KR101358749B1 - Measuring instrument and method of radiopharmaceutical synthesis yield - Google Patents

Abstract

The present invention relates to a radiopharmaceutical synthesis yield meter, the radiopharmaceutical synthesis yield meter of the present invention, the housing; A mounting part coupled to the housing and mounted with a thin film on which radiopharmaceuticals are deployed; A measurement unit installed inside the housing and measuring a synthetic yield of radiopharmaceuticals deployed in the thin film; An output unit for outputting a measured value of the synthetic yield measured by the measuring unit; And a controller for controlling the output unit to output the measured value.
According to the present invention, the measuring part including a sensor capable of measuring the radiopharmaceutical synthesis yield is fixed, and the mounting part equipped with a thin film on which the radiopharmaceuticals are deployed moves to measure the synthetic yield of radiopharmaceuticals, so that the movement of the sensor may occur. There is an effect that can minimize the error that can be.

Description

Radiopharmaceutical Synthetic Yield Meter and Method of Measurement {MEASURING INSTRUMENT AND METHOD OF RADIOPHARMACEUTICAL SYNTHESIS YIELD}

The present invention relates to a radiopharmaceutical synthesis yield measuring device and a measuring method, and more particularly, to a meter and a measuring method for measuring the synthetic yield of the synthesized radiopharmaceuticals.

Radiopharmaceuticals are synthesized by reacting a mixture of radioisotopes and reagents. Representative examples of such radiopharmaceuticals include radiopharmaceuticals used for positron emission tomography, and in order to synthesize radiopharmaceuticals, radioisotopes generated from cyclotrons are synthesized by labeling precursors.

As described above, since radiopharmaceuticals contain radioisotopes, if the radioisotopes contained in radiopharmaceuticals to be administered to the patient are unnecessarily high, they may be rather dangerous for the patient.

When synthesizing radiopharmaceuticals, unlabeled radioisotopes do not serve as drugs, so it is necessary to identify the proportion of radioisotopes normally synthesized in radiopharmaceuticals so that unnecessary radioisotopes are not administered to patients.

In addition, radiopharmaceuticals use isotopes with short half-lives to minimize their impact on patients, which require rapid verification as the amount of radioactivity continues to decrease after production is complete.

Therefore, TLC (thin-layer chromatography) technique is used to perform this verification procedure. The TLC technique is a method in which a fine particle carrier having a certain polarity is uniformly applied to a fixed support, and a suitable solvent is used as a mobile phase. This is a chromatographic method in which a small amount of the separation material applied thereon is developed with a solvent, and each mixture is separated by polarity difference on the stationary phase.

The apparatus for measuring the ratio of labeled isotopes and unlabeled isotopes by scanning the developed support using the TLC technique as described above is called a radio-TLC scanner. The existing Radio-TLC scanner is a desktop-type device that is mounted in a certain space. It raises the TLC plate deployed on the device and measures the radiation distribution by placing a sensor on it. However, in the past, a plurality of sensors The radiation distribution was measured using a sensor array, or in the case of using one sensor, the sensor was moved to measure the radiation distribution according to the position.

Therefore, in order to use the existing Radio-TLC, a certain space or more is required, and there is a problem that there is a limitation of the used space because it cannot be used while moving. In addition, even in the case of portable equipment, there is a problem that an error occurs in the measured value due to the vibration generated by the movement of the sensor because the sensor moves to measure the radiation distribution. Moreover, even in the case of a radio-TLC scanner manufactured in a portable manner, there is a problem in that there is a limitation in use because the result check must be performed through a separate device such as a PC.

The present invention is to solve the above-described problems, the present invention can minimize the error that may occur in the sensor when measuring the synthetic yield of the radiopharmaceutical, and the measuring instrument and measurement that can reduce the size of the radiopharmaceutical synthesis yield measuring instrument The purpose is to provide a method.

In order to achieve this object, the radiopharmaceutical synthesis yield measuring device of the present invention comprises: a housing; A mounting portion movably coupled to the housing and mounted with a thin film on which radiopharmaceuticals are deployed; A measurement unit installed inside the housing and measuring a synthetic yield of radiopharmaceuticals deployed in the thin film; An output unit for outputting a measured value of the synthetic yield measured by the measuring unit; And a control unit for controlling the movement of the mounting unit, the operation of the measurement unit, and the output unit.

At this time, it is preferable that the cartridge is inserted into the mounting portion to prevent contamination of the radiopharmaceutical synthesis yield measuring device.

Preferably, the mounting portion moves in a direction substantially parallel to the thin film, and the measurement unit is preferably installed in the housing to be movable in a direction substantially perpendicular to the thin film.

In addition, the control unit may adjust the position of the measuring unit to adjust the distance between the measuring unit and the thin film according to the intensity of the radiation emitted from the radiopharmaceutical.

On the other hand, the radiopharmaceutical synthesis yield measuring method of the present invention in order to achieve this object, the first step of mounting a thin film on which the radiopharmaceutical is deployed; Moving the mounting unit; Measuring the synthetic yield of the radiopharmaceuticals developed in the thin film moving with the movement of the mounting unit; And outputting a measured value of the measured synthetic yield.

At this time, the thin film in the first step is inserted into the cartridge, it is preferable that the cartridge is mounted on the mounting portion, the mounting portion moved in the second step is preferably moved in a direction substantially parallel to the thin film.

And after step 1-1, adjusting the position of the measuring unit to adjust the distance between the measuring unit and the thin film measuring the synthetic yield of the radiopharmaceutical according to the intensity of the radiation emitted from the radiopharmaceutical. Can be.

According to the present invention, the measuring unit including a sensor capable of measuring the radiopharmaceutical synthesis yield is fixed, and the mounting part equipped with a thin film on which radiopharmaceuticals are deployed moves to measure the synthetic yield of radiopharmaceuticals, so that the sensor moves. There is an effect that can minimize the errors that can occur due to vibration or shock.

Furthermore, since the thin film on which the radiopharmaceutical drug has been developed is inserted into the cartridge, and the cartridge is mounted on the mounting part, the mounting part can be prevented from being contaminated with radioactivity due to the radiopharmaceutical.

In addition, since the sensor is fixed to measure the synthetic yield of the radiopharmaceuticals, there is almost no space for the sensor to move, thereby reducing the size of the radiopharmaceutical synthesis yield measuring device.

In addition, the position of the sensor can be shifted by several tens of millimeters according to the intensity of the radioisotope synthesized in the radiopharmaceutical. The measuring range can be adjusted to maximize the measuring range.

1 is a block diagram showing a radiopharmaceutical synthesis yield measuring instrument of the present invention.
Figure 2 is a schematic diagram showing a radiopharmaceutical synthesis yield measuring device of the present invention.
Figure 3 is a schematic diagram showing the radioactivity measurement of the cartridge with the thin film removed to confirm the degree of calibration and contamination of the initial state in the radiopharmaceutical synthesis yield measuring device of the present invention.

Preferred embodiments of the present invention will be described more specifically with reference to the accompanying drawings.

Referring to the drawings shown in Figures 1 to 3, the radiopharmaceutical synthesis yield measuring apparatus 100 of the present invention is the housing 110, the drive unit 120, the mounting unit 130, the measuring unit 140, the output unit and It is configured to include a controller 160.

As shown in FIG. 2, the housing 110 has a predetermined space formed therein. The mounting unit 130, the measuring unit 140, and the control unit 160 may be accommodated in the housing 110, respectively, and the outside of the housing 110 may display the result measured by the measuring unit 140. The output unit is installed.

The driver 120 is driven under the control of the controller 160 and is provided to drive the mounting unit 130. In an embodiment of the present invention, the drive unit 120 includes a motor, and the mounting unit 130 is connected to the mounting unit 130 by a rack gear (not shown) or the like, and the mounting unit 130 is moved by the driving of the motor.

The mounting unit 130 is coupled to move to the housing 110 and is moved according to the operation of the driving unit 120. In addition, the mounting portion 130 is provided with a mounting space in which a cartridge 132 into which a thin layer 134 into which radiopharmaceuticals are deployed is inserted can be mounted. The mounting unit 130 is automatically moved under the control of the control unit 160, and when the mounting space in which the cartridge 132 can be mounted is exposed to the outside by the movement of the mounting unit 130, the user may attach the cartridge to the mounting unit 130. 132 can be detached.

In addition, in addition to the thin film 134, if the sample can be deployed and mounted on the cartridge 132, any form may be mounted on the mounting unit 130 to measure the synthetic yield of the radiopharmaceutical.

In addition, the mounting unit 130 is automatically moved even when measuring the synthetic yield of radiopharmaceuticals or measuring whether the cartridge 132 is contaminated with radioactivity in the thin film 134 mounted on the mounting unit 130, and thus the entire cartridge 132. May be measured by the measuring unit 140.

The measuring unit 140 includes a radioactive sensor for measuring the ratio of radioisotope synthesized isotope and non-synthesized isotope in the radiopharmaceutical. When the cartridge 132 is mounted on the mounting unit 130 while the radiopharmaceutical is inserted into the cartridge 132 in the form of a thin film 134, the user can start measuring the synthetic yield of the radiopharmaceutical through the control unit 160. have. Then, the measuring unit 140 is a synthetic yield is measured for the entire radiopharmaceutical thin film 134 as the mounting unit 130 is moved in a fixed state.

At this time, the mounting portion 130 is moved in a direction substantially parallel to the thin film 134 inserted into the cartridge, where the direction substantially parallel, the distance between the thin film 134 and the measuring unit 140 is the measurement result It means the direction that does not change enough to affect. That is, the mounting unit 130 is moved in the horizontal direction, as shown in Figures 2 and 3, and measures the synthesis yield of the thin film according to the moving position of the mounting unit 130.

Here, the measuring unit 140 is synthesized according to the ratio of the separated portion by using the phenomenon that the synthesized solvent and the unsynthesized solvent are separated according to the polarity when the radiopharmaceutical is developed in the thin film 134 on which the radiopharmaceutical is deployed. Measure the yield.

In addition, the measuring unit 140 is installed inside the housing 110 to move about several tens of millimeters, and the movement of the measuring unit 140 may be moved in a direction substantially perpendicular to the thin film 134 as shown in FIGS. 2 and 3. Can be. The radiopharmaceuticals vary in the intensity of radioactivity as the amount of synthesized radioisotopes is high and low. When the intensity of radioactivity is high, the measuring unit 140 may be moved away from the cartridge 132, and the intensity of radioactivity is increased. In the weak case, the measuring unit 140 may be moved to approach the cartridge 132.

Since the intensity of the radioactivity decreases in inverse proportion to the cube of the distance, even if only the position of the measuring unit 140 is moved by several tens of millimeters, the effect on the distance movement is significantly increased. Accordingly, the distance that the measurement unit 140 can be moved will be enough to about tens of millimeters.

 Here, the direction substantially perpendicular to the thin film 134 means a direction in which the distance between the measuring unit 140 and the thin film 134 is closer and farther away.

In this case, when the measuring unit 140 is moved, it is preferable not to move while measuring the synthetic yield in the measuring unit 140 and to move only while not measuring the synthetic yield. This is because if the measuring unit 140 is moved while measuring the synthetic yield, an error may occur in the measured value due to the impact that may occur due to the movement of the measuring unit 140.

In addition, the movement of the measuring unit 140 may be configured to move by manual operation, and may be configured to automatically move under the control of the control unit 160 as necessary. When the measuring unit 140 is configured to move automatically, a motor for moving the measuring unit 140 may be separately provided. In this case, the motor is operated under the control of the controller 160.

The output unit is for displaying the measured value measured by the measuring unit 140 and is installed outside the housing 110. And in the embodiment of the present invention will be described for the case where the output unit is provided with a touch screen 150. Therefore, the measured value measured by the radiopharmaceutical synthesis yield measuring device 100 is displayed through the touch screen 150, the user can determine how much the synthetic yield of the radiopharmaceutical through it.

In addition, the user may control the radiopharmaceutical synthesis yield measuring device 100 by using the output unit provided as the touch screen 150. That is, in order to mount the cartridge 132 on the mounting unit 130, the mounting unit 130 must be moved so that the mounting space of the mounting unit 130 is exposed to the outside. The user inputs a command for this through the touch screen 150. can do.

In addition, although the position of the measuring unit 140 may be manually moved, when the automatic operation is possible, the position of the measuring unit 140 may be adjusted through the touch screen 150.

The controller 160 controls the mounting unit 130, the measuring unit 140, and the touch screen 150, respectively. When measuring the radiopharmaceutical synthesis yield of the control unit 160 is fixed so that the measuring unit 140 is not moved, the mounting unit 130 is moved so that the measurement unit 140 can measure the radiopharmaceutical synthesis yield. The measured value of the radiopharmaceutical synthesis yield measured by the measuring unit 140 is output through the touch screen 150.

In addition, in order to detach the cartridge 132 from the mounting unit 130, the mounting unit 130 may be moved so that the mounting space of the mounting unit 130 is exposed to the outside. In addition, the position of the mounting unit 130 or the measuring unit 140 may be controlled by receiving a user command input to the touch screen 150.

Here, even if the control unit 160 is configured to move the position of the measuring unit 140, it is to fix the position of the measuring unit 140 so that the measuring unit 140 is not moved during the measurement of the radiopharmaceutical synthesis yield desirable.

In addition, even when the cartridge 132 is mounted or not mounted on the mounting unit 130, the control unit 160 may measure the radioisotope in the measuring unit 140. In addition, in the state where the thin film 134 in which the radiopharmaceutical is developed is inserted or not inserted into the cartridge 132, the measuring unit 140 may preferably measure the radioisotope. This is to check whether the cartridge 132 or the mounting portion 130 is contaminated with radioactivity in a state where the radiopharmaceutical is not installed. Therefore, as shown in FIG. 3, in the state where the radiopharmaceutical thin film 134 is not inserted into the cartridge 132, the controller 160 controls the mounting unit 130 and the measuring unit 140 to measure the amount of radioisotope. Can be.

Looking at the method of measuring the radiopharmaceutical synthesis yield as described above, the user inserts the thin film 134, the radiopharmaceutical development is inserted into the cartridge 132 to mount the cartridge 132 to the mounting portion 130. When the user starts the measurement of the synthetic yield of the radiopharmaceutical through the touch screen 150, the controller 160 controls the driving unit 120 to move the mounting unit 130. When the mounting unit 130 moves, the measuring unit 140 measures the radiopharmaceutical synthesis yield in the thin film 134 on which the radiopharmaceutical is deployed.

The controller 160 receives the measured value measured from the measuring unit 140 and controls the measured value to be output to the touch screen 150. At this time, the mounting unit 130 is preferably moved in a direction substantially perpendicular to the measurement direction measured by the measuring unit 140.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It should be understood that the scope of the present invention is to be understood as the scope of the following claims and their equivalents.

100: radiopharmaceutical synthesis yield measuring instrument
110: housing 120: drive part
130: mounting portion 132: cartridge
134: thin film 140: measuring unit
150: touch screen 160: control unit

Claims (9)

housing;
A mounting portion movably coupled to the housing and mounted with a thin film on which radiopharmaceuticals are deployed;
A drive unit for moving the mounting unit from the housing;
A measurement unit installed inside the housing and measuring a synthetic yield of radiopharmaceuticals deployed in the thin film;
An output unit for outputting a measured value of the synthetic yield measured by the measuring unit; And
And a control unit controlling the driving unit to move the mounting unit, controlling the measuring unit to measure the synthetic yield of the radiopharmaceutical, and controlling the output unit to output the measured value. The method according to claim 1,
The radiopharmaceutical synthesis yield measuring device, characterized in that the mounting portion is a cartridge in which the thin film is inserted. The method according to claim 1,
And said mounting portion moves in a direction substantially parallel to said thin film. The method according to claim 1,
The measuring unit is a radiopharmaceutical synthesis yield measuring device, characterized in that installed in the housing to be movable in a direction substantially perpendicular to the thin film. The method according to claim 1,
The control unit is a radiopharmaceutical synthesis yield measuring device, characterized in that for adjusting the position of the measuring unit to adjust the distance between the measuring unit and the thin film according to the intensity of the radiation emitted from the radiopharmaceutical. Radiopharmaceutical synthesis yield measuring instrument including a housing, a mounting portion movably coupled to the housing, a driving unit for moving the mounting portion, a measuring unit for measuring the synthetic yield of radiopharmaceuticals and an output unit for outputting the measured value of the synthetic yield In the radiopharmaceutical synthesis yield measurement method,
A step 1 in which a thin film on which radiopharmaceuticals are deployed is mounted on the mounting unit;
Moving the mounting unit to a position where the measurement of the thin film can be made;
A three step of measuring the synthetic yield of the radiopharmaceuticals developed on the thin film moving in accordance with the movement of the mounting unit; And
A radiopharmaceutical synthesis yield measuring method comprising the step of outputting the measured value of the measured synthetic yield to the output unit. The method of claim 6,
The thin film in the first step is inserted into the cartridge, the radiopharmaceutical synthesis yield measuring method, characterized in that the cartridge is mounted on the mounting portion. The method of claim 6,
The mounting portion is moved in the step 2 radiopharmaceutical synthesis yield measuring method, characterized in that for moving in a direction substantially parallel to the thin film. The method of claim 6,
After the step 1 further comprises the step 1-1 of adjusting the position of the measuring unit to adjust the distance between the measuring unit and the thin film measuring the synthetic yield of the radiopharmaceutical according to the intensity of the radiation emitted from the radiopharmaceutical Radiopharmaceutical synthesis yield measuring method characterized in that.

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