JP2004024419A - Dose distribution measuring model and dose distribution measuring instrument - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dose distribution measuring model and a dose distribution measuring instrument in which a sphere container with a radiation detecting means inside can be easily opened/closed and prescribed liquid can be easily filled in the container. <P>SOLUTION: A sphere separable into hemispheres and a radiation detecting means placed in the sphere are equipped on this dose distribution measuring instrument. Water is filled into the sphere to form a sphere water phantom. An engaging mechanism to engage the opening part side of the upper hemisphere 1A with the opening part side of the lower hemisphere 1B is equipped on the sphere water phantom. The engaging mechanism comprises an upper engaging part 3A with projected parts 7 equipped on the inner wall part to the opening part side of the upper hemisphere 1A and a lower engaging part 3B equipped on the inner wall part to the opening part side of the lower hemisphere 1B while having guide groove parts 11 to guide the projected parts 7 toward a slantly vertical direction along the wall surface of the sphere 1. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a dose distribution measurement model and a dose distribution measurement device that are preferably applied to a device or the like that previously simulates the dose and distribution of radiation actually irradiated when setting a schedule of radiation therapy for a human body. is there.
[0002]
Specifically, a spherical container in which the radiation detecting means such as an X-ray film is disposed inside, or a spherical container in which the radiation detecting means such as an ion chamber is inserted is divided into hemispheres. A projection is provided on a wall on the opening side of the hemisphere, and a guide groove is provided on a wall on the opening side of the other hemisphere for guiding the projection in a predetermined direction along the wall surface of the container. According to the guide groove, the spherical container can be easily sealed and opened.
[0003]
[Prior art]
In recent years, radiotherapy techniques for the human body and the like have been increasingly advanced. Along with this, when a radiation treatment site is determined, it is required to simulate with high accuracy whether or not the radiation dose is optimal to be applied to the treatment site.
[0004]
In this simulation, an irradiation dose, an irradiation angle, a scanning angle range, and the like of a treatment site are set based on an irradiation field pattern when the measurement model is irradiated with radiation. Therefore, it is desired to use a three-dimensional model as close to a human body as possible for this measurement model.
[0005]
In response to this request, various pseudo models (phantoms) have been proposed by various research institutions and manufacturers. For example, a spherical phantom made of an acrylic resin is known as a pseudo model of a human head.
[0006]
FIG. 14 is a perspective view showing a configuration example of a spherical phantom 90 of this type. The spherical phantom 90 shown in FIG. 14 has a spherical body 91 made of colorless and transparent acrylic resin having a diameter of about 17 cm. This sphere 91 is the main body of the sphere phantom 90. The sphere 91 is provided with a cavity extending from the outside to the inside, and a radiation detecting means 92 made of an X-ray film or the like is arranged in the cavity.
[0007]
FIG. 15 is a cross-sectional view illustrating a configuration example of the sphere 91. As shown in FIG. 15, a cavity 99 for inserting and arranging the X-ray detecting means 92 is provided on a plane passing through the center of the sphere 91. The cavity 99 is formed to have a slightly larger area than the X-ray detecting means 92. The height H of the hollow portion 99 is made larger than the thickness of the X-ray detecting means 92 so as not to hinder the access of the X-ray detecting means 92.
[0008]
In FIG. 14, the support 93 that covers the lower half of the sphere 91 and supports it from below is made of urethane resin. When performing radiation treatment on the human head, radiation is irradiated to the spherical phantom 90 on the support base 31 in advance, and the dose distribution of the spherical phantom 90 in an arbitrary direction cross section is measured. Then, based on the measurement result, a dose of the radiation that is irradiated to a portion other than the treatment site of the human head and its distribution are simulated. Thereby, it is determined whether or not the irradiation dose and the irradiation position of the radiation to the human head are appropriate.
[0009]
[Problems to be solved by the invention]
By the way, according to the spherical phantom 90 according to the conventional example, the radiation detecting means 92 is inserted and arranged in the hollow portion 99 of the spherical body 91. For this reason, if the sphere 91 is inclined with respect to the XY plane in FIG. 14, there is a possibility that the radiation detecting means 92 may fall out of the cavity 99. Further, there is a problem that the air layer in the cavity 99 affects the measurement result of the dose distribution.
[0010]
Accordingly, the present invention has been made to solve such a problem, and it has been made possible to easily seal and open a spherical container in which a radiation detecting means is disposed, and to easily fill a predetermined liquid into the container. It is an object of the present invention to provide a dose distribution measurement model and a dose distribution measurement device that can be filled into a device.
[0011]
[Means for Solving the Problems]
The above-mentioned problem has a spherical container divided into hemispheres, and radiation detecting means disposed in the container, and a radiation dose distribution measurement of the radiation in which the container is filled with a predetermined liquid. A model, comprising: an engaging mechanism for engaging the opening side of one hemisphere of the container with the opening side of the other hemisphere of the container; A projection provided on a wall of the opening of the other hemisphere, and a guide groove provided on a wall of the opening of the other hemisphere for guiding the projection in a predetermined direction along the wall surface of the container. And a first dose distribution measurement model characterized by the following.
[0012]
According to the first dose distribution measurement model according to the present invention, the protrusion is provided on the opening-side wall of one hemisphere, and the guide groove is provided on the opening-side wall of the other hemisphere. The projections are guided in a predetermined direction along the wall surface of the container by the guide grooves.
[0013]
Therefore, one hemisphere can be easily engaged with the other hemisphere according to the guide of the guide groove. For example, with a spherical container placed in a water tank, the container can be easily sealed and opened.
[0014]
The dose distribution measuring device according to the present invention has a spherical container divided into hemispheres, and radiation detecting means disposed in the container, and the container is filled with a predetermined liquid. An apparatus comprising a radiation dose distribution measurement model and radiation irradiation means for irradiating radiation from an arbitrary direction toward the dose distribution measurement model, wherein the dose distribution measurement model is one of the hemispheres of the container. An opening mechanism is provided for engaging the opening side and the opening side of the other hemisphere of the container, and the engaging mechanism comprises a projection provided on a wall of the opening side of one hemisphere. And a guide groove provided on a wall on the opening side of the other hemisphere for guiding the projection in a predetermined direction along the wall surface of the container.
[0015]
According to the dose distribution measurement device according to the present invention, since the above-described dose distribution measurement model is applied, a spherical water phantom can be easily prepared, which contributes to an accurate formulation of a radiation treatment plan for a human head. it can.
[0016]
The second dose distribution measurement model according to the present invention includes a spherical container divided into a pair of hemispheres, a through-hole provided in one hemisphere of the container, and a fitting through the through-hole into the container. A radiation detection means to be inserted, a radiation dose distribution measurement model in which the container is filled with a predetermined liquid, the opening of one hemisphere of the container, and the other of the container An engaging mechanism for engaging the opening of the hemisphere is provided. The engaging mechanism includes a projection provided on a wall of the opening of one hemisphere and a projection provided on a wall of the container. And a guide groove provided on a wall on the opening side of the other hemisphere for guiding in a predetermined direction.
[0017]
According to the second dose distribution measurement model according to the present invention, one hemisphere can be engaged with the other hemisphere in accordance with the guide of the guide groove, similarly to the first dose distribution measurement model. Therefore, the predetermined liquid can be easily filled in the spherical container.
[0018]
In addition, since the insertion length of the radiation detecting means can be adjusted with respect to the spherical container filled with the predetermined liquid, this dose distribution measurement model can be used for, for example, simulation of radiation irradiation to the uterus.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a dose distribution measurement model, a dose distribution measurement device, and a dose distribution measurement method according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing a configuration example of a dose distribution measuring device 200 according to an embodiment of the present invention.
[0020]
In this embodiment, a projection is provided on a wall on the opening side of one hemisphere constituting the spherical container, and the other is provided to guide the projection in a predetermined direction along the wall surface of the container. A guide groove is provided on the wall on the opening side of the hemisphere so that one hemisphere can be engaged with the other hemisphere according to the guide of the guide groove, and the spherical container is easily sealed and opened. In addition to this, the container can be easily filled with a predetermined liquid.
[0021]
The dose distribution measuring device 200 shown in FIG. 1 irradiates radiation such as X-rays to the head of a human body and, when performing radiation treatment on a predetermined affected part in the head of the human body, actually irradiates the affected part. This device simulates the dose of radiation and its distribution in advance.
[0022]
As shown in FIG. 1, the dose distribution measuring device 200 includes a spherical water phantom (an example of a first dose distribution measurement model) 100 for measuring (monitoring) a radiation dose and its distribution, and a spherical water phantom 100. And a radiation irradiating device (an example of a radiation irradiating means) 150 for irradiating a predetermined amount of radiation toward.
[0023]
First, the spherical water phantom 100 will be described. As shown in FIG. 1, the spherical water phantom 100 includes a spherical container (hereinafter, also referred to as a spherical body) 1. This sphere 1 is the main body of the sphere water phantom 100. As shown in FIG. 2, the sphere 1 as the main body has a structure such that the sphere 1 is equally divided vertically into two parts by a plane passing through the center (ball center) of the sphere 1.
[0024]
Hereinafter, the upper hemisphere portion of the sphere 1 shown in FIG. 2 is referred to as an upper hemisphere 1A, and the lower hemisphere portion is referred to as a lower hemisphere 1B. The upper hemisphere 1A and the lower hemisphere 1B are each provided with an engagement mechanism on the inner wall portion on the opening side for tightly adhering the two hemispheres. This attachment mechanism will be described later.
[0025]
Further, inside the sphere 1, a radiation detecting means 20 is disposed when measuring the radiation dose and its distribution. In a state where the radiation detecting means 20 is provided, the sphere 1 is filled with water, purified water, distilled water, or the like (an example of a predetermined liquid), and is sealed and held. This radiation detecting means 20 will also be described later.
[0026]
As shown in FIG. 2, predetermined graduation lines 51 are provided on the surface of the sphere 1 in the horizontal and vertical directions. The graduation line 51 is for reading the inclination of the sphere 1 with respect to the radiation irradiation direction of the radiation irradiation device 150 (see FIG. 1). As shown in FIG. 2, the graduation lines 51 are provided on the surface of the sphere 1 at equal intervals of 5 ° in the horizontal and vertical directions, for example. The sphere 1 is made of, for example, a colorless and transparent acrylic resin.
[0027]
By the way, since acrylic resin has a specific gravity close to 1, radiation scattering characteristics and absorption characteristics are close to water. In addition, the human body is mostly composed of water. Therefore, a water phantom made of an acrylic resin has radiation scattering characteristics and absorption characteristics close to those of a human body. By using a water phantom made of this acrylic resin when setting the schedule of radiation treatment for the human body, it is possible to obtain a simulation result with high consistency.
[0028]
FIG. 3 is a cross-sectional view of the spherical water phantom 100 shown in FIG. As shown in FIG. 3, the sphere 1 has a wall having a predetermined thickness, and the inside of the wall is hollow. In FIG. 3, when the thickness of the wall is T1, T1 is about 2 mm. When the diameter (outer diameter) of the sphere 1 is T2, T2 is about 200 mm.
[0029]
Further, in order to make the opening side of the upper hemisphere 1A of the sphere 1 and the opening side of the lower hemisphere 1B closely adhere with high airtightness, an engaging mechanism is provided on the opening side of the sphere 1. ing. This engaging mechanism includes, for example, an upper engaging portion 3A attached to an inner wall portion on the opening side of the upper hemisphere 1A and a lower engaging portion attached to an inner wall portion on the opening side of the lower hemisphere 1B. 3B. The attachment of each of these engaging portions to the inner wall portion of the hemisphere is performed by a predetermined adhesive or the like.
[0030]
4A and 4B are enlarged cross-sectional views illustrating a configuration example of the engagement mechanism 3. The upper engaging portion 3A shown in FIG. 4A has a ring shape along the inner wall on the opening side of the upper hemisphere 1A. An eave (eave) portion 9 is provided on the upper surface of the upper engaging portion 3A. The eave portion 9 functions as a stopper when the upper engaging portion 3A is engaged with the lower engaging portion. It is designed such that when the eaves portion 9 comes into contact with the upper surface of the lower engaging portion 3B, the engagement between the upper engaging portion 3A and the lower engaging portion is completed.
[0031]
Further, as shown in FIG. 4A, a projection 7 to be inserted into a predetermined portion of the lower engaging portion is provided on the inner peripheral surface of the upper engaging portion 3A. As shown in FIG. 5, four protrusions 7 are provided on the inner peripheral surface of the upper engaging portion 3A, for example, at equal intervals of 90 ° with respect to the ring center of the upper engaging portion 3A. The size of the protrusion 7 is, for example, about 2 mm in diameter and about 2 mm in height.
[0032]
Of course, the number of the protrusions 7 is not limited to four, and for example, twelve protrusions may be provided on the inner peripheral surface at equal intervals of 30 °. As the number of the protrusions 7 increases, the adhesion between the upper engaging portion 3A and the lower engaging portion can be increased.
[0033]
Returning to FIG. 4A, when the diameter (outer diameter) of the upper engaging portion 3A is T3 and the height is T4, for example, T3 = 196 mm and T4 = 13 mm. In addition, when the dimensional height from the lower surface of the upper engaging portion 3A to the center of the protrusion 7 is T5, T5 is about 3 mm. The upper engaging portion 3A is made of, for example, a colorless and transparent acrylic resin.
[0034]
On the other hand, the lower engaging portion 3B shown in FIG. 4B has a ring shape along the inner wall portion on the opening side of the lower hemisphere 1B. Guide grooves 11 are provided on the outer peripheral surface of the lower hemisphere 1B at positions corresponding to the protrusions 7 shown in FIG. 4A. The guide groove 11 guides the above-described protrusion 7 (see FIG. 5) in an oblique vertical direction along the wall surface of the sphere. As shown in FIG. 6, four guide grooves 11 are provided on the outer peripheral surface of the lower engaging portion 3B, for example, at equal intervals of 90 ° with respect to the ring center of the lower engaging portion 3B.
[0035]
Returning to FIG. 4B, the guide groove portion 11 has a shape like a dovetail groove formed obliquely downward from the outer peripheral upper surface of the lower engaging portion 3B, for example. In FIG. 4B, the guide groove 11 includes a front portion 11A into which the protrusion 7 is inserted, and a rear portion 7B which is inserted into the front portion 11A and holds the protrusion 7 guided obliquely downward. I have.
[0036]
The front portion 11A of the guide groove 11 has, for example, an inclination of about 15 ° below the upper surface of the lower engaging portion 3B and a groove length of about 10 mm. Further, the rear portion 11B of the guide groove 11 has, for example, an inclination of about 2 ° downward with respect to the upper surface of the lower engaging portion 3B, and has a groove length of about 15 mm. Further, the guide groove 3 has a groove width of about 3 mm and a depth of about 2 mm. The dimension width and the dimension depth of the groove are common to the front part 11A and the rear part 11B.
[0037]
In FIG. 4B, when the diameter (outer diameter) of the lower engaging portion 3B is T6 and the height is T7, for example, T6 = 196 mm and T7 = 26 mm. When the height from the upper surface of the lower engaging portion 3B to the center of the end of the guide groove 11 is T8, T8 is about 5 mm.
[0038]
Further, a plate groove portion 18 for supporting the radiation detecting means and the like is provided on the upper surface of the lower engaging portion 3B. As shown in FIG. 6, four plate groove portions 18 are provided on the inner peripheral upper surface of the lower engaging portion 3B, for example, at equal intervals of 90 ° with respect to the ring center of the lower engaging portion 3B. Have been. The dimensional width of the plate groove portion 18 is, for example, about 3 mm, and the dimensional length is about 11 mm. The lower engaging portion 3B is made of, for example, a colorless and transparent acrylic resin.
[0039]
As shown in FIG. 6, an O-ring 17 is provided on the outer peripheral surface side of the lower engaging portion 3B. The size of the O-ring 17 is, for example, about 3.1 mm in diameter and about 185 mm in inner diameter. When the O-ring 17 is pressed by the upper engaging portion 3A (see FIG. 4A) and the lower engaging portion 3B, the inside of the sphere 1 (see FIG. 3) is hermetically sealed.
[0040]
7A and 7B are conceptual diagrams showing an operation example of the engagement mechanism 3. FIG. As described above, the engagement mechanism 3 is used to make the upper hemisphere 1A and the lower hemisphere 1B adhere to each other with high airtightness and to seal the inside of the sphere 1 (see FIG. 3). It is designed so that the O-ring 17 is pressed by 3A and the lower engaging part 3B. The operation of pressing the O-ring 17 (the operation of the engagement mechanism) will be described.
[0041]
First, as shown in FIG. 7A, the protrusion 7 of the upper engaging portion 3A is inserted into the guide groove 11 of the lower engaging portion 3B. Next, with the projection 7 inserted into the guide groove 11, the upper engaging portion 3A is rotated clockwise (leftward in FIG. 7A) with respect to the lower engaging portion 3B.
[0042]
Then, the upper engaging portion 3A moves diagonally downward in FIG. 7A along the guide groove portion 11. When the upper engaging portion 3A is rotated clockwise by about 20 mm, as shown in FIG. 7B, the lower surface of the eaves portion 9 of the upper engaging portion 3A comes into contact with the upper surface of the lower engaging portion 3B. . At this time, the O-ring 17 provided on the outer peripheral surface side of the lower engaging portion 3B is pressed between the lower engaging portion 3B and the upper engaging portion 3A. Since the gap between the upper engaging portion 3A and the lower engaging portion 3B is completely sealed by the pressed O-ring 17, the spherical body 1 can be easily sealed. Further, in this state, the upper engaging portion 3A and the lower engaging portion 3B can be separated from each other by turning the upper engaging portion 3A counterclockwise about 20 mm with respect to the lower engaging portion 3B. it can.
[0043]
If the shape of the entrance (front part) of the guide groove 11 is widely curved as shown in FIG. 7A, the protrusion 7 can be easily inserted into the guide groove 11, which is convenient.
[0044]
Next, the spherical water phantom 100 includes radiation detecting means for monitoring the radiation dose and its distribution in response to radiation. FIG. 8 is a perspective view illustrating a configuration example of the radiation detection unit 20. As shown in FIG. 8, the radiation detecting means 20 includes a photosensitive film such as an X-ray film 21, a pair of light-shielding films 23A and 23B arranged in the vertical direction of the X-ray film 21, and a light-shielding film 23A. , And 23B from above and below.
[0045]
Among these, the X-ray film 21 is, for example, a rectangular silver halide film. The sphere 1 (see FIG. 1) on which the X-ray film 21 is set is irradiated with radiation of a planned dose from a planned angle, and then the X-ray film 21 is subjected to a development process, whereby the sphere 1 (see FIG. 1) It is possible to measure the dose of radiation transmitted through the inside and its distribution. The size of the X-ray film 21 is, for example, approximately 10 cm × 10 cm in length × width. The shape of the X-ray film 21 is not limited to a rectangle, but may be a circle. Further, the X-ray film 21 is not limited to a silver halide film, and may be used without particular limitation as long as it has a property of being sensitive to radiation.
[0046]
Further, the pair of light-shielding films 23A and 23B shown in FIG. 8 are made of, for example, black paper 72 and a water-resistant laminated film 74 that covers the black paper 72. By sandwiching the X-ray film 21 between a pair of black papers 72 and then performing a lamination process on the black paper 72, the X-ray film 21 can be sealed (waterproofed) and protected from visible light. . The shape of the black paper 72 is, for example, a circle having a diameter of about 16 cm. The shape of the laminate film 74 is, for example, a circle having a diameter of about 18 cm. In this laminating process, a laminating apparatus or the like which sticks when pressed is used.
[0047]
The laminating apparatus and the laminating film 74 are preferably designed so as to prevent generation of static electricity. Thereby, exposure of the X-ray film 21 due to static electricity can be prevented.
[0048]
Further, the pair of plates 25A and 25B are made of, for example, a colorless and transparent acrylic resin or the like, and have a circular shape with a diameter of about 19 cm and a thickness of 3 mm. Lock portions 76 are provided on the outer peripheral portions of the plates 25A and 25B, for example, at equal intervals of 90 ° with respect to the center of the plates. By arranging the locking portion 76 in the plate groove portion 18 (see FIG. 6), the radiation detecting means 20 is positioned with respect to the sphere 1 (see FIG. 1).
[0049]
At a predetermined position of such a plate 25A and / or 25B, a metal for shielding radiation, for example, lead or copper is embedded. For example, in a plate 25A shown in FIG. 8, four coppers 78 are embedded at regular intervals of 90 ° with respect to the center of the plate. The copper 78 causes four coordinate points to be projected on the X-ray film 21 after irradiation. Therefore, when monitoring the dose distribution of the radiation, the position of the dose distribution can be confirmed using the coordinate points as a mark, which is convenient. In FIG. 8, the dimensional distance from the center of the plate to the copper 78 is, for example, about 4 cm.
[0050]
By the way, the thickness of the plates 25A and 25B can be arbitrarily changed. When changing the thickness of the plate 25A and / or 25B, a spacer 26 as shown in FIG. 8 is prepared. By arbitrarily combining the spacer 26 and the plates 25A and / or 25B, the radiation detecting means 20 can be stably fixed in the sphere 1 and the arrangement position thereof can be finely adjusted. For example, in FIG. 8, a plate 25A having a thickness of 1 mm is used, and a spacer 26 having a thickness of 2 mm is arranged below the plate 25B. Thus, the radiation detecting means 20 can be disposed on the XY plane 2 mm above the center of the sphere 1 (see FIG. 1), and the dose distribution on the XY plane 2 mm above can be measured.
[0051]
The spacer 26 has, for example, a ring shape having a locking portion, and is made of an acrylic resin. The spacers 26 and the plates 25A and 25B are color-coded according to the thickness. For example, the plates 25A and 25B having a thickness of 1 mm are made blue and transparent, and the spacers 26 having a thickness of 2 mm are made yellow. Then, the thickness of the spacer 26 and the thickness of the plates 25A and 25B can be checked at a glance from the outside of the sphere, which is convenient.
[0052]
The spherical water phantom 100 shown in FIG. 1 includes a support 31 for supporting the spherical body 1 from below. The support table 31 is, for example, wooden. Therefore, absorption or scattering of radiation by the support 31 can be suppressed, and the dose distribution of the radiation irradiated toward the sphere 1 from below the support can be correctly measured.
[0053]
A plurality of circular concave portions (not shown) are provided at predetermined positions on the upper surface of the disk portion 33 that supports the lower portion of the support table 31. These recesses are for fixing the position of the scale table, which will be described later.
[0054]
Further, the spherical water phantom 100 has a position correcting means 40 for correcting the position of the spherical body 1 with respect to a predetermined reference point. FIG. 9 is a perspective view showing a configuration example of the position correction means 40. As shown in FIG. 9, the position correcting means 40 includes, for example, a graduation table 41 capable of surrounding the sphere 1, a graduation plate 43 arranged inside the sphere 1, and a laser beam directed toward the sphere 1 from a predetermined direction. 45, and a pair of side laser pointers (not shown) for irradiating 45.
[0055]
Among them, the scale table 41 includes, for example, a ring-shaped plate 67 having a circular opening slightly larger than the outer diameter of the sphere 1 and a leg 69 for maintaining the ring-shaped plate 67 horizontally at a predetermined height. It consists of: As shown in FIG. 9, scales are provided on the upper surface of the ring-shaped plate 67 at equal intervals of 5 ° from the center of the ring-shaped plate. Further, for example, three leg portions 69 are provided at equal intervals downward from the upper surface of the ring-shaped plate. As shown by the broken arrows in FIG. 9, the legs 69 are arranged in the concave portions of the support base 31.
[0056]
The scale plate 43 has the same shape as the plates 25A and 25B described above. For example, the scale plate 43 is made of a colorless and transparent acrylic resin or the like, and has a circular shape with a diameter of about 19 cm. Further, a locking portion 76 is provided on the outer peripheral portion of the scale plate 43, similarly to the plates 25A and 25B. The scale plate 43 is positioned with respect to the sphere 1 and locked by the locking portion 76.
As shown in FIG. 9, the graduation plate 43 is provided with graduation lines at regular intervals of 45 ° from the center of the graduation plate 43, for example. The interval between the graduation lines is not limited to 45 °, but may be, for example, 5 °. Further, copper for adjusting the X, Y, and Z axes of the sphere 1 is embedded in the center of the scale plate 43.
[0057]
Further, the pair of side laser pointers has, for example, a semiconductor laser element that irradiates laser light having a wavelength of 650 nm to 800 nm in a predetermined direction with good directivity. The position of the sphere 1 is adjusted such that the laser light emitted from these side laser pointers scatters on the copper at the center of the scale plate 43. Thereby, the center of the sphere 1 and the orthogonal point of the laser light emitted from the side laser pointer can be overlapped.
[0058]
Next, returning to FIG. 1, the radiation irradiation device 150 that irradiates the spherical water phantom 100 with a predetermined dose of radiation will be described. The radiation irradiation device 150 shown in FIG. 1 irradiates radiation such as X-rays in a predetermined direction. The radiation irradiation device 150 includes an irradiation head 152 that irradiates radiation in a predetermined direction, and a head rotation mechanism (not shown) that rotates the irradiation head 152 in parallel with the XY plane about the Z axis in FIG. And Hereinafter, the center of rotation of the irradiation head 152 rotated and moved by the head rotating mechanism is also referred to as an isocenter (radiation irradiation center).
[0059]
For example, as shown by a dashed arrow in FIG. 1, the irradiation head 152 is configured to move on an orbit at a predetermined distance from the isocenter by a head rotating mechanism. At this time, the center of the sphere 1 is set so that the isocenter and the orthogonal point of the side laser pointer coincide with each other, and the orthogonal point of the side laser pointer is located at the center of the sphere 1 (that is, the copper at the center of the scale plate 43). Make corrections. Thereby, the center of the sphere 1 and the isocenter can be matched.
The above-described head rotation mechanism may be set so that the irradiation head 152 in FIG. 1 is rotationally moved about the X axis in parallel with the YZ plane.
[0060]
Next, a method of measuring the radiation dose and its distribution using the above-described dose distribution measuring device 200 will be described. First, the position of the spherical water phantom 100 is corrected so that the center of the spherical body 1 matches (collates) with the isocenter. As shown in FIG. 10, the scale plate 43 is set inside the sphere 1 in advance, and the sphere 1 and the scale 41 are arranged at predetermined positions on the support 31. Before and after this, the position of the spherical water phantom 100 is adjusted so that the laser beams emitted from the pair of side laser pointers are orthogonal to each other at the isocenter.
[0061]
Next, the sphere 1 is picked up from the support table 31 without moving the support table 31. Then, the sphere 1 is separated into an upper hemisphere 1A and a lower hemisphere 1B, and the scale plate 43 is taken out from the sphere 1. After that, the upper hemisphere 1A, the lower hemisphere 1B, and the radiation detecting means 20 are placed in a water tank (not shown) filled with purified water or distilled water, and the spherical water phantom 100 is placed in the water tank. Assemble.
[0062]
As described above, since the positions of the protrusions 7 (see FIG. 7) and the guide grooves 11 (see FIG. 7) correspond to each other, the opening side of the upper hemisphere and the opening side of the lower hemisphere. The spheres can be easily assembled by facing each other, inserting each protrusion into the guide groove, and rotating the upper hemisphere clockwise about 20 mm with respect to the lower hemisphere. Alternatively, after assembling the sealed sphere 1, the sphere can be divided by rotating the upper hemisphere counterclockwise about 20 mm with respect to the lower hemisphere.
[0063]
Next, in FIG. 10, the sphere 1 filled with water is placed on a support 31. Then, the inclination of the sphere 1 with respect to the X, Y, and Z axes is determined while making the scale provided on the surface of the sphere 1 correspond to the scale of the scale plate 43. Thereby, the direction of the X-ray film with respect to the irradiation direction of the radiation is determined.
[0064]
After that, the scale table 41 is removed from the support table 31 without moving the support table 31. Then, as shown in FIG. 1, radiation is emitted from the irradiation head 152 toward the spherical water phantom 100. Since the spherical water phantom 100 is a sphere having a uniform radius, radiation is uniformly emitted from the irradiation line head 152 rotating at a constant speed around the isocenter toward the center of the spherical water phantom 100.
[0065]
FIG. 11 shows an example of the measurement result of the radiation dose distribution. As shown in FIG. 11, the radiation dose and its distribution can be determined from the coordinate points 55A to 55D photographed on the X-ray film and the density of the image. Since the dose distribution in a cross section in any direction centering on the isocenter can be monitored, for example, by repeating the measurement a plurality of times while arbitrarily adjusting the inclination of the sphere 1, it is possible to measure the dose distribution in three dimensions.
[0066]
As described above, the spherical water phantom 100 according to the present invention includes the engagement mechanism 3 for engaging the opening side of the upper hemisphere 1A and the opening side of the lower hemisphere 1B. The mechanism 3 has an upper engaging portion 3A provided on the inner wall on the opening side of the upper hemisphere 1A having the projection 7, and guides the projection 7 obliquely up and down along the wall surface of the sphere 1. The lower hemisphere 1B is provided with a lower engaging portion 3B provided on an inner wall portion of the lower hemisphere 1B on the opening side.
[0067]
Therefore, the upper hemisphere 1A can be engaged with the lower hemisphere 1B according to the guide of the guide groove 11, so that the sphere 1 can be easily sealed and opened even in the water tank. Therefore, the sphere 1 can be easily filled with purified water or distilled water.
[0068]
In addition, as shown in FIG. 12, when the air introduction portion 60 is provided at the top of the upper hemisphere 1A, when the sphere 1 filled with water is separated into the upper hemisphere 1A and the lower hemisphere 1B. It is convenient because the load caused by the pressure difference can be eliminated. Further, distilled water or purified water can be injected into the sphere 1 from the air introduction unit 60, and distilled water or purified water can be discharged from the sphere 1.
[0069]
As shown in FIG. 12, the air introducing portion 60 includes an opening portion having a long diameter portion and a short meridian portion, a flat rubber member 61 provided in the opening portion, and a plug portion 62 fitted into the opening portion. It consists of: As shown in FIG. 12, a predetermined thread groove is provided on the inner wall surface of the long diameter portion of the opening.
[0070]
Screws corresponding to the screw grooves provided on the inner wall surface of the long diameter portion are engraved on the outer peripheral surface of the plug portion 62. A linear groove 63 is provided on the upper surface of the plug 62. By inserting a coin or the like into the groove 63 and rotating it, the plug 62 can be tightened or loosened.
[0071]
When the plug 62 is removed after irradiating the spherical water phantom 100 with radiation, the inside of the spherical body 1 can be placed under the atmospheric pressure, so that the pressure difference between the inside and the outside of the spherical body 1 can be eliminated. it can. The air introduction section 60 is not limited to the upper hemisphere 1A, but may be provided in the lower hemisphere.
[0072]
In this embodiment, the case where the X-ray film 21 or the like is used for the radiation detecting means has been described, but the invention is not limited to this. For example, as in a spherical water phantom 150 (second dose distribution measurement model) shown in FIG. 13, an ion chamber (also referred to as an ionization chamber type measuring device or a probe) 75 for measuring an absolute dose is used as radiation detection means. May be.
[0073]
In this case, the above-described air introduction unit 60 is used as a through-hole for inserting the ion chamber 75 into the sphere 1. The ion chamber 60 is inserted into the air introduction section (hereinafter also referred to as a chamber insertion port) 60 to a predetermined depth and fixed, and the sphere 1 is filled with distilled water or purified water. The method of filling distilled water or purified water into the sphere 1 is the same as that of the sphere water phantom 100.
[0074]
That is, the upper hemisphere to which the ion chamber 75 is fixed and the lower hemisphere are put in a water tank filled with distilled water, purified water or the like, and the sphere 1 is assembled in this water tank. The upper hemisphere and the lower hemisphere are provided with the engagement mechanism 3 shown in FIG. 7, so that the sphere 1 can be easily sealed and opened in the water tank.
[0075]
The spherical water phantom 150 can freely adjust the insertion length of the ion chamber 75 with respect to the sphere 1. For example, when simulating radiation irradiation to the uterus, the spherical water phantom 150 is viewed from the lower abdomen of a woman. Can be used. Therefore, by using the spherical water phantom 150, it is possible to correctly determine whether or not the irradiation dose or the irradiation position of the radiation to the uterus is appropriate.
[0076]
【The invention's effect】
As described above, according to the first dose distribution measurement model according to the present invention, a model having a spherical container divided into hemispheres and radiation detecting means disposed in the container is used. There is provided an engaging mechanism for engaging the opening side of one hemisphere and the opening side of the other hemisphere, and this engaging mechanism is provided on the wall on the opening side of one hemisphere. It comprises a projection provided and a guide groove provided in a wall on the opening side of the other hemisphere for guiding the projection in a predetermined direction along the wall surface of the container.
[0077]
According to this configuration, one hemisphere can be engaged with the other hemisphere in accordance with the guide of the guide groove, so that the spherical container can be easily sealed and opened. Therefore, the predetermined liquid can be easily filled in the spherical container, which contributes to accurate measurement of the dose distribution of an arbitrary cross section.
[0078]
Further, according to the dose distribution measurement device according to the present invention, a dose distribution measurement model in which the radiation is irradiated and the dose distribution is measured, and a radiation irradiation unit that irradiates the radiation to the dose distribution measurement model from a predetermined direction. The dose distribution measurement model comprises an engaging mechanism for engaging the opening side of one hemisphere and the opening side of the other hemisphere, and the engaging mechanism includes one side. A projection provided on a wall on the opening side of the hemisphere, and a projection provided on a wall on the opening side of the other hemisphere for guiding the projection in a predetermined direction along the wall surface of the container. And a guide groove.
[0079]
Therefore, since a spherical dose distribution measurement model filled with a predetermined liquid can be easily prepared, it can contribute to an accurate formulation of a radiation treatment plan.
[0080]
Furthermore, according to the second dose distribution measurement model according to the present invention, a spherical container divided into a pair of hemispheres, a through-hole provided in one hemisphere of the container, A radiation detection means fitted in a container, wherein the container is filled with a predetermined liquid and a radiation dose distribution measurement model, wherein an opening side of one hemisphere and another hemisphere And a projection provided on a wall on the opening side of one hemisphere, and a projection provided along a wall surface of the container. And a guide groove provided on a wall on the opening side of the other hemisphere for guiding in a predetermined direction.
[0081]
With this configuration, similarly to the first dose distribution measurement model, one hemisphere can be engaged with the other hemisphere according to the guide of the guide groove. Therefore, the spherical container can be easily closed and opened in water, and the spherical container can be easily filled with a predetermined liquid.
[0082]
In addition, the insertion length of the radiation detection means can be adjusted for a spherical container filled with a predetermined liquid. For example, when simulating radiation irradiation to the uterus, this dose distribution measurement model is used for a female lower abdomen. It can be used freshly.
[0083]
INDUSTRIAL APPLICABILITY The present invention is very suitable when applied to an apparatus for simulating in advance the dose and distribution of radiation applied to the vicinity of an affected part when planning a radiation treatment for a human head, a uterus and the like.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a configuration example of a dose distribution measuring device 200 according to an embodiment of the present invention.
FIG. 2 is a side view showing a configuration example of a sphere 1;
FIG. 3 is a cross-sectional view taken along the line X1-X2 showing a cross-sectional structure of the sphere 1;
4A and 4B are enlarged cross-sectional views showing a configuration example of the engagement mechanism 3. FIG.
FIG. 5 is a plan view showing a configuration example of an upper engaging portion 3A.
FIG. 6 is a plan view showing a configuration example of a lower engaging portion 3B.
FIGS. 7A and 7B are conceptual diagrams illustrating the operation of the engagement mechanism 3. FIGS.
FIG. 8 is a perspective view showing a configuration example of the radiation detecting means 20.
FIG. 9 is a perspective view showing a configuration example of a position correction unit 40.
FIG. 10 is a conceptual diagram illustrating a position correction method of the spherical water phantom 100.
FIG. 11 is a conceptual diagram illustrating an example of a measurement result of a dose distribution.
FIGS. 12A and 12B are conceptual diagrams illustrating a configuration example of an air introduction unit 60. FIGS.
FIG. 13 is a perspective view showing a configuration example of a spherical water phantom 150.
FIG. 14 is a perspective view showing a configuration example of a spherical phantom 90 according to a conventional example.
FIG. 15 is an enlarged sectional view showing a configuration example of a sphere 91.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... spherical body, 3 ... engagement mechanism, 7 ... protrusion part, 11 ... guide groove part, 17 ... O-ring, 20, 75 ... radiation detection means, 100 ... spherical body Water phantom (first dose distribution measurement model), 150: spherical water phantom (second dose distribution measurement model), 200: dose distribution measurement device

Claims (6)

A spherical container divided into hemispheres, having radiation detection means disposed in the container, a radiation dose distribution measurement model of radiation filled with a predetermined liquid in the container,
An opening portion of one hemisphere of the container and an engaging mechanism for engaging the opening side of the other hemisphere of the container,
The engagement mechanism,
A projection provided on a wall on the opening side of the one hemisphere,
A dose distribution measurement model, comprising: a guide groove provided on a wall on the opening side of the other hemisphere for guiding the protrusion in a predetermined direction along a wall surface of the container. 2. The dose distribution measurement model according to claim 1, wherein a plurality of the protrusions and the guide grooves are provided at equal intervals along a wall surface of the spherical container. 3. The engagement mechanism,
2. The dose distribution measurement model according to claim 1, further comprising an O-ring pressed by a wall on the opening side of one hemisphere and a wall on the opening side of the other hemisphere. 3. . One hemisphere, or comprises an air inlet provided at a predetermined position of the other hemisphere,
The air introduction section,
An opening having a predetermined shape;
The dose distribution measurement model according to claim 1, further comprising a plug fitted into the opening. A spherical container divided into hemispheres, and radiation detection means disposed in the container, a radiation dose distribution measurement model in which the container is filled with a predetermined liquid, and an arbitrary A radiation irradiation means for irradiating radiation from the direction toward the dose distribution measurement model,
The dose distribution measurement model,
An opening portion of one hemisphere of the container and an engaging mechanism for engaging the opening side of the other hemisphere of the container,
The engagement mechanism,
A projection provided on a wall on the opening side of the one hemisphere,
And a guide groove provided on a wall on the opening side of the other hemisphere for guiding the protrusion in a predetermined direction along the wall surface of the container. . A spherical container divided into a pair of hemispheres, a through hole provided in one hemisphere of the container, and radiation detecting means inserted into the container from the through hole; A dose distribution measurement model of radiation that is filled with a predetermined liquid,
An opening portion of one hemisphere of the container and an engaging mechanism for engaging the opening side of the other hemisphere of the container,
The engagement mechanism,
A projection provided on a wall on the opening side of the one hemisphere,
A dose distribution measurement model, comprising: a guide groove provided on a wall on the opening side of the other hemisphere for guiding the protrusion in a predetermined direction along a wall surface of the container.

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