KR101633250B1 - Apparatus for synthesis of radioactive compound - Google Patents

Abstract

The apparatus for synthesizing a radioactive compound according to the present invention includes an auxiliary chamber in which a radioactive compound synthesizing module for radioactive synthesis is carried, an auxiliary chamber disposed adjacent to the auxiliary chamber, and a radioactive compound synthesis module carried in from the auxiliary chamber, And a transfer unit for transferring the radioactive compound synthesis module from the auxiliary chamber to the reaction chamber and a reaction chamber for shielding the radiation generated during the radioactive synthesis reaction, And a shielding door selectively openable and closable as the radioactive compound synthesis module transports the radioactive-compound synthesis module.
The present invention has its own double shielding function and thus can be manufactured as a miniaturized module device as compared with the conventional device, and it is advantageous in terms of cost since the cost incurred in the production of a hot cell is advantageous, and radioactive synthesis can be performed several times a day There is an excellent effect in terms of time.

Description

[0001] APPARATUS FOR SYNTHESIS OF RADIOACTIVE COMPOUND [0002]

TECHNICAL FIELD The present invention relates to a radioactive compound synthesizer, and more particularly, to a radioactive compound synthesizer for synthesizing a radioactive drug that can be used for PET.

In the case of synthesis of radioactive pharmaceuticals with short half-lives, synthesis is carried out through a device which allows the radioactive isotopes and reagents to mix and react and the obtained product to be purified. Certain elements of these compositing devices may be sensitive to radiation or chemical corrosion.

As a representative example of a radiopharmaceutical, the synthesis of a radiopharmaceutical for positron emission tomography (PET) is performed by labeling a radioactive isotope produced in a cyclotron with a precursor. For this synthesis, an automatic synthesizer is essential. In the case of mass synthesis, synthesis by human hands is impossible because radiation is continuously released during the manufacturing process.

When a proton beam of ten to several MeV from a cyclotron is irradiated to the target (target device) H ₂ ¹⁸ O, a radioactive isotope, ¹⁸ F ion, is generated. When the generated ¹⁸ F ion is attached to the glucose molecule at position 2, it becomes FDG. FDG is a glucose analog (2-deoxy- 2- ( ¹⁸ F) fluoro-D-glucose). FDG can be used for proton-emission tomography (PET).

F이 혼합된 H₂ ¹⁸O을 이송하게 되며, 이송되는 H₂ ¹⁸O는 1~2cc에 불과하다. 그리고, 관로의 연결부 또는 꺾이는 부분에서

F이 혼합된 H₂ ¹⁸O이 유실되는 경우가 많이 발생하고 있다. 1~2cc의 H₂ ¹⁸O에는 약 2 Ci 이상의 높은 방사선이 검출되기 때문에 핫셀까지의 이송과정에서 방사능 물질 유출 및 환경 오염 문제가 제기되고 있다.

F은 1.2 MeV의 높은 에너지를 방사하는 핵종이므로 매우 주의가 요구된다.According to the prior art (Korean Patent No. 10-1001300), FDG is produced at a remote place or in a hot cell so as to shield radiation emitted from a target of a cyclotron. Generally, the distance from the target of the cyclotron to the hot cell is several tens of meters. In addition, along the pipeline within a diameter of 1 millimeter

F is mixed with H ₂ ¹⁸ O, and the transferred H ₂ ¹⁸ O is only 1 to 2 cc. And, at the connecting part or the bent part of the channel

F mixed with H ₂ ¹⁸ O is often lost. H ₂ ¹⁸ O of 1 to 2 cc can detect high radiation of about 2 Ci or more. Therefore, there is a problem of radioactive material leakage and environmental pollution in the process of transferring to a hot cell.

F is a radionuclide that emits a high energy of 1.2 MeV.

According to the prior art (Japanese Patent Laid-Open Publication No. 2004-515330), a hot cell, which is a separate shielding facility, is required in order to shield radioactivity generated during radioactive synthesis. The hot cell requires a large space . And can not support the synthesis of various kinds of radiopharmaceuticals, so that there are limitations in applicability to various new drug development.

Korean Patent No. 10-1001300 Japanese Patent Publication No. 2004-515330

It is an object of the present invention to provide a radioactive synthesis apparatus having a shielding wall and a shielding door so as to shield a radioactive outflow from the apparatus itself and to perform radioactive synthesis without using a separate hot cell.

It is also an object of the present invention to provide a device capable of being synthesized several times in a day, having a spatial advantage by constituting a radiometric synthesizing apparatus as a compacting apparatus.

An apparatus for synthesizing a radioactive compound according to the present invention includes: an auxiliary chamber into which a radioactive compound synthesis module for radioactive synthesis is introduced; A reaction chamber disposed adjacent to the auxiliary chamber and capable of providing a space for synthesizing the radioactive compound and shielding the radiation leakage due to the synthesis, A transfer unit for transferring the radioactive compound synthesis module from the auxiliary chamber to the reaction chamber; And a shielding door that shields radiation generated in the reaction chamber and selectively opens and closes as the radioactive compound synthesis module transfers the radiation.

In addition, the auxiliary chamber and the reaction chamber form a chamber wall capable of shielding the outflow of radiation, and the shielding door of the reaction chamber can independently shield the space in which the radioactive compound synthesis module is fastened to the base unit have.

The shielding door may include a control unit for automatically controlling opening or closing of the radioactive compound synthesis module when the radioactive compound synthesis module is transferred from the auxiliary chamber to the reaction chamber.

The shielding door may be closed automatically after the radioactive compound synthesis module enters the reaction chamber and before the synthesis of the radioactive compound occurs, thereby forming a closed space.

Further, the thickness of the shielding wall and the shielding door of the reaction chamber may be at least 30 mm or more, and the shielding door may include a door portion which can be opened or closed due to rising and falling, And the like.

Furthermore, the shielding door may further include a driving unit installed at one side of the shielding door to drive the door unit to move up and down in a sliding manner.

The apparatus may further include a discharge unit installed inside the reaction chamber, capable of collecting a supply unit for supplying a radioactive compound to the radioactive compound synthesis module and a radioactive compound synthesis module for which a radioactive combination reaction has been completed.

And the discharge unit includes a collection door capable of being opened and closed so that the reacted radioactive compound synthesis module can be collected in the discharge part; And a discharge latch configured to allow the radioactive compound synthesis module to be automatically collected into the discharge unit upon contact.

The details of other embodiments are included in the detailed description and drawings.

The radioactive compound synthesizing apparatus according to the present invention has a self-shielding function, so that a hot cell is not required compared with a conventional apparatus, and the apparatus can be manufactured as a compact apparatus.

In addition, it is advantageous from the viewpoint of price because it saves the cost incurred in the production of the hot cell, and the radioactive synthesis can be performed several times a day compared to the conventional technology, and therefore, it has an excellent temporal advantage.

1 is a perspective view of a radioactive compound synthesizer according to an embodiment of the present invention.
2 is an enlarged view of a supply unit inside a reaction chamber according to one embodiment of the present invention.
3 is an enlarged view of a base unit and a temperature control unit in an auxiliary chamber according to an embodiment of the present invention.
4 is a top view showing the dimensions of the apparatus for synthesizing a radioactive compound according to an embodiment of the present invention.
FIG. 5 is a perspective view illustrating a coupling relationship between a base unit and a radioactive compound synthesis module according to an embodiment of the present invention. FIG.
6 is a perspective view illustrating a process of moving the lid of the apparatus for synthesizing a radioactive compound according to an embodiment of the present invention.
FIGS. 7 and 8 are flowcharts showing the coupling, transport, and discharge of the radioactive compound synthesis module in the apparatus for synthesizing a radioactive compound according to one embodiment of the present invention.

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

Hereinafter, a radioactive compound synthesizing apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the terminology or words of the present disclosure should not be construed as limited to conventional or preliminary, and that the inventor may properly define the concept of a term to describe its invention in its best possible manner And should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, various equivalents It should be understood that water and variations may be present.

FDG can be used for proton-emission tomography. The isotopes for proton emission tomography are ¹⁸ F, ¹¹ C, ¹⁵ O and ¹³ N. Hereinafter, an embodiment targeting ¹⁸ F is described. However, the present invention is not necessarily limited to this, and it is also applicable to a radioactive material synthesizing apparatus applying other proton-emitting tomographic isotopes.

1 is a perspective view of a radioactive compound synthesizer according to an embodiment of the present invention.

1A is a perspective view of a radioactive compound synthesizer 10 showing only an outer shape by the lid 130 and FIG. 1B is a perspective view showing the inside of the radioactive compound synthesizer 10 from which the lid 130 is removed.

FIG. 2 is an enlarged view of a radioactive compound synthesis module in a reaction chamber according to an embodiment of the present invention. FIG. 3 is an enlarged view of a base unit and a temperature control unit in an auxiliary chamber according to an embodiment of the present invention. to be.

4 is a top view showing the dimensions of the apparatus for synthesizing a radioactive compound according to an embodiment of the present invention.

FIG. 5 is a perspective view illustrating a coupling relationship between a base unit and a radioactive compound synthesis module according to an embodiment of the present invention. FIG.

1 to 5, the present invention provides a radioactive compound synthesis system, comprising: an auxiliary chamber 110 into which a radioactive compound synthesis module L for carrying out radioactive synthesis is introduced; an auxiliary chamber 110 disposed adjacent to the auxiliary chamber 110; A reaction chamber 120 in which the loaded radioactive compound synthesis module L provides a space for synthesizing the radioactive compound and blocks radiation outflow due to the synthesis, the radioactive compound synthesis module L in the auxiliary chamber 110, The radiation generating module 120 shields the radiation generated in the transfer chamber 300 and the reaction chamber 120 from being transferred to the reaction chamber 120 and selectively transfers the radiation generated by the radiation compound synthesis module L And includes a shielding door 400 that can be opened and closed.

The chamber 100 is provided with a radioactive compound synthesis module L and a compound provided inside the chamber 100 so that the top surface can be opened so as to be discharged to the outside, May be made of lead having a thickness of at least 30 mm, and it is constituted by 50 mm in the present embodiment.

A shielding door 400 may be installed in the chamber 100 and a space may be defined by the reaction chamber 120 and the auxiliary chamber 110 based on the shielding door 400. The auxiliary chamber 110 is installed in an openable form to the outside so that the radioactive compound synthesis module L introduced from the outside can be fastened to the base unit 200 and is used for various kinds of compounds introduced from the outside, The cassette C constituting the material to be deposited may be disposed under the auxiliary chamber 110. According to the embodiment of the present invention, the mounting position of the cassette C is limited, but the present invention is not limited thereto. The mounting position of the mounting portion of the cassette C may be set at a proper position for introducing the compound into the reaction chamber 120 And the number of cartridges C1 of the compound provided in the cassette C may also be appropriately varied depending on the reaction.

The reaction chamber 120 corresponds to a certain portion of the space partitioned in the chamber 100 and is connected to the reactor R of the radioactive compound synthesis module L so that the radioactive compound reaction occurs in the radioactive compound synthesis module L, Providing an environment for supplying the solution and inducing the synthesis reaction. Specifically, the reaction chamber 120 serves to shut off the emission of radiation from a small amount of isotopes or secondary radioactive substances remaining in the reaction chamber 120 due to the closure of the shielding door 400. Also, it can be separated from the auxiliary chamber 110 to be hermetically closed even in the chamber, so that the radiation generated during the radioactive reaction can be completely blocked from flowing out.

In the reaction chamber 120, a valve unit 800 capable of controlling the radioactive compound, a supply unit 500 capable of supplying the radioactive compound into the radioactive compound synthesis module L, a container unit 500 for collecting the final product and the waste, A temperature control unit 700 for heating or cooling the radioactive compound synthesis module L may be provided for the radioactive compounding reaction and a radioactive compound synthesis module L may be installed under the reaction chamber 120, A discharge unit 600 capable of collecting can be installed. A detailed description of the above configuration will be given later.

The base unit 200 serves to support the radioactive compound synthesizing module L while the radioactive compound synthesizing module L is moved and the synthesis reaction supports the radioactive compound synthesizing module L when the radioactive compound synthesizing module L is pulled from the outside do.

Specifically, the base unit 200 is installed in the chamber 100 and on the upper surface of the movable transfer part 300, and includes a coupling part 210 for attaching and detaching the radioactive compound synthesis module L, And a second temperature regulation unit 720 that can heat or cool the module L. The coupling part 210 serves to couple and fix the radioactive compound synthesis module L carried into the chamber 100.

As shown in FIG. 5, the radioactive compound synthesis module L includes a plurality of channels U through which a substance necessary for the synthesis of a radioactive compound can flow and flow, and a reactor R in which a radioactive compound synthesis reaction takes place, (Not shown) that can be inserted into the body cavity. The radioactive compound synthesis module (L) is a disposable module, which is discarded after one radioactive combination reaction has occurred.

The coupling part 210 is automatically coupled to the radioactive compound synthesis module L when the radioactive compound synthesis module L is introduced into the auxiliary chamber 110 and the radioactive compound synthesis module L moves to the reaction chamber 120, At least one of them may be provided so as to be automatically separated thereafter.

According to an embodiment of the present invention, two fastening portions 210 are provided on the side of the base unit 200 and in the direction of the reaction chamber 120. But it is not limited thereto, and it may be arranged at a suitable position for attaching / detaching the radioactive compound synthesis module L, and may be configured in various numbers.

The second temperature regulating unit 720 is constituted by a part of the entire temperature regulating unit on the side of the base unit 200 for heating or cooling the radioactive compound synthesizing module L. [ Hereinafter, the temperature control unit 700 will be described.

The temperature control unit 700 may be formed to surround the reactor R of the radioactive compound synthesis module L and may include a first temperature control unit 710 and a second temperature control unit 720 including a semi- . The first temperature regulating unit 710 is installed under the reaction chamber 120 and has a semi-cylindrical shape 711 that can surround a half of the reactor R of the radioactive compound synthesis module L to enable heat transfer or cooling. And a support plate 712 capable of supporting the same.

The second temperature control unit 720 may be disposed on the side surface of the base unit 200 in a semi-cylindrical shape at a position opposite to the first temperature control unit 710. Accordingly, the second temperature control unit 720 is transferred by the transfer unit 300 to form a complete cylinder when the first temperature control unit 710 is coupled with the first temperature control unit 710 in the reaction chamber 120, and the radioactive compound synthesis module L of the reactor R is seated. Thus, the entire reactor (R) can be uniformly heated or cooled for radioactive synthesis.

The first temperature regulating unit 710 and the second temperature regulating unit 720 may have protrusions and grooves that fit into the protrusions so that they can be accurately fitted to each other.

In an embodiment of the present invention, the temperature control unit 700 is disclosed in a separate form and in a cylindrical shape, but is not limited thereto, and may be a configuration in which the reactor R of the radioactive compound synthesis module L can be heated evenly And may have various shapes.

1 and 4, the transfer unit 300 is installed inside the chamber and serves to guide the base unit 200 coupled with the radioactive compound synthesis module L to move within the chamber 100 do.

The transfer unit 300 includes a plate 310 disposed under the base unit 200 and a base unit 200 placed on the plate 310. The transfer unit 300 transfers the base unit 200 mounted on the plate 310 from the auxiliary chamber 110 to the reaction chamber 120 (Not shown).

The transfer unit 300 is transferred into the reaction chamber 120 formed as a shielded space so that the radiation compounding module L can shield the radiation during the radioactive compound reaction. The chamber may be formed so as to separate the space in which the radioactive compound synthesis module L is drawn from the outside and the space provided in the base unit 200 and the space connected to the supply unit 500 so that the radioactive compound reaction occurs, have. Accordingly, when the transfer unit 300 is moved into the auxiliary chamber 110 together with the radioactive compound synthesis module L, the transfer chamber 300 is separated from the reaction chamber 120, which is a space through which the radiation can be drained, The radioactive compound synthesis module L can be inserted into the apparatus.

The transfer unit 300 includes a power transmission means (not shown) and a transfer line 320 so that the base unit 200 to which the radioactive compound synthesis module L is coupled is moved in the longitudinal direction of the apparatus, So that it can move to the upper side.

However, the present invention is not limited to this configuration. When the transfer unit 300 is installed in the radioactive compound synthesis module L, It is also possible to arrange such that it can be rotated and elevated.

Referring again to Figures 1 and 4, the shielding door 400 is disposed on the path through which the transfer part 300 travels, and is made of a residual trace of isotopes or secondary radioactive material inside the reaction chamber 120 And serves to selectively open or close the radioactive compound synthesizing module L as the radioactive compound synthesizing module L transports the radioactive compound by the transferring unit 300. [

In addition, the shielding door 400 may serve to partition the reaction chamber 120 and the auxiliary chamber 110.

Specifically, when the radioactive compound synthesizer 10 is used several times, a small amount of radioactive isotopes or secondary radioactive substances generated in the course of synthesizing the radioactive compound remain in the reaction chamber 120. Therefore, when the radioactive compound synthesis module is installed for the synthesis of the new radioactive compound, the shielding door 400 may be closed so that the reaction chamber 120 and the auxiliary chamber 110 are separated from each other so that the radiation exists only in the reaction chamber 120 . Thereafter, the new radioactive compound synthesis module L is introduced into the auxiliary chamber 110, the auxiliary chamber 110 connected to the outside is completely shielded, and then the shielding door 400 is opened to move into the reaction chamber 120 Is repeated. The reaction chamber 120 and the auxiliary chamber 110 are completely separated from each other by the shielding door 400 to prevent the radiation from flowing out to the outside and the radioactive compound synthesis proceeds more frequently Can be achieved.

The shielding door 400 includes a door part 410 which can be opened or closed due to a rise or fall and a door groove 420 that provides a space into which the door part 410 is inserted when the door part 410 is opened. . ≪ / RTI > The shielding door 400 may further include a driving unit 430 installed at one side of the shielding door 400 and driving the door unit 410 to move up and down in a sliding manner. The door part 410 can be configured to be raised and lowered by the driving part 430 so that the space of the radioactive compound synthesizer 10 can be efficiently utilized.

When the transfer part 300 coupled with the radioactive compound synthesis module approaches the shielding door 400 so as to move to the reaction chamber 120 through the door, the door is automatically opened and the transfer part 300 is inserted into the reaction chamber 120 A sensor may be installed in each of the transfer unit 300 and the shielding door 400 so that the shielding door 400 is automatically closed when the supply unit 500 is correctly connected.

In addition to being capable of shielding the radiation generated during the synthesis of the radioactive reactant primarily by the chamber walls of the reaction chambers 120 and the auxiliary chambers 110, the shielding door 400 is present inside the reaction chamber 120 There is an advantage in that the radioactive compound synthesis module is installed in the base unit 200 by cutting off the emission of the radiation from the minute isotopes or the secondary radioactive material. Specifically, it is possible to prevent radiation from leaking primarily by the chamber walls. The space in which the radioactive compound synthesis module L can be transported to the outside is limited to the auxiliary chamber 110 so that a space for synthesizing the radioactive compound is generated inside the reaction chamber 120, The shielding door 400 is formed so that the chamber 110 can be separated. Therefore, when the radioactive compound synthesis module is installed in the base unit 200 in the auxiliary chamber 110, radiation emitted from a small amount of isotopes or secondary radioactive substances remaining in the reaction chamber 120 is transferred to the auxiliary chamber 110 It is possible to block the emission and minimize the exposure of the user.

In general, the material forming the outer walls of the reaction chamber 120 and the auxiliary chamber 110 can be formed of lead which can absorb the gamma rays generated from the radiation without transmitting the gamma rays.

1, the size of the apparatus for synthesizing a radioactive compound according to an embodiment of the present invention and the thickness of each chamber wall are shown, but the present invention is not limited thereto. The size of the internal module may be reduced, And can be formed into a shape having various dimensions according to a material which can be shielded with a thin thickness. In addition, since the present invention can manufacture a radiation synthesizing apparatus that is compact without using a hot cell unlike the prior art, it is appropriate to adjust the size of each configuration so as to have a shape as small as possible.

Since the shielding door 400 also serves as a passage for entering the reaction chamber 120 for synthesizing the radioactive compound, it is preferable to make the shielding door 400 as small as possible. In addition, Or a control unit (not shown) that can control the closing of the door.

The discharge unit 600 is disposed under the reaction chamber 120 and collects the radioactive compound synthesis module L in which the compound reaction has been completed.

Specifically, the discharge unit 600 is disposed under the reaction chamber 120 between the supply unit 500 and the shielding door 400, and is located on the path conveyed by the radioactive compound synthesis module L. After the reaction The radioactive compound synthesizing module L is disposed so as to shield the radioactive compound from leaking out.

The radioactive compound synthesis module (L) should be discarded after one radioactive synthesis reaction as a disposable module, and the disposal process is also important to prevent radiation leakage. Since the radioactive compound synthesis module L having the possibility of radiation leakage is completed and shielded by the discharge unit 600 having the independent space below the reaction chamber 120 after completion of the radioactive compound synthesis reaction, The damage of the radiation that flows out to the outside is blocked. Therefore, it is possible to operate the apparatus of the present invention irrespective of the period of time during which the apparatus can not be used because of the radiation half-life due to the radioactive compound synthesis module (L) during the reproduction of the next radioactive compound.

In the present invention, in the lower part of the reaction chamber 120, the radioactive compound synthesis module L to be discarded to be treated is directly processed in the reaction chamber 120 without being transferred to the outside or the auxiliary chamber 110, (600).

The discharge unit 600 includes a collection door 610 that can be opened and closed so that the reacted radioactive compound synthesis module L can be collected in the discharge unit 600 and the auxiliary chamber 610 in the reaction chamber 120. [ 110), which is located on the moving path of the radioactive compound synthesis module (L), and which is separated from the base unit automatically when the radioactive compound synthesis module (L) And a latch 620.

The door of the collection door 610 is automatically opened when the radioactive compound synthesis module L to be disposed has a sensor and the radioactive compound synthesis module L is introduced into the discharge unit 600 The door can be automatically closed.

The discharge latch 620 is formed to protrude a certain distance from the lower portion of the reaction chamber 120. The discharge latch 620 is disposed on the lower side of the reaction chamber 120. When the reaction compound 120 is moved from the reaction chamber 120 to the auxiliary chamber 110, It can be formed in such a manner that it does not advance in the direction of the auxiliary chamber 110 and falls into the discharge unit 600 while being caught.

Specifically, a spring is provided inside the discharge latch 620 and is configured to have a predetermined slope in the direction of the auxiliary chamber 110 in the reaction chamber 120. Therefore, when the mobile unit 300 enters the reaction chamber 120, the discharge latch 620 is inserted into the lower portion of the reaction chamber 120 so that the mobile unit 300 can move without resistance. However, when the mobile unit 300 moves from the reaction chamber 120 to the auxiliary chamber 110, the radioactive compound synthesis module L combined with the base unit 200 of the mobile unit 300 moves to the discharge latch 620, And the radioactive compound synthesis module L is separated from the base unit 200 and collected into the discharge unit.

The discharge unit 600 is provided inside the radioactive compound synthesizer 10 so that the radioactive compound synthesis module L that has completed the synthesis of the radioactive compound can be immediately stored in the independent independent shielded space of the discharge unit 600. As a result, a new radioactive compound synthesis reaction can be started while storing the radioactive compound synthesis module L to be disposed in the discharge unit 600. Such a structure of the present invention provides an advantage that the radioactive compound can be synthesized several times a day as compared with the prior art.

However, the above-described method shows a form in which the radioactive compound synthesis module L can be collected according to an embodiment of the present invention, and the shape and the method of the discharge unit 600 are not limited thereto, Can be expressed.

Inside the reaction chamber 120, there are provided a valve part 800 capable of controlling the amount of the compound when the radioactive compound is injected into the radioactive compound synthesis module L, a container part 800 for storing the waste generated in the radioactive reaction, (Not shown) for discharging the compound into the radioactive compound synthesis module L and controlling the flow of the compound into the radioactive compound synthesis module L can be disposed.

The valve unit 800 is disposed at the upper end of the supply unit 500 and is connected to the compound cartridge C1 and the supply unit 500 disposed in the auxiliary chamber 110. [ Thus, the compound in the cartridge serves to control the supply amount of the supply unit 500 in an appropriate amount.

The container unit 900 is arranged to be connected to the radioactive compound synthesis module L in the reaction chamber 120. (L) Compound and waste can be treated through separate connection lines, respectively, such as a vessel capable of recovering the final compound produced in Reactor (R) and a vessel capable of collecting waste generated during the radiation reaction .

In addition, a pump unit connected to the radioactive compound synthesis module L may be provided to supply or discharge the compound used in the reaction in the radioactive compound synthesis module L. The pump section is installed at the bottom of the auxiliary chamber 110, and two of them can be installed as injection and recovery pumps to transport the compounded fluid disposed according to each connection tube using the pressure action. However, the above example is an embodiment of the present invention, and the position and the number of the pump unit can be variously changed for a proper and efficient radioactive reaction.

6 is a perspective view illustrating a process of moving the lid of the apparatus for synthesizing a radioactive compound according to an embodiment of the present invention.

6, the lid 130 can be slidably moved below the reaction chamber 120 and the auxiliary chamber 110 so that the user can easily check the inner space of the radioactive compound synthesizer 10 Cleaning and maintenance. Also, it is easy to install the radioactive compound synthesis module L in the auxiliary chamber 110 base unit 200.

In general, the lid portion 130 is made of lead and has a considerable weight, so that it is necessary for the user to conveniently move it. Accordingly, due to the slide structure as described above, the radioactive compound synthesis module L can be easily introduced into the auxiliary chamber 110 and installed therein. And the convenient opening of the lid 130 of the reaction chamber 120 is necessary for cleaning and maintenance after several uses of the radioactive compound reaction.

However, the manner of movement of the cover 130 is not limited thereto, and various methods can be implemented so that the user can conveniently open or close the cover 130.

FIGS. 7 and 8 are flowcharts showing the coupling, transport, and discharge of the radioactive compound synthesis module in the apparatus for synthesizing a radioactive compound according to one embodiment of the present invention.

Hereinafter, the operation of the apparatus 10 for synthesizing a radioactive compound according to an embodiment of the present invention will be described.

7 and 8, the radioactive compound synthesis module L is installed inside the auxiliary chamber 110 (Fig. 7 (a)) and shielded by the lid. Thereafter, the base unit 200 coupled with the radioactive compound synthesis module L is transferred from the auxiliary chamber 110 to the reaction chamber 120 by the transfer unit 300 (Fig. 7 (b)). The synthesis module L is connected to the supply unit 500 in the reaction chamber 120 to supply a compound or the like to the synthesis reaction of radioactive compounds (Fig. 7 (c)). The radioactive compound synthesis module L is moved back to the auxiliary chamber 110 from the reaction chamber 120 (Fig. 8 (a)), and the radioactive compound synthesis module L is released to the discharge unit 600 during transport (Fig. The radioactive compound synthesis module L is separated from the discharge unit 600 by the user so that the user can move the reaction chamber 120 to the auxiliary chamber 110. [ (Fig. 8 (c)).

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, . Therefore, it should be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

Radioactive compound synthesizer: 10
Chamber: 100 auxiliary chamber: 110
Reaction chamber: 120 Cover part: 130
Base unit: 200 Fastening part: 210
Feeding section: 300 plates; 310
Transfer line: 320 Shielded door: 400
Door part: 410 Door groove: 420
Driving part: 430 chamber wall: 140
Radioactive compound synthesis module: L Reactor: R
Cassette: C Euro: U
Cartridge: C1 discharge unit: 600
Collector door: 610 Exit clasp: 620
Supply unit: 500 Temperature control unit: 700
First temperature control unit: 710 Second temperature control unit: 720

Claims (9)

An auxiliary chamber into which a radioactive compound synthesis module in which radioactive synthesis takes place is carried;
A reaction chamber disposed adjacent to the auxiliary chamber and capable of providing a space for synthesizing the radioactive compound and shielding the radiation leakage due to the synthesis,
A transfer unit for transferring the radioactive compound synthesis module from the auxiliary chamber to the reaction chamber; And
And a shielding door that shields radiation generated in the reaction chamber and is selectively openable and closable as the radioactive compound synthesis module transfers the radioactive compound by the transporting unit,
Wherein the shielding door is opened such that after the synthesis of the radioactive compound is completed, the transporting part is moved from the reaction chamber to the auxiliary chamber after the radioactive compound synthesis module is collected.
The method according to claim 1,
Wherein the auxiliary chamber and the reaction chamber form a chamber wall capable of shielding the outflow of radiation,
Wherein the shielding door of the reaction chamber is capable of independently shielding the space where the radioactive compound synthesis module is fastened with the base unit.
3. The method of claim 2,
Wherein the shielding door includes a control unit for automatically controlling opening or closing of the radioactive compound synthesis module, which is a space into which a substance for synthesis of a radioactive compound is introduced and synthesized, from the auxiliary chamber to the reaction chamber. Synthesizer.
The method of claim 3,
Wherein the shielding door is automatically closed after forming the radioactive compound synthesis module into the reaction chamber and before the synthesis of the radioactive compound is performed to form a closed space.
5. The method of claim 4,
Wherein the thickness of the chamber wall and the shielding door of the reaction chamber is at least 30 mm or more.
The method according to claim 1,
Wherein the shielding door includes a door portion that can be opened or closed due to the rise and fall, and a door groove that provides a space into which the door portion is inserted when the door portion is opened.
The method according to claim 6,
Wherein the shielding door further comprises a driving part installed at one side of the shielding door to drive the door part up and down in a sliding manner.
The method according to claim 1,
Further comprising a supply unit installed in the reaction chamber for supplying a radioactive compound reaction material to the radioactive compound synthesis module and a discharge unit for collecting the compound synthesis module.
9. The method of claim 8,
Wherein the discharge unit includes a collection door capable of being opened and closed so that the reacted radioactive compound synthesis module can be collected into the discharge part; And
And a discharge latch configured to allow the radioactive compound synthesis module to be automatically collected into the discharge unit upon contact.

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