KR20130076205A - Rotation type dual window phantom - Google Patents

Abstract

PURPOSE: A rotary type dual window phantom is provided to minimize errors as measurement is performed while an ionization chamber is fixed to the phantom. CONSTITUTION: A rotary type dual window phantom includes a box-shaped phantom (10) in which fluid is filled inside, an ionization chamber (20), a first phantom window (11), and a second phantom window (12). The ionization chamber is installed so that a radiation measuring sensor (21) is arranged inside the phantom. The first phantom window is formed on a side of the phantom so that radiation radiated from radiation radiator is transmitted through the inside of phantom. The second phantom window is formed on a side of the phantom facing the first phantom window so that radiation radiated from radiation radiator is transmitted through the inside of phantom.

Description

Rotation type Dual Window Phantom

The present invention relates to a phantom for radiation measurement, and more particularly to a rotary dual window phantom capable of bidirectional measurement by rotation.

Several well known techniques for treating malignant tumors include the use of radiation. Radiation sources, such as, for example, medical linear accelerators, are typically used to generate radiation directed to a particular area of a patient. Appropriate amount of radiation directed to the patient's disease site is very important. When properly provided, the radiation produces an ionizing effect on the patient's tumor tissue, destroying the tumor cells. In other words, by properly managing the output dose of radiation equipment (dose) it is possible to treat the tumor while preventing the surrounding normal tissue damage. The purpose of these therapies is to focus large amounts of radiation on tumor or malignant tumor cells while minimizing radiation exposure to surrounding healthy tissues. A small electron accelerator can be used for the generation of radiation and a collimator can be used for the adjustment of the irradiation area.

The beam accelerated by the accelerator collides with an electron beam beam or a target material such as tungsten to generate X-rays. The X-rays are mainly used for cancer treatment. The energy of X-rays depends on the accelerator specification, and the output (radiation dose at a certain distance per unit time) is determined by the institution used.

In the accelerator, beam emission is pulsed. Collimators are used for beam delivery, the most advanced of which are multileaf collimators. Some accelerators irradiate radiation using electron beam scanning instead of collimators.

Linear accelerators used in the treatment of malignancies should be calibrated so that the radiation output is in line with the expected values in order to accurately deliver the planned dose. This is because, if the output is calibrated differently than expected, the prescribed radiation dose determined by the doctor may not be delivered accurately, resulting in the destruction of normal tissue or the recurrence of cancer. Therefore, it is very important to measure the power output of the radiation treatment device on a regular basis and to calibrate the power output if there is a difference from the expected value. The Ministry of Education, Science and Technology also defines the output measurement and calibration of radiation equipment in the medical field through technical standards on radiation safety management in the medical field.

An existing system for measuring and calibrating the output of radiation generated by medical radiators is to use a tank of cube filled with water. This is because the density of the human body is close to the density of water, so a tank filled with water provides a suitable medium to create a simulation of the intensity and distribution of radiation that can occur in the patient's body. Because. The tank mentioned above is commonly referred to as a water phantom. The phantom is made of acrylic, and a phantom window made of a thin plastic material is formed on one surface to which radiation is irradiated. The radiation generated by the linear accelerator is guided through the phantom window into the water in the phantom, and at one point in the phantom tank, the radiation meter or radiation intensity or output dose can be measured at a variable depth and at a location within the water. .

1 is a front perspective view of a general water phantom 100 is shown. In order to measure the intensity (hereinafter, dose) of the radiation, the radiation R irradiated from the irradiator 300 is incident perpendicularly to the phantom window 110, and the radiation detector 200 (hereinafter, ionized) is positioned at an arbitrary depth D. The radiation intensity at the depth D is measured. Here, the depth D refers to the distance between the phantom window 110 and the ionizer 200. The procedure is as follows.

1. Irradiation (R) is used to measure doses at depths A and B and to determine the quality parameters (energy measures) from two values. (Typically B = 2A) The current International Measurement Guidelines (IAEA TRS-398) specify A as 10 cm.

In addition, when solids having a similar composition to water but different densities are used, the unit of cm is preferably multiplied by the density and expressed as g / cm ² .

2. Calculate the quality variable correction factor.

3. Place the ionizer 200 at the desired depth of measurement and irradiate the radiation (R), then apply the correction factor to determine the dose.

In this case, a direct determination method and an indirect determination method are used as measurement methods for determining the quality variable. The direct determination method is performed as shown in FIG. 2 and the indirect determination method is shown in FIG. 3.

Referring to FIG. 2, the direct determination method is shown in FIG. 2A because the distance C1 between the irradiator 300 and the ionophore 200 must be constant according to the depth change (A or B) of the ionosphere 200. After measuring the radiation by placing the ionizing box 200 at the depth A, to place the ionizing box 200 at the depth B and at the same time to reduce the distance between the phantom window 110 and the irradiator 300 by the distance of A and B The water phantom 100 must be moved towards the irradiator 300.

The calculation method of quality variable correction factor according to the direct determination method is as follows. When the depth A dose is D _A and the depth _B is D _B , the quality variables TPR _{B, A} = D _B / D _A.

Referring to FIG. 3, the indirect determination method maintains a constant distance (C2) between the radiation irradiator 300 and the phantom window 110, and measures a dose value according to a depth change (A or B) of the ionizing box 200. Calculate

The calculation method of the quality variable correction factor according to the indirect determination method is as follows. When the depth dose A is D _A and the depth dose _B is D _B , the depth dose rate PDD _{B, A} = D _B / D _A is calculated first, and then the quality variables TPR _{B, A} = 1.2661 * PDD _{B, A} -0.0595 Will be calculated.

As described above, the conventional water phantom in measuring the dose for calculating the quality variable correction factor has the following problems.

In the case of the direct determination method, since the ionization box 200 and the water phantom 100 need to be moved, the experiment is not easy, and when the water phantom 100 is moved, there is a possibility of error, so accurate calculation of the quality variable is difficult.

In the case of the indirect determination method, the error is reduced because the water phantom 100 does not need to be moved, but the exact ionization box 200 needs to be moved and installed since the ionophore 200 needs to be moved, leaving room for error. do.

Therefore, it is necessary to develop a phantom for accurate calculation of quality parameter correction factors and easy measurement.

The present invention has been made in order to solve the above problems, an object of the present invention, having a pair of opposing phantom window, and comprises a rotatable phantom to determine the depth of the ionizer or the distance between the irradiator and the ionizer. It is to provide a rotary dual window phantom that is adjustable by rotation.

The rotatable dual window phantom of the present invention includes a phantom on a housing in which fluid is filled therein; An ionization box installed so that a radiation measuring sensor is located inside the phantom; A first phantom window formed at a side of the phantom such that radiation irradiated from a radiation irradiator is transmitted to the inside of the phantom; And a second phantom window formed on a side of the phantom opposite to the first phantom window such that the radiation irradiated from the irradiator is transmitted inside the phantom. .

In addition, when the distance between the measurement sensor and the first phantom window on the line parallel to the irradiation direction is d, the distance between the measurement sensor and the second phantom window is 2d.

At this time, the phantom, the rotating means is provided to be rotatable based on an axis perpendicular to the irradiation direction; .

In addition, the rotating means, the rotating shaft protruding above the ground or measuring table; A rotary groove recessed upwardly from a bottom surface of the phantom to be fitted to the rotary shaft; And a control unit.

In addition, the rotation groove is formed in a portion corresponding to the measurement sensor in parallel with the radiation direction, the distance from the first phantom window is d, the distance from the second phantom window is 2d.

In another embodiment, the rotation groove is formed at the center of the first phantom window and the second phantom window parallel to the radiation direction, the distance between the first phantom window and the second phantom window is 1.5d. do.

The rotary dual window phantom of the present invention having the above configuration can be applied to the calculation of the quality variable according to the direct determination or the indirect determination method, so that the measurement is made by the rotation of the phantom, thereby making it easy to experiment. In addition, since the measurement is made while the ionizer is fixed to the phantom, it is possible to accurately calculate the quality variables by minimizing the possibility of error occurrence.

1 is a phantom front perspective view of a conventional
2 is a schematic front view of an experimental method according to a conventional direct determination method
3 is a schematic front view of an experimental method according to a conventional indirect determination method
4 is a phantom front perspective view of a first embodiment of the present invention;
5 is a phantom front perspective view of a second embodiment of the present invention;
6 is a schematic front view of a test method according to the first embodiment of the present invention (direct determination method)
7 is a schematic front view of the experimental method according to the second embodiment of the present invention (indirect determination method)

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

Example 1

The rotary dual window phantom according to the first embodiment of the present invention is a configuration for calculating the quality variable correction factor according to the direct determination method described in the background art.

Referring to FIG. 4, the rotatable dual window phantom includes a phantom 10, an ionizer 20, and a rotation means 50. The phantom 10 may be formed on an enclosure of a cuboid. The phantom 10 may be made of acrylic material. Water may be filled in the phantom 10. At this time, the first phantom window 11 is formed on one side of the radiation incident direction of the phantom 10. The first phantom window 11 may be made of a thin plastic material that is easy to transmit radiation. The first phantom window 11 is formed on the whole of one side of the phantom 10 integrally with the phantom 10, or penetrates the rest except for the peripheral portion of one side of the phantom 10, as shown in the figure, It may be formed by bonding the first phantom window 11 on the outside or the inside of the (10). The second phantom window 12 is formed on the opposite surface of the first phantom window 11. That is, the second phantom window 12 is formed on the other side of the phantom 10. The second phantom window 12 may be made of a thin plastic material that is easy to transmit radiation. The second phantom window 12 is formed entirely with the other side of the phantom 10 integrally with the phantom 10, or as shown in the figure penetrates the remainder except the other side peripheral portion of the phantom 10, the phantom It may be formed by bonding the second phantom window 12 on the outside or the inside of the (10).

The ionizing box 20 may be installed inside the phantom 10 filled with water. The ionizing box 20 is configured to measure the radiation intensity transmitted through the phantom 10 and includes a radiation measuring sensor 21 and a data cable 22. The ionizing box 20 may be installed such that the radiation measuring sensor 21 is located at the center of the vertical direction of the phantom 10. As an example, the upper end of the ionizing box 20 is fixedly installed on the upper side of the phantom 10, and formed to have a length such that the radiation measuring sensor 21 configured at the other end is positioned at the center of the vertical direction in the vertical direction of the phantom 10. do. The data cable 22 is configured to transmit a measurement signal sensed by the radiation measuring sensor 21 to the outside, and one end thereof is connected to the radiation measuring sensor 21, and the other end thereof may be configured to be exposed to the outside of the phantom 10. have. At this time, the ionizing box 20 is preferably installed at one-third of the length from one side surface to the other side of the phantom 10, based on the radiation direction. That is, if the distance from the first phantom window 11 to the radiation measuring sensor 21 of the ionizing box 20 is d, the ionization is performed such that the distance from the radiation measuring sensor 21 to the second phantom window 12 becomes 2d. It is preferable that 20 is arrange | positioned. Therefore, the length from one side of the phantom 10 to the other side may be 3d.

The rotating means 50 includes a rotating groove 51 and the rotating shaft 52. The rotating means 50 is configured for rotating the phantom 10 about an axis perpendicular to the irradiation direction. The rotating shaft 52 is formed on the experiment table T on which the phantom 10 is mounted. The rotating shaft 52 is formed to protrude upward of the experiment table T in a cylindrical shape. The rotary groove 51 is configured to be inserted into the rotary shaft 52 and is formed recessed upward from the bottom surface of the phantom 10. At this time, the rotary groove 51 is preferably formed at a position corresponding to the extension line of the ionizing box (20). In other words, when the distance from the first phantom window 11 to the radiation measuring sensor 21 of the ionizing box 20 is d, the distance between the rotating groove 51 and the first phantom window is d, and the rotating groove 51 and 2 The distance to the phantom window may be 2d.

The above configuration enables calculation of the quality variable correction factor according to the direct determination method only by the rotation of the phantom 10 without changing the position of the irradiator and the ionizing box 20.

Hereinafter, an experimental method according to the phantom of the first embodiment of the present invention configured as described above will be described with reference to the drawings.

As shown in FIG. 5A, the phantom 10 is disposed so that the first phantom window 11 and the irradiator 30 face each other in order to measure the radiation by placing the ionizing box 20 at a first position (depth A in the background description). Place it. In this case, the distance C1 between the irradiator 30 and the ionizing box 20 should be the same when the ionizing box 20 is disposed at the second position (depth B in the background description) and measured. When the distance between the first phantom window 11 and the ionosphere 20 is d in the arrangement state as described above, the distance between the first phantom window 11 and the second phantom window 12 may be 3d. After measuring the intensity of the radiation through the ionizing box 20 in the above state, the following steps are performed.

As shown in FIG. 5B, the phantom 10 is disposed so that the second phantom window 12 and the irradiator 30 face each other in order to measure radiation by placing the ionizing box 20 at a second position (depth B in the background description). It rotates 180 degrees by the rotating means 50. At this time, the distance C1 of the radiation irradiator 30 and the ionizing box 20 is disposed in the same manner as when the ionizing box 20 is disposed at the first position (depth A in the background description). This is possible because the rotation axis of the rotating means 50 is configured in the same line as the position where the ionizing box 20 is installed. In the arrangement state as described above, the distance between the second phantom window 12 and the ionosphere 20 is 2d. This is because the distance between the first phantom window 11 and the ionosphere 20 is d, and the distance between the first phantom window 11 and the second phantom window 12 is 3d. In this state, after measuring the intensity of the radiation through the ionizing box 20 to calculate the correction factor of the quality variable.

- Example 2

The rotary dual window phantom according to the second embodiment of the present invention is a configuration for calculating the quality variable correction factor according to the indirect determination method described in the background art.

Referring to FIG. 6, the rotatable dual window phantom includes a phantom 10, an ionizer 20, and a rotation means 60.

The configuration of the second embodiment is different from only the forming position of the rotation means 60 in the configuration of the first embodiment, the rest of the configuration will be described in detail only the configuration of the rotation means 60 or less.

The rotating means 60 includes a rotating groove 61 and the rotating shaft 62. The rotating means 60 is configured for rotating the phantom 10 about an axis perpendicular to the irradiation direction. The rotating shaft 62 is formed on the experiment table T on which the phantom 10 is mounted. The rotating shaft 62 is formed to protrude upward of the experiment table T in a cylindrical shape. The rotary groove 61 is configured to be inserted into the rotary shaft 62 and is formed recessed upward from the bottom surface of the phantom 10. In this case, the rotation groove 61 is preferably formed at the center of the first phantom window 11 and the second phantom window 12. That is, when the distance from the first phantom window 11 to the second phantom window 12 is 3d, the distance between the rotary groove 51 and the first phantom window 11 is 1.5d, and the rotary groove 51 and the second The distance from the phantom window 12 may also be 1.5d.

The above configuration enables calculation of the quality parameter correction factor according to the indirect determination method only by the rotation of the phantom 10 without changing the position of the irradiator and the ionizing box 20.

Hereinafter, an experimental method according to the phantom of the second embodiment of the present invention configured as described above will be described with reference to the drawings.

As shown in FIG. 7A, the phantom 10 is disposed so that the first phantom window 11 and the irradiator 30 face each other in order to measure the radiation by placing the ionizing box 20 at a first position (depth A in the background description). Place it. At this time, the distance (C2) of the radiation irradiator 30 and the first phantom window 11 is arranged to place the ionizing box 20 in a second position (depth B in the background description), and the radiation irradiator 30 and the second phantom window during measurement The distance in (12) should be the same. When the distance between the first phantom window 11 and the ionosphere 20 is d in the arrangement state as described above, the distance between the first phantom window 11 and the second phantom window 12 may be 3d. In addition, the distance between the first phantom window 11 and the rotation means 60 may be 1.5d. After measuring the intensity of the radiation through the ionizing box 20 in the above state, the following steps are performed.

As shown in FIG. 7B, the phantom 10 is disposed so that the second phantom window 12 and the irradiator 30 face each other in order to measure the radiation by placing the ionizing box 20 at a second position (depth B in the background description). It rotates 180 degrees by the rotating means 60. At this time, the distance C2 between the irradiator 30 and the second phantom window 12 is the radiation irradiator 30 and the first phantom window (when the ionizer 20 is disposed at the first position (depth A in the background description). It is arranged equal to the distance of 11). This is possible because the rotation axis of the rotation means 60 is configured in the center of the first phantom window 11 and the second phantom window 12. In the arrangement state as described above, the distance between the second phantom window 12 and the ionosphere 20 is 2d. This is because the distance between the first phantom window 11 and the ionosphere 20 is d, and the distance between the first phantom window 11 and the second phantom window 12 is 3d. In this state, after measuring the intensity of the radiation through the ionizing box 20 to calculate the correction factor of the quality variable.

In the above-described configuration, the rotating means 50 of the first embodiment and the rotating means 60 of the second embodiment are described, respectively, but the rotary grooves 52 and 62 according to the respective rotating means 50 and 60 are described. It will be possible to apply to one phantom 10, it is possible to apply by alternately inserting each of the rotary grooves 52, 62 in a single rotation shaft according to the experimental method.

The technical idea should not be construed as being limited to the above-described embodiment of the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, such modifications and changes are within the scope of protection of the present invention as long as it is obvious to those skilled in the art.

10: Phantom 11: First Phantom Window
12: second phantom window
20: ionizer 21: radiation measuring sensor
22: connecting cable
30: irradiator R: radiation
50, 60: rotation means 51, 61: rotation groove
52, 62: rotation axis

Claims (6)

A phantom on an enclosure filled with fluid therein;
An ionization box installed so that a radiation measuring sensor is located inside the phantom;
A first phantom window formed at a side of the phantom such that radiation irradiated from a radiation irradiator is transmitted to the inside of the phantom; And
A second phantom window formed on a side of the phantom opposite to the first phantom window such that radiation irradiated from a radiation irradiator is transmitted to the inside of the phantom;
Including, a rotary dual window phantom.
The method of claim 1,
On a line parallel to the irradiation direction,
The distance between the measurement sensor and the first phantom window is d, the distance between the measurement sensor and the second phantom window is 2d, the rotary dual window phantom.
The method of claim 2,
The phantom is,
Rotating means provided to be rotatable based on an axis perpendicular to the irradiation direction; Further comprising, a rotary dual window phantom.
The method of claim 3,
Wherein,
A rotating shaft protruding above the ground or the measuring table;
A rotary groove recessed upwardly from a bottom surface of the phantom to be fitted to the rotary shaft;
Rotate dual window phantom, characterized in that it comprises a.
5. The method of claim 4,
The rotary groove,
Parallel to the irradiation direction
Is formed in a portion corresponding to the measurement sensor, the distance between the first phantom window is d, the distance between the second phantom window is 2d, the rotary dual window phantom.
5. The method of claim 4,
The rotary groove,
Parallel to the irradiation direction
Is formed in the center of the first phantom window and the second phantom window, the distance between the first phantom window and the second phantom window is 1.5d, the rotary dual window phantom.

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