KR101733784B1 - Auto dispensing system with intergrity test for radiopharmaceuticals - Google Patents

Abstract

The present invention relates to an auto-dispensing system for radiopharmaceuticals comprises the following: a radiopharmaceutical drug supplying unit; a radiopharmaceutical drug dispensing unit receiving radiopharmaceuticals from the radiopharmaceutical drug supplying unit, and dispensing the same; a gas supplying unit supplying compressed gas to the radiopharmaceutical drug dispensing unit; and a valve unit connected to the gas supplying unit or the radiopharmaceutical drug supplying unit, for either supplying the radiopharmaceuticals or the compressed gas into a filter of the radiopharmaceutical drug dispensing unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an automatic dispensing system for sterilizing a radioactive pharmaceutical product,

The present invention relates to a radiopharmaceutical dispensing system capable of sterile filter testing, and more particularly, to a radiopharmaceutical dispensing system configured to dispense a radiopharmaceutical to vials and to easily test a filter for filtering out foreign substances from radiopharmaceuticals .

Today, the scope of radioactive pharmaceutical use and utilization technology are rapidly developing, and the annual usage rate in Korea is over 100,000 curies per year (Ci).

Despite the general tendency to avoid radiation from radiopharmaceuticals, the reason for such a high usage rate is due to the intrinsic properties of radioactive pharmaceuticals with strong permeability.

Especially, Positron Emission Tomography (PET) using radioactive isotopes is useful as an examination method for early detection of cancer. The PET test is performed by intravenously administering a radiopharmaceutical such as FDG (2-deoxy-2-fluoro-D-glucose) to a human body to be examined and then radiating radiation emitted from a specific tissue or organ do.

PET can be used for early detection of micro cancer cells and tumor tissues of a few millimeters in size that could not be detected by conventional methods, but also by confirming cancer metastasis, recurrence, and antitumor effect.

Unlike conventional diagnostic equipment (CT.MRI), the PET test is essentially an inevitable use of radiopharmaceuticals for PET testing. Therefore, the facilities that produce radiopharmaceuticals are also increased in proportion to the increase of PET test.

When making radiopharmaceuticals with radiation-emitting properties, all facilities are operated in the space where they are shielded to protect the operator. An automatic dispensing device that dispenses radioactive medicines automatically is not developed by the operator due to the fear of radiation exposure.

However, the conventional radiopharmaceutical dispensing apparatus is equipped with a filter for filtering out foreign substances from the radioactive medicines supplied to the vial. In most cases, there is no function of the test work for judging the abnormality of the filter. In order to proceed, there is a very cumbersome and insecure problem in which the operator has to work while taking the exposures.

In other words, the conventional radiopharmaceutical dispensing apparatus has a configuration in which a radiopharmaceutical is passed through a filter and then supplied to the vial. In this case, when the filter is defective, the radiopharmaceuticals and foreign substances may be supplied to the vial The stability of the finally produced radiopharmaceutical can not be secured and the end result can not be used. Therefore, it is very important to test the filter every time a radiopharmaceutical is produced.

The conventional radiopharmaceutical dispensing apparatus is not provided with a separate structure for testing the filter so that the filter that has been used in the radiopharmaceuticals after the radiopharmaceutical is finally produced is directly tested after the operator takes it out of the radiopharmaceutical dispensing apparatus Work was performed. For reference, if the filter is determined to be defective after the test operation, the radiopharmaceutical produced through the filter is discarded.

However, in the above process, the radiation shielding casing surrounding the radiopharmaceutical dispensing apparatus must be opened, and radiation medicines remaining in the filter cause radiation workers to be exposed to radiation. In particular, exposure to the hands is a serious threat to workers.

Accordingly, the applicant of the present invention has proposed the present invention to solve the above-mentioned problems, and as a prior art document related thereto, Korean Patent Laid-Open Publication No. 10-2015-0010287 entitled " Control Method of Radiopharmaceutical Distribution System '.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above problems, and it is an object of the present invention to provide an automatic radiopharmaceutical dispensing system that can easily test a filter used in the production of a radiopharmaceutical without damaging workers.

It is also possible to provide a set of dispensing syringes and filters in multiple sets so that the dispensing syringes and filters used to dispense or manufacture one kind of radiopharmaceutical are not required to be used to dispense or produce other types of radiopharmaceuticals It is possible to provide a radiopharmaceutical dispensing system that prevents dispensing syringes and filters from leaving disparate radiopharmaceuticals.

According to an aspect of the present invention, there is provided a radiopharmaceutical supply system comprising: a radiopharmaceutical supply unit; A radiopharmaceutical dispensing unit for receiving the radiopharmaceuticals from the radiopharmaceutical supply unit and dispensing the radiopharmaceuticals; A gas supply unit for supplying a compressed gas to the radiopharmaceutical dispensing unit; And a valve unit connected to the radiopharmaceutical dispensing unit through a first supply pipe and connected to the radiopharmaceutical dispenser through a gas supply unit and a second supply pipe, and the radiopharmaceutical dispensing unit includes: , An index table; A first rotating part rotatably mounted on the index table and having a plurality of vials mounted thereon; And a radiopharmaceutical dispenser provided above the first rotating part for injecting the radiopharmaceutical supplied from the radiopharmaceutical supply part into at least one of the plurality of vials, A first cylinder connected to the first cylinder; A filter provided in the first cylinder; And a first needle which is supplied through the transfer tube and which injects the radioactive medicament that has passed through the filter into any one of the plurality of vials. When the radiopharmaceuticals supply unit supplies the radiopharmaceutical to the radiopharmaceutical dispensing unit , The valve unit communicates the first supply pipe and the transfer pipe with each other and interrupts the communication between the second supply pipe and the transfer pipe, and after the radiopharmaceutical dispensing operation by the radiopharmaceutical dispensing unit is completed, The bubble point test is performed on the filter, the valve unit communicates the second supply pipe and the transfer pipe, interrupts the communication between the first supply pipe and the transfer pipe, and supplies the bubble point test from the gas supply unit And the compressed gas is supplied to the filter Is applied, and when the compressed gas to the filter is applied, the first needle may be accomplished by the radiopharmaceutical dispensing apparatus capable of a sterile filter test, it characterized in that the state inserted in any of said plurality of vials.

The valve unit may further include a three-way valve for selectively interrupting a flow path communicating with the first supply pipe and the transfer pipe and a flow path through which the second supply pipe and the transfer pipe communicate with each other; And a first drive motor for driving the three-way valve.
The valve unit may further include: a support bar supporting the three-way valve; A body disposed on an upper portion of the support bar and having the first drive motor mounted on one side thereof; And a gripping piece mounted on the other side of the body and rotated by receiving power from the first driving motor, wherein the gripping piece forms a space portion in which the upper portion of the three-way valve is received.

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The three-way valve is provided along the longitudinal direction of the support bar, and the body is provided to be movable along the longitudinal direction of the support bar.

The valve unit may further include a transfer unit for transferring the rotation unit along the longitudinal direction of the support bar, wherein the transfer unit includes: a second drive motor disposed at one side of the support bar; And a conveying rod that receives power from the second driving motor and rotates and is connected to the body of the rotating unit.

The radiopharmaceutical dispenser may further include a second rotation unit rotatably mounted on the index table and capable of raising and lowering the radiopharmaceutical dispenser and mounting the radiopharmaceutical dispenser, A first fixing bracket coupled to the second rotating part and interlocked with the rotation and the wiping / lowering operation of the second rotating part; And a first support bracket connected to the first fixing bracket and to which the first cylinder is mounted, wherein the radiopharmaceutical discharge unit is provided along the circumferential direction of the second rotation unit.

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The automated medicament dispensing system capable of sterile filter testing of the present invention has the effect that the testing of the filter used in the dispensing or production of the radiopharmaceuticals can be performed immediately after the production of the radiopharmaceuticals.

In addition, the automatic radiopharmaceutical dispensing system capable of sterile filter testing according to the present invention can easily perform a test operation of a filter without opening a radioactive shield casing, thereby preventing damage to an operator's exposure.

In addition, the automatic radiopharmaceutical dispensing system capable of sterile filter testing of the present invention has an effect of easily detecting the abnormality of the radiopharmaceuticals by the test operation of the filter.

In addition, the automatic dispensing system for radiopharmaceuticals capable of sterile filter testing of the present invention has an effect that the operator does not need to wash the syringe, which stores medicines to be mixed with the radiopharmaceuticals, every time the radiopharmaceuticals are produced, from time to time.

In addition, in the radiopharmaceutical dispensing system capable of sterile filter testing according to the present invention, as the number of washing operations of the syringe is reduced, the number of times the radiation shielding casing is opened is also reduced, thereby minimizing the exposure to radioactivity.

In addition, the radiopharmaceutical dispensing system capable of sterile filter testing of the present invention has the effect of quickly and easily producing various types of radiopharmaceuticals immediately required by a company such as a hospital, and responding to emergency situations.

1 is a block diagram showing a configuration of a radiopharmaceutical dispensing system capable of sterile filter testing according to an embodiment of the present invention;
2 is a perspective view of a valve according to an embodiment of the present invention;
3 is a plan view of a valve according to an embodiment of the present invention;
FIG. 4 is a view showing a state in which a 3-way valve according to an embodiment of the present invention connects a radiopharmaceutical supply unit and a radiopharmaceutical dispensing unit. FIG.
FIG. 5 is a view showing a state in which the three-way valve shown in FIG. 4 is rotated to interconnect the gas supply unit and the radiopharmaceutical dispensing unit;
6 is a perspective view of a radiopharmaceutical dispensing unit according to an embodiment of the present invention.
7 is a perspective view of a radiopharmaceutical discharge unit according to an embodiment of the present invention;
FIG. 8 is a front view of a radiopharmaceutical dispenser according to an embodiment of the present invention; FIG.
FIG. 9 is a front view showing a state in which the radiopharmaceuticals discharge part shown in FIG. 8 is lowered.
10 is a perspective view of a dispensing scan unit according to an embodiment of the present invention;
11 is a front view of a dispensing scan unit according to an embodiment of the present invention.
12 is a front view showing a state in which the dispensing injection unit shown in Fig. 11 is lowered;
Fig. 13 is a front view showing an elevation of the movable member of the dispensing scan unit shown in Fig. 12; Fig.
Fig. 14 is a front view showing a state in which the movable member of the dispensing scanning unit shown in Fig. 13 is lowered. Fig.
FIG. 15 is a front view showing a state in which a radiopharmaceutical dispenser according to an embodiment of the present invention is lowered toward a vial containing dilute water for a test operation of a filter. FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings.

It should be understood, however, that the invention is not limited to the disclosed embodiments, but is capable of many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims.

Hereinafter, a radiopharmaceutical dispensing system 100 capable of sterile filter testing according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 15. In describing the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as not to obscure the gist of the invention.

1, the system 300 for sterilizing a sterile filter according to an embodiment of the present invention includes a radiopharmaceutical supply unit 200 and a radiopharmaceutical supply unit 200, And a gas supply unit 400 for supplying a compressed gas to the radiopharmaceutical dispenser 300. The gas supply unit 400 or the radiopharmaceutical supply unit 300 may include a radiopharmaceutical dispenser 300, And a valve unit 500 connected to the radiopharmaceutical dispenser 300 to supply the radioactive medicines to the filter 333b (see FIG. 7) or to supply the compressed gas.

The radiopharmaceutical dispenser 200 receives the radiopharmaceuticals from a radiopharmaceutical synthesizer (not shown) and stores the radiopharmaceuticals. The radiopharmaceutical dispenser 200 includes a first supply pipe 210, which is connected to the radiopharmaceutical dispenser 300 to deliver the radiopharmaceuticals, See Figs. 4 and 5).

The gas supply unit 400 includes a known device for supplying a compressed gas such as a gas booster or a gas compressor and includes a second supply pipe 410 connected to the radiopharmaceutical dispenser 300 to deliver compressed gas, See Figs. 4 and 5).

The valve unit 500 is disposed between the radiopharmaceutical dispenser 200 and the radiopharmaceutical dispenser 300 and is connected to the transfer pipe 3 of the first supply pipe 210 and the radiopharmaceutical dispenser 300, Can be connected to each other in a communicable manner.

The valve unit 500 may connect the second supply pipe 410 of the gas supply unit 400 and the transfer pipe 3 of the radiopharmaceutical dispenser 300 so as to communicate with each other.

That is, the valve unit 500 can be connected to only one of the first supply pipe 210 and the second supply pipe 410 so as to be able to communicate with the transfer pipe 3.

As shown in FIGS. 2 and 3, the valve unit 500 includes a three-way valve 510 having first to third ports 511, 512 and 513, 510 and the support bar 520. The three-way valve 510 rotates to rotate the first to third ports 511, 512, 513 And a rotating unit 530 for changing the position. 2 and 3, a first supply pipe (not shown) connected selectively to the first to third ports 511, 512 and 513 of the three-way valve 510, 210, the second supply pipe 410 and the transfer pipe 3 are omitted.

4 and 5, the three-way valve 510 is rotated by the rotation unit 530 so that the first supply pipe 210 of the radiopharmaceutical supply unit 200 and the radioactive- The second supply pipe 410 of the gas supply unit 400 and the transfer pipe 3 of the radiopharmaceutical dispensing unit 300 can communicate with each other, .

That is, when the radiopharmaceuticals are requested and dispensed by a company such as a hospital, for example, the three-way valve 510, the first supply pipe 210 and the transfer pipe 3 are communicated with each other So that the radiopharmaceutical dispenser 300 is supplied with the radiopharmaceuticals.

Meanwhile, when the radioactive pharmaceuticals are finally distributed or produced, the three-way valve 510 allows the second supply pipe 410 and the transfer pipe 3 to be communicably connected to each other, So that the compressed gas is supplied to the distributor 300.

Here, the gas supplied to the radiopharmaceutical dispenser 300 is supplied to the filter 333b used for distributing or producing the radiopharmaceutical, and applies pressure to the filter 333b. At this time, if the filter 333b is torn or broken at a predetermined pressure or higher, the radioactive pharmaceutical product previously produced may be finally shipped. Conversely, if the filter 333b is torn or broken at a preset pressure or less, the radioactive pharmaceutical product previously produced is discarded. This is because the filter 333b is used to dispense or produce the radiopharmaceutical despite the fact that the foreign substance is not sufficiently filtered out from the radiopharmaceutical. That is, the filter 333b must have durability enough to be torn or damaged at a preset pressure or higher.

For reference, a method of confirming the degree of tearing or breakage of the filter 333b will be described in detail below together with the configuration of the radiopharmaceutical dispenser 300. [

As shown in FIG. 4, the first to third ports 511, 512, and 513 provided in the three-way valve 510 are spaced apart from each other in the circumferential direction of the three-way valve 510 Directional valve 310. The three-way valve 310 is spaced apart at an interval of 90 degrees in the embodiment of the present invention.

The first port 511 is communicably connected to the first supply pipe 210 of the radiopharmaceutical supply unit 200 when dispensing or producing a radiopharmaceutical, Is connected to the transfer tube (3) of the radiopharmaceutical dispenser (300) so as to be able to communicate with the transfer tube (3).

Therefore, the radiopharmaceuticals discharged from the radiopharmaceutical supply unit 200 can be supplied to the radiopharmaceutical dispenser 300 through the first port 511 and the third port 513 sequentially.

On the other hand, the three-way valve 510 may be rotated by the rotating unit 530 and disposed in the state shown in FIG. 5 after the dispensing or production of the radiopharmaceutical is completed. At this time, the first port 511 connected to the first supply pipe 210 is rotated 90 degrees and is not connected to the first supply pipe 210 or the second supply pipe 410, 3 is communicably connected to the second supply pipe 410 of the gas supply unit 400. The third port 513 is connected to the second supply pipe 410 of the gas supply unit 400 by 90 degrees. The second port 512, which is not connected to the first supply pipe 210 or the second supply pipe 410, is rotated 90 degrees when the radiopharmaceutical is dispensed or produced, And is connected to the conveying pipe 3 of the apparatus.

Therefore, the compressed gas discharged from the gas supply unit 400 can be supplied to the radiopharmaceutical dispenser 300 through the third port 513 and the second port 512 sequentially.

2, the rotation unit 530 for rotating the three-way valve 510 includes a body 531 disposed on one side of the support bar 520, A first drive motor 532 provided at one side; And a gripping piece 533 provided on the other side of the body 531 and rotated by receiving power from the first driving motor 532.

The body 531 may be formed in such a manner that it does not interfere with the first supply pipe 210 connected to the three-way valve 510, the second supply pipe 410 and the transfer pipe 3, And may be arranged in a direction perpendicular to the longitudinal direction of the bar 520. For example, the first supply pipe 210, the second supply pipe 410, and the transfer pipe 3 are preferably made of flexible tubular tubes.

The gripping piece 533 forms a space portion in which the upper portion of the three-way valve 510 can be received. Accordingly, the upper portion of the three-way valve 510 inserted into the space portion can be rotated in conjunction with the rotation of the gripping piece 533.

The three-way valve 510 is connected to the radiopharmaceutical dispenser 300 so that the radiopharmaceutical dispenser 300 can communicate with the radiopharmaceutical dispenser 300 by the rotation of the grip piece 533. Alternatively, (400) and the radiopharmaceutical dispenser (300) in a communicable manner.

The gripping piece 533 is rotated by a first power transmitting means 534 connected to the first driving motor 532 and the first power transmitting means 534 is rotated by the first driving motor A second driven pulley 534b connected to the gripping piece 533 and a first driven pulley 534a and a first driven pulley 534b, And a first belt 534c connecting the first belt 534c and the first belt 534c.

Accordingly, when the first driving motor 532 is rotated, the gripping piece 533 is rotatable by the power transmitting means 534. For reference, in the embodiment of the present invention, the gripping piece 533 is described as being rotated by the driving motor, the belt, and the pulley. However, the gripping piece 533 may be rotated by various known torque generating means.

Meanwhile, the three-way valve 510 may be provided along the longitudinal direction of the supporting bar 520. At this time, the rotation unit 530 is movable along the longitudinal direction of the support bar 520 to rotate any one of the three-way valves 510 among the plurality of three-way valves 510.

The reason why the three-way valves 510 are provided is that a plurality of the three-way valves 510 are provided in each of the plurality of radiopharmaceutical dispensers 330 provided in the radiopharmaceutical dispenser 300, And supplies the medicines or the compressed gas provided from the gas supply unit 400 individually.

That is, the three-way valve 510 is connected to the conveyance pipe 3 provided to each of the plurality of radiopharmaceuticals discharge units 330, the number of which corresponds to the number of the plurality of radiopharmaceuticals discharge units 330 .

In this case, the rotation unit 530 is movable along the longitudinal direction of the support bar 520 as described above, and the valve unit 500 according to an embodiment of the present invention includes the rotation unit 530 And a transfer unit 540 for transferring the support bar 520 along the longitudinal direction of the support bar 520.

The transfer unit 540 includes a second drive motor 541 disposed at one side of the support bar 520 and a second drive motor 542 rotated by receiving power from the second drive motor 541, And a conveying rod 542 connected to the body 531.

The feed rod 542 is also rotated by the second power transmission means 543 connected to the second drive motor 541 and the second power transmission means 543 is rotated by the second drive motor 542, A second driven pulley 543a provided on the drive shaft, a second driven pulley 543b connected to the feed rod 542 and a second driven pulley 543b connected to the second driven pulley 543a and the second driven pulley 543b And a second belt 543c.

Accordingly, when the drive shaft of the second drive motor 541 is rotated, the second main pulley 543a and the second driven pulley 543b are rotated. As a result, the transfer rod 542 is rotated, The body 531 of the unit 530 can be reciprocally moved along the longitudinal direction of the support bar 520. [

A screw is formed on an outer surface of the feed rod 542 and a through hole is formed in the body 531 to allow the feed rod 542 to be inserted therein. The through hole may be formed with a screw that is rotatably coupled with a screw formed on the outer surface of the feed rod 542.

The configuration in which the body 531 linearly reciprocates along the conveying rod 542 by rotation of the conveying rod 542 is a well-known structure that can be easily carried out by anyone skilled in the art, The detailed configuration and operation description thereof are omitted in the specification of the present invention. In addition, in the embodiment of the present invention, the conveying rod 542 is described as being rotated by the driving motor, the belt, and the pulley. However, the conveying rod may be rotated by various known torque generating means.

Accordingly, the rotation unit 530 can select any three-way valve 510 among the three-way valves 510 provided at the upper portion of the support bar 520 to rotate.

The radiopharmaceutical dispenser 330 connected to the three-way valve 510 rotated by the rotation unit 530 receives the radiopharmaceutical from the radiopharmaceutical supply unit 200, Compressed gas can be supplied.

That is, when the radiopharmaceuticals are dispensed or produced, the three-way valve 510 is connected to the first supply pipe 210 of the radiopharmaceutical supply unit 200 so that the radiopharmaceuticals discharge unit 330 can receive the radiopharmaceuticals. And a transfer tube (3) provided in the radiopharmaceutical drug discharging part (330) are communicably connected to each other. After the radiopharmaceutical is dispensed or produced, the three-way valve 510 is rotated by the rotation unit 530 so that the radiopharmaceuticals discharge unit 330 can receive the compressed gas, 400 and the transfer tube 3 provided in the radiopharmaceutical discharge unit 330 are communicably connected to each other.

6, the radiopharmaceutical dispenser 300 includes an index table T and a plurality of vials 1a, 1b, and 1c rotatably provided on the index table T, A second rotation part 320 disposed on one side of the first rotation part 310 and capable of rotating and raising and lowering on the index table T, A radiopharmaceutical dispenser 330 provided in the radiopharmaceutical dispenser 320 and communicably connected to the radiopharmaceutical supply unit 200 or the gas supply unit 400 by the valve unit 500, And a dispensing scanning unit 340 for supplying a medicine or dilution water to the vials 1a, 1b, 1c.

The first rotary part 310 is formed in a generally cylindrical shape and can be rotated by receiving power from a third drive motor 311 provided on the index table T. [

The first rotating part 310 is formed with a groove 312 through which a plurality of vials 1a, 1b, and 1c can be inserted.

The grooves 312 may be formed in a size corresponding to the size of the vials 1a, 1b, 1c, and may be formed in the upper portion of the first rotating portion 310, 310 along the circumferential direction.

In addition, the groove 312 may be formed in the first rotation part 310 to a depth at which only the body part of the vials 1a, 1b, 1c can be inserted. Accordingly, when the vials 1a, 1b, 1c are inserted into the grooves 312, the cap portions of the vials 1a, 1b, 1c are exposed to the upper portion of the first rotating portion 310 as shown in FIG. do.

The vials 1a, 1b, and 1c inserted into the grooves 312 include a first vial 1a storing radioactive pharmaceuticals and dilution water, a second vial 1b storing dilution water, and finally a diluted radioactive And a third vial 1c in which the medicines are packed and shipped.

That is, the first rotary part 310 may be provided with a plurality of first vials 1a for storing the radiopharmaceuticals and the dilution water, and a second vial 1b containing diluted water such as saline, A plurality of third vials 1c to be finally shipped can be provided. At this time, the vials 1a, 1b, and 1c may be provided along the circumferential direction of the first rotation unit 310. [

The second rotary part 320 is formed in a generally cylindrical shape in the same manner as the first rotary part 310. The second rotary part 320 receives power from a fourth drive motor 321 provided on the index table T, (Not shown).

The second rotary part 320 receives power from a not shown up / down driving part (not shown) and descends in a direction in which the index table T is disposed, or moves in the opposite direction in which the index table T is disposed As shown in FIG.

The first rotation unit 310 and the second rotation unit 320 are rotated by the third drive motor 311 and the fourth drive motor 321 and the second rotation unit 320 The constitution of ascending or descending by the ascending / descending driving section is well known to those skilled in the art, so that the description of the constitution is omitted in order to avoid obscuring the gist of the present invention in the specification of the present invention . The up / down driving unit may be implemented by a driving motor, a pneumatic cylinder, or a hydraulic cylinder.

The radiopharmaceuticals discharge unit 330 and the dispensing scan unit 340 may be sequentially disposed along the circumferential direction of the second rotation unit 320 on the circumferential surface of the second rotation unit 320, . For reference, in one embodiment of the present invention, four radiopharmaceutical dispensers 330 and four dispensing scans 340 are sequentially disposed on the circumferential surface of the second rotating part 320, However, the present invention is not limited thereto, and four or more of them may be provided on the circumferential surface of the second rotation part 320.

7 to 9, the radiopharmaceutical dispenser 330 includes a first fixing bracket 331 coupled to a circumferential surface of the second rotation unit 320, a first fixing bracket 331 And a first scanning unit 333 provided on the first supporting bracket 332. The first supporting bracket 332 is connected to the first supporting bracket 332 and the first supporting bracket 332,

The first fixing bracket 331 can be rotated or moved up and down in conjunction with the rotation and the wiping / lowering motion of the second rotating part 320.

The first supporting bracket 332 is connected to a lower portion of the first fixing bracket 331 and forms a predetermined space in which the first scanning unit 333 can be seated.

The first scanning unit 333 includes a first cylinder 333a communicably connected to the transfer tube 3 connected to the three-way valve 510 and a second cylinder 333b provided in the first cylinder 333a A filter 333b for filtering foreign substances from the radiopharmaceutical supplied from the transfer tube 3 and a hollow first needle 333c provided at the lower portion of the first cylinder 333a.

One end of the transfer pipe 3 is communicably connected to the second port 512 or the third port 513 of the three-way valve 510 and the other end is communicated with the upper portion of the first cylinder 333a . For example, in the embodiment of the present invention, the number of the radiopharmaceutical dispensers 330 is four. Therefore, the number of the transfer tubes 3 may be four, corresponding to the number of the radiopharmaceutical dispensers 330.

Accordingly, the transfer tube 3 may receive the radiopharmaceutical provided by the radiopharmaceutical supply unit 200 or the compressed gas provided by the gas supply unit 400 and supply the compressed gas to the first cylinder 333a.

For reference, the radiopharmaceutical provided in the radiopharmaceutical supply unit 200 is in a liquid state, and thus the liquid radiopharmaceutical is supplied to the first cylinder 333a through the transfer tube 3. [

The filter 333b filters the foreign substance from the liquid radiopharmaceutical supplied to the first cylinder 333a through the transfer tube 3 and is provided at the longitudinally stopped portion of the first cylinder 333a . Therefore, the radiopharmaceutical supplied through the upper portion of the first cylinder 333a flows into the first needle 333c provided at the lower portion of the first cylinder 333a via the filter 333b.

The first needle 333c can inject a liquid medicinal liquid in which a foreign substance is filtered through the filter 333b into the first vial 1a provided in the first rotating part 310. [

9, when the second rotating part 320 is lowered, the first needle 333c penetrates the rubber member formed in the cap of the vial 1a, Is inserted into the body to discharge the liquid radiopharmaceuticals into the body of the first vial (1a).

At this time, due to the internal pressure formed inside the body of the first vial (1a), the liquid medicinal liquid in the first needle (333c) may not be discharged smoothly into the body of the vial (1). Therefore, the first support bracket 332 may be provided with a hollow auxiliary needle 334, as shown in FIGS. 8 and 9.

The auxiliary needle 334 is inclined at one side of the first supporting bracket 332 and the auxiliary needle 334 penetrates the rubber member formed in the cap of the first vial 1a together with the first needle 333c, The pressure of the inside of the body of the first vial 1a can be lowered by being inserted into the body of the vial 1a.

Therefore, the first needle 333c inserted into the body of the first vial 1a can smoothly discharge the liquid medicinal liquid in the first vial 1a by the auxiliary needle 334 .

The stopper of the first cylinder 333a provided with the filter 333b is seated on the upper surface of the first support bracket 332. The first support bracket 332 is provided with the first cylinder 333a May be further provided with a clamp 335 for fixing an intermediate portion of the first support bracket 332 on the first support bracket 332.

10 to 14, the distribution scanning unit 340 includes a second fixing bracket 341 coupled to the circumferential surface of the second rotation unit 320, a second fixing bracket 341 coupled to the second rotation unit 320, A second scanning unit 343 provided on the second supporting bracket 342 and a second supporting bracket 342 connected to the piston 343b of the second scanning unit 343, And a moving member 344 for moving the lifting member 343b upward or downward.

Like the first fixing bracket 331, the second fixing bracket 341 can be rotated or moved up and down in conjunction with the rotation and the upward / downward movement of the second rotation unit 320. The fifth driving motor 345 is provided with a fifth driving motor 345 for providing a driving force to move the moving member 344 up or down to the second fixing bracket 341, The second fixing bracket 341 may be mounted on a third supporting bracket 346 fixedly connected to the second fixing bracket 341 and supported on the second fixing bracket 341.

The second supporting bracket 342 is connected to the second fixing bracket 341 via the third supporting bracket 346 and is provided with a predetermined space in which the second scanning unit 343 can be seated .

The second scanning unit 343 includes a second cylinder 343a for storing medicines mixed with the diluted water or the radiopharmaceutical and a second cylinder 343b for storing medicines mixed with the radioactive medicines in the longitudinal direction of the second cylinder 343a inside the second cylinder 343a A reciprocating piston 343b and a hollow second needle 343c provided below the second cylinder 343a.

The moving member 344 is provided on the upper portion of the second supporting bracket 342 and the fifth driving motor 345 and the driving shaft (not shown) of the fifth driving motor 345 is rotated It can be raised or lowered.

It should be noted that the configuration in which the moving member 344 is raised or lowered by the fifth driving motor 345 is well known to those skilled in the art, The detailed constructional description thereof is omitted in order to avoid ambiguity. Further, the shifting member 344 is not limited to the driving motor but may be connected to the compression cylinder or the hydraulic cylinder so as to be raised or lowered.

The dispensing scanner 340 having the above configuration can supply diluted water to the first vial 1a into which the radiopharmaceuticals in the liquid state are injected by the radiopharmaceutical dispenser 330 and supply the medicines . At this time, in order to supply the dilution water such as saline solution to the first vial 1a storing the radiopharmaceuticals in liquid form by the radiopharmaceutical dispenser 330, the dispensing scans 340 may include a second vial Lt; RTI ID = 0.0 > 1b. ≪ / RTI >

The first rotation unit 310 and the second rotation unit 320 may be rotated such that the dispense scanning unit 340 is positioned above the second vial 1b storing dilution water. Then, as shown in FIG. 11, the distribution scanning unit 340 is positioned above the second vial 1b storing the dilution water.

The distribution scanning unit 340 moves downward to the second vial 1b where the dilution water is stored in association with the downward movement of the second rotation unit 320. [ 12, the second needle 343c of the second scanning unit 343 is inserted into the body of the second vial 1b through the cap of the second vial 1b storing the diluted water, .

13, when the moving member 344 is raised, the piston 343b of the second scanning unit 343 is raised inside the second cylinder 343a, The diluted water is filled in the second cylinder 343a.

Next, the first rotating part 310 and the second rotating part 320 are rotated to inject the diluted water stored in the second cylinder 343a into the first vial 1a storing the radioactive medicine, And the second cylinder 343a is disposed above the stored first vial 1a.

Then, as shown in FIG. 14, a dispensing scan unit 340 having a second cylinder 343a storing diluted water is positioned above the first vial 1a storing the radioactive medicine.

When the second rotating part 340 is lowered in the above state, the second needle 343c is inserted into the body of the first vial 1a storing the radioactive medicine. The piston 343b descends in the second cylinder 343a while being interlocked with the lowering of the moving member 344 so that the diluted water stored in the second cylinder 343a is supplied to the second needle 343c, To the first vial 1a storing the radioactive pharmaceutical product.

After the dilution water is supplied, the dispensing scanning unit 320 can be moved to the home position together with the upward movement of the second rotating unit 320.

After completing the above process, diluted water can be supplied to the first vial 1a storing the radiopharmaceuticals.

Further, since the radiopharmaceutical can be introduced into the third vial 1c which is finally shipped from the first vial 1a storing the radioactive medicine and the dilution water, when the medicine is to be injected into the third vial 1c, The dispensing unit 340 dispenses diluted water into the first vial 1a of the plurality of dispensing scans 340. The dispensing unit 340 dispenses diluted water into the first vial 1a The liquid medicine can be drawn out from the third vial 1c and the radioactive medicine can be injected into the third vial 1c.

The operation of dispensing medicines from the first vial 1a storing the liquid medicines in the liquid dispensing part 340 and injecting the medicines into the third vial 1c stored with the radioactive medicines and the dilution water is the same as the above- The operation of extracting diluted water from the second vial 1b storing only the diluted water and injecting the diluted water into the first vial 1a storing the radiopharmaceuticals is omitted. Only the angle at which the first rotation unit 310 and the second rotation unit 320 are rotated is different so that the distribution scanning unit 340 can be disposed above the third vial 1c to be finally shipped.

Further, in the embodiment of the present invention, it has been described that the diluted water is added to the first vial 1a storing the radioactive medicine, and then the medicine is further added, but the present invention is not limited thereto. That is, the first vial 1a in which the radioactive medicine and the diluting water are stored together can be finally shipped and used by injecting the diluted water only into the first vial 1a storing the radioactive pharmaceutical product, without supplying medicines.

As described above, when the liquid medicine is put into the first vial 1a storing the radiopharmaceuticals and dilution water by the dispensing scanner 340, the radiopharmaceutical can be finally completed.

The radiopharmaceutical dispenser 330 and the dispensing scanner 340 described above are used to produce one type of radiopharmaceuticals and the remaining three radiopharmaceutical dispensers 330 ) And the dispensing unit 340 can be used to produce radiopharmaceuticals of a kind different from the radiopharmaceuticals described above.

That is, since the first rotary part 310 is provided with the first vial 1a in which the radiopharmaceuticals are ultimately stored and the third vials 1c in which different kinds of medicines are stored, it is possible to produce different kinds of radiopharmaceuticals Another pair of radiopharmaceutical dispensers 330 and dispensing scans 340 may be used. At this time, the first rotating part 310 and the second rotating part 320 are rotated by the first pair of radiopharmaceuticals discharging part 330 and the dispensing scanning part 340, 1a and the third vial 1c in which the other kind of medicine is stored.

Therefore, the automatic radiopharmaceutical dispensing system 100 capable of sterile filter testing according to an embodiment of the present invention can be configured to perform a sterilization filter test every time the operator produces other types of radiopharmaceuticals, It is possible to quickly and easily produce various kinds of radiopharmaceuticals immediately required by a hospital such as a hospital, and whenever an operator produces different kinds of radiopharmaceuticals, the radiation exposure exposure And thus it is possible to enhance the safety of the radiation worker over the existing bonsai device.

Finally, the third vial 1c containing the radiopharmaceutical can be drawn out from the groove 312 of the first rotation part 310 by the transfer part 350 shown in FIG.

The transferring unit 350 holds the first and the third vials 1a and 1c in the groove 312 by gripping the cap of the first vial 1a containing the radioactive medicine or the finally discharged third vial 1c, And the drawn first and third vials 1a and 1c can be transferred to a storage box (not shown).

Like the radiopharmaceutical dispenser 330 and the dispensing scanner 340, the transfer unit 350 is provided on the circumferential surface of the second rotating unit 320, and is rotated by the second rotating unit 320 So as to face the vial 1a containing the radiopharmaceuticals.

Thus, when the radiopharmaceutical is finally distributed or produced, the filter 333b of the radiopharmaceutical discharge unit 330 used for distributing or producing the radiopharmaceutical may be tested. That is, the filter 333b used to produce the radiopharmaceutical may be tested to determine whether or not the finally produced radiopharmaceutical is abnormal.

15, the radiopharmaceutical drug discharging unit 330 may include an upper portion of the second vial 1b containing diluted water by rotation of the first rotating unit 310 and the second rotating unit 320, .

Then, the second rotating part 320 is lowered so that the first needle 313c of the radiopharmaceutical discharge part 330 is inserted into the second vial 1b containing the diluted water.

Next, as shown in FIG. 5, the three-way valve 510 is rotated using the rotation unit 530. The second port 512 of the three-way valve 510 is communicably connected to the transfer tube 3 communicably connected to the first cylinder 333a of the radiopharmaceutical discharge unit 330, The third port 513 of the directional valve 510 may be communicably connected to the second supply pipe 410 of the gas supply unit 400.

In this state, the compressed gas can be supplied to the first cylinder 333a of the radiopharmaceutical drug discharging unit 330.

The compressed gas supplied to the first cylinder 333a may be supplied to the second vial 1b through which the diluted water is stored via the filter 333b and the first needle 333c.

Further, since the filter 333b is pressurized by the compressed gas, the gas supply unit 400 can gradually increase the pressure of the compressed gas.

Accordingly, the filter 333b is torn or deformed by the compressed gas whose pressure is gradually increased. At this time, a bubble point phenomenon occurs in the interior of the second vial 1b storing the dilution water . That is, the bubbles generated inside the second vial 1b can detect the abnormality of the filter 333b used in the production of the radiopharmaceuticals.

For example, when the pressure at the time of occurrence of the bubble point phenomenon is equal to or lower than a predetermined pressure, the filter 333b is unsuitable for distributing or producing the radiopharmaceutical. At this time, the first vial 1a storing the radiopharmaceuticals dispensed or produced by the filter 333b is discarded and the radioactive medicines are reproduced.

Conversely, when the pressure at the point of time when the bubble point phenomenon occurs is equal to or higher than a preset pressure, the filter 333b is suitable for distributing or producing the radiopharmaceutical. At this time, the first vial 1a storing the radiopharmaceuticals dispensed or produced by the filter 333b can be finally supplied to a company such as a hospital.

For reference, the preset pressure refers to a pressure that the filter 333b sufficiently filtering out foreign substances from the radiopharmaceuticals can tolerate when dispensing or producing the radiopharmaceutical, and can be changed according to the specification of the filter 333b Of course it is.

Accordingly, the radiopharmaceutical dispensing system 100 capable of sterile filter testing according to an embodiment of the present invention can perform the test operation of the filter used in the dispensing or production of the radiopharmaceuticals immediately after the radiopharmaceutical is produced And the radiation shielding casing can be easily carried out from the outside without opening the radiation shielding casing, thereby preventing damage to the worker's exposure.

Meanwhile, a radiopharmaceutical dispensing apparatus 100 capable of sterile filter testing according to an embodiment of the present invention includes a first needle 333c inserted into the first through third vials 1a, 1b, When the second needle 343c is pulled out of the first to third vials 1a, 1b and 1c by the upward movement of the second rotating part 320, the first to third vials 1a, 1b, 1c (See FIG. 6) for preventing the first needle 313c or the second needle 323c from being lifted together with the first needle 313c or the second needle 323c to be separated from the groove 312 of the first rotation part 310 do.

1, the release preventing member 360 is provided in a tubular guide member 313 for guiding the up / down movement of the second rotating unit 310, Is pivotally connected.

The other end of the release preventing member 360 is formed in a ring shape so as to be able to hang the bottleneck portions of the first to third vials 1a, 1b, and 1c provided in the first rotating portion 310.

The second rotation part 320 is lowered so that the first needle 333c of the radiopharmaceutical discharge part 330 or the second needle 343c of the dispensing part 340 1b and 1c among the plurality of first to third vials 1a, 1b and 1c provided in the first rotary part 310, the guide member 313 ). That is, the release preventing member 360 is not in contact with the first to third vials 1a, 1b, and 1c when the second rotation unit 320 is lowered.

In contrast, when the lowered second rotating part 320 is lifted, the release preventing member 360 is rotated on the guide member 313 to move the bottlenecks of the first to third vials 1a, 1b, 1c You can walk around the site.

The first to third vials 1a, 1b and 1c hung on the other end of the separation preventing member 360 are separated by the separation preventing member 360 from the upward movement of the second rotation part 320 And can be stably received in the groove 312 without being raised along the first needle 333c or the second needle 343c raised together with the second needle 333c.

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.

Therefore, the scope of the present invention should not be limited by the described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

100: Automated radiopharmaceutical dispensing system with sterile filter test
200: Radiopharmaceuticals supply unit 210: First supply pipe
300: radiopharmaceutical dispensing part 310: first rotating part
320: second rotating part 330: radioactive medicine discharging part
331: first fixing bracket 332: first supporting bracket
333: first scanning unit 340:
341: second fixing bracket 342: second supporting bracket
343: second scanning unit 400: gas supply unit
410: second supply pipe 500: valve part
510: three way valve 520: support bar
530: Rotating unit 540: Feeding unit
1a, 1b, 1c: vials

Claims (15)

A radiopharmaceutical supply unit 200;
A radiopharmaceutical dispenser 300 for receiving the radiopharmaceuticals from the radiopharmaceuticals supply unit 200 and dispensing the radiopharmaceuticals;
A gas supply unit 400 for supplying a compressed gas to the radiopharmaceutical dispenser 300; And
The radiopharmaceutical dispenser 300 is connected to the radiopharmaceutical dispenser 200 through a first supply pipe 210 and is connected to the gas supply unit 400 through a second supply pipe 410, And a valve unit (500)
The radiopharmaceutical dispenser 300 includes an index table T; A first rotation part 310 rotatably provided on the index table T and mounted with a plurality of vials; And a radiopharmaceutical dispenser (330) disposed on the upper side of the first rotating part (310) for injecting the radiopharmaceutical supplied from the radiopharmaceutical supply part (200) into at least one of the plurality of vials,
The radiopharmaceutical discharge unit 330 includes a first cylinder 333a connected to the transfer tube 3; A filter 333b provided in the first cylinder 333a; And a first needle 333c that is supplied through the transfer tube 3 and injects the radioactive medicine that has passed through the filter 333b into any one of the plurality of vials,
When supplying the radiopharmaceutical to the radiopharmaceutical dispenser 300 from the radiopharmaceutical supply unit 200, the valve unit 500 communicates the first supply pipe 210 and the transfer pipe 3 with each other, The communication between the second supply pipe 410 and the transfer pipe 3 is blocked,
When the bubble point test is performed on the filter 333b of the radiopharmaceutical dispenser 330 after the radiopharmaceutical dispensing operation by the radiopharmaceutical dispenser 300 is completed, The first supply pipe 410 and the transfer pipe 3 are communicated with each other and the communication between the first supply pipe 210 and the transfer pipe 3 is blocked so that the gas is supplied from the gas supply unit 400 A compressed gas is applied to the filter 333b of the radiopharmaceutical discharge unit 330 through the transfer pipe 3,
Wherein the first needle (333c) is inserted into any one of the plurality of vials when the compressed gas is applied to the filter (333b).
delete The method according to claim 1,
The valve unit 500 includes:
A three-way valve (not shown) for selectively interrupting a flow path through which the first supply pipe 210 and the transfer pipe 3 communicate with each other and a flow path through which the second supply pipe 410 and the transfer pipe 3 communicate with each other, (3 way valve, 510); And
And a first drive motor (532) for driving the three-way valve (510).
The method of claim 3,
The valve unit 500 includes:
A support bar 520 for supporting the three-way valve 510;
A body 531 disposed above the supporting bar 520 and having the first driving motor 532 mounted on one side thereof;
And a gripping piece (533) mounted on the other side of the body (531) and rotated by receiving power from the first driving motor (532)
And the gripping part (533) forms a space part in which the upper part of the three-way valve (510) is received.
5. The method of claim 4,
The three-way valve 510 is provided along the longitudinal direction of the support bar 520,
Wherein the body (531) is movable along the longitudinal direction of the support bar (520).
6. The method of claim 5,
The valve unit 500 further includes a transfer unit 540 for transferring the body 531 along the longitudinal direction of the support bar 520,
The transfer unit 540,
A second driving motor 542 mounted on one side of the supporting bar 520;
And a transfer rod (542) receiving power from the second driving motor (542) and connected to the body (531), the sterilization filter (333b) being capable of testing the radiopharmaceutical dispensing system.
The method according to claim 1,
The radiopharmaceutical dispenser 300 may further include a second rotation part 320 provided on the index table T so as to be rotatable and capable of ascending and descending and on which the radiopharmaceutical dispenser 330 is mounted,
The radiopharmaceutical dispenser 330 includes a first fixing bracket 331 coupled to a circumferential surface of the second rotator 320 and interlocked with rotation and up / down movement of the second rotator 320; And a first support bracket (332) connected to the first fixing bracket (331) and to which the first cylinder (333a) is mounted,
The radiopharmaceutical dispenser (330) is provided with a plurality of the radiopharmaceutical dispensers (330) along the circumferential direction of the second rotating part (320). delete delete delete delete delete delete delete delete

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