JPH01245185A - Instrument for measuring radioactivity of solution in vial shield and vial shield used for said instrument - Google Patents

Abstract

PURPOSE:To measure the radioactivity quantity of a vial without taking the vial out of a vial shield by forming an engaging pin of a body shutter in such a manner that said pin engages with a hole provided to a vial shield shutter. CONSTITUTION:The vial shield 20 is imposed to a recess 2 of the columnar body 1 and a body shutter 5 having the engaging pin 6 is opened and closed in a vertical direction by a shutter handle 8. The vial shield 20 has the vial shield body 21 in which the vial is housed and which is formed of a radioactivity shielding material and the vial shield shutter 25 which has the hole 26 to engage with the engaging pin 6 provided to the body shutter 5 and is provided slidably in a vertical direction. A cap body 22 having an injection needle injection port is provided atop said shield. The vial shield shutter 26 is moved downward as well when the body shutter 5 moves downward. The radioactivity quantity of the vial is then measured by a radioactivity detector provided behind the body shutter 5 through the open part of the vial shield shutter 25.

Description

Detailed Description of the Invention [Industrial Application Field] The present invention relates to a radioactivity measuring device for a solution in a vial shield and a vial shield used in the device, and in particular, to measuring the radioactivity of a solution in a vial shield without taking out the vial from the vial shield. The present invention relates to a radioactivity measuring device for a solution in a vial shield that is capable of measuring the amount of radioactivity in a vial shield, and a vial shield that is most suitable for the device.

[Conventional technology]

In recent medical treatments, it has become increasingly popular to inject radioactive compounds into the human body and use the radioactivity concentrated in the affected area to investigate the disease state of the affected area.

To dispense the required amount of radioactivity from a vial into a syringe, the vial is removed from the vial shield, the current amount of radioactivity in the vial is measured using, for example, a Curie meter, and the vial is refilled to avoid exposure. After storing it in a vial shield, I used a syringe to roughly estimate it and then took it out. Then, to check whether the amount of radioactivity dispensed into the syringe is the predetermined amount, it is measured with a Curie meter. If it is too much or too little, it is returned to the vial or taken out, and the predetermined amount of radioactivity is dispensed with the Curie meter again. The team repeatedly performed tasks such as measuring whether the

[Problem to be solved by the invention]

However, in this conventional method of dispensing a predetermined amount of radioactivity into a syringe, it is necessary to remove the vial from the vial shield and measure the amount of radioactivity, and to dispense the predetermined amount of radioactivity into the syringe several times. Measurements using a Curie meter had the disadvantage of being exposed to radioactivity, as this was done dozens of times a day. Furthermore, radioactivity has a half-life, and the amount of radioactivity changes at that point, so each vial must be removed from the vial shield and measured, which takes time.
It was also a tedious task.

The present invention aims to solve the above-mentioned drawbacks,
It is an object of the present invention to provide a radioactivity measuring device for a solution in a vial shield that can measure the amount of radioactivity in a vial without removing the vial from the vial shield, and a vial shield used in the device.

[Means to solve the problem]

In order to achieve the above object, the apparatus for measuring radioactivity of a solution in a vial shield of the present invention includes a columnar body having a recess in the center on which the vial shield is placed, and a columnar body that is movable up and down in the recess. A main body shutter equipped with at least one or more engaging bins, a shutter opening/closing mechanism for vertically opening and closing the main body shutter, a radioactivity measuring device provided behind the main body shutter, and the radioactivity measuring device. It is equipped with a display that displays the amount of radioactivity measured by.

The recessed part of the main body where the vial shield is placed is
It is preferable that the mounting table is provided with a guide rail.

In addition, the vial shield has a structure in which a vial is stored inside, and has a guide groove on the bottom that is guided by a guide rail provided on the above-mentioned mounting table, and the vial shield body is made of radioactive shielding material. and a vial shield shutter, which is formed of a radioactive shielding material and is provided with a hole that engages with an engagement pin provided on the main body shutter, and is slidable in the vertical direction, on the side surface of the vial shield main body. , is provided with a syringe needle inlet on the upper surface and a lid body made of a radioactive shielding material.

[For production]

When the Rifle Shield, which stores the vial inside, is installed along the guide rail provided on the mounting table of the main body, the engagement pin of the main body shutter engages with the hole provided in the vial shield shutter. match. When the main body shutter moves downward, the via and shield shutters are also moved downward. Via the open portion of the vial shield shutter, the amount of radioactivity in the vial is measured by a radioactivity detector provided behind the main body shutter.

An embodiment of the present invention will be described below with reference to the drawings.

〔Example〕

Fig. 1 is a perspective view of an embodiment of a radioactivity measuring device for a solution in a vial shield according to the present invention, Fig. 2 is a perspective view of an embodiment of a vial shield used in the device, and Fig. 3 is a bottom portion of the vial shield. 4 is a sectional view taken along the line A-A in FIG. 1 when the vial shield is installed; FIG. 5 is a partial sectional view taken along the line B-B in FIG. 4; FIG. 6 shows the circuit configuration of an embodiment of the radioactivity measuring device used in the present invention.

1 to 5, a cylindrical main body 1 is provided with a recess 2 in the center thereof in which a vial shield 20 is placed. A mounting table 3 on which the vial shield 20 is placed is provided below the recessed portion 2, and a guide rail 4 is provided on the mounting table 3. A main body shutter 5 is disposed at the end of the guide rail 4 so as to be movable up and down.

A claw portion 5a is provided at the lower end of the main body shutter 5, and the claw portion 5a allows the shutter on the vial shield side, which will be described later, to be opened. Further, two engaging pins 6 are provided on the surface of the main body shutter 5. A shutter groove 7 for allowing the main body shutter 5 to move downward is bored inside the mounting table 3,
A shutter handle 8 is provided on the right side body 1 of the recessed portion 2. By pushing the shutter handle 8 downward, the main body shirt and
The structure is such that the lever 5 moves downward.

For example, it is a mechanism in which the shutter handle 8 and the main body shutter 6 are connected by a connecting rod, so that the shutter handle 8 and the main body shutter 6 are interlocked. Behind the main body shutter 5, a radioactivity detector 9 for detecting the amount of radioactivity is arranged along the main body shutter 5, and behind it, the output of the radioactivity detector 9 is appropriately amplified and subjected to predetermined electrical processing. An electric circuit section 10 is arranged.

A display 11 for displaying the amount of radioactivity detected by the radioactivity detector 9 is provided at the top of the main body l.

Note that 12 and 13 are shielding members for shielding radioactivity.

On the other hand, the vial shield 20 installed on the mounting table 3 of the main body 1 is composed of a vial shield main body 21 and a lid body 22 made of a radioactive material such as lead.

The vial shield main body 21 has a cylindrical shape with a bottom surface, and has a structure in which a vial is housed in the center thereof. A notch 23 is provided on the side surface of the vial shield body 1, and guide grooves 24 are provided on both end surfaces of the notch 23, respectively. The guide groove 2
4, a vial shield shutter 25 is slidably inserted therein. Needless to say, the vial shield shutter 25L is made of a radioactive shielding material, such as lead. On the surface of the vial shield shutter 25, there are two engaging pins 6 provided on the main body shutter 5 described above.
Holes 26 are bored at positions where they are respectively engaged.

The hole 26 is for sliding the vial shield shutter 25 in response to the vertical movement of the main body shutter 5, and the vial shield shutter 25 has a function of shielding radioactivity. It is a hanging hole and does not go through.

A lid body 22 is provided at the upper end of the vial shield body 21, and the vial shield body l is provided through the lid body 22.
A vial is placed inside.

When a vial is housed in the vial shield main body l, by sliding the vial shield shutter 25 downward, the vial can be viewed directly through the opened notch 23.

A circular recess 27 is provided on the outer bottom surface of the vial shield main body l, and a slide plate recess 2 is provided in the circular recess 27.
8 is provided. A slide plate 29 and a spring 30 that is engaged with a protrusion 29a provided on the slide plate 29 are fitted into the slide plate recess 28, and a bottom plate 31 is inserted into the circular recess 27 by screws (not shown). is fixed.

Normally, the elastic force of the spring 30 causes the slide plate 29 to pop out to the position of the vial shield shutter 25, thereby functioning as a stopper. When the end surface of the slide plate 29 facing the vial shield shutter is pushed, the slide plate 29 moves backward and the vial shield shutter 25 becomes slidable.

When the bottom plate 31 is fixed in the circular recess 27, the bottom plate 31 and the bottom edge 20a of the main body are configured to be on the same plane, and the bottom plate 31 and the bottom edge 20a of the main body have the above-mentioned Guide grooves 32 and 33 guided by guide rails 4 provided on the mounting table 3 of the main body 1 are provided in a straight line at a central position passing through the vial shield shutter 25.

A vial (not shown) containing a radioactive drug solution is housed in the vial shield main body 21 having such a configuration. The vial shield 20 containing the vial is placed on the mounting table 3 of the main body 1, and the guide grooves 32 and 33 provided on the bottom of the vial shield 20 are aligned with the guide rails 4 provided on the mounting table 3. and slide the vial shield 20 toward the main body shutter 5 side to install it. The claw portion 5a provided at the lower end of the main body shutter 5 comes into contact with the end surface of the claw portion 5a of the slide plate 29 provided on the bottom surface of the vial shield 20, causing the slide plate 29 to retreat.

By retreating the slide plate 29, the vial shield 20
The vial shield shutter 25 provided in the vial shield shutter 25 becomes slidable. At this time, two engaging pins 6 provided on the main body shutter 5 are respectively engaged with holes 26 provided on the vial shield shutter 25, and the vial shield shutter 25 also moves in accordance with the vertical movement of the main body shutter 5.

When the shutter handle 8 is pushed down, the main shutter 5 connected to the shutter handle 8 is lowered, and the pie-arcino shutter 25 is also lowered accordingly. When the shutter handle 8 is pushed down to the lowest position and stopped at the hook position, both the main body shutter 5 and the vial shield shack 25 are fully opened, and the vial shield 20
The vial housed inside directly faces the radioactivity detector 9. Thereby, the amount of radioactivity of the radioactive drug solution in the vial can be measured with the circuit configuration shown in FIG.

That is, in FIG. 6, numerals 9, 10, 11 correspond to those explained in FIGS. 1 to 5, 35 is a scintillator, 36 is a photodetector, 37 is an amplifier, and 38 is an analog-digital converter. It represents.

As described above, radioactivity is emitted from the side surface of the vial housed in the vial shield 20 to the radioactivity detector 9. This radioactivity is absorbed by the scintillator 3 in the radioactivity detector 9.
5, and the scintillator 35 generates photons corresponding to the amount of radioactivity. This scintillator 3
The photons generated from 5 are converted into electrical signals by a photodetector 36, amplified appropriately by an amplifier 37, and then converted into analog signals.
It is digitized by a digital converter 38. Then, it is digitally displayed on the display 11.

When the measurement is completed, the shutter handle 8 is removed from the hook position and is returned to its original uppermost position by the elastic force of a spring (not shown). As a result, the main body shutter 5 returns to its original height position, and therefore the vial shield 20
The vial shield shutter 25 is also returned to its original position and closed. When the vial shield 20 is taken out from the main body 1, the slide plate 29 provided on the bottom of the vial shield 20 moves forward to the position of the vial shield shack 25 due to the elastic force of the spring 30, and the slide plate 29 is moved forward to the position of the vial shield shack 25, and the slide plate 29 is moved forward to the position of the vial shield shack 25 by the elastic force of the spring 30. Become.

〔Effect of the invention〕

As explained above, according to the present invention, the amount of radioactivity can be measured while the vial is placed in the vial shield. (1) There is no need to take the vial in and out of the vial shield, thereby reducing exposure to radioactivity. There will be fewer opportunities.

(2) When measuring the amount of radioactivity, there is no need to take out each vial from the vial shield, improving measurement efficiency.

[Brief explanation of the drawing]

Fig. 1 is a perspective view of an embodiment of a radioactivity measuring device for a solution in a vial shield according to the present invention, Fig. 2 is a perspective view of an embodiment of a vial shield used in the device, and Fig. 3 is a bottom portion of the vial shield. 4 is a sectional view taken along the line A-A in FIG. 1 when the vial shield is installed; FIG. 5 is a partial sectional view taken along the line B-B in FIG. 4; FIG. 6 shows the circuit configuration of an embodiment of the radioactivity measuring device used in the present invention. In the figure, 1 is the main body, 2 is the recessed part, 3 is the mounting table, 4 is the guide rail, 5 is the main body shutter, 5a is the claw part, 6 is the engagement pin, 8 is the handle, and 9 is the radioactivity. detector, 10
11 is an electric circuit section, 11 is a display, 20 is a vial shield, 21 is a vial shield body, 22 is a lid body, 24 is a guide groove, 25 is a nominal shield shutter, 29 is a slide plate, 30 is a spring, 31 is a In the bottom plate, 32 and 33 are guide grooves, 35 is a scintillator, 36 is a photodetector, 37 is an amplifier, and 38 is an analog-to-digital converter. Figure 1 Figure 2 Figure 3 Figure 6UA

Claims (1)

[Claims] 1. A column-shaped main body having a recess in the center on which a vial shield is placed, and at least one engagement pin movable up and down in the center of the recess. A main body shutter, a shutter opening/closing mechanism that opens and closes the main body shutter in the vertical direction, a radiation measuring device provided behind the main body shutter, and a display that displays the amount of radioactivity measured by the radiation measuring device. A radioactivity measurement device for the solution in a vial shield, which is equipped with a container. 2. The apparatus for measuring radioactivity of a solution in a vial shield according to claim 1, wherein the recessed portion of the main body on which the vial shield is placed is provided with a guide rail on its mounting table. 3. A vial shield main body formed of a radioactive shielding material, which has a structure in which a vial is stored, and has a guide groove on the bottom surface that is guided by a guide rail provided on the mounting table, and the vial On the side of the shield body, there is a vial shield shutter made of radioactive shielding material and equipped with a hole that engages with an engagement pin provided on the body shutter, and is slidable in the vertical direction, and an injection shield on the top surface. A vial shield including a needle injection port and a lid made of a radioactive shielding material.