KR102538148B1 - Radiation detector for measurement of quality assurance and scintillator structure thereof - Google Patents

Abstract

According to an embodiment of the present invention, a signal receiving unit including a scintillator fiber structure formed in a shape corresponding to one surface of a radiation irradiation body of a radiation therapy equipment and generating scintillation by absorbing at least a portion of radiation is used, Disclosed are a radiation detection device for quality control of equipment for near-ocular radiation therapy that detects radiation of treatment equipment and a scintillator structure thereof.

Description

Radiation detection device for quality control of equipment for near-ocular radiation therapy and its scintillator structure

The present invention relates to a radiation detection device for quality control of equipment for near-ocular radiation therapy and a scintillator structure thereof.

In the case of quality management of radiation therapy equipment, daily, monthly, quarterly, and annual items are set, and each management item is different according to parts replacement.

For example, in the case of quality control of eye plaque, which is one of the equipment for near-ocular radiation therapy, a report published by the American Association of Physicists in Medicine (AAPM), an international recommendation, Management is described, but there is no clear quality control protocol and no recommendations are made accordingly. Therefore, institutions that treat eye plaque use the specifications provided by the company as they are or use them for treatment after self-verification.

In the conventional case, the dose is checked with a device made using an ion chamber, but it is difficult to check the distribution of the dose, and there are disadvantages in that real-time monitoring cannot be performed with high resolution.

(Patent Document) Registered Patent No. 10-1617773 (registration announcement on May 03, 2016)

The problem to be solved according to an embodiment of the present invention includes analyzing the dose and distribution of radiation for quality control of equipment for near-ocular radiation therapy.

In addition, it includes designing a scintillator structure of a radiation detection device in a shape suitable for radiation detection of equipment for near-ocular radiation therapy.

Other objects not specified in this specification may be additionally considered within the scope that can be easily inferred from the following detailed description and effects thereof.

In order to solve the above problems, the radiation detection device for detecting radiation of the radiation treatment equipment according to an embodiment of the present invention is formed in a form in which at least a part corresponds to one surface of the radiation emitter of the radiation treatment equipment, A signal receiver including a scintillator fiber structure that absorbs at least a portion of the radiation to generate a scintillation, one side of which is connected to one side of the signal receiver to prepare a transmission path for the flash of light, and the other side of the signal transfer unit and a signal analyzer connected to, converting the flash of light into an electrical signal and analyzing an irradiation state of the radiation, wherein the scintillator fiber structure includes a first scintillator fiber including a first bent part and a second bent part. The first scintillator fiber and the second scintillator fiber, when viewed in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device, the first bent portion is the first scintillator fiber. It looks extended in the longitudinal direction, and the second bent portion is arranged to look extended in the second longitudinal direction.

Here, the radiation treatment equipment may include equipment for near-ocular radiation therapy.

Here, analyzing the irradiation state of the radiation may include analyzing a dose and distribution of radiation emitted from the radiation treatment equipment.

Here, the scintillator fiber structure includes a first scintillator fiber group and a second scintillator fiber group, and the first scintillator when viewed in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device. The fiber group and the second scintillator fiber group may be arranged so as to cross each other.

Here, the first scintillator fiber group and the second scintillator fiber group may be arranged to appear perpendicular to each other when viewed in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device.

Here, the scintillator fiber structure is formed by extending along a straight line passing through the centers of the radiation treatment equipment and the radiation detection device in an area surrounded by the first scintillator fiber group and the second scintillator fiber group It may further include a third scintillator fiber group including a plurality of scintillator fibers.

Here, the signal analyzer may analyze the thickness of the irradiation body by comparing doses in the first scintillator fiber group, the second scintillator fiber group, and the third scintillator fiber group.

A scintillator fiber structure of a radiation detection device for detecting radiation of radiation therapy equipment according to another embodiment of the present invention includes a first scintillator fiber including a first bent portion and a second scintillator fiber including a second bent portion. The first scintillator fiber and the second scintillator fiber have a first bent portion extending in a first longitudinal direction when viewed from a straight line passing through the centers of the radiation treatment equipment and the radiation detection device. visible, and the second bent portion is arranged so as to be seen extending in the second length direction.

Here, the radiation treatment equipment may include equipment for near-ocular radiation therapy.

Here, the scintillator fiber structure includes a first scintillator fiber group and a second scintillator fiber group, and the first scintillator when viewed in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device. The fiber group and the second scintillator fiber group may be arranged so as to cross each other.

Here, the first scintillator fiber group and the second scintillator fiber group may be arranged to appear perpendicular to each other when viewed in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device.

Here, the scintillator fiber structure is formed by extending along a straight line passing through the centers of the radiation treatment equipment and the radiation detection device in an area surrounded by the first scintillator fiber group and the second scintillator fiber group It may further include a third scintillator fiber group including a plurality of scintillator fibers.

As described above, according to the embodiments of the present invention, it is possible to analyze the dose and distribution of radiation for quality management of equipment for near-ocular radiation therapy.

In addition, high-resolution monitoring results can be obtained in real time by designing a scintillator structure of a radiation detection device in a shape suitable for radiation detection of equipment for near-ocular radiation therapy.

Even if the effects are not explicitly mentioned here, the effects described in the following specification expected by the technical features of the present invention and their provisional effects are treated as described in the specification of the present invention.

1 is a block diagram illustrating a radiation detection device according to an embodiment of the present invention.
2 illustrates an example of near-ocular radiation therapy equipment to which a radiation detection apparatus according to an embodiment of the present invention is applied.
3 is a diagram illustrating a radiation detection device for quality control of equipment for near-ocular radiation therapy according to an embodiment of the present invention.
4 is a diagram illustrating a scintillator structure of a radiation detection device according to an embodiment of the present invention.

Hereinafter, a radiation detection device for quality control of equipment for near-ocular radiation treatment related to the present invention and a scintillator structure thereof will be described in more detail with reference to the drawings. However, the present invention may be embodied in many different forms and is not limited to the described embodiments. And, in order to clearly describe the present invention, parts irrelevant to the description are omitted, and the same reference numerals in the drawings indicate the same members.

The suffixes "module" and "unit" for components used in the following description are given or used together in consideration of ease of writing the specification, and do not have meanings or roles that are distinct from each other by themselves.

The present invention relates to a radiation detection device for quality control of equipment for near-ocular radiation therapy and a scintillator structure thereof.

1 is a block diagram illustrating a radiation detection device according to an embodiment of the present invention.

Referring to FIG. 1 , a radiation detection apparatus 10 according to an embodiment of the present invention includes a signal receiving unit 100 , a signal transmitting unit 200 and a signal analyzing unit 300 .

Radiation detection device 10 according to an embodiment of the present invention is a device for performing dose and distribution measurement for quality control of eye plaque equipment applied to eye treatment using the radioactive isotope Ruthenuim-106. am.

The radiation detection device 10 according to an embodiment of the present invention may perform real-time monitoring with high resolution using a scintillator fiber.

The signal receiving unit 100 includes a scintillator fiber structure having at least a portion formed in a shape corresponding to one surface of a radiation irradiation body of the radiation treatment equipment and absorbing at least a portion of the radiation to generate scintillation.

Here, the irradiation body may refer to the entire module attached to the eye, including a portion of the eye plaque device to which radiation is irradiated.

The irradiation body to be described below may be described in combination with eye plaque equipment.

The scintillator fiber structure includes a first scintillator fiber including a first bent portion and a second scintillator fiber including a second bent portion.

Here, the first bent part and the second bent part are provided in a form corresponding to the curved surface of the eye plaque equipment.

The scintillator fiber structure will be described later in detail with reference to FIG. 4 .

One side of the signal transmission unit 200 is connected to one side of the signal reception unit to provide a transmission path for flashing light.

In one embodiment of the present invention, the signal delivery unit 200 may use an optical fiber having at least one cut end.

The signal analysis unit 300 is connected to the other side of the signal transfer unit, converts the flash of light into an electrical signal, and analyzes the irradiation state of the radiation.

Analyzing the irradiation state of radiation is to analyze the dose and distribution of radiation emitted from radiation therapy equipment.

In one embodiment of the present invention, the signal analysis unit 300 may be implemented using a semiconductor light receiving device, and converts an optical signal according to a flash of light transmitted through an optical fiber of the signal transmission unit 200 into an electrical signal. can

2 illustrates an example of near-ocular radiation therapy equipment to which a radiation detection apparatus according to an embodiment of the present invention is applied.

Radiation therapy equipment to which the radiation detection device according to an embodiment of the present invention is applied includes equipment for near-ocular radiation therapy.

Brachytherapy is a method of fixing a radioactive material in the vicinity of a tumor through surgery.

As shown in Figure 2, the equipment for near-ocular radiation therapy is to attach a ruthenium isotope metal plate emitting radiation to the eyeball to remove the tumor by irradiation, and is located in the center of the eye plaque equipment at the location of the tumor in the eyeball. Eye plaque devices can be attached to various sides of the eye so that the converging radiation is irradiated.

As radiation is irradiated inside the eyeball while attached to the eyeball, rather than irradiated from the outside of the eyeball, unlike the existing method of measuring the radiation dose from the outside, it is possible to predict the irradiated position inside the eyeball in advance. For this purpose, the scintillator fiber is positioned in a form corresponding to the radius of curvature of the eye plaque device, and the scintillator fiber is arranged to mimic the shape in which one side of the eye is in contact with the eye plaque device.

In order to more accurately irradiate the radiation material to the vicinity of the tumor, it is necessary to check the dose and distribution in advance. In order to check the radiation dose and distribution of , the scintillator fiber is designed in a form corresponding to one side (21) of the Eye plaque equipment.

As shown in FIG. 2, the equipment 20 for near-ocular radiation therapy is a structure for concentrating radiation on a tumor located in the eyeball, and uses eye plaque equipment having a different radius of curvature according to the size and shape of the eyeball. do.

The radiation detection device according to an embodiment of the present invention changes the angle of the bent portion of the scintillator fiber to correspond to the radius of curvature of the eye plaque device, so that the doses at C1, C2, and C3 of the eye plaque device can be checked, respectively. It is possible to analyze whether the dose distribution and thickness of the eye plaque equipment are constant.

In the radiation detection device according to an embodiment of the present invention, the scintillator fiber structure of the signal receiver absorbs at least a portion of the radiation to generate a flash of light, and the signal analyzer converts the flash of light into an electrical signal to analyze the dose and distribution of the radiation. do.

3 is a diagram illustrating a radiation detection device for quality control of equipment for near-ocular radiation therapy according to an embodiment of the present invention.

A radiation detection device for quality control of equipment for near-ocular radiation therapy according to an embodiment of the present invention can be implemented in various forms, and is not limited to the form shown in FIG. 3 .

3 shows a radiation detection device 10 according to a first embodiment of the present invention.

Referring to FIG. 3, the signal receiving unit 100 is formed in a form in which at least a portion corresponds to one surface of the irradiation body of the radiation treatment equipment, and the scintillator fiber structure 110 absorbs at least a portion of the radiation to generate scintillation. includes

Here, the scintillator fiber structure 110 is a structure including a plurality of scintillator fibers extending in a straight direction passing through the centers of the radiation treatment equipment 20 and the signal receiver 200 of the radiation detection device.

A plurality of scintillator fibers are provided with different lengths, and are formed with relatively longer lengths toward the center, so that they can be positioned along the curved surface of the eye plaque equipment.

Here, since the thickness (D) of the eye plaque device is constant, the structure of ends of a plurality of scintillator fibers can be designed based on the radius of curvature of the curved surface of the eye plaque device.

The signal analysis unit 300 is connected to the other side of the signal transfer unit, converts the flash of light into an electrical signal, and analyzes the irradiation state of the radiation.

In one embodiment of the present invention, the signal analysis unit 300 may be implemented using a semiconductor light receiving device, and converts an optical signal according to a flash of light transmitted through an optical fiber of the signal transmission unit 200 into an electrical signal. can

According to the radiation detection device 10 according to the second embodiment of the present invention, the first fixing part provided outside the scintillator fiber structure 110 to fix the scintillator fiber structure 110 and the radiation treatment equipment 20 ) It may include a second fixing part for fixing to one surface.

Accordingly, the arrangement of the eye plaque equipment and the end of the scintillator fiber structure can be fixed despite changes in the external environment, thereby reducing measurement error.

In addition, each of the plurality of scintillator fibers of the scintillator fiber structure 110 is provided to be assembled to the signal collection unit 200 and the first fixing part, and the length at which each of the plurality of scintillator fibers is drawn into the first fixing part is provided. It is possible to change the alignment of a plurality of scintillator fibers according to the radius of curvature of the eye plaque equipment by including assembly holes inside the signal collection unit 200 so as to be able to adjust .

According to the radiation detection device 10 according to the third embodiment of the present invention, scintillator fibers extending along the curved surface of the eye plaque device of the radiation treatment device 20 are included.

Specifically, the scintillator structure of the radiation detection device according to the third embodiment of the present invention is prepared to include a first scintillator fiber including a first bent portion and a second scintillator fiber including a second bent portion, When viewed from a straight direction passing through the centers of the treatment equipment and the radiation detection device, the first bent portion is disposed to extend in a first longitudinal direction and the second bent portion appears to extend in a second longitudinal direction.

If the scintillator fibers are arranged along one direction, a large amount of fibers are required to absorb the radiation beam, but in the case of the third embodiment, costs are reduced by including scintillator fibers arranged in different directions. has the effect of

The scintillator structure of the radiation detection device according to the third embodiment of the present invention corresponds to the structure shown in FIG. 4 below.

4 is a diagram illustrating a scintillator structure of a radiation detection device according to an embodiment of the present invention.

4(a) is a side view of the scintillator structure of the radiation detection device, and FIG. 4(b) shows the scintillator structure of the radiation detection device in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device. It is shown in the form seen.

Referring to FIG. 4 , the scintillator structure of the radiation detection device according to an embodiment of the present invention includes a first scintillator fiber 114 including a first bent portion and a second scintillator fiber including a second bent portion ( 115).

A dose distribution in real time and high resolution can be measured using the structure shown in FIG. 4, and beam characteristics (PDD) can be measured by overlapping scintillator fibers.

In addition, since it is arranged in a form corresponding to one side of the eye plaque device, the consistency of the application thickness of the eye plaque device can be predicted.

Specifically, as shown in (b) of FIG. 4, the first scintillator fiber and the second scintillator fiber, when viewed from a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device, the first bent portion is the first scintillator fiber. It looks extended in the longitudinal direction, and the second bent portion is disposed so as to look extended in the second longitudinal direction.

When the scintillator fibers are arranged along one direction, a large amount of fibers are required to absorb the radiation beam, but according to an embodiment of the present invention, the first scintillator fiber and the second scintillator fiber are arranged in different directions. As it is arranged, there is an effect of cost reduction. In addition, in the laminated structure, in one embodiment of the present invention, two layers are shown, but it is not limited thereto, and an arrangement of three or more layers is also possible.

In addition, the scintillator fiber structure includes a plurality of third scintillators formed by extending along a straight line passing through the centers of the radiation treatment equipment and the radiation detection device within the region surrounded by the first scintillator fiber group and the second scintillator fiber group. It further includes a third scintillator fiber group that includes radar fibers 116 .

Referring to (a) of FIG. 4 , the diameter L1 of the third scintillator fiber 116 and the diameter L3 of the first scintillator fiber 114 are 0.5 mm to 1.5 mm.

Also, the distance L2 between the third scintillator fibers 116 is 1.5 mm to 2.5 mm.

In addition, the length of the bent part (L4) corresponds to the length of the eye plaque equipment, and is implemented with a diameter of 15mm or more, which is the smallest among the eye plaque equipment, to enable measurement of eye plaque equipment of various lengths.

Referring to (b) of FIG. 4, the scintillator fiber structure includes a first scintillator fiber group including a plurality of first scintillator fibers 114 and a second scintillator fiber group including a plurality of second scintillator fibers 115. It includes 2 scintillator fiber groups, and is arranged so that the first scintillator fiber group and the second scintillator fiber group cross each other when viewed in a straight line direction passing through the centers of the radiation therapy equipment and the radiation detection device.

Specifically, the first scintillator fiber group and the second scintillator fiber group are arranged to look perpendicular to each other when viewed from a straight line passing through the centers of the radiation treatment equipment and the radiation detection device.

In addition, the scintillator fiber structure extends along a straight line passing through the center of the radiation treatment equipment and the radiation detection device in the region 117 surrounded by the first scintillator fiber group and the second scintillator fiber group. It further includes a third scintillator fiber group including third scintillator fibers 116 .

Here, the width L5 of the region 117 surrounded by the first scintillator fiber group and the second scintillator fiber group is 1.5 mm to 2.5 mm.

In addition, to describe the arrangement of the plurality of first scintillator fibers 114 in the first scintillator fiber group in detail, the central scintillator fiber located at the point corresponding to the central part of the eye plaque equipment, and the right side of the central scintillator fiber It includes a first side scintillator fiber located at a predetermined distance apart from each other and a second side scintillator fiber located at a predetermined interval apart from each other on the right side of the first side scintillator fiber, and includes a central scintillator fiber and a first side scintillator fiber. , and the second side scintillator fibers are arranged so that the length of the bent part becomes shorter.

Accordingly, as shown in (a) of FIG. 4, the central scintillator fiber, the first side scintillator fiber, and the second side scintillator fiber are located at a predetermined height from the point corresponding to the center of the eye plaque equipment. will do

The above description is just one embodiment of the present invention, and those skilled in the art can implement it in a modified form without departing from the essential characteristics of the present invention. Therefore, the scope of the present invention should be construed to include various embodiments within the scope equivalent to those described in the claims without being limited to the above-described embodiments.

10: radiation detection device
100: signal receiver
200: signal transmission unit
300: signal analysis unit

Claims (12)

A radiation detection device for detecting radiation of radiation therapy equipment,
a signal receiving unit including a scintillator fiber structure having at least a portion formed in a shape corresponding to one surface of a radiation irradiation body of the radiation therapy equipment and generating scintillation by absorbing at least a portion of the radiation;
a signal transmission unit having one side connected to one side of the signal reception unit and providing a transmission path of the flash of light; and
A signal analysis unit connected to the other side of the signal transfer unit and converting the flash of light into an electrical signal to analyze the irradiation state of the radiation;
The scintillator fiber structure includes a first scintillator fiber including a first bent portion and a second scintillator fiber including a second bent portion,
In the first scintillator fiber and the second scintillator fiber, when viewed in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device, the first bent portion appears to extend in a first longitudinal direction, and the second scintillator fiber extends in a first longitudinal direction. The bent portion is arranged to look extended in the second longitudinal direction,
The scintillator fiber structure includes a first scintillator fiber group and a second scintillator fiber group,
The first scintillator fiber group and the second scintillator fiber group are disposed to cross each other when viewed in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device,
The scintillator fiber structure includes a plurality of scintillator fiber structures extending along a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device within a region surrounded by the first scintillator fiber group and the second scintillator fiber group. The radiation detection device further comprising a third scintillator fiber group including scintillator fibers. According to claim 1,
The radiation treatment equipment includes equipment for near-ocular radiation treatment. According to claim 1,
Analyzing the irradiation state of the radiation includes analyzing a dose and distribution of radiation emitted from the radiation treatment equipment. delete According to claim 1,
The first scintillator fiber group and the second scintillator fiber group are arranged to look perpendicular to each other when viewed in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device. delete According to claim 1,
The signal analyzer compares doses in the first scintillator fiber group, the second scintillator fiber group, and the third scintillator fiber group to analyze the thickness of the irradiation object. In the scintillator fiber structure of a radiation detection device for detecting radiation of radiation therapy equipment,
The scintillator fiber structure includes a first scintillator fiber including a first bent portion and a second scintillator fiber including a second bent portion,
In the first scintillator fiber and the second scintillator fiber, when viewed in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device, the first bent portion appears to extend in a first longitudinal direction, and the second scintillator fiber extends in a first longitudinal direction. The bent portion is arranged to look extended in the second longitudinal direction,
The scintillator fiber structure includes a plurality of scintillator fiber structures extending along a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device within a region surrounded by the first scintillator fiber group and the second scintillator fiber group. A scintillator fiber structure further comprising a third scintillator fiber group comprising scintillator fibers. According to claim 8,
The radiation treatment equipment is a scintillator fiber structure of a radiation detection device including equipment for near-ocular radiation treatment. According to claim 9,
The scintillator fiber structure includes a first scintillator fiber group and a second scintillator fiber group,
The scintillator fiber structure of the radiation detection device arranged such that the first scintillator fiber group and the second scintillator fiber group cross each other when viewed in a straight line direction passing through the centers of the radiation treatment equipment and the radiation detection device. . According to claim 10,
The first scintillator fiber group and the second scintillator fiber group are arranged to look perpendicular to each other when viewed from a straight line passing through the centers of the radiation treatment equipment and the radiation detection device. . delete

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