JPH056159B2 - - Google Patents

Description

Detailed Description of the Invention (Field of Industrial Application) The present invention relates to a vial shielding device with a radioactivity measuring device, particularly a vial shielding device that is capable of shielding radioactivity and knowing the amount of radioactivity of a solution present in a vial. This invention relates to a vial shield device with a radioactivity measuring device.

(Prior Art) 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, remove the vial from the vial shield container, measure the current amount of radioactivity in the vial using, for example, a Curie meter, and take precautions to avoid exposure. After storing the vial in the vial shield container again, the vial was taken out with a rough guide using a syringe. Then, in order to check whether the amount of radioactivity dispensed into the syringe is the prescribed amount, it is measured with a Curie meter.If it is too much or insufficient, it is returned to the vial or taken out, and the prescribed amount of radioactivity is measured again with the Curie meter. When I measured whether it was being dispensed, I was repeatedly performing the same task.

(Problem to be Solved by the Invention) However, in this conventional method of dispensing a predetermined amount of radioactivity into a syringe, the vial is removed from the vial shield container and the radioactivity amount is measured, and the predetermined amount of radioactivity is The disadvantage of having to measure the amount of radioactivity many times with a Curiemeter to dispense it into a syringe was that it was done thousands of times a day, resulting in exposure to radioactivity. 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 container and measured, which is time consuming and troublesome work. was.

The purpose of the present invention is to solve the above-mentioned drawbacks, by embedding a radioactivity measuring device in the vial shield container and displaying the indicator on the surface of the vial shield container. The purpose of the present invention is to provide a vial shield device with a radioactivity measuring device that can display the radioactivity amount of a solution and dispense the required amount of radioactivity into a syringe without removing the vial from the vial shield container. There is.

(Means for Solving the Problems) Therefore, the vial shielding device with a radioactivity measuring device of the present invention is a hollow radioactivity shielding material having a syringe needle inlet and a structure in which a vial is housed. A container body formed of a container body, a window formed of a radioactivity shielding material on the side of the container body, a radioactivity measuring device embedded in the container body, and a radiation measuring device that measures radioactivity. The present invention is characterized by comprising a display provided on the surface of the container body that displays the amount of radioactivity.

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

(Example) Fig. 1 is an external perspective view of a vial shield device with a radioactivity measuring device according to the present invention, Fig. 2 is a vertical sectional view, and Fig. 3 is a view taken along the line A-A in Fig. 2. FIG. 4 shows another shape of the buried radioactivity detector, and FIG. 5 shows the circuit configuration of one embodiment of the radioactivity measuring device.

In FIGS. 1 to 3, a container body 1 is a container 4 having a hollow part 3 for storing a vial 2.
and a bottom container 5 for fixing the vial 2 in a predetermined position of the container 4. Inside the container 4, a cylindrical body 41 is formed of a radiation shielding material, for example, a material with high specific gravity such as lead, and a part of the cylinder 41 is made of a material with a high specific gravity such as lead.
As shown in FIGS. 3 and 3, a radioactivity detector 6 for detecting the amount of radioactivity and a molded electric circuit section 7 are fitted. The radioactivity detector 6 is fitted into the cylindrical body 41 along the side surface of the vial 2. A mouth hole 8 into which the mouth of the vial 2 is inserted is provided at the upper end of the container 4, and an upper plate 10 made of stainless steel is provided on the uppermost surface of the mouth hole 8 in which a syringe needle inlet 9 is bored. A window is provided on the side of the container 4. A transparent glass material such as lead glass 11 that shields radioactivity is fitted into the window, and the lead glass 11
The amount of solution remaining in the vial 2 can be visually checked through the window. The lead glass 11
In order to clarify the existence of the window, it is drawn in a different position in Figures 1 and 3. The surface of the container 4 is covered with a synthetic resin material 14 to cover the molded electric circuit part 7 and the lead of the cylindrical body 41, and a display 12 is placed in a part thereof so that it can be seen from the outside as shown in FIGS. 1 and 3. It is buried in Note that there is a protrusion 2 at the lower end of the container 4 to facilitate attachment and detachment from the bottom container 5.
3 is provided and engages with a recess provided in the bottom container 5 to constitute a mechanism for attaching and detaching the container 4 and the bottom container 5. Inside the bottom container 5, a cylindrical body 51 is formed of a radioactivity shielding material, such as lead, for shielding radioactivity. A spring 13 is installed to fix the vial 2. By installing the spring 13, the vial 2 can be moved into the container 4 according to the arbitrary length of the vial 2.
It can be fixed inside. This spring 13
Needless to say, a spacer may be used instead. Further, if the container 4 is for a fixed-length vial 2, the spring 13 is not necessarily required, and the bottom container 5 can directly fix the vial 2.

Similar to the container 4, the outside of the cylinder 51 is covered with a synthetic resin material 14 to maintain aesthetic appearance.
Although the synthetic resin material 14 of the container 4 and the bottom container 5 is not necessarily required, it is provided from the above-mentioned aesthetic point of view. Although it is possible to further improve the aesthetic appearance by painting the surface of the synthetic resin material 14, painting is not always necessary.

Note that 15 is a zero adjustment screw for the display 12, 16 is a calibration for the display 12, and 17 is a button battery.

FIG. 5 shows the configuration of an embodiment of the radioactivity measuring device buried in the container 4, and reference numerals 6, 7, and 12 correspond to those in FIGS. 1 to 3. Reference numeral 18 represents a scintillator, 19 a photodetector, 20 an amplifier, and 21 an analog-to-digital converter.

The scintillator 18 and photodetector 19 described above are embedded as the radioactivity detector 6, and the amplifier 20 and analog-digital converter 21 are embedded as the electric circuit section 7 in the side wall of the cylindrical body 41. The display 12 shown in FIG. 5 is also embedded in the synthetic resin material 14 of the container 4 so that the display can be seen from the outside, as explained in FIGS. 1 to 3.

A brief explanation of the operation in FIG. 5 is as follows. That is, when the vial 2 containing a radioactive solution is inserted into the hollow part 2 of the container body 1, the radioactivity in the vial 2 is emitted from the side and bottom surfaces of the vial 2. This radioactivity is detected by the scintillator 18 in the radioactivity detector 6, and the scintillator 18 generates photons corresponding to the amount of radioactivity. The photons generated from the scintillator 18 are converted into electrical signals by the photodetector 19, amplified appropriately by the amplifier 20, and then converted into analog signals.
It is digitized by a digital converter 21. Then, it is digitally displayed on the display 12. Therefore, the current amount of radioactivity remaining in the vial 2 is digitally displayed on the display 12.

In general handling, a switch (not shown) provided on the side of the container 4 is turned on, and the current amount of radioactivity in the vial 2 is displayed on the display 12. Then, the needle of the syringe is inserted into the vial 2 through the injection needle inlet 9, and the necessary amount of radioactivity is injected into the syringe while watching the display on the display 12. The amount of radioactivity in the vial 2 after being injected into the syringe is displayed on the display 12, so the amount of radioactivity injected into the syringe can be seen, and the amount of radioactivity in the remaining liquid in the vial 2 can be seen on the display 12. At the same time, the amount of liquid remaining in the vial 2 can be visually confirmed through the window of the lead glass 11.

Note that the mechanism for attaching and detaching the container 4 and the bottom container 5 is the second one.
It goes without saying that the attachment and detachment is not limited to the one using the convex portion 23 shown in the figure, but may be made using other mechanisms, such as a screw mechanism.

Further, although the container 4 and the bottom container 5 can be attached and detached from the bottom side of the vial 2, they can also be attached and detached from the top side of the vial 2. In this case, the radioactivity detector 6 can be fitted into the position of the cylinder body 41 corresponding to the side surface of the vial 2 as shown in FIG. It is also possible to fit it into the position of the cylinder body 51 corresponding to the bottom of the vial bottle 2.

The above explanation has been about a scintillator-type radioactivity detector, but it is also possible to embed the radioactivity detector in the container body 1 in exactly the same way for a semiconductor-type radioactivity detector that can be further miniaturized. These also fall within the scope of the present invention.

In addition, although the appearance of the container body 1 becomes larger, it is also possible to embed an ionization chamber or a radiation measuring device using a Geiga-Mueller tube (GM tube) in the container body 1, and the present invention also applies to these. It belongs to the range.

(Effects of the Invention) As explained above, according to the present invention, the amount of radioactivity can be measured and displayed while the vial is placed in the vial shield container. (1) Inserting and removing the vial from the vial shield container There is no need to do so, and there are fewer opportunities to be exposed to radioactivity.

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

(3) Regardless of the half-life of the radioactive substance, the current amount of radioactivity is displayed, making it easier to inject the necessary amount of radioactivity into the syringe.
Also, the amount of radioactivity remaining in the vial can be known at a glance.

There are advantages such as:

[Brief explanation of the drawing]

Fig. 1 is an external perspective view of a vial shield device with a radioactivity measuring device according to the present invention, Fig. 2 is a vertical cross-sectional view, Fig. 3 is a view taken along arrow A-A in Fig. 2, and Fig. 4 is a buried Another shape diagram of the radioactivity detector shown in FIG. 5 shows the circuit configuration of an embodiment of the radioactivity measuring device. In the figure, 1 is the container body, 2 is the vial, 3 is the hollow part, 4 is the container, 5 is the bottom container, 6 is the radioactivity detector, 7 is the electric circuit, 9 is the injection needle inlet, 10 is the top board, 11 is lead glass, 12 is a display, 13 is a spring, 17 is a button battery, 22 is a radioactivity detector, 4
1 represents a cylindrical body, and 51 represents a cylindrical body.

Claims (1)

[Scope of Claims] 1. A container body formed of a hollow radioactive shielding material and provided with a syringe needle inlet and a structure in which a vial is housed, and a radioactive shielding material on the side surface of the container body. a window made of wood, a radioactivity measuring device embedded in the container body, and an indicator provided on the surface of the container body for displaying the amount of radioactivity measured by the radioactivity measuring device. A vial shielding device with a radioactivity measuring device, characterized by comprising: