KR102088349B1 - Hot cell - Google Patents

Abstract

The present application relates to a hot cell, according to the hot cell of the present application, by reducing the radioactive concentration of the radiopharmaceutical synthesized inside the hot cell and discharged to the outside of the hot cell, it is possible to reduce internal and external exposure of workers, and prevent the expansion of radioactive contamination And worker's psychological stability.

Description

Hot Cell {HOT CELL}

This application relates to a hot cell.

Because of the danger of radioactivity, the space handling radioactive materials consists of a shielding material such as lead, which prevents leakage of radiation. In particular, where radioactive drugs are handled, a chamber-type space called a hot cell is used to work. Is doing.

The hot cell should be designed with a negative pressure so that the air pressure inside is lower than the external pressure in order to prevent the outflow of internal radioactivity. The normal hot cell for such a negative pressure constitutes an air inlet on the upper part and an air outlet on the bottom to form air. It is configured to maintain negative pressure therein by allowing it to be sucked with pressure at the outlet side.

In the case of a conventional hot cell, when producing radiopharmaceuticals with high scattering properties such as carbon-11, nitrogen-13, and fluorine-18, the range of radioactivity concentrations discharged to the outside may exceed the legal standard, and the radiopharmaceutical synthesis device There is a case in which radiation that directly leaks leaks out of the hot cell and the radiation rate increases in the work space where the worker resides.

This can cause internal and external exposure of workers, and there is a great difficulty that can affect the quality and manufacturing process of radiopharmaceuticals due to contamination of the working environment, and a hot cell is required to solve this.

An object of the present application is to provide a hot cell capable of reducing internal and external exposure of a worker by minimizing radiation leaked from inside the hot cell, preventing expansion of radioactive contamination and securing a psychological stability of the worker.

The hot cell of the present application may include an attenuation tank chamber to slow the flow rate of radiopharmaceuticals, thereby reducing radioactivity concentration by the unique physical half-life of radioisotopes contained in the radiopharmaceuticals.

According to the hot cell of the present application, by reducing the radioactive concentration of the radiopharmaceutical synthesized inside the hot cell and discharging it to the outside of the hot cell, it is possible to reduce the internal and external exposure of the worker, prevent the expansion of radioactive contamination and secure the psychological stability of the worker. You can.

1 is a view schematically showing a hot cell according to an embodiment of the present application.
2 is a view showing an exemplary attenuation channel disposed inside the attenuation tank chamber according to an embodiment of the present application.
3 is an exploded view of a synthesis apparatus chamber according to an embodiment of the present application.
4 is a view exemplarily showing a path through which a radiopharmaceutical flows in a hot cell according to an embodiment of the present application.
5 is a view schematically showing a hot cell according to another embodiment of the present application.

Hereinafter, a hot cell of the present application will be described with reference to the attached drawings, and the attached drawings are exemplary and the hot cell of the present application is not limited to the attached drawings.

This application relates to a hot cell. 1 schematically shows a hot cell according to an embodiment of the present application. As shown in Figure 1, the hot cell 100 according to an embodiment of the present application is a synthesis device 110, the synthesis device chamber 120, the supply port 130, the intake port 140, the inner duct 150, It includes an attenuation tank chamber 160 and an exhaust port 170, and the attenuation tank chamber 160 includes an attenuation channel 161.

The attenuation channel 161 is a space for reducing the radioactive concentration of the radiopharmaceutical synthesized by the synthesizing device 110, disposed inside the attenuation tank chamber 160 connected to the inner duct 150, and the intake vent The inhaled radioactive drug is introduced through 140 to form a passage through which the radioactive drug flows.

The attenuation channel 161 is provided to bend the flow direction of the radiopharmaceutical at least two times along the direction toward the exhaust port 170 in the attenuation tank chamber 160.

2 is a view showing an exemplary attenuation channel disposed inside the attenuation tank chamber according to an embodiment of the present application. 2, the attenuation channel 161 may include one or more “U” shaped sections U. Specifically, the one or more "U" shaped sections (U) may mean a form in which one or more "U" shaped sections (U) provided so that the flow direction of the radiopharmaceutical is bent at least twice or more are alternately connected to each other. . Accordingly, the radiopharmaceutical may flow in one direction along the “U” -shaped section U and collide with the bent portion of the “U” -shaped section U, and the flow rate may be slowed down.

In addition, as shown in FIG. 2, the attenuation channel 161 may include one or more of the rising section ↑ and the falling section ↓, respectively. Accordingly, the radiopharmaceutical may pass through the rising section (↑) and the falling section (↓) provided in the attenuation channel 161, and collide with the upper and lower portions of the attenuation channel 161 to further slow the flow rate.

In one example, the radiopharmaceutical may pass through attenuation channels 161 provided inside the attenuation tank chamber 160 in a range of 20 minutes to 2 hours. Specifically, the time for the radiopharmaceutical to pass through all the attenuation channels 161 provided inside the attenuation tank chamber 160 may be 40 minutes to 100 minutes or 60 minutes to 80 minutes. As the radiopharmaceutical passes through the attenuation channels 161 provided inside the attenuation tank chamber 160 at a time in the above-described range, the radioactivity concentration can be reduced by the unique physical half-life of the radiopharmaceutical.

The synthesizing device 110 is a device for synthesizing radiopharmaceuticals. The term "radiopharmaceuticals" in this specification refers to radioactive materials such as radioactive isotopes and their labeled compounds used in samples such as blood taken directly from the human body or collected from the human body for the purpose of diagnosis and treatment or medical research. it means. The synthesis device 110 may include a synthesis device 110 known in the art according to the type of radiopharmaceutical to be synthesized.

In one example, the type of radiopharmaceutical synthesized through the synthesis device 110 may include one or more radioactive isotopes selected from the group consisting of carbon-11, nitrogen-13 and fluorine-18. The term "radioisotope" in this specification is an isotope of a certain element (isotope), the nucleus (nucleus) is unstable and radioactive decay (radioactive decay) that releases the particles having energy in the process of changing to a more stable state Means

The radioisotope of the aforementioned type may include nuclides with a half-life of 5 minutes to 120 minutes. Specifically, the radioactive isotope may include a nuclide with a half-life of 7 minutes to 115 minutes or 9 minutes to 110 minutes. More specifically, the carbon-11 may include a nuclide with a half-life of 9.96 minutes, the nitrogen-13 may include a nuclide with a half-life of 20.3 minutes, and the fluorine-18 may include a nuclide with a half-life of 109.7 minutes. have. The radioactive isotope may include a nuclide having a half-life in the above-described range, thereby reducing the intensity of radioactivity in the process of passing through the attenuation tank chamber 160. In this specification, the term "half-life" refers to the time it takes for the radioactivity intensity to be reduced to half the original intensity.

The synthesis device chamber 120 is a space for handling radioactive materials, and may be provided to accommodate the above-described synthesis device 110 therein. The synthesis device chamber 120 may be made of a radiation shielding material because of the risk of radioactivity emitted from the radiopharmaceutical synthesized by the synthesis device 110. For example, the synthesizer chamber 120 may be made of one radiation shielding material selected from the group consisting of lead, steel and tungsten. The term "radiation shielding material" as used herein refers to a material used for the purpose of protecting a person from the effects of radioactivity by absorbing radiation.

3 is an exploded view of a synthesis apparatus chamber according to an embodiment of the present application. As shown in FIG. 3, the synthesizing device chamber 120 includes an air supply 130. The supply port 130 is a hole for introducing external air into the interior of the synthesis apparatus chamber 120, and is provided on the upper portion of the synthesis apparatus chamber 120.

In one example, the air supply unit 130 may include a fan (Fan) 131, in order to flow the outside air into the synthesis device chamber 120.

4 is a view exemplarily showing a path through which a radiopharmaceutical flows in a hot cell according to an embodiment of the present application. As shown in FIG. 4, the air supply 130 includes a fan 131, so that external air may be introduced into the synthesis device chamber 120.

In addition, the synthesis device chamber 120 inhales the radioactive drug generated after synthesis by the synthesis device 110 to move the intake port 140 to move to the attenuation tank chamber 160 through the inner duct 150. Includes. 3, the intake port 140 is provided on the side surface of the synthesis device chamber 120.

Specifically, as shown in FIG. 1, the intake port 140 may be provided on the side of the synthesis device chamber 120 in a state where the inner duct 150 is surrounded. The term "wrap around" in the present specification means a state in which the inner duct 150 is wrapped so that the intake vent 140 is not exposed to the outside, and specifically, the area of the intake vent 140 is the cross-sectional area of the inner duct 150. By controlling as follows, it may mean a state in which the intake port 140 is not exposed to the outside by the inner duct 150.

In one example, the intake port 140 may include a fan (Fan) 141 to inhale the radiopharmaceuticals inside the synthesis device chamber 110. As shown in FIG. 4, by including a fan 141 in the intake port 140, all radiopharmaceuticals present inside the synthesis apparatus chamber 120 can be moved in one direction to face the attenuation tank chamber 160. have.

The inner duct 150 is a passage and structure for moving the radiopharmaceutical synthesized by the synthesizing device 110 to the attenuation tank chamber 160, an open surface of the inner duct 150 is the synthesizing chamber ( 120) is connected to the intake port provided on the side. In addition, the other open side of the inner duct 150 may be connected to the attenuation tank chamber 160. By moving the radiopharmaceutical synthesized by the synthesizing device 110 to the attenuation tank chamber 160 through the inner duct 150, the attenuation tank chamber without the release of the radiopharmaceutical synthesized by the synthesizing device 110 ( 160) to decrease the radioactivity concentration.

In one example, the attenuation tank chamber 160 is a radiation shielding material due to the risk of radioactivity emitted from the radiopharmaceutical in the process of passing the attenuation channel 161 provided inside the attenuation tank chamber 160 It can be made of. For example, the attenuation tank chamber 160 may be made of one radiation shielding material selected from the group consisting of lead, steel and tungsten.

The exhaust port 170 is a hole for discharging the radiopharmaceutical that has passed through the attenuation tank chamber 160 to the outside, and may be provided on one surface of the attenuation tank chamber 160. The radiopharmaceutical can pass through the attenuation tank chamber 160 to reduce radioactivity concentration and discharge radioactive medicine with reduced radioactivity concentration through the exhaust port 170, thereby reducing internal and external exposure of workers and radioactive contamination. Prevents expansion and secures psychological stability of workers.

In one example, the exhaust port 170 may include an exhaust duct 180 to discharge the radiopharmaceutical that has passed through the attenuation tank chamber 130 to the outside of the hot cell 100. Specifically, the exhaust duct 180 may be provided to be connected to the exhaust port 170 to extend outside the hot cell 100. In this case, the exhaust port 170 may be in a state where the exhaust duct 180 is surrounded.

The radiopharmaceutical discharged to the outside of the hot cell 100 by the exhaust duct 180 passes through the attenuation tank chamber 130 inside the hot cell, thereby reducing the concentration of radiation, thereby reducing internal and external exposure of workers, and radioactive contamination. Prevents expansion and secures psychological stability of workers.

5 is a view schematically showing a hot cell according to another embodiment of the present application. As shown in FIG. 5, the hot cell 200 according to another embodiment of the present application includes a synthesis device 210, a synthesis device chamber 220, an air supply port 230, an intake port 240, and an internal duct 250 , The attenuation tank chamber 260 and the exhaust port 270, and the attenuation tank chamber 260 includes a partition 261.

The partition 261 is a structure for reducing the radioactive concentration of radiopharmaceuticals, disposed inside the attenuation tank chamber 260 connected to the inner duct 250, and the radiopharmaceutical sucked through the intake vent 240 It is arranged in a plurality to form a passage through which the radiopharmaceutical flows.

The plurality of partition walls 261 are provided to bend at least two or more times in the flow direction of the radiopharmaceutical along the direction toward the exhaust port in the attenuation tank chamber 260.

In one example, the plurality of partition walls 261 may be alternately arranged while maintaining a predetermined interval. The plurality of partition walls 261 may be alternately arranged to form a “U” -shaped flow passage so that the flow direction of the radiopharmaceutical is bent at least twice or more.

When the radiopharmaceutical flows in a predetermined direction, it collides with a plurality of alternately arranged partition walls 261, and the exhaust port is disposed along a flow passage provided to bend at least two times or more between the partition 261 and the partition 261. 270). The radiopharmaceutical may pass through the plurality of barrier ribs 261 and collide with a curved portion of the plurality of barrier ribs 261, thereby slowing a flow rate.

In one example, the radiopharmaceutical may be 20 minutes to 2 hours through all of the plurality of partition walls 261 provided inside the attenuation tank chamber 260. Specifically, the time for the radiopharmaceutical to pass all of the plurality of partition walls 261 provided inside the attenuation tank chamber 260 may be 40 minutes to 100 minutes or 60 minutes to 80 minutes. As the radiopharmaceuticals pass through all of the plurality of partition walls 261 provided inside the attenuation tank chamber 260 at a time in the above-described range, the radioactivity concentration can be reduced by the unique physical half-life of the radiopharmaceutical.

The synthesis device 210, the synthesis device chamber 220, the supply port 230, the fans 231, 241, the intake port 240, the internal duct included in the hot cell 200 according to another embodiment of the present application (250), the attenuation tank chamber 260, the exhaust port 270 and the exhaust duct 280, the details of the synthesis device 110, the synthesis included in the hot cell 100 according to an embodiment of the present application As described in the device chamber 120, the air supply 130, the fans 131, 141, the intake port 140, the inner duct 150, the attenuation tank chamber 160, the exhaust port 170 and the exhaust duct 180 Since it is the same as described above, it will be omitted.

The radiopharmaceutical discharged to the outside of the hot cell 200 by the exhaust duct 280 passes through the attenuation tank chamber 260 inside the hot cell to reduce the concentration of radioactivity, thereby reducing internal and external exposure of workers, and radioactive contamination. Prevents expansion and secures psychological stability of workers.

100, 200: hot cell
110, 210: synthesis device
120, 220: synthesis chamber
130, 230: air supply
131, 141, 231, 241: fan
140, 240: intake vent
150, 250: internal duct
160, 260: attenuation tank chamber
161: attenuation channel
170, 270: exhaust
180, 280: exhaust duct
261: bulkhead
U: "U" shaped section
↑: Rising section
↓: Descent section

Claims (19)

Synthesis device for synthesizing radiopharmaceuticals;
A synthesis device chamber provided to accommodate the synthesis device therein;
An air supply port provided in the synthesis device chamber, through which external air flows into the synthesis device chamber;
It is provided in the synthesis device chamber, the intake port for inhaling the radiopharmaceutical generated after synthesis;
An internal duct connected to an intake vent;
An attenuation tank chamber which is connected to the internal duct and includes an attenuation channel through which the radioactive drug sucked through the intake port flows; And
It includes an exhaust port for discharging the radiopharmaceutical that has passed through the attenuation tank chamber to the outside,
The attenuation channel is provided to bend the flow direction of the radiopharmaceutical at least two times along the direction toward the exhaust port in the attenuation tank chamber,
The radiopharmaceutical has a time passing through all attenuation channels of 20 minutes to 2 hours,
The radiopharmaceutical includes at least one radioisotope selected from the group consisting of carbon-11, nitrogen-13 and fluorine-18,
The radioactive isotope includes a nuclide with a half-life of 5 to 120 minutes,
The attenuation channel is a space for reducing the radioactivity concentration by the unique physical half-life of the radiopharmaceutical synthesized by the synthesis device,
The intake port is provided on the side of the synthesizing chamber with the inner duct surrounded.
A hot cell in which the area of the intake port is controlled to be less than the cross-sectional area of the inner duct, so that the intake port is not exposed to the outside by the inner duct. The method of claim 1,
The attenuation channel is a hot cell comprising one or more "U" shaped sections. The method of claim 1,
The attenuation channel is a hot cell including one or more rising and falling sections, respectively. delete delete delete The method of claim 1,
The synthesis chamber is a hot cell made of one radiation shielding material selected from the group consisting of lead, steel and tungsten. The method of claim 1,
The hot air supply is a hot cell including a fan. The method of claim 1,
The intake vent is a hot cell including a fan. The method of claim 1,
The attenuation tank chamber is a hot cell made of one radiation shielding material selected from the group consisting of lead, steel and tungsten. Synthesis device for synthesizing radiopharmaceuticals;
A synthesis device chamber provided to accommodate the synthesis device therein;
An air supply port provided in the synthesis device chamber, through which external air flows into the synthesis device chamber;
It is provided in the synthesis device chamber, the intake port for inhaling the radiopharmaceutical generated after synthesis;
An internal duct connected to an intake vent;
An attenuation tank chamber connected to the inner duct and including a plurality of partition walls arranged to form a flow path through which the radioactive drug sucked through the intake port flows; And
It includes an exhaust port for discharging the radioactive drug that has passed through the attenuation tank chamber to the outside,
The plurality of partition walls are arranged such that the flow direction of the radiopharmaceutical is bent at least two times along the direction toward the exhaust port in the attenuation tank chamber,
The radiopharmaceutical has a time of 20 minutes to 2 hours through all of the plurality of barrier ribs,
The radiopharmaceutical includes at least one radioisotope selected from the group consisting of carbon-11, nitrogen-13 and fluorine-18,
The radioactive isotope includes a nuclide with a half-life of 5 to 120 minutes,
The plurality of partition walls is a space for reducing the concentration of radioactivity by the unique physical half-life of the radiopharmaceutical synthesized by the synthesis device,
The intake port is provided on the side of the synthesizing chamber with the inner duct surrounded.
A hot cell in which the area of the intake port is controlled to be less than or equal to a cross-sectional area of the inner duct, so that the intake port is not exposed to the outside by the inner duct. The method of claim 11,
Hot cells arranged in a plurality of partition walls. delete delete delete The method of claim 11,
The synthesis chamber is a hot cell made of one radiation shielding material selected from the group consisting of lead, steel and tungsten. The method of claim 11,
The hot air supply is a hot cell having a fan. The method of claim 11,
The intake vent is a hot cell having a fan. The method of claim 11,
The attenuation tank chamber is a hot cell made of one radiation shielding material selected from the group consisting of lead, steel and tungsten.

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