KR101241110B1 - Glass Dosimeter Calibration Phantom - Google Patents

Abstract

The present invention relates to a glass dosimeter radiation dose measurement phantom used to measure the radiation dose of the glass dosimeter used for radiation therapy, the glass dosimeter radiation dose measurement phantom according to the present invention, from one side to the center A base plate having an opening formed therein and a guide rail formed along both sides of the opening; A cartridge having both ends slidably coupled to the inside of the opening while sliding along the guide rail portion, the cartridge having a size and shape corresponding to that of the glass dosimeter, and having a cylindrical dosimeter insertion hole into which the glass dosimeter is inserted; Both end portions of the cartridge mounted on the base plate slide along the guide rails of the base plate to be detachably coupled to the inside of the opening, including a stopping plate (stopping plate) for close contact with the inside of the opening Characterized in that.

Description

Glass Dosimeter Calibration Phantom {Glass Dosimeter Calibration Phantom}

The present invention relates to a phantom for measuring a radiation dose of a glass dosimeter, and more particularly, to a phantom used for measuring a radiation dose of a glass dosimeter used for external radiation therapy and proximity radiation therapy.

In general, there are surgical methods and radiation therapy to treat prostate cancer. However, with the development of medical science, it is reported that radiation therapy is equivalent or more effective than the above-described surgical methods, and radiation is being used for the treatment of prostate cancer.

However, the treatment of prostate cancer using radiation has its own effects, but when radiation is applied to healthy tissues around the tumor, the site is exposed to radiation and causes a very serious side effect. Therefore, minimizing the irradiation of healthy tissues around the tumor with appropriate treatment plan and monitoring the direct and indirect doses to healthy tissues are very important items in the treatment of prostate cancer using radiation and it has been studied continuously. to be.

Radiation therapy for prostate cancer is divided into external radiation therapy that irradiates high energy radiation from the outside and close radiation therapy where relatively low energy isotope is inserted into the human body.

External radiation therapy is the most common method of focusing radiation on high-energy radiation from 6 MeV to 15 MeV, using CT planning data, and focusing on the local area where cancer cells are located inside the human body. Radiation therapy. Proximity radiotherapy has the principle of injecting a seed containing a radioisotope, an isotope, in the prostate gland and near the tumor, so that the isotope can intensively destroy the cancerous tissue of the tumor. The radiation treatments described above are particularly useful for patients who have difficulty in surgery due to old age or heart disease, and are receiving attention as a treatment that improves the quality of life of patients because they can be treated without experiencing urinary incontinence or erectile dysfunction. .

For the best radiation treatment, it is very important to measure whether radiation is irradiated to the body organs and cancer cells with the same radiation as the treatment plan. To this end, a radiation dose was measured by inserting a thermoluminescence dosimeter into a phantom having a density similar to that of the body, and emitting a brachytherapy radiation to the phantom to measure the response of the thermofluorescence dosimeter.

Recently, however, the frequency of using glass dosimeters, which are next-generation dosimeters, replaces thermofluorescence dosimeters, but the glass dosimeters are cylindrical and cannot be used in phantoms using conventional rectangular dosimeters. There is.

The present invention is to solve the above problems, an object of the present invention is to provide a phantom for measuring the radiation dose of the glass dosimeter, which can measure the accurate radiation dose using the glass dosimeter.

In order to achieve the above object, the present invention, in the glass dosimeter radiation dose measurement phantom used for measuring the radiation dose of the glass dosimeter used for radiation therapy, an opening is formed from one side to the center, A base plate having guide rails formed on both sides of the opening; A cartridge having both ends slidably coupled to the inside of the opening while sliding along the guide rail portion, the cartridge having a size and shape corresponding to that of the glass dosimeter, and having a cylindrical dosimeter insertion hole into which the glass dosimeter is inserted; Both end portions of the cartridge mounted on the base plate slide along the guide rails of the base plate to be detachably coupled to the inside of the opening, including a stopping plate (stopping plate) for close contact with the inside of the opening It provides a glass dosimeter phantom for measuring radiation dose.

According to one embodiment of the present invention, a plurality of cartridges are inserted into and coupled to the opening of the base plate, and each of the cartridges is characterized in that a spacer for adjusting the distance between the cartridges is arranged.

In addition, the guide rail portion of the base plate is made of a '' 'groove formed along both sides of the opening of the guide plate, the side of the cartridge and the stopping plate is formed in the guide portion is inserted into the guide rail guide grooves Can be.

In addition, an alignment mark for setting the irradiation position may be displayed on the base plate.

According to the present invention, since the glass dosimeter made of a cylindrical is almost fitted into the dosimeter insertion hole of the cartridge, the air gap is hardly generated, so that accurate radiation dose measurement can be made.

In addition, since the cartridge on which the glass dosimeter is mounted is easily attached to and detached from the base plate by sliding, it is possible to obtain a very convenient advantage.

1 is an exploded perspective view of a phantom for measuring a radiation dose of a glass dosimeter according to an embodiment of the present invention.
2 is a plan view of the phantom for measuring the radiation dose of the glass dosimeter shown in FIG.
3 is a longitudinal cross-sectional view of main parts of the phantom for measuring the radiation dose of the glass dosimeter shown in FIG. 1.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the glass dosimeter radiation dose measurement phantom according to the present invention.

1 to 3, the glass dosimeter radiation dose measurement phantom according to a preferred embodiment of the present invention is a base plate 10, a plurality of cartridges 20 detachably coupled to the base plate 10 And a stopper plate 40 detachably coupled to the base plate 10 in a state in which the spacer 30 and the cartridge 20 and the spacer 30 are coupled to the base plate 10. The base plate 10, the cartridge 20, the spacer 30, and the stopping plate 40 are all made of a synthetic resin material such as acrylic having a density similar to that of the human body.

The base plate 10 is made of a square flat plate, and has a structure in which an open portion 11 of a rectangular shape is opened from one side portion to a center portion. Guide rails 12 are formed at both sides of the opening 11. In this embodiment, the guide rail portion 12 is composed of a 'c'-shaped groove formed along both sides of the opening (11).

The base plate 10 may be made of a single body, but may be made by joining a plurality of flat pieces.

The cartridge 20 is formed of a rectangular bar having the same thickness as the base plate 10, is inserted into the opening 11 of the base plate 10 is coupled. On both sides of the cartridge 20, guide portions 22 are inserted and guided into the grooves of the guide rail portions 12.

In addition, the cartridge 20 is formed to penetrate a plurality of cylindrical dosimeter insertion holes 21 into which the cylindrical glass dosimeter 50 is inserted. The dosimeter insertion hole 21 has a size slightly larger than the size of the glass dosimeter 50, and is made of the same cylindrical shape as the glass dosimeter 50 through the one end of the dosimeter insertion hole 21. The dosimeter insertion hole 21 is inserted to fit snugly. As such, when the glass dosimeter 50 is almost fitted into the dosimeter insertion hole 21 of the cartridge 20, an air gap does not occur between the dosimeter insertion hole 21 and the glass dosimeter 50. Accurate radiation dose measurements can be made.

The spacer 30 is formed of the same rectangular bar as the cartridge 20 and inserted into the opening 11 of the base plate 10 to be coupled thereto. Guide portions 32 that are inserted into and guided inside the grooves of the guide rail portion 12 are formed on both side edge portions of the spacer 30. It is disposed between the cartridge 20 to adjust the spacing and position between the cartridge 20, the spacer 30 may have the same width as the cartridge 20, but differently cartridge 20 It can have a different width than).

The stopping plate 40 is coupled to the inside of the opening 11 in a state in which the cartridge 20 and the spacers 30 are mounted inside the opening 11 of the base plate 10. By adhering the cartridge 20 to the inside of the opening 11, the air gap between the cartridge 20 and the spacers 30 is prevented from being generated and the cartridges 20 and the spacers 30 are opened. ) It keeps its position by fixing it inside. At both ends of the stopping plate 40, guide parts 42 are inserted into the guide rails 12 of the base plate 10 and slide therein.

The stop plate 40 may be formed with a handle 44 so that the operator can easily hold and handle by hand.

Meanwhile, alignment marks M1, M2, and M3 for setting the irradiation position are displayed on the upper surfaces of the base plate 10 and the stopping plate 40. Here, the alignment mark is represented by a 10 × 10 cm square at the center of the base plate 10, and an irradiation area display line M1 at which the cartridges 20 are located, and the irradiation area display line. It consists of phantom position alignment display lines M2 extending from each center of M1 in all directions. Height-aligned display lines M3 for setting the height with the irradiation apparatus are also displayed on each side of the base plate 10.

Referring to the operation of the glass dosimeter radiation dose measurement phantom configured as described above are as follows.

The operator inserts the glass dosimeter 50 into the dosimeter insertion hole 21 through one end of each dosimeter insertion hole 21 of the cartridge 20. Then, the cartridges 20 and the spacers 30 on which the glass dosimeters 50 are mounted are alternately inserted into the opening 11 of the base plate 10 one by one. At this time, the guide portions 22 formed at both ends of the cartridge 20 and the guide portions 32 formed at both ends of the spacers 30 are inserted into the grooves of the guide rail portion 12 of the base plate 10. When sliding, the cartridges 20 and the spacers 30 are easily mounted inside the opening 11 of the base plate 10.

When the cartridges 20 and the spacers 30 are both mounted on the base plate 10, the guide parts 42 at both ends of the stopping plate 40 may be removed from the guide rails 12 of the base plate 10. The stopper plate 40 is coupled to the inside of the opening 11 of the base plate 10 by sliding in the groove. When the stopping plate 40 is completely inserted into the opening 11, the cartridge 20 and the spacer 30, which have been inserted first, are brought into close contact with the inside by the stopping plate 40, and an air gap is formed therebetween. In addition, it does not occur and maintains a constant position without moving inside the opening 11.

As described above, the phantom on which the plurality of cartridges 20 are mounted is placed at a designated position on a treatment table (not shown) below a linear accelerator (not shown) for radiotherapy. At this time, the operator aligns the state positions of the phantom and the linear accelerator using the display lines displayed on the base plate 10 and the stopping plate 40.

When the alignment of the position between the base plate 10 and the linear accelerator is completed, the radiation is irradiated from the irradiation head (not shown) of the linear accelerator. At this time, the irradiated radiation is irradiated almost exactly to the area inside the irradiation area display line M1 of the base plate 10, and the glass dosimeter 50 located at a predetermined depth (for example, 1.4 cm from the upper surface) of the phantom. The output is set so that the correct dose of radiation (e.g. 100 cGy) is absorbed.

After irradiating the phantom as described above, the phantom is moved to another place to separate the glass dosimeter 50 from the cartridge 20, and then the reaction of the glass dosimeter 50 is measured to measure the radiation dose of the glass dosimeter 50. do.

As described above, according to the present invention, the glass dosimeter is inserted into the dosimeter insertion hole 21 of the cartridge 20 so that the air gap is hardly generated, so that accurate radiation dose measurement can be made.

In addition, since the cartridge 20 is easily detachably coupled to the base plate 10 in a sliding manner, it is possible to obtain advantages that are very convenient to use.

In this embodiment, only one spacer 30 is inserted between the cartridges 20, but alternatively, two or more spacers 30 may be inserted and used between the cartridges 20.

Embodiment of the phantom for measuring the radiation dose of the glass dosimeter according to the present invention described above is presented for illustrative purposes only to help the understanding of the present invention, the present invention is not limited thereto, and the present invention is not limited thereto. It will be apparent to those skilled in the art that various modifications and implementations can be made within the scope of the technical spirit set forth in the appended claims.

10: base plate 11: opening part
12: guide rail portion 20: cartridge
21: Dosimeter insertion hole 22: Guide portion
30 spacer 32 guide portion
40: stopping plate 42: guide portion
50: glass dosimeter

Claims (4)

In the glass dosimeter radiation dose measurement phantom used for measuring the radiation dose of the glass dosimeter used for radiation therapy,
A base plate 10 having an opening portion 11 formed from one side portion to a center portion and having guide rail portions 12 formed on both sides of the opening portion 11;
Consists of a rectangular bar having the same thickness as the base plate 10, both ends are detachably coupled to the inside of the opening 11 while sliding along the guide rail portion 12, and the glass dosimeter 50 A plurality of cartridges 20 having a corresponding size and shape and having a cylindrical dosimeter insertion hole 21 into which the glass dosimeter 50 is inserted;
Both ends are coupled while sliding along the guide rail portion 12 of the base plate 10, is arranged in close contact between each of the cartridge 20 to form a rectangular bar to adjust the distance between the cartridge 20 Spacers 30; And,
Both ends of the cartridge 20 and the spacer 30 are mounted on the base plate 10 so that both ends thereof slide along the guide rail portion 12 of the base plate 10 to be detachable inside the opening 11. A phantom for radiation dose measurement of a glass dosimeter comprising a stopping plate 40 coupled to the cartridge 20 and the spacer 30 in close contact with the opening 11. delete According to claim 1, The guide rail portion 12 of the base plate 10 is made of '' 'grooves formed along both sides of the opening 11, the cartridge 20 and the stopping plate ( 40 is a glass dosimeter radiation dose measurement phantom, characterized in that the guide portion (22, 42) is inserted into the guide rail portion 12 is inserted into the groove of the guide rail portion (12). The phantom of claim 1, wherein the base plate (10) is marked with an alignment mark for setting the irradiation position.

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