and ⁹⁸ Mo (n, γ) ⁹⁹ Mo
As a result, molybdenum 99 which is RI is generated. Molybdenum 99 breaks down to technetium 99m. In order to recover the technetium 99m, a recovery liquid (physiological saline in this embodiment) is injected from the recovery liquid inlet 7 to take in the technetium 99m into the recovery liquid, and the recovered liquid is taken out from the recovery liquid outlet 8. Technetium 99m is separated and collected from the collected liquid that has been taken out, and the collected technetium 99m is used for SPECT. The RI generating material 5 of this embodiment is pebble so that the collected liquid can easily pass. Since molybdenum 98, which is the RI generating material 5, has a natural abundance of 24%, in this embodiment, the number of atoms of molybdenum 98 is increased by enrichment. Further, the container 6 is preferably made of a low-activation material that is not corroded by physiological saline, and in this embodiment, SUS is used.

As described above, in the present embodiment, neutrons are multiplied by the neutron multiplier 2, so that neutrons causing a nuclear reaction with the RI generating material 5 can be increased, and the RI generating efficiency can be improved. Can be. In this embodiment,
Since neutrons are slowed down by the neutron moderator 3, RI
It is possible to increase neutrons that cause a nuclear reaction with the product 5
The RI generation efficiency can be improved. Embodiment 2 An isotope nuclide producing apparatus according to another embodiment of the present invention will be described with reference to FIG. In the isotope nuclide production apparatus of this embodiment, two sets of laminates obtained by laminating a neutron multiplier, a neutron moderator, and an RI generator are provided in a container. Hereinafter, differences from the first embodiment will be described.

Neutrons generated by irradiating the target 4 with the charged particle beam pass through the container 1 and reach the neutron multiplier 2a, where they are multiplied by the neutron multiplier 2a. Neutrons multiplied by the neutron multiplier 2a are as follows:
After being decelerated by the neutron moderator 3a, a nuclear reaction occurs with the RI generator 5a to generate RI (molybdenum 99). Neutrons that have not caused a nuclear reaction in the RI producing material 5a are classified into those that are reflected by the neutron multiplier 2b and those that enter the neutron multiplier 2b. The neutrons reflected by the neutron multiplier 2b are returned to the RI generator 5
a, and RI is generated by a nuclear reaction. On the other hand, neutrons incident on the neutron multiplier 2b are multiplied by the neutron multiplier 2b. The neutrons multiplied by the neutron multiplier 2b are decelerated by the neutron moderator 3b, and then cause a nuclear reaction with the RI generator 5b to generate RI. In addition, between the RI generator 5a and the neutron multiplier 2b and the neutron moderator 3a, and between the RI generator 5b and the neutron moderator 3b, a partition plate (not shown) made of a material that transmits neutrons. Are inserted into the layers of the RI generating materials 5a, 5b separated by the partition plates, and the collected liquid is injected from the collected liquid inlets 7a, 7b, and the collected liquid is discharged from the collected liquid outlets 8a, 8b. .

As described above, by providing two sets of laminates in which the neutron multiplier, the neutron moderator, and the RI generating material are laminated, a part of the neutrons which did not cause a nuclear reaction in the RI generating material 5a can be increased. Since the light is reflected by the multiplier 2b and is incident on the RI generating material 5a, the RI generating efficiency can be improved. It should be noted that the number of laminates of the neutron multiplier, the neutron moderator, and the RI generating material is not limited to two sets, and the effects of the present embodiment can be obtained with a plurality of sets. Further, the same effect can be obtained even if the neutron multiplier, the neutron moderator, and the RI generating material are mixed without being laminated. Embodiment 3 An isotope nuclide producing apparatus according to another embodiment of the present invention will be described with reference to FIG. The isotope nuclide production apparatus of this embodiment includes a neutron multiplier, a neutron moderator, and an RI
Each layer of the generator is spherical. Hereinafter, differences from the first embodiment will be described.

FIG. 3 is a sectional view of the isotope nuclide production apparatus of the present embodiment. As shown in the figure, in the isotope nuclide production apparatus of the present embodiment, the neutron multiplier 2 has a spherical shape having a spherical space inside, and the target 4
Is provided. Further, an introduction pipe 9 for introducing neutrons is connected to the internal space of the neutron multiplier 2,
Neutrons are generated by irradiating the target 4 with the charged particle beam through the introduction tube 9. Although the generated neutrons spread radially, most of the neutrons can be made incident on the neutron multiplier 2 because the neutron multiplier 2 is provided so as to surround the neutron multiplier 2 except for the introduction tube 9. After the neutrons incident on the neutron multiplier 2 are multiplied, they reach the neutron moderator 3 and are decelerated. The neutrons decelerated by the neutron moderator 3 enter the RI generator 5 and generate RI by a nuclear reaction.

According to the present embodiment, since the neutron multiplier 2, neutron moderator 3, and RI generator 5 are spherical, most of the neutrons that spread radially can be used for RI production, and RI generation Efficiency can be improved. Embodiment 4 An isotope nuclide producing apparatus according to another embodiment of the present invention will be described with reference to FIG. The isotope nuclide production apparatus of this embodiment has a structure in which the RI generating material is divided into a plurality of regions and can be taken out for each region. Hereinafter, points different from the first embodiment will be described.

As shown in FIG. 4, the RI generating material 5 is divided into a plurality of regions a to d and can be individually taken out. As mentioned above, technetium 99m is molybdenum 9
9, the amount of technetium 99m generated in molybdenum 99 increases for a predetermined time after the generation of molybdenum 99 is stopped.
By taking out the technetium 99m, it is possible to secure the technetium 99m beyond its half-life. FIG. 5 shows molybdenum 99 and technetium 9 when irradiation of neutrons to molybdenum 98 is stopped after 8 hours.
A nuclide amount of 9 m is shown. As shown, molybdenum 98
The technetium 99m increases even after the irradiation of neutrons is stopped and the nuclide amount of molybdenum 99 starts to decrease.
This is due to the decay of molybdenum 99
This is because the amount of generated m exceeds the amount of attenuation of technetium 99m. Therefore, molybdenum 99 should be taken out of the apparatus so that technetium 99m is taken out at the time when the amount of technetium 99m reaches a peak and can be used for SPECT.

As described above, according to the present embodiment, the technetium 99m is taken out together with the molybdenum 99 to obtain a technetium 99 having a time longer than the half life of the technetium 99m.
m can be secured.

In each of the embodiments described above, a target is irradiated with a charged particle beam to generate neutrons.
A neutron source may be used without using a target. Neutron sources include those that generate neutrons by (γ, n) reaction due to bremsstrahlung from accelerated electrons, and those that irradiate accelerated protons to matter to generate neutrons by (p, n) reaction There are already known ones such as irradiating protons to metal or the like to generate neutrons by spallation. In the case where a neutron source is used in the third embodiment, the backflow of the neutrons in the introduction pipe 9 can be prevented by forming the target portion to which the neutrons are applied in a V shape.

In each embodiment, neutrons are multiplied by using a neutron multiplier. However, even if only a neutron moderator is provided without providing a neutron multiplier, the neutron moderator is compared with the prior art. It is possible to improve the production efficiency.

Further, in each of the embodiments, the case where molybdenum 99 (finally technetium 99m) is produced using neutrons has been described. However, the present invention can be similarly applied to nuclides other than molybdenum 99. it can. FIG. 6 shows the nuclides that can be produced by the present invention, the reaction at the time of nuclide production, the threshold of energy required for the reaction, the half-life and the decay of the nuclide. When the nuclides generated by the threshold reaction among the nuclides shown in FIG. 6 are used, the thickness of the neutron moderator is adjusted so that the neutrons incident on the RI generation unit are equal to or larger than the threshold.

[0022]

According to the present invention, the RI generation efficiency can be improved.

[Brief description of the drawings]

FIG. 1 is a structural diagram of an apparatus for producing various isotopes according to a preferred embodiment of the present invention.

FIG. 2 is a structural diagram of an isotope nuclide production apparatus according to another embodiment of the present invention.

FIG. 3 is a structural diagram of an isotope nuclide production apparatus according to another embodiment of the present invention.

FIG. 4 is a structural view of an isotope nuclide production apparatus according to another embodiment of the present invention.

FIG. 5 is a diagram showing a temporal change in the amount of nuclides of molybdenum 99 and technetium 99m when irradiation of neutrons to molybdenum 98 is stopped for 8 hours.

FIG. 6 is a table showing the reaction and half-life / decay for each product nuclide.

[Explanation of symbols]

1, 6: container, 2: neutron multiplier, 3: neutron moderator,
4 target, 5 RI generating material, 7 recovered liquid inlet, 8 recovered liquid outlet.

 ──────────────────────────────────────────────────続 き Continuing from the front page (72) Inventor Kazuhiro Takeuchi 7-2-1, Omika-cho, Hitachi City, Ibaraki Prefecture Inside Power and Electricity Research Laboratory, Hitachi, Ltd. (72) Toshikatsu Mori Omika-cho, Hitachi City, Ibaraki Prefecture 7-2-1, Hitachi, Ltd. Power and Electric Development Laboratory

Claims (7)

[Claims] 1. A neutron moderator for slowing down incident neutrons, and an isotope nuclide generating material for generating isotope nuclides by a nuclear reaction of the neutrons slowed by the neutron moderator. Isotope nuclide production equipment. 2. A neutron multiplier for multiplying an incident neutron, a neutron moderator for slowing down the neutrons multiplied by the neutron multiplier, and a nucleus of a neutron moderated by the neutron moderator. An isotope nuclide producing apparatus, comprising: an isotope nuclide producing material that generates an isotope nuclide by a reaction. 3. A container for storing the isotope nuclide producing material,
3. The container according to claim 1, further comprising an inlet for injecting a liquid that binds to the isotope nuclide into the container, and an outlet for discharging the liquid from the container. An isotope nuclide production apparatus according to the above. 4. The method according to claim 1, wherein the isotope nuclide producing material is divided into a plurality of regions, and is taken out for each region after the generation of the isotope nuclide. Isotope nuclide production equipment. 5. A hydrogen storage material or metal impregnated with tritium, and neutrons are generated by irradiating the hydrogen storage material or the metal with a charged particle beam. An isotope nuclide production apparatus according to any one of the above. 6. The isotope nuclide production apparatus according to claim 1, further comprising a neutron source for generating neutrons. 7. The isotope nuclide producing material is molybdenum 98
The isotope nuclide production apparatus according to any one of claims 1 to 6, wherein