JP6061324B2 - Radiation source manufacturing method and apparatus - Google Patents

Description

  The present invention relates to a method and an apparatus for manufacturing a radiation source, and more particularly, to easily generate a point source from a radioactive solution containing a volatile radioactive substance suitable for use in manufacturing a calibration point source for a PET apparatus. The present invention relates to a method and apparatus for manufacturing a radiation source.

  As described in Patent Documents 1 and 2, in a nuclear medicine imaging apparatus such as a PET apparatus, time information for determining the detection time of a detector is calibrated using a point source. ing.

  On the other hand, regarding the production of a radiation source, Patent Document 3 discloses that a hydrophilic polymer containing an aqueous solution of a radioactive substance is formed to a uniform thickness, or the radioactive substance is penetrated into a hydrophilic polymer layer having a uniform thickness. And a method for producing a beta ray radionuclide surface radiation source that has been absorbed and then lyophilized in vacuum or a sparingly soluble compound is formed in the layer and then dried.

  For the production of a point source, a method of dropping a radioactive solution onto a film, drying and sealing, or immersing the absorber in the source solution, then pulling up, drying and sealing is performed. ing.

JP 2012-2669 A JP 2012-21976 JP 7-128499 A

  However, in the case of radioactive solutions containing volatile radioactive materials, using these methods will cause the radioactive materials to diffuse into the air and contaminate the surrounding environment as well as the facility's exhaust equipment. It has been difficult to produce radiation sources from radioactive solutions containing volatile radioactive materials.

  The present invention has been made to solve the above-mentioned conventional problems, and when manufacturing a radiation source from a radioactive solution containing a volatile radioactive substance, the surrounding environment and exhaust equipment are not contaminated, and volatile It is an object of the present invention to make it possible to easily manufacture a radiation source from a radioactive solution containing a certain radioactive substance.

The present invention contains a radioactive solution containing a volatile radioactive substance, a suction / discharge device for the radioactive solution, and a radiation source support film that supports the manufactured point radiation source or planar radiation source in a sealed container, On the radiation source supporting film, an adsorbing gas for solidifying and dropping the radioactive gas by reacting with a radioactive gas (also referred to as a volatile component) generated by vaporizing the radioactive solution is introduced into the sealed container. point source or with the production of planar-ray source, the radioactive solution is vaporized from the generate radioactive gas, gas adsorption tank radioactive gas monitoring device to a gas inlet and / or outlet is installed in the closed vessel directing the gas circulation adsorber with, and radioactive gas to generate vaporized from the radioactive solution in the sealed container so as to adsorb the gas adsorption vessel, it solves the above problems That.

The present invention also includes a radioactive solution containing a volatile radioactive substance, a suction / discharge device for the radioactive solution, and a radiation source support film that supports the manufactured point radiation source or planar radiation source. An airtight container, an adsorbed gas inflow device for injecting an adsorbed gas for solidifying and dropping the radioactive gas by reacting with the radioactive gas generated by vaporizing the radioactive solution in the airtight container, and the airtight container A gas circulation adsorption device having a gas adsorption tank with a radioactive gas monitoring device installed at the gas inlet and / or outlet, and a point source or a planar shape on the radiation source support film in the sealed container with the production of the source, to provide an apparatus for producing the radiation source, characterized in that the radioactive gas generate by vaporizing from the radioactive solution in the sealed container was set to be adsorbed to the gas adsorption vessel It is intended.

Here, a radiation source chamber for accommodating the radiation source containing the radioactive solution is provided in the sealed container, and a shutter that can be opened and closed can be installed in a partition between the radiation source chamber and other portions.

  Further, the radioactive solution suction / discharge device can be moved by a moving device in the sealed container.

One or more radiation source support films and / or radioactive solution absorbers can be installed in the sealed container.

Moreover, the said radiation source support film can be affixed inside a frame .

  In the conventional method, when a radiation source is manufactured from a radioactive solution containing a radioactive substance with a high concentration of volatile, a dedicated glove box or the like is required to cause radioactive surface contamination in the vicinity. When the method of the present invention is used, even if a radiation source is produced from a radioactive solution containing a volatile radioactive substance, the surrounding environment is not contaminated, and the generated radioactive gas is adsorbed in the gas adsorption tank. , Almost no special equipment other than manufacturing equipment is required. In addition, it can be confirmed by a radioactive gas monitor that the radioactivity and adsorbed gas concentration of the gas in the sealed container are sufficiently low. Therefore, it is possible to safely and easily produce a radiation source from a radioactive solution containing a volatile radioactive substance, which has been difficult until now.

Pipeline diagram showing the overall configuration of an embodiment of the present invention Sectional view showing the sealed container part A plan view showing the radiation source table The top view and sectional view which show a source support similarly The top view which shows the modification of the radiation source table of the said embodiment The top view which shows the other modification of a source table similarly Flow chart showing the processing procedure

  Hereinafter, the present invention will be described in detail with reference to the drawings.

  In this embodiment, as shown in FIG. 1 (overall view) and FIG. 2 (sectional view of a sealed container portion), a radioactive solution 14 containing a volatile radioactive substance, and a syringe that is a suction / discharge device for the radioactive solution 14 120 and a gas cylinder filled with an adsorbing gas, which constitutes an airtight container 100 for accommodating the radiation source support film 142 as a radiation source support, and an adsorbed gas inflow device 200 for allowing adsorbed gas to flow into the airtight container 100 202 and the switch 204, and the gas circulation adsorption apparatus 300 which has the gas adsorption tank 310 in which the radioactive gas monitoring apparatuses 312 and 314 connected to the said airtight container 100 were each installed in the gas inlet and outlet are mainly provided. Yes.

  The sealed container 100 seals the inner structure with the outer wall 102, and the outer wall 102 can be partially or entirely removed, and some operations and adjustments can be added to the inner structure with a human hand. .

  As shown in detail in FIG. 2, the hermetic container 100 is partitioned by a partition 106 having a shutter 108, and the radiation source 10 disposed in the radiation source chamber 104 at the lower side of the figure, and above the partition 106. The arranged syringe 120 and the radiation source table 140 are provided.

  The partition 106 is for suppressing contamination of the surface of the radiation source. A shutter 108 is installed on the partition 106, and when the radioactive solution 14 is sucked up by the syringe 120, the shutter 108 is opened. 108 is closed. The partition 106 and the shutter 108 can be omitted.

  The radiation source 10 includes a radiation source container 12, a radioactive solution 14 accommodated therein, and a radiation source cap 16 for sealing. The radiation source cap 16 is made of an elastic material so that the hermeticity of the radiation source 10 can be maintained even when the needle 126 of the plunger 124 is inserted and withdrawn.

  The syringe 120 mainly includes a syringe container 122 and a plunger 124 having a needle 126 disposed at the tip thereof. The syringe container 122 is fixed to a syringe fixing jig 130, and the plunger 124 is a plunger moving device. 132 allows relative movement with respect to the syringe container 122. The syringe fixing jig 130 and the plunger 124 are fixed to a stage 110 planted in the sealed container 100 via a syringe moving device 136.

  The plunger 124 can be moved up and down by the syringe moving device 136 as a whole, and can be moved up and down as a single unit by the plunger moving device 132 to suck up and discharge the radioactive solution 14. In addition, the syringe 120 may be provided with a mechanism that can drop a fixed amount like a micropipette.

  The radiation source table 140 is rotatable with respect to the stage 112 planted in the sealed container 100 and passes through the radiation source table 140 when the syringe 120 sucks the radioactive solution 14 from the radiation source 10. A hole 140A is provided so that it is possible. Further, a counterbore 140B is formed around the hole 140A.

  On the hole 140A and countersink 140B of the radiation source table 140, a film 142B is stuck in a frame 142A as shown in FIG. 4A (plan view) and FIG. 4B (cross-sectional view). A radiation source support film 142 is placed and fixed. Here, the frame 142 </ b> A is used to facilitate handling of the radiation source support film 142. As shown in FIG. 2, the radioactive solution absorber 150 can be placed on the radiation source support film 142, and the radiation solution absorber 150 is bent to prevent accidental movement. Can be formed.

  In FIG. 2, 114 is a desiccant for promoting drying of the radioactive solution 14 and the radioactive solution absorber 150 that are dropped on the radiation source support film 142, for example, disposed above the partition 106.

The adsorbed gas accommodated in the gas cylinder 202 connected to the hermetic container 100 via the switch 204 reacts with the volatile component of the radioactive solution 14 containing a volatile radioactive substance to solidify the volatile component. Can be dropped on the radioactive solution absorber 150 and the radiation source support film 142. The adsorbed gas inflow hole may be near the radioactive solution to be dropped.

  As shown in detail in FIG. 1, the gas circulation adsorption device 300 includes connectors 302 and 352 for separating pipes as necessary, switches 304 and 350 for flowing and stopping gas, and gas Adsorption tank 310, radioactive gas monitoring devices 312 and 314 provided before and after the adsorption tank 310, a circulation pump 320 for circulating the gas, a flow meter 330 for monitoring the gas flow rate, and a gas flow rate for adjusting the flow rate A flow controller 340.

  The inlet side of the sealed container 100 and the gas circulation adsorption device 300 is connected by switches 402 and 404 and a distributor 406, and the outlet side of the gas circulation adsorption device 300 and the sealed container 100 are a distributor 410 and a switch. 412 and 414 are connected.

  The gas adsorbent in the gas adsorption tank 310 of the gas circulation adsorption device 300 can adsorb radioactive gas, adsorbed gas, and water vapor in the gas.

  Radiation of the gas flowing into and out of the gas circulation adsorption device 300, that is, the gas flowing out of the hermetic container 100 and the gas flowing in by the radioactive gas monitoring devices 312 and 314 installed before and after the gas adsorption tank 310. Performance and adsorption gas concentration can be monitored, and it can be confirmed that the inside of the sealed container 100 is normal. At the same time, whether or not the adsorption capacity of the gas adsorbent in the gas adsorption tank 310 satisfies a predetermined capacity by measuring the ratio of the radioactivity measured by the gas monitoring devices 312 and 314 and the ratio of the adsorbed gas concentration. I can confirm.

  Any one of the radioactive gas monitoring devices 312 and 314 is omitted, and the adsorption capacity of the gas adsorbent in the gas adsorption tank 310 is calculated from the radioactivity of one radioactive gas monitoring device and the time variation of the attenuation of the adsorption gas concentration. It is also possible to confirm whether or not satisfies the predetermined ability.

  With these structures, the volatilization of the radioactive substance can be suppressed, and even if the radioactive substance volatilizes in the hermetic container 100, the inside of the hermetic container 100 can be normalized, and the radiation source can be used without contaminating the peripheral equipment and the exhaust equipment. Can perform manufacturing work.

  The configuration of the radiation source table 140 is not limited to that shown in FIG. 3, and may be a table capable of rotating as shown in FIG. 5 or a table capable of translational movement as shown in FIG. 6.

  Hereinafter, the manufacturing procedure of the sealed radiation source will be described with reference to FIG.

  First, in step 1010, the radiation source 10, the radiation source support film 142, the radioactive solution absorber 150 and the desiccant 114 as necessary are installed in the sealed container 100, and the sealed container 100 is sealed.

  Next, in step 1020, the switch 204 of the adsorption gas inflow device 200 is opened, and the adsorption gas is introduced from the gas cylinder 202 into the sealed container 100.

  Next, the routine proceeds to step 1030, the shutter 108 is opened, the syringe 120 is moved downward by the syringe moving device 136, the needle 126 is inserted into the radiation source 10, and the plunger 124 is moved upward by the plunger moving device 132. Then, a predetermined amount of the radioactive solution 14 is sucked into the syringe container 122.

  Next, in step 1040, the syringe 120 is raised by the syringe moving device 136, moved to a height at which the radioactive solution 14 can be dropped onto the radioactive solution absorber 150, and the shutter 108 is closed.

  Next, at step 1050, the radiation source table 140 is rotated to move the radiation source support film 142 below the syringe 120.

  Next, in Step 1060, the plunger 124 is moved down by the plunger moving device 132 to discharge the radioactive solution 14 in the syringe container 122 and dropped onto the radioactive solution absorber 150. At this time, if the radiation source table 140 is a rotary table as shown in FIG. 3, the radioactive solution 14 can be sequentially dropped onto the plurality of radiation solution absorbers 150.

  After the dripping is completed, the shutter 108 is opened, and in step 1070, the radioactive solution 14 remaining in the syringe container 122 is injected into the empty source container 12 containing the radioactive solution 14 in the same shape as the radiation source 10. So that it can be stored.

  Next, the process proceeds to step 1080, the gas circulation adsorption device 300 is operated, and the radioactive gas, adsorption gas, and water vapor generated by vaporization from the radioactive solution 14 are removed from the gas, and the air in the sealed container 100 is purified. The radioactive solution 14 dropped on the radioactive solution absorber 150 is dried.

  Next, in step 1090, after confirming that the radioactive gas and the adsorbed gas can be sufficiently removed by the radioactive gas monitoring devices 312 and 314, in step 1100, a part or all of the outer wall 102 of the hermetic container 100 is removed. Then, a radiation source cover film having the same form as the radiation source support film 142 is placed on the radiation source support film 142 and the radioactive solution absorber 150, and the radioactive solution absorber 150 is sealed. Furthermore, the radiation source may be cut out together with the cover film and covered with metal.

  A germanium chloride 68 gallium chloride 68 aqueous solution was used as the radioactive solution 14 in the radiation source 10. Hydrogen sulfide was used as the adsorbed gas, and tetraphosphorous deoxyoxide was used as the desiccant 114. The radioactive solution 14 was sucked with a syringe 120 and dropped onto an ion exchange resin as a radioactive solution absorber 150 on a VYNS (vinyl chloride / vinyl acetate copolymer) film as a radiation source support film 142. The gas circulation adsorption device 300 was operated to dry the dropped radioactive solution 14 and to clean the inside 100 of the sealed container. Thereafter, the VYNS film for the source cover is placed on the ion exchange resin (150) on the VYNS film (142) on which the germanium 68 and gallium 68 have been adsorbed, and this is cut out and covered with aluminum, A point source of gallium 68 was used.

  In the above description, the radioactive solution absorber 150 is used. However, the radioactive solution 14 may be dropped directly on the radiation source support film 142 without using the radioactive solution absorber 150 to form a radiation source. Is possible.

  In the above description, the point source is obtained. However, it is also possible to obtain a planar source by increasing the amount dropped from the syringe 120 or by making the radioactive solution absorber 150 planar.

  According to the present invention, a point source can be easily manufactured from a radioactive solution containing a volatile radioactive substance. In particular, it becomes possible to manufacture a point source for calibration of a PET apparatus which is a nuclear medicine diagnostic apparatus.

DESCRIPTION OF SYMBOLS 10 ... Radiation source 12 ... Radiation source container 14 ... Radioactive solution 16 ... Radiation source cap 100 ... Sealed container 102 ... Outer wall 104 ... Radiation source chamber 106 ... Partition 108 ... Shutter 110, 112 ... Stage 114 ... Desiccant 120 ... Syringe 122 ... Syringe container 124 ... Plunger 126 ... Needle 130 ... Syringe fixing jig 132 ... Plunger moving device 136 ... Syringe moving device 140 ... Radiation source table 140A ... Hole 140B ... Countersink 142 ... Radiation source support film 142A ... Frame 142B ... Film 150 ... Radioactive solution absorber 200 ... Adsorption gas inflow device 202 ... Gas cylinder 204, 304, 350, 402, 404, 412, 414 ... Switch 300 ... Gas circulation adsorption device 302, 352 ... Joiner 310 ... Gas adsorption tank 312, 314 ... Radioactive gas monitoring device 20 ... circulation pump 330 ... flow meter 340 ... flow controllers 406, 410 ... distributor

Claims (6)

A radioactive solution containing a volatile radioactive substance, an aspirator / discharger of the radioactive solution, and a radiation source support film that supports the manufactured point radiation source or planar radiation source are contained in a sealed container,
A point source or a planar surface is formed on the radiation source support film while allowing an adsorption gas to solidify and drop the radioactive gas by reacting with the radioactive gas generated by vaporizing the radioactive solution into the sealed container. While producing the radiation source,
The closed radioactive gas to generate vaporized from the radioactive solution in a vessel, is guided to the gas circulation adsorption system having a gas adsorption vessel which radioactive gas monitoring apparatus is installed in the gas inlet and / or outlet,
Method for producing a radiation source, characterized in that the adsorption of radioactive gas to generate vaporized from the radioactive solution in the sealed vessel to the gas adsorption vessel. A sealed container for containing a radioactive solution containing a volatile radioactive substance, a suction / discharger of the radioactive solution, and a source support film for supporting the manufactured point source or planar source;
An adsorbed gas inflow device for allowing an adsorbed gas to flow into the sealed container by reacting with the radioactive gas generated by evaporation from the radioactive solution and solidifying and dropping the radioactive gas ;
A gas circulation adsorption device having a gas adsorption tank in which a radioactive gas monitoring device is installed at the gas inlet and / or outlet connected to the sealed container;
Together to produce a point source or a planar radiation source to the radiation source support film on at the sealed container, so as to adsorb radioactive gas generate by vaporizing from the radioactive solution in the sealed container to the gas adsorption vessel An apparatus for producing a radiation source, characterized in that   A radiation source chamber for accommodating a radiation source containing the radioactive solution is provided in the sealed container, and a shutter that can be opened and closed is provided in a partition between the radiation source chamber and other portions. The manufacturing apparatus of the radiation source of Claim 2.   4. The radiation source manufacturing apparatus according to claim 2, wherein the radioactive solution aspirator / discharger is movable by a moving device in the sealed container.   The radiation source manufacturing apparatus according to any one of claims 2 to 4, wherein a single or a plurality of radiation source support films and / or radioactive solution absorbers can be installed in the sealed container. .   The said radiation source support film is affixed inside the frame, The manufacturing apparatus of the radiation source of Claim 5 characterized by the above-mentioned.

Images