JP2016174674A - Radiation therapy apparatus controller, radiation therapy system, radiation therapy apparatus control method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enlarge a range to be irradiated with radiation by a radiation therapy apparatus and improve uniformity in radiation dose within an irradiation object range.SOLUTION: A radiation therapy apparatus controller which controls a radiation therapy apparatus includes: a radiation source for emitting radiation; a multi-leaf collimator provided at an aperture through which the radiation passes for forming an irradiation range of the radiation by operating a plurality of leaves capable of blocking the radiation; and an aperture moving part for moving the aperture so that the irradiation range of the radiation on a virtual plane moves in one direction within the virtual plane. The controller has a multi-leaf collimator control section for controlling the multi-leaf collimator so that a shape of the irradiation range of the radiation on the virtual plane simulates a shape having a side inclined to the direction orthogonal to the movement direction of the irradiation range of the radiation on the virtual plane.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a radiation therapy apparatus control apparatus, a radiation therapy system, a radiation therapy apparatus control method, and a program.

The radiation irradiation range (irradiation target range) is obtained by a single radiation irradiation with the position of the radiation irradiation device (the device that radiates radiation provided in the radiation therapy device) fixed. A technique for enlarging the irradiation area is proposed.
For example, in the radiation irradiation method described in Patent Document 1, a step of irradiating a first portion of a subject with a first radiation radiated from a first point and a first radiating from a second point are performed. Irradiating a second portion of the subject different from the first portion of the subject, and the position of the second point relative to the subject coincides with the position of the first point relative to the subject.
According to the radiation irradiation method described in Patent Document 1, it is possible to control the dose of radiation irradiated to the portion of the subject with higher accuracy using a smaller radiation irradiation apparatus. As a result, the bending of the support that supports the radiation irradiation apparatus is reduced, the radiation irradiation apparatus can be positioned with higher accuracy, and the portion irradiated with radiation can be controlled with higher accuracy.

JP 2008-173182 A

In the method of expanding the irradiation target range by irradiating the radiation multiple times, in order to uniformly irradiate the irradiation target range, the overlapping of the irradiation regions and the gap are made as small as possible at the joint of the irradiation regions for each irradiation. Thus, it is desirable to control the position and shape of the irradiation region.
On the other hand, as another method for expanding the radiation irradiation target range, a method of moving the irradiation region by changing the direction or position of the radiation irradiation apparatus while irradiating the radiation can be considered. In this method, since there is no joint between irradiation areas, it is not necessary to perform control for reducing the overlap or gap between irradiation areas. On the other hand, in the method of moving the irradiation area by changing the direction or position of the radiation irradiation apparatus while irradiating radiation, the irradiation area at the start of irradiation and the irradiation area at the end of irradiation are irradiated more than the irradiation area in the middle. Time may be shortened and dose may be reduced. In order to uniformly irradiate the irradiation target area with radiation, it is desirable that the irradiation time can be secured also in the irradiation region at the start of irradiation and the irradiation region at the end of irradiation.

  The present invention is capable of expanding a radiation irradiation range and improving the uniformity of radiation dose in the irradiation target range, a radiation therapy apparatus control device, a radiation therapy system, a radiation therapy apparatus control method, and a program I will provide a.

  According to the first aspect of the present invention, the radiation therapy apparatus control device operates a radiation source that emits radiation and a plurality of leaves that are provided in an opening through which the radiation passes and can shield the radiation, Radiation comprising: a multi-leaf collimator that forms the radiation irradiation region; and an opening moving unit that moves the opening so that the radiation irradiation region in the virtual plane moves in one direction in the virtual plane. A radiotherapy apparatus control apparatus for controlling a treatment apparatus, wherein a shape of the radiation irradiation area in the virtual plane is inclined with respect to a direction orthogonal to a moving direction of the radiation irradiation area in the virtual plane. A multi-leaf collimator controller that controls the multi-leaf collimator is provided so as to simulate the shape of the multi-leaf collimator.

  The multi-leaf collimator control unit simulates a shape in which the radiation irradiation area in the virtual plane has sides on the front side and the rear side in the movement direction of the virtual plane, and the virtual side of the virtual side The inclination with respect to the direction orthogonal to the moving direction of the radiation irradiation area on the plane and the inclination of the rear side with respect to the direction orthogonal to the movement direction of the radiation irradiation area on the virtual plane with the same direction and the same magnitude The multi-leaf collimator may be controlled so as to have an inclination.

  The opening moving unit moves the opening so that the irradiation region of the radiation in the virtual plane reciprocates in one direction in the virtual plane, and the multi-leaf collimator control unit moves the inclination in the forward path The multi-leaf collimator may be controlled so that the direction of the inclination in the return path is opposite.

  According to a second aspect of the present invention, a radiation therapy system operates a radiation source that emits radiation and a plurality of leaves that are provided in an opening through which the radiation passes and that can shield the radiation. A multi-leaf collimator that forms an irradiation area of the light source, an opening moving unit that moves the opening so that the irradiation area of the radiation in the virtual plane moves in one direction in the virtual plane, and the Multi-leaf collimator control for controlling the multi-leaf collimator so that the shape of the radiation irradiation region simulates a shape having a side inclined with respect to a direction orthogonal to the moving direction of the radiation irradiation region in the virtual plane A section.

  According to a third aspect of the present invention, a radiation therapy apparatus control method operates a radiation source that emits radiation, and a plurality of leaves that are provided in an opening through which the radiation passes and can shield the radiation, Radiation comprising: a multi-leaf collimator that forms the radiation irradiation region; and an opening moving unit that moves the opening so that the radiation irradiation region in the virtual plane moves in one direction in the virtual plane. A radiation therapy apparatus control method for a radiation therapy apparatus control apparatus for controlling a therapy apparatus, wherein a shape of the radiation irradiation area on the virtual plane is orthogonal to a movement direction of the radiation irradiation area on the virtual plane A multi-leaf collimator control step for controlling the multi-leaf collimator so as to simulate a shape having an inclined side with respect to the shape.

  According to a fourth aspect of the present invention, the program operates a radiation source that emits radiation and a plurality of leaves that are provided in an opening through which the radiation passes and can shield the radiation, thereby irradiating the radiation. A radiotherapy apparatus comprising: a multi-leaf collimator that forms a region; and an opening moving unit that moves the opening so that the irradiation region of the radiation in the virtual plane moves in one direction in the virtual plane. The computer is configured to simulate the shape of the radiation irradiation region in the virtual plane having a side inclined with respect to a direction orthogonal to the moving direction of the radiation irradiation region in the virtual plane. A program for executing a multi-leaf collimator control step for controlling a leaf collimator.

  According to the above-described radiotherapy apparatus control apparatus, radiotherapy system, radiotherapy apparatus control method, and program, it is possible to expand the radiation irradiation range and improve the uniformity of the radiation dose in the irradiation target area. Can do.

It is a schematic block diagram which shows the function structure of the radiotherapy system in one Embodiment of this invention. It is a schematic block diagram which shows the apparatus structure of the radiotherapy apparatus in the embodiment. It is explanatory drawing which shows the example of arrangement | positioning of the leaf in the multi-leaf collimator of the embodiment. It is a schematic block diagram which shows the function structure of the radiotherapy apparatus control apparatus in the embodiment. It is a figure which shows typically the example of formation of the irradiation area | region by the radiotherapy apparatus in the same embodiment. It is a figure which shows the example of a motion of the multileaf collimator in the case of formation of an irradiation area | region in the same embodiment. It is a figure which shows the example of a motion of the multileaf collimator in the case of formation of an irradiation area | region in the same embodiment. It is a figure which shows the example of a motion of the multileaf collimator in the case of formation of an irradiation area | region in the same embodiment. In the same embodiment, it is a figure which shows the example of the shape of an irradiation area | region in the case of reciprocating an irradiation area | region. In the same embodiment, it is a figure which shows the example of distribution of a radiation dose at the time of moving an irradiation area | region in one way. In the same embodiment, it is a figure which shows the example of distribution of a radiation dose at the time of reciprocating an irradiation area | region. It is a figure which shows the example of the shape of the irradiation object range in the embodiment. It is a figure which shows the example of the irradiation area | region set with respect to the irradiation object range in the same embodiment. In the embodiment, it is a figure which shows the example of operation | movement of the multileaf collimator by the radiation irradiation with respect to the irradiation object range. It is a figure which shows the example of the number attached | subjected to the leaf in the same embodiment. It is a figure which shows the example of the position of the leaf in the virtual multileaf collimator in the embodiment. In the same embodiment, it is a flowchart which shows the example of the procedure of the process which a radiotherapy system performs radiation irradiation.

Hereinafter, although embodiment of this invention is described, the following embodiment does not limit the invention concerning a claim. In addition, not all the combinations of features described in the embodiments are essential for the solving means of the invention.
FIG. 1 is a schematic block diagram showing a functional configuration of a radiation therapy system in one embodiment of the present invention. In FIG. 1, the radiation therapy system 1 includes a radiation therapy apparatus control apparatus 10 and a radiation therapy apparatus 20.

The radiation therapy system 1 is a system for performing radiation therapy. Specifically, the radiation therapy system 1 emits radiation (therapeutic radiation). The therapeutic radiation irradiated by the radiation therapy system 1 may be an electromagnetic wave such as an X-ray, or a particle beam such as a heavy particle beam or a proton beam.
The radiation therapy apparatus 20 performs irradiation of therapeutic radiation according to the control of the radiation therapy apparatus control apparatus 10.

FIG. 2 is a schematic configuration diagram showing a device configuration of the radiation therapy apparatus 20. In the figure, the radiotherapy apparatus 20 includes a turning drive device 211, an O-ring 212, a traveling gantry 213, a swing mechanism 221, an irradiation unit 230, and a couch 281. The irradiation unit 230 includes a radiation irradiation device 231 and a multi-leaf collimator (MLC) 232.
Further, in FIG. 2, a virtual plane P21 is shown as an example of the virtual plane. The virtual plane here is a plane approximately orthogonal to the therapeutic radiation B11 irradiated by the irradiation unit 230. For example, the virtual plane may be provided near the body surface of the patient PT, or may be provided near the upper surface of the couch 281.

The turning drive device 211 rotates the O-ring 212 while supporting the O-ring 212 on the base so as to be rotatable about the rotation axis A11. The rotation axis A11 is a vertical axis.
The O-ring 212 is formed in a ring shape centered on the rotation axis A12, and supports the traveling gantry 213 so as to be rotatable about the rotation axis A12. The rotation axis A12 is a horizontal axis (that is, an axis perpendicular to the vertical direction), and is orthogonal to the rotation axis A11 at the isocenter P11. The rotation axis A12 is fixed with respect to the O-ring 212. That is, the rotation axis A12 rotates around the rotation axis A11 as the O-ring 212 rotates.
The O-ring 212 rotates by itself so as to integrally rotate the traveling gantry 213 and each part installed in the traveling gantry 213 around the rotation axis A11. In particular, the O-ring 212 rotates the irradiation unit 230 around the rotation axis A11 by rotating itself.

The traveling gantry 213 is formed in a ring shape centered on the rotation axis A <b> 12, and is disposed inside the O-ring 212 so as to be concentric with the O-ring 212. The radiotherapy apparatus 20 further includes a travel drive device (not shown), and the travel gantry 213 rotates around the rotation axis A12 with power from the travel drive device.
The traveling gantry 213 rotates by itself to integrally rotate each part installed in the traveling gantry 213 around the rotation axis A12. In particular, the traveling gantry 213 rotates the irradiation unit 230 around the rotation axis A12 by rotating itself.

The swing mechanism 221 is fixed inside the ring of the traveling gantry 213 and supports the irradiation unit 230 on the traveling gantry 213. The head swing mechanism 221 rotates the irradiation unit 230 around a pan axis A21 and rotates the irradiation unit 230 around a tilt axis A22.
The pan axis A21 is an axis parallel to the rotation axis A12 and is fixed to the traveling gantry 213. The head swing mechanism 221 rotates the irradiation unit 230 about the pan axis A21 to swing the irradiation unit 230 left and right with respect to the rotation axis A12 (thus, left and right with respect to the patient PT). The patient PT is a treatment subject who is irradiated with the therapeutic radiation B11.
The tilt axis A22 is an axis orthogonal to the pan axis A21 and is fixed to the traveling gantry 213. The swing mechanism 221 rotates the irradiation unit 230 about the tilt axis A22 to swing the irradiation unit 230 in the direction of the rotation axis A12 (accordingly, up and down with respect to the patient PT).

The irradiation unit 230 irradiates the therapeutic radiation B11 having an irradiation region (irradiation field) having a shape corresponding to the shape of the affected part. The irradiation region referred to here is a region irradiated with the therapeutic radiation B11.
The radiation irradiation apparatus 231 corresponds to an example of a radiation source in the present invention, and emits therapeutic radiation B11. Since the radiation irradiating device 231 is supported by the traveling gantry 213 via the swing mechanism 221, once the radiation irradiating device 231 is directed to the isocenter P 11 by adjusting the swing mechanism 221, the swivel drive device 211 performs O Even if the ring 212 rotates or the traveling gantry 213 is rotated by the traveling drive device, the therapeutic radiation B11 always passes through the isocenter P11.

The multi-leaf collimator 232 is provided at the tip of the radiation irradiation apparatus 231 (the portion that emits the therapeutic radiation B11), and forms an irradiation region of the therapeutic radiation B11.
FIG. 3 is an explanatory diagram showing an example of leaf arrangement in the multi-leaf collimator 232. This figure shows an example in which the multi-leaf collimator 232 is viewed from the irradiation target side (lower side in the example of FIG. 2).

  In the figure, the X axis indicates the pan direction and the Y axis indicates the tilt direction. The pan direction here is the direction of movement of the irradiation region in the virtual plane P21 when the swing mechanism 221 rotates the irradiation unit 230 about the pan axis A21 (and accordingly, left and right with respect to the patient PT). Further, the tilt direction is the moving direction of the irradiation region in the virtual plane P21 when the irradiation unit 230 is rotated about the tilt axis A22 (thus, up and down with respect to the patient PT).

In FIG. 3, the multi-leaf collimator 232 is provided with an opening H <b> 11 through which the therapeutic radiation B <b> 11 emitted from the radiation irradiation device 231 passes. The multi-leaf collimator 232 includes a plurality of leaves 233 provided in the opening H11 so as to be able to shield part or all of the therapeutic radiation B11. Specifically, two leaves 233 are arranged in pairs so that they can be opened and closed in both directions (movable in the X-axis direction), and the leaves 233 are operated (moved in the X-axis direction) for treatment. An irradiation region of radiation B11 is formed. Operating the leaf 233 here means moving the leaf 233 in the X-axis direction to change the shape of the irradiation region.
Each of the leaves 233 has a length equal to or greater than the width of the opening H11 (the length in the X-axis direction), and can be closed with a single opening. That is, in a state where one leaf 233 is completely opened, the therapeutic radiation B11 in a region corresponding to the width of the leaf 233 can be shielded over the entire width of the opening H11 with only the other leaf 233.

Further, as described above, the swing mechanism 221 rotates the irradiation unit 230 to move the irradiation region of the therapeutic radiation B11 on the virtual plane P21. The head swing mechanism 221 corresponds to an example of an opening moving unit, and by causing the irradiation unit 230 to swing, the irradiation region of the therapeutic radiation B11 on the virtual plane P21 moves in one direction within the virtual plane P21. Then, the opening H11 of the multi-leaf collimator 232 is moved. In particular, the swing mechanism 221 rotates the irradiation unit 230 about the tilt axis A22 so that the irradiation region of the therapeutic radiation B11 on the virtual plane P21 is tilted in the virtual plane P21 (up and down with respect to the patient PT). ) The opening H11 of the multi-leaf collimator 232 is moved so as to move in one direction.
However, the opening moving unit included in the radiation therapy apparatus 20 is not limited to the swing mechanism 221. For example, the radiotherapy apparatus 20 may include an arm that supports the irradiation unit 230 movably in parallel with the upper surface of the couch 281 instead of the swing mechanism 221 as the opening moving unit.

The couch 281 is used when the patient PT lies down.
The radiation therapy apparatus control apparatus 10 controls the radiation therapy apparatus 20 to perform irradiation with the therapeutic radiation B11. The radiotherapy apparatus control apparatus 10 includes a computer, for example.
FIG. 4 is a schematic block diagram showing a functional configuration of the radiation therapy apparatus control apparatus 10. In the figure, the radiotherapy device control apparatus 10 includes an O-ring control unit 101, a traveling gantry control unit 102, a swing mechanism control unit 103, a multi-leaf collimator control unit 104, and a radiation irradiation device control unit 105. Prepare.

The O-ring control unit 101 controls the position of the O-ring 212 by controlling the rotation of the O-ring 212 by the turning drive device 211.
The traveling gantry control unit 102 controls the position (rotation angle) of each unit installed in the traveling gantry 213 by controlling the rotation of the traveling gantry 213 by the traveling drive device. In particular, the traveling gantry control unit 102 controls the position of the irradiation unit 230 in the traveling gantry 213.

The swing mechanism control unit 103 controls the swing (rotation about the pan axis A21 and rotation about the tilt axis A22) of the irradiation unit 230 by the swing mechanism 221.
The multi-leaf collimator control unit 104 controls the multi-leaf collimator 232 to form an irradiation region of the therapeutic radiation B11.
The radiation irradiation device control unit 105 controls the radiation irradiation device 231 to output (irradiate) the therapeutic radiation B11.
The radiotherapy apparatus control apparatus 10 controls the radiotherapy apparatus 20 based on, for example, a treatment plan created by a doctor in charge of radiotherapy using the treatment plan apparatus.

FIG. 5 is a diagram schematically illustrating an example of formation of an irradiation region by the radiation therapy apparatus 20. In the figure, an example of radiation irradiation by operating the multi-leaf collimator 232 and the swing mechanism 221 when the therapeutic radiation B11 is irradiated on a region longer than the width in the tilt direction of the opening H11 of the multi-leaf collimator 232 Is shown.
First, the radiation therapy apparatus 20 moves the irradiation region by the operation of the multi-leaf collimator 232 in a state where the swing mechanism 221 is fixed with the radiation irradiation apparatus 231 facing one end (starting end) of the irradiation target range. (Figure G111, G112).

Next, the radiation therapy apparatus 20 moves the irradiation region by rotating the irradiation unit 230 in the tilt direction by the swing mechanism 221 while fixing the position (opening / closing state) of each leaf 233 in the multi-leaf collimator 232. (Figure G113).
Thereafter, when the irradiation region (region irradiated with the therapeutic radiation B11) reaches the other end (termination) of the irradiation target range, the radiotherapy device 20 fixes the multi-swing mechanism 221 in a fixed state. The irradiation area is moved by the operation of the leaf collimator 232 (FIGS. G114 and G115).
Hereinafter, the position of the end portion of the leaf 233 in the multi-leaf collimator 232 in the pan direction is referred to as the position of the leaf 233.

Here, as shown in FIG. 5, a triangle is formed by connecting the corners inside the leaf 233 that are in contact with the opening (the corner that enters the opening most). That is, although the opening is not an accurate triangle due to the rectangular shape of the leaf 233, it has a shape simulating a triangle. Therefore, the shape of the irradiation area in the virtual plane P21 is also a shape simulating a triangle. Here, the shape simulating a certain shape (simulated shape) is a shape from which a simulated shape can be obtained by partial linear approximation or curve approximation.
Further, both sides L11 and L12 of the triangle are inclined with respect to a direction (Y-axis direction) orthogonal to the moving direction (X-axis direction) of the radiation irradiation region in the virtual plane.

  FIG. G121 shows an example of the distribution of radiation dose in the virtual plane. As shown in FIG. G121, the irradiation amount when the shape of the opening is triangular is such that the irradiation amount continuously changes in the direction (Y-axis direction) perpendicular to the moving direction of the radiation irradiation region. Yes (gradual). On the other hand, the amount of irradiation is uniform in the direction of movement of the radiation irradiation region (X-axis direction).

  6-8 is a figure which shows the example of a motion of the multileaf collimator in the case of formation of an irradiation area | region. FIG. 6 shows an example of the operation of the multi-leaf collimator 232 in chronological order from FIG. G211 in a state where the swing mechanism 221 is fixed with the radiation irradiation device 231 facing one end (starting end) of the irradiation target range. ing.

In FIG. G211, the leaf 233 on the right side (hereinafter referred to as the right leaf) in the drawing is fully closed so as to be able to open one side.
In FIGS. G212 to G215, the right leaf is gradually opened to increase the opening. The therapeutic radiation B11 output (irradiated) by the radiation irradiation device 231 passes through this opening and is irradiated to the affected part of the patient PT.

Here, as shown in FIG. G215, the positions (opening and closing states) of the plurality of consecutively arranged leaves 233 (right leaf) are different from each other by a distance L21 from the bottom to the top of the figure. The amount that is open is decreasing as you go. Thereby, the side (line L31) inclined with respect to the moving direction of the leaf 233 (the direction of the Y axis) is simulated.
As described above, the leaf 233 is gradually opened, so that a time for the leaf 233 to operate can be secured. Here, when it is assumed that the leaf 233 in the fully closed state is fully opened immediately, it takes time for the leaf 233 to open, and there is a possibility that the radiation dose is uneven. On the other hand, in the operation in which the leaf 233 illustrated in FIG. 6 gradually opens, the operation time of the leaf 233 can be secured, and the assumed position (open / closed state) of the leaf 233 and the actual leaf The difference from the position 233 can be reduced. Thereby, according to the operation in which the leaf 233 illustrated in FIG. 6 gradually opens, the unevenness of the radiation dose can be reduced.

In FIG. G216, in addition to the opening operation of the right leaf, the left leaf 233 (hereinafter referred to as the left leaf) as viewed in the drawing is closed to form a parallelogram. In particular, like the lines L32 and L33, sides inclined with respect to the moving direction of the leaf 233 are simulated. Thereby, the shape of the irradiation region of the therapeutic radiation B11 on the virtual plane P21 is inclined with respect to a direction (pan direction) orthogonal to the moving direction (tilt direction) of the irradiation region of the therapeutic radiation B11 on the virtual plane P21. It is a shape simulating a parallelogram having
Further, in FIGS. G211 to G216, the shape of the opening by the multi-leaf collimator 232 is a shape that simulates the movement of the parallelogram at a constant speed.

  FIG. 7 shows a state in which the position (open / closed state) of each leaf 233 in the multi-leaf collimator 232 is fixed. The radiation therapy apparatus 20 moves the irradiation region by rotating the irradiation unit 230 in the tilt direction by the swing mechanism 221 while fixing the position of each leaf 233 in the multi-leaf collimator 232.

Specifically, in FIG. 7, the shape of the opening that simulates the parallelogram described with reference to FIG. G216 of FIG. 6 is maintained. As described with reference to FIG. G133 in FIG. 5, the radiotherapy apparatus 20 rotates the swing mechanism 221 around the tilt axis while maintaining the shape of the opening that simulates the parallelogram. The irradiation area is moved in the tilt direction. Thereby, the shape of the irradiation region of the therapeutic radiation B11 on the virtual plane P21 is inclined with respect to a direction (pan direction) orthogonal to the moving direction (tilt direction) of the irradiation region of the therapeutic radiation B11 on the virtual plane P21. It is a shape simulating a parallelogram having
Note that the line on which the line L32 is projected onto the virtual plane corresponds to an example of the side on the front side in the movement direction of the virtual plane P21 in the irradiation region on the virtual plane. The line on which the line L33 is projected onto the virtual plane corresponds to an example of the rear side of the irradiation area on the virtual plane in the moving direction of the virtual plane P21.

Further, the line L32 and the line L33 are inclined in the same direction and the same size with respect to the pan direction. Thereby, the line (front side) on which the line L32 is projected on the virtual plane and the line (rear side) on which the line L33 is projected on the virtual plane have the same direction and the same size with respect to the pan direction. It is inclined.
Thereby, the length of the opening in the tilt direction becomes uniform. For example, the lengths D11 and D12 shown in FIG. G221 are the same length. By making the length of the opening in the tilt direction uniform, the irradiation time of the therapeutic radiation B11 when the irradiation region moves in the tilt direction can be made uniform, and in particular, the radiation dose can be made uniform in the pan direction. can do.

FIG. 8 shows that the irradiation region (region irradiated with the therapeutic radiation B11) reaches the other end (termination) of the irradiation target range, and the radiation therapy apparatus 20 is in a state where the swing mechanism 221 is fixed. The operation of the multi-leaf collimator 232 is shown in time order from FIG. G231.
In FIG. G231, the shape of the opening simulating the parallelogram in FIG. 7 is maintained.
In FIGS. G232 to G235, the right leaf is fully open, and the left leaf is gradually closed to reduce the opening.

Here, as shown in FIG. G232, the positions (open / closed states) of the plurality of consecutively arranged leaves 233 (left leaves) are different from each other by a distance L21, from the bottom to the top of the figure. The amount that is closed decreases as you head toward it. Thereby, a side inclined with respect to the moving direction of the leaf 233 (the direction of the Y axis) is simulated.
As described above, the leaf 233 is gradually closed, so that a time for the leaf 233 to operate can be secured. Here, when it is assumed that the leaf 233 in the fully opened state is fully closed immediately, it takes time for the leaf 233 to close, and there is a possibility that the radiation dose is uneven. On the other hand, in the operation in which the leaf 233 illustrated in FIG. 8 is gradually closed, the operation time of the leaf 233 can be secured, and the assumed position (opening / closing state) of the leaf 233 and the actual leaf The difference from the position 233 can be reduced. Thereby, according to the operation in which the leaf 233 illustrated in FIG. 8 is gradually closed, the unevenness of the radiation dose can be reduced.
In FIGS. G231 to G236, the shape of the opening by the multi-leaf collimator 232 is a shape that simulates the movement of the parallelogram at a constant speed.

FIG. 9 is a diagram illustrating an example of the shape of the irradiation region when the irradiation region is reciprocated. G311 shows an example of the shape of the irradiation area on the forward path, and FIG. G312 shows an example of the shape of the irradiation area on the return path.
In the example of FIG. 9, as described with reference to FIGS. 6 to 8, the shape of the opening of the multi-leaf collimator 232 is a shape that simulates a parallelogram, and the shape of the irradiation region is also a parallelogram in the example of FIG. The shape simulates the shape. In addition, the shape of the irradiation area is reversed left and right in the forward path and the return path. That is, the direction of the inclination of the side of the parallelogram simulating the shape of the irradiation region is opposite between the forward path and the backward path.

Next, with reference to FIGS. 10 and 11, an example of the radiation dose distribution will be described for each of the case where the irradiation region is moved in one way and the case where the irradiation region is reciprocated.
FIG. 10 is a diagram illustrating an example of the radiation dose distribution when the irradiation region is moved in one way. As shown in FIG. 6 to FIG. 8, this figure shows an example in which the shape of the irradiation region is changed to a shape simulating a parallelogram and moved in one way. Further, FIG. G410 shows an example of the irradiation target range of the therapeutic radiation B11. FIGS. G411, G412, and G413 are graphs showing the irradiation amount distribution in the opening / closing direction of the leaf 233 near the start of the irradiation target range, near the center of the irradiation target range, and near the end of the irradiation target range, respectively.
Looking at the graphs in FIGS. G411, G412, and G413, although the distributions in G411 and G413 are slightly different, the top portion of each graph is almost flat and is a graph that is close to a rectangle. Is evenly irradiated.

FIG. 11 is a diagram showing an example of the radiation dose distribution when the irradiation region is reciprocated. As shown in FIG. 9, this figure shows an example in which the irradiation area is reciprocally moved in a shape simulating a parallelogram. Further, FIG. G420 shows an example of an irradiation target range of the therapeutic radiation B11. FIGS. G421, G422, and G423 are graphs showing the distribution of the irradiation amount in the opening / closing direction of the leaf 233 near the start end of the irradiation target range, near the center of the irradiation target range, and near the end of the forward path of the irradiation target range, respectively. Yes.
Looking at the respective graphs in FIGS. G421, G422, and G423, the top portions of the graphs are almost flat and nearly rectangular, and the radiation is uniformly irradiated to the irradiation target range. In particular, as compared with FIG. 10, the uniformity of the irradiation amount distribution is further increased near the forward path start end and the forward path end of the irradiation target range.

In addition, the shape of the irradiation target range is not limited to the rectangle shown in FIG. 5 and FIGS.
FIG. 12 is a diagram illustrating an example of the shape of the irradiation target range.
FIG. 13 is a diagram illustrating an example of an irradiation region set for the irradiation target range in FIG. 12. The irradiation target range in FIG. 12 is longer in the tilt direction than the irradiation area in which the radiation therapy apparatus 20 can irradiate the radiation by one irradiation.

In accordance with the control of the radiotherapy apparatus control apparatus 10, the radiotherapy apparatus 20 first fixes the swing mechanism 221 by directing the radiation irradiation apparatus 231 within the range A <b> 31 and moves the irradiation area by operating the multi-leaf collimator 232. Irradiation for radiation B11. The range A31 includes one end (starting end) of the irradiation target range.
Next, the radiotherapy apparatus 20 irradiates the therapeutic radiation B11 while moving the irradiation area by rotating the swing mechanism 221 around the tilt axis according to the control of the radiotherapy apparatus control apparatus 10. At that time, the multi-leaf collimator 232 is operated according to the shape of the irradiation target range.
Thereafter, when the radiation irradiation device 231 faces the range A32, the radiation therapy device 20 fixes the swing mechanism 221 and irradiates the therapeutic radiation B11 while moving the irradiation region by the operation of the multi-leaf collimator 232. The range A32 includes the other end (termination) of the irradiation target range.

FIG. 14 is a diagram illustrating an example of the operation of the multi-leaf collimator 232 in radiation irradiation with respect to the irradiation target range in FIG.
First, the radiation therapy apparatus 20 fixes the swing mechanism 221 with the radiation irradiation apparatus 231 in the range A31, and operates the multi-leaf collimator so as to gradually widen the irradiation area from the start end of the irradiation target range. Irradiation is performed (FIGS. G511 and G512). At that time, as in the case of FIG. 6, the leaf 233 is opened stepwise. Thereby, the side (line L41) inclined with respect to the moving direction of the leaf 233 (the direction of the Y axis) is simulated.

  Next, the radiation therapy apparatus 20 irradiates the therapeutic radiation B11 while moving the irradiation region by rotating the swing mechanism 221 about the tilt axis (FIGS. G521 and G522). At that time, the multi-leaf collimator 232 is operated according to the shape of the irradiation target range. Further, sides (lines L42 and L43) that are inclined with respect to the moving direction of the leaf 233 (the direction of the Y axis) are simulated.

  Thereafter, when the irradiation region includes the end of the irradiation target range, the radiation therapy apparatus 20 fixes the swing mechanism 221 and operates the multi-leaf collimator so as to gradually narrow the irradiation region toward the end of the irradiation target range. Then, therapeutic radiation is irradiated (FIGS. G531, G532). At that time, the leaf 233 is closed stepwise as in the case of FIG. Thereby, a side (line L44) inclined with respect to the moving direction of the leaf 233 (the direction of the Y axis) is simulated.

  The position of the leaf 233 in the radiation irradiation described with reference to FIG. 12 to FIG. 14 is expressed as in Expression (1).

Here, t indicates time. As the value of t, the elapsed time from the start of radiation irradiation to the irradiation target is used.
MCL _i (t) indicates the position of the i-th leaf. i is a positive integer representing 1 ≦ i ≦ M indicating the leaf number. M is a constant (for example, M = 30) indicating the number of columns of leaves (the number of columns composed of pairs of left and right leaves). The leaf position here is the distance from a predetermined reference position to the tip of the leaf in the pan direction. The predetermined reference position can be set at various positions. For example, the center of the opening of the multi-leaf collimator 232 (the center of the left end and the right end of the opening H11 shown in FIG. 3 in the drawing) may be used as the reference position. Alternatively, the end of the opening (either the left end or the right end of the opening H11 shown in FIG. 3 in the drawing) may be used as the reference position.
The following constants are set for each of the left leaf and the right leaf to determine the leaf position. When the irradiation area is reciprocated, the leaf position is obtained by setting each constant for the forward path and the return path.

  FIG. 15 is a diagram illustrating an example of numbers assigned to the leaves 233. In the drawing, a set of two leaves 233 included in the multi-leaf collimator 232 is set as a row, and numbers 1, 2,..., M are sequentially given from the lower row in the drawing. The multi-leaf collimator 232 includes a left leaf and a right leaf in each column, and the multi-leaf collimator 232 includes 2M leaves.

G _i (t) in the equation (1) is a term for simulating a side inclined with respect to the moving direction of the leaf 233 (the direction of the Y axis) as indicated by lines L51 and L52 in FIG. It is shown as (2).

Here, b _i is a parameter indicating the magnitude of the inclination of the side inclined with respect to the movement direction (Y-axis direction) of the leaf 233 with respect to the movement direction of the leaf 233, as indicated by lines L51 and L52 in FIG. The numerical value varies depending on the time.
a _i and c _i are constants.
t ₁ indicates the time when the swing mechanism 221 starts to rotate around the tilt axis.
t ₂ represents the time at which swing mechanism 221 is completed rotation about the tilt axis.
F _i (t) is a term for adjusting the irradiation region to the irradiation target. This F _i (t) is preset as the position of the virtual multi-leaf collimator, for example.

FIG. 16 is a diagram illustrating an example of a leaf position in the virtual multi-leaf collimator. In the figure, each leaf of the virtual multi-leaf collimator is set according to the shape of the irradiation target.
Here, the length of the irradiation target in the X-axis direction is longer than the width of the opening H11 (FIG. 3) of the multi-leaf collimator 232 in the X-axis direction (tilt direction), and thereby the opening of the virtual multi-leaf collimator. The width in the X-axis direction is longer than the width in the X-axis direction of the opening H11 of the multi-leaf collimator 232. On the other hand, the width (length in the X-axis direction) of each leaf in the virtual multi-leaf collimator is the same as the width in the multi-leaf collimator 232. For this reason, the number N of leaf rows in the virtual multi-leaf collimator is larger than the number M of rows of leaves 233 in the multi-leaf collimator 232.

The value of F _i (t) in Expression (1) is a value indicating the position of any leaf when the irradiation region of the virtual multi-leaf collimator is matched with the irradiation target as in the example of FIG.
For example, the position of the opening H11 of the multi-leaf collimator 232 is from the start of radiation irradiation to the irradiation target until the swing mechanism 221 starts rotating around the tilt axis (0 ≦ t ≦ t ₁ ). This corresponds to the position of the area A31 shown in FIG. Therefore, the value of F _i (t) (1 ≦ i ≦ M) is a value indicating the leaf of the column of number 1 in FIG.

On the other hand, when the time s has elapsed from the time t ₁ (t = t ₁ + s) and the position of the opening H11 of the multi-leaf collimator 232 is shifted from the position of the time by one leaf width, F _i The value of (t ₁ + s) is a value indicating the leaf of the column of number i + 1 in FIG.
Further, at t ₁ <t ≦ t ₂ , the time k × s has elapsed from time t ₁ (t = t ₁ + k × s), and the position of the opening H11 of the multi-leaf collimator 232 is changed from the time position to the leaf position. In a state shifted by k widths, the value of F _i (t ₁ + k × s) is a value indicating the leaf of the column of number i + k in FIG.
Further, after the swing mechanism 221 stops rotating around the tilt axis (t ₂ <t), the value of F _i (t) is a value indicating the leaf in the column of number i + (N−M) in FIG. It becomes.

Next, the operation of the radiation therapy system 1 will be described with reference to FIG.
FIG. 17 is a flowchart illustrating an example of a processing procedure in which the radiation therapy system 1 performs radiation irradiation. For example, when the radiation treatment system 1 receives a user operation for instructing the start of the irradiation of the therapeutic radiation B11, the radiation treatment system 1 starts the process of FIG.
In the process of FIG. 17, the radiation irradiation apparatus control unit 105 instructs the radiation irradiation apparatus 231 to start outputting the therapeutic radiation B11, and the radiation irradiation apparatus 231 starts outputting the therapeutic radiation B11 according to the instruction. (Step S101).

Next, the multi-leaf collimator control unit 104 instructs the multi-leaf collimator 232 to operate the leaf, and the multi-leaf collimator 232 moves the leaf 233 according to the instruction, and the examples of FIGS. G511 and G512 in FIG. In this way, the shape of the irradiation region is matched with the shape of the irradiation target, and the range of the irradiation region is expanded (step S102).
Next, the radiation therapy apparatus control apparatus 10 determines whether the time t is t ₁ <t, that is, whether it is time to start the rotation of the swing mechanism 221 around the tilt axis (step S103). ).
When it is determined that t ₁ <t is not satisfied (step S103: NO), the process returns to step S102.

On the other hand, if it is determined in step S103 that t ₁ <t (step S103: YES), the swing mechanism 221 moves the irradiation area, and the multi-leaf collimator 232 sets the shape of the irradiation area. (Step S111). Specifically, the swing mechanism control unit 103 instructs the swing mechanism 221 to rotate about the tilt axis, and tilts the irradiation region by rotating the swing mechanism 221 around the tilt axis according to the instruction. Move in the direction. In addition, the multi-leaf collimator control unit 104 instructs the multi-leaf collimator 232 to operate the leaf, and the multi-leaf collimator 232 moves the leaf 233 according to the instruction to match the shape of the irradiation region with the shape of the irradiation target. .

Next, the radiation therapy apparatus control apparatus 10 determines whether or not the time t is t ₂ <t, that is, whether or not the swing mechanism 221 has finished rotating around the tilt axis (step S112). ).
When it is determined that t ₂ <t is not satisfied (step S112: NO), the process returns to step S111.

On the other hand, if it is determined in step S112 that t ₂ <t (step S112: YES), the multi-leaf collimator control unit 104 instructs the multi-leaf collimator 232 to operate the leaf, and the multi-leaf collimator In step S121, the leaf 233 moves the leaf 233 according to the instruction to match the shape of the irradiation region with the shape of the irradiation target as in the examples of FIGS. G531 and G532 in FIG. ).

Next, the radiation therapy apparatus control apparatus 10 determines whether or not the time t becomes t _E <t (step S122). Here, time t _E is the time at which the irradiation of the therapeutic radiation B11 ends.
When it is determined that t _E <t is not satisfied (step S122: NO), the process returns to step S121.

On the other hand, when it is determined in step S122 that t _E <t is satisfied (step S122: YES), the radiation irradiation apparatus control unit 105 instructs the radiation irradiation apparatus 231 to end the output of the therapeutic radiation B11. The radiation irradiation apparatus 231 ends the output of the therapeutic radiation B11 in accordance with the instruction (step S131).
Then, the process of FIG. 17 is complete | finished.

As described above, the multi-leaf collimator control unit 104 is configured such that the shape of the irradiation region of the therapeutic radiation B11 on the virtual plane P21 is orthogonal to the moving direction (tilt method) of the irradiation region of the therapeutic radiation B11 on the virtual plane P21. The multi-leaf collimator 232 is controlled so as to simulate a shape having a side inclined with respect to (pan direction = movement direction of the leaf 233).
Accordingly, the multi-leaf collimator control unit 104 can operate the leaf 233 gradually by operating the leaf 233 of the multi-leaf collimator 232 according to the side inclined with respect to the moving direction of the leaf 233. Time for 233 to operate can be secured. The difference between the assumed position of the leaf 233 and the actual position of the leaf 233 can be reduced in that the leaf 233 only needs to be operated gradually, and unevenness in the radiation dose can be reduced.
Thus, according to the radiotherapy apparatus control apparatus 10, the range in which the radiation irradiation apparatus 231 irradiates the therapeutic radiation B11 can be expanded, and the uniformity of the radiation dose in the irradiation target range can be improved. it can.

In addition, the multi-leaf collimator control unit 104 simulates the shape of the irradiation region of the therapeutic radiation B11 on the virtual plane P21 having sides on the front side and the rear side in the moving direction of the virtual plane P21. Inclination with respect to a direction (pan direction = movement direction of the leaf 233) orthogonal to the moving direction (tilt direction) of the therapeutic radiation irradiation region in the virtual plane P21 and the radiation irradiation region in the virtual plane P21 of the rear side The multi-leaf collimator 232 is controlled so that the inclination with respect to the direction orthogonal to the moving direction is the same direction and the same magnitude.
As a result, as described with reference to FIG. 7, the length of the opening in the tilt direction becomes uniform. By making the length of the opening in the tilt direction uniform, the irradiation time of the therapeutic radiation B11 when the irradiation region moves in the tilt direction can be made uniform, and in particular, the radiation dose can be made uniform in the pan direction. can do.

The swing mechanism 221 moves the opening H11 of the multi-leaf collimator 232 so that the irradiation area of the therapeutic radiation B11 on the virtual plane P21 reciprocates in one direction in the virtual plane P21. The multi-leaf collimator control unit 104 controls the multi-leaf collimator 232 so that the inclination direction in the forward path is opposite to the inclination direction in the return path.
Thereby, as described with reference to FIG. 11, it is possible to further improve the uniformity of the irradiation amount in the irradiation target range of the therapeutic radiation B <b> 11.

A program for realizing all or part of the functions of the radiotherapy apparatus control apparatus 10 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed. The processing of each unit may be performed as necessary. Here, the “computer system” includes an OS and hardware such as peripheral devices.
Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used.
The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design changes and the like without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 1 Radiation therapy system 10 Radiation therapy apparatus control apparatus 20 Radiation therapy apparatus 211 Rotation drive apparatus 212 O-ring 213 Traveling gantry 221 Swing mechanism 230 Irradiation part 231 Radiation irradiation apparatus 232 Multi-leaf collimator 233 Leaf 281 Couch

Claims (6)

A radiation source that emits radiation;
A multi-leaf collimator that is provided in an opening through which the radiation passes and operates a plurality of leaves capable of shielding the radiation to form an irradiation region of the radiation;
An opening moving unit that moves the opening so that the irradiation region of the radiation in the virtual plane moves in one direction in the virtual plane;
A radiotherapy apparatus control apparatus for controlling a radiotherapy apparatus comprising:
The multi-leaf collimator is controlled so that the shape of the radiation irradiation region in the virtual plane simulates a shape having a side inclined with respect to a direction orthogonal to the moving direction of the radiation irradiation region in the virtual plane. A radiotherapy apparatus control device comprising a multi-leaf collimator control unit.   The multi-leaf collimator control unit simulates a shape in which the radiation irradiation area in the virtual plane has sides on the front side and the rear side in the movement direction of the virtual plane, and the virtual side of the virtual side The inclination with respect to the direction orthogonal to the moving direction of the radiation irradiation area on the plane and the inclination of the rear side with respect to the direction orthogonal to the movement direction of the radiation irradiation area on the virtual plane with the same direction and the same magnitude The radiotherapy apparatus control apparatus according to claim 1, wherein the multi-leaf collimator is controlled so as to be inclined. The opening moving unit moves the opening so that the irradiation region of the radiation in the virtual plane reciprocates in one direction in the virtual plane,
The radiotherapy apparatus control device according to claim 2, wherein the multi-leaf collimator control unit controls the multi-leaf collimator so that the inclination direction in the forward path and the inclination direction in the return path are opposite to each other. . A radiation source that emits radiation;
A multi-leaf collimator that is provided in an opening through which the radiation passes and operates a plurality of leaves capable of shielding the radiation to form an irradiation region of the radiation;
An opening moving unit that moves the opening so that the irradiation region of the radiation in the virtual plane moves in one direction in the virtual plane;
The multi-leaf collimator is controlled so that the shape of the radiation irradiation region in the virtual plane simulates a shape having a side inclined with respect to a direction orthogonal to the moving direction of the radiation irradiation region in the virtual plane. A multi-leaf collimator control unit,
A radiation therapy system comprising: A radiation source that emits radiation;
A multi-leaf collimator that is provided in an opening through which the radiation passes and operates a plurality of leaves capable of shielding the radiation to form an irradiation region of the radiation;
An opening moving unit that moves the opening so that the irradiation region of the radiation in the virtual plane moves in one direction in the virtual plane;
A radiotherapy apparatus control method of a radiotherapy apparatus control apparatus for controlling a radiotherapy apparatus comprising:
The multi-leaf collimator is controlled so that the shape of the radiation irradiation region in the virtual plane simulates a shape having a side inclined with respect to a direction orthogonal to the moving direction of the radiation irradiation region in the virtual plane. A radiotherapy apparatus control method comprising a multi-leaf collimator control step. A radiation source that emits radiation;
A multi-leaf collimator that is provided in an opening through which the radiation passes and operates a plurality of leaves capable of shielding the radiation to form an irradiation region of the radiation;
An opening moving unit that moves the opening so that the irradiation region of the radiation in the virtual plane moves in one direction in the virtual plane;
A computer for controlling a radiotherapy apparatus comprising:
The multi-leaf collimator is controlled so that the shape of the radiation irradiation region in the virtual plane simulates a shape having a side inclined with respect to a direction orthogonal to the moving direction of the radiation irradiation region in the virtual plane. A program for executing a multi-leaf collimator control step.