JPH0449254A - Method for synthesizing methyl iodide labeled with 11c and apparatus for synthesizing the same - Google Patents

Abstract

PURPOSE:To improve utilization efficiency of a raw material gaseous carbon dioxide labeled with <11>C and shorten synthesis time of the objective compound by sensing radiation and judging the time of completing the feed of the aforementioned raw material to a reaction vessel with a change in the radiation in synthesizing the subject compound from the above-mentioned raw material. CONSTITUTION:<11>CH3I useful as a labeling compound for a position emission tomography (PET) system used in a positron tomographic testing method is synthesized by a step for producing <11>CO2 gas labeled with <11>C in a target box 4, a step for feeding the <11>CO2 gas produced in the above-mentioned step to a reaction vessel 14 and a step for synthesizing the <11>CH3I labeled with the <11>C from the <11>CO2 gas in the aforementioned reaction vessel 14. In the process, radiation in a step 7 for feeding the aforementioned <11>CO2 gas is sensed with a radiation sensor 22 to judge the time of completing the feed of the <11>CO2 gas with a change (b) in output thereof. Thereby, utilization efficiency of the <11>CO2 gas is enhanced and the synthesis time of the <11>CH3I is simultaneously shortened.

Description

Detailed Description of the Invention [Field of Industrial Application] The present invention relates to a method and apparatus for synthesizing a labeled compound for a PET system used in positron tomography, which is one of medical image diagnostic techniques. It is something.

[Conventional technology]

The labeling compound for the PET system is 11C-labeled methyl iodide, and this 11C-labeled methyl iodide was synthesized using a synthesizer as shown in FIG.

In the third session, reference numeral 1 is a target gas cylinder that stores a target mixed gas.
It is connected to a target box 4 that generates gas. This target box 4 is connected to a collection pipe 8 by a conveying pipe 7 via an electromagnetic pulp 5.6, and a helium gas cylinder 9 is connected to an electromagnetic valve 10 and the electromagnetic valve 6.
The collection pipe 8 is connected to the collection pipe 8 via a transport pipe 11 and a transport pipe 7.

The collection tube 8 is housed in a cooling container 12 and is connected to a reaction container 14 via a transport tube 13. An exhaust pipe 15 is connected to the reaction vessel 14, and a syringe 16 filled with hydroiodic acid is connected to the reaction vessel 14 via a conveying pipe 18 via an electromagnetic valve 17.

In order to synthesize methyl iodide labeled with 11c using the synthesizer as described above, first, the target mixed gas in the gas cylinder 1 is passed through the valve 2 into the target box 4.
Fill it. Then, a proton beam 19 supplied from a cyclotron (not shown) is irradiated for a certain period of time, and a nuclear reaction ("
N(p・α)"C) produces "co" gas.

Next, the target gas containing the COz gas is sent via the valve 5.6 to the collection tube 8 which is cooled in the cooling vessel 12, and the CO gas is collected. After the collection is completed, the collection tube 7 is heated, and the helium gas in the gas cylinder 9 is further supplied to the collection tube 8 through the valve 10.6, so that 11CO of the collection tube 8 is removed.

Gas is fed into the reaction vessel 14.

In this reaction vessel 14, CO* gas is bubbled to cause a reaction, and after the bubbling is completed, the reaction vessel 14 is heated to evaporate the solvent, which is then discharged through the exhaust pipe 15.

Then, the syringe 16 is operated to send the stored hydroiodic acid (HI) into the reaction vessel 14 to synthesize methyl iodide labeled with IC.

Then, 11 (Q
In order to recognize when the supply of □ is finished, the time control function of a computer, sequencer, etc. must be set for a certain amount of time, which is the empirically determined average time required for this process plus extra time for safety. I entered it as a set value into a certain device and recognized the end of this process.

[Problem to be solved by the invention]

In the conventional methyl iodide synthesis method described above, the timing of the end of the supply of CO was determined based on experience. Since the time required from start to finish varies each time due to subtle differences in conditions, it was necessary to set a longer time.

However, since IC is a radionuclide with a very short half-life of about 20 minutes, increasing the setting time will increase the disappearance of ■CO□ supplied during that time.
It was difficult to maintain a high utilization rate.

There was also the problem that the time from the start of supply of CO□ to the synthesis of CH3I could not be shortened.

It is an object of the present invention to solve the above problems and provide a method and apparatus that can increase the utilization efficiency of COt and synthesize cHar in a short time.

[Means to solve the problem]

The present invention has been made to achieve the above objects,
A radiation sensor is provided at the COz gas introduction part, and the timing of the end of the supply of 11 CO□ is determined based on the detection signal of this radiation sensor.

That is, the method for synthesizing 11C-labeled methyl iodide of the present invention is based on the method for synthesizing 11C-labeled methyl iodide.
A step of generating IJCO to generate gas, and the 11CO
A J I CO2 supply step in which the ICO2 gas produced in the 8 generation step is supplied to the reaction vessel, and 11C in the reaction vessel.
Methyl iodide (amed at mouth C using O□ gas as raw material)
11CH3I) a synthesizing step CH3I synthesis step,
Said "co" in the supply process.

The device is characterized in that the end of gas supply is determined by detecting radiation and a change in its output.

In addition, the apparatus for synthesizing 11C-labeled methyl iodide of the present invention includes a target box that generates carbon dioxide ("GO□") gas, which is labeled with 11C, and a 11C-labeled methyl iodide using 11CO! gas as a raw material. Methyl iodide (CH3
1) a reaction vessel for synthesizing the target box and the reaction vessel, a transfer pipe connecting the target box and the reaction vessel, a radiation detection section provided in the transfer tube, and a radiation sensor provided adjacent to the detection section. The system is characterized by the following.

In the present invention, the supply of COt gas to the reaction vessel is terminated by detecting radiation.
IC0, while the gas is being supplied, the detected amount is large, but +1 (Q□ This is based on the fact that the detected amount decreases when the gas supply ends. In other words, it is possible to recognize the point when the detected amount suddenly decreases. Therefore, it is determined that the supply of 11CO gas has ended.

To recognize when the detected amount of radiation has decreased,
The output of the radiation sensor can be visually judged by displaying it on various display devices such as a display, or the output of the radiation sensor can be input into a control means such as a personal computer and judged automatically, and the next work can be automatically carried out. It is also possible to have it start automatically.

The location where radiation is detected is not particularly limited as long as it is between the target box and the reaction container.

[Effect]

In the method and apparatus for synthesizing 11C-labeled methyl iodide of the present invention, a radiation sensor detects the radiation of 11CQ□ gas sent out from a target box, and I'COt gas is detected from the detection signal of this radiation sensor. Determine when supply ends.

〔Example〕

An embodiment of the apparatus for synthesizing 11C-labeled methyl iodide of the present invention will be described based on FIG.

FIG. 1 is a schematic diagram showing the outline of the synthesis device, and FIG. 2 is a diagram showing the output curve of the radiation sensor.

In FIG. 1, reference numeral 21 denotes a detection tube provided in the transport tube 7 between the target box 4 and the collection tube 8, and a radiation sensor 22 is arranged adjacent to this detection tube 21. This radiation sensor 22 is connected to a personal computer 24 via an A/D converter 23.

In addition, the target box 4, collection tube 8, reaction container 14
The other configurations are the same as the conventional one.

Next, a method for synthesizing 11C-labeled methyl iodide using the above synthesis apparatus will be described.

Send the target gas from the target gas cylinder 1 to the target box 4, and then send the target gas from the target gas cylinder 1 to the target box 4.
1 The process of generating CO gas is the same as the conventional method.

The 11 CQt gas generated in the target box 4 is sent to the day before collection through the transport pipe 7, but at this time
The I CO□ gas passes through the detection tube 21 and is detected by the radiation sensor 2.
2 detects the radiation of the gas passing through the detection tube 21.The radiation sensor 22 detects the radiation and outputs an electrical signal as shown in FIG. 2 in response to the detected amount.

That is, when the supply of I'CO gas is started, the output curve y rises from the supply start point a, and I
When the supply of CO and gas is constant, the output curve y also becomes approximately constant. Then, when the supply of l'cO gas is stopped, the output curve y falls.

Therefore, by confirming the supply start point a and the supply end point a, it is possible to reliably recognize the start and stop of the gas supply.

The electrical signal output from the radiation sensor 22 as described above is converted into a digital signal by the A/D converter 23 and then input to the personal computer 24 . Then, the personal computer 24 displays the data on the display based on the input data, determines when the supply ends, and causes the collection tube 8 to start collection work.

Then, the steps after the collection operation using the collection tube 8 are performed in the same manner as before.

〔Effect of the invention〕

The present invention provides a "co," from the target box to the reaction vessel.
By installing a radiation sensor in the middle of the gas supply and detecting the radiation of the I I CO2 gas being sent by this radiation sensor, it is possible to recognize when the gas supply has ended. Since termination can be recognized immediately, "co," can be used under any conditions.
Gas can be used efficiently and the synthesis time of methyl iodide labeled with 11c can be shortened.

[Brief explanation of drawings]

Figure 1 is a schematic diagram of an embodiment of the apparatus for synthesizing 11C-labeled methyl iodide of the present invention, Figure 2 is a diagram showing the output curve of a radiation sensor, and Figure 3 is a diagram showing the conventional 110-labeled methyl iodide synthesis device. Schematic diagram of methyl iodide synthesis apparatus 1...Target gas cylinder 4...Target box 8...Collection tube 14...Reaction container 21...Detection tube 22...Radiation sensor

Claims (2)

[Claims] (1) Carbon dioxide labeled with ^1^1C (^1^1C
O_2) ^1^1CO_2 generation step of generating gas,
^1^1CO_ produced in the ^1^1CO_2 generation process
2 gases are supplied to the reaction vessel ^1^1CO_2 supply process, and in the reaction vessel ^1^1CO_2 gas is used as a raw material^
Methyl iodide labeled with 1^1C (^1^1CH_3
I) Synthesizing ^1^1CH_3I synthesis step, and ^1^1CO_2 in the ^1^1CO_2 supplying step.
A method for synthesizing methyl iodide labeled with ^1^1C, characterized in that the end of gas supply is determined by detecting radiation and a change in its output. (2) Carbon dioxide labeled with ^1^1C (^1^1C
O_2) Target box that generates gas and ^1^
A reaction vessel for synthesizing ^1^1C-labeled methyl iodide (^1^1CH_3I) from 1CO_2 gas, a transport pipe connecting the target box and the reaction vessel, and a transport pipe provided in the transport pipe. A device for synthesizing methyl iodide labeled with ^1^1C, comprising a radiation detection section and a radiation sensor provided adjacent to the detection section.