JP6259283B2 - Model generation apparatus, radiotherapy apparatus control apparatus, and model generation method - Google Patents

Description

  The present invention relates to a model generation apparatus, a radiotherapy apparatus control apparatus, and a model generation method.

In radiation therapy, in addition to irradiating a radiation irradiation target such as a tumor, it is desired to reduce the exposure dose of a normal site, and several related techniques have been proposed.
For example, the method described in Patent Document 1 calculates the predicted path 73 based on the affected part positions 71-0 to 71-n where the affected part is arranged at the measurement times t0 to tn, and controls based on the predicted path 73. There is a difference between the step of calculating the path 75, the step of controlling the drive device that drives the radiation irradiation apparatus so that the radiation irradiation apparatus faces the control path 75, and the predicted path 73. Controlling the radiation irradiating apparatus so that the therapeutic radiation is exposed only when it is within a predetermined error range. According to such an operation, the radiation irradiation apparatus can be driven with higher accuracy so that the period during which the therapeutic radiation is exposed to the affected area becomes longer.

JP 2011-160942 A

  In radiotherapy, when a fluoroscopic image is captured using X-rays in order to grasp the position of an irradiation target other than during irradiation with therapeutic radiation, a normal site is exposed. In particular, in moving body tracking irradiation, when imaging of a fluoroscopic image of an irradiation target is repeated at short time intervals in order to build a model that shows the relationship between the respiration signal by an infrared marker or the like and the position of the irradiation target, the exposure dose of a normal part Will increase. On the other hand, when reducing the number of fluoroscopic images, such as by increasing the imaging interval of fluoroscopic images in order to reduce the exposure dose of normal parts, if the accuracy of the model decreases due to the decrease in the number of fluoroscopic images obtained, therapeutic radiation Exposure to normal sites may increase during irradiation.

  The present invention has been made in consideration of such circumstances, and the purpose of the present invention is to generate information on the position information of the irradiation target such as fluoroscopic image capturing when generating a model indicating the position of the irradiation target for radiotherapy. The object is to reduce the number of acquisitions and to generate a model with higher accuracy.

  According to the first aspect of the present invention, the model generation device includes a reference model storage unit that stores a reference model of movement of an irradiation target that periodically moves, and a respiratory signal that is a signal generated in synchronization with respiration. The information indicating the position of the irradiation target is acquired at a predetermined timing indicated by the phase of the respiratory signal in the respiratory signal acquisition unit to be acquired and the irradiation target position information acquisition device that acquires the information indicating the position of the irradiation target. An irradiation target position model indicating a relationship between the respiratory signal and the position of the irradiation target based on the position information acquisition control unit, the reference model, the respiratory signal, and the information indicating the position of the irradiation target. A model generation unit for generation.

  The reference model storage unit stores the reference model at the time of inspiration and the reference model at the time of expiration, and the model generation unit is information indicating the position of the irradiation target acquired by the irradiation target position information acquisition device Based on the position history information generation unit that generates the history information of the position of the irradiation target by combining the reference model at the time of inspiration and the reference model at the time of expiration, and based on the history information of the position of the irradiation target A parameter setting unit that sets parameters of the irradiation target position model.

  The position information acquisition control unit may cause the irradiation target position information acquisition device to acquire information indicating the position of the irradiation target at the timing of the peak position of the respiratory signal.

  The position information acquisition control unit causes the irradiation target position information acquisition device to acquire information indicating the position of the irradiation target at the timing of the peak position of the irradiation target predicted from the timing of the peak position of the respiratory signal. It may be.

  The position information acquisition control unit suppresses acquisition of information indicating the position of the next irradiation target for a predetermined time after the irradiation target position information acquisition apparatus acquires information indicating the position of the irradiation target. Also good.

  The position information acquisition control unit may cause the irradiation target position information acquisition device to acquire information indicating the position of the irradiation target in a predetermined time range corresponding to the timing of the peak position of the respiratory signal.

  Further, according to the second aspect of the present invention, the radiotherapy device control apparatus includes a reference model storage unit that stores a reference model of movement of an irradiation target that moves periodically, and a signal that is generated in synchronization with respiration. A respiratory signal acquisition unit that acquires a respiratory signal, an irradiation target position information acquisition device that acquires information indicating the position of the irradiation target, and the irradiation target position information acquisition at a predetermined timing indicated by the phase of the respiratory signal Based on the position information acquisition control unit that causes the apparatus to acquire information indicating the position of the irradiation target, the reference model, the respiratory signal, and the information indicating the position of the irradiation target, the respiratory signal and the irradiation target A model generation unit that generates an irradiation target position model that indicates a relationship with the position of the radiation, and controls irradiation of the radiation irradiation apparatus based on the irradiation target position model generated by the model generation unit A morphism controller comprises a.

  According to the third aspect of the present invention, the model generation method includes a respiration signal acquisition step of acquiring a respiration signal that is a signal generated in synchronization with respiration, and a predetermined phase indicated by the phase of the respiration signal. Based on a position information acquisition step of acquiring information indicating the position of the irradiation target at timing, a reference model of the movement of the irradiation target that periodically moves, the respiratory signal, and information indicating the position of the irradiation target. And a model generation step of generating an irradiation target position model indicating a relationship between the respiratory signal and the position of the irradiation target.

  According to the model generation device, the radiotherapy device control device, and the model generation method described above, when generating a model indicating the position of the irradiation target for radiotherapy, the number of times of acquisition of the position information of the irradiation target such as imaging of a fluoroscopic image is calculated. Reduced and higher accuracy models can be generated.

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 infrared marker which the infrared camera in the embodiment images. It is a schematic block diagram which shows the function structure of the radiotherapy apparatus control apparatus in the embodiment. It is explanatory drawing which shows the example of the reference | standard model which the reference | standard model memory | storage part in the same embodiment memorize | stores. It is explanatory drawing which shows the example of acquisition of the irradiation target in the same embodiment. It is explanatory drawing which shows the example of the historical information of the position of the irradiation target which the position history information generation part in the embodiment acquires. It is explanatory drawing which shows the example of the flow of a treatment at the time of implementing tracking irradiation of multiple times with respect to the same patient using the radiotherapy system in the embodiment. It is a flowchart which shows the process sequence which the radiotherapy apparatus control apparatus in the embodiment acquires an irradiation object position model using a reference | standard model. It is explanatory drawing which shows the example of prediction of the position of irradiation object using the irradiation object position model obtained in the process sequence which the radiotherapy apparatus control apparatus in the embodiment performs.

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 therapy planning device 11, a radiation therapy device control device 12, and a radiation therapy device 13.

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.
In particular, the radiation therapy system 1 performs radiation irradiation by tracking irradiation. The tracking irradiation referred to here is a method of acquiring position information of an irradiation target that moves by breathing or the like in real time, and controlling the radiation therapy apparatus so as to continuously irradiate the irradiation target with radiation. In addition, the irradiation target here is a portion that is a target of therapeutic radiation irradiation in a patient's body, such as a tumor.

  The treatment planning device 11 generates a treatment plan for the radiation treatment system 1 to emit therapeutic radiation. The treatment plan here is information indicating the content of control performed by the radiation therapy apparatus control apparatus 12 on the radiation therapy apparatus 13. Specifically, the treatment plan generated by the radiation therapy system 1 indicates a plan of how to operate the radiation therapy apparatus 13 to perform irradiation of therapeutic radiation.

The radiation therapy apparatus control device 12 controls the radiation therapy apparatus 13 according to the treatment plan generated by the treatment planning apparatus 11 and causes the therapeutic radiation to be emitted by the tracking irradiation. The radiotherapy device control device 12 includes, for example, a computer. In particular, the radiotherapy apparatus control apparatus 12 generates a model indicating the relationship between the respiratory signal and the position of the irradiation target, detects the position of the irradiation target using the model, and controls the radiotherapy apparatus. .
The radiation therapy apparatus 13 performs irradiation with therapeutic radiation according to the control of the radiation therapy apparatus control apparatus 12.

  FIG. 2 is a schematic configuration diagram showing a device configuration of the radiation therapy apparatus 13. In the figure, the radiotherapy apparatus 13 includes a turning drive device 311, an O-ring 312, a traveling gantry 313, a swing mechanism (Gimbal mechanism) 321, an irradiation unit 330, sensor arrays 351, 361, and 362 and a couch 381. The irradiation unit 330 includes a radiation irradiation device 331, a multi-leaf collimator (MLC) 332, imaging radiation sources 341 and 342, and an infrared (IR) camera 391.

The turning drive device 311 supports the O-ring 312 on the base so as to be rotatable about the rotation axis A <b> 11, and rotates the O-ring 312 according to the control of the radiotherapy device control device 12. The rotation axis A11 is a vertical axis.
The O-ring 312 is formed in a ring shape centered on the rotation axis A12, and supports the traveling gantry 313 so as to be rotatable about the rotation axis A12. The rotation axis A12 is an axis in the longitudinal direction of the couch 381. 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 312. That is, the rotation axis A12 rotates around the rotation axis A11 as the O-ring 312 rotates.

The traveling gantry 313 is formed in a ring shape centered on the rotation axis A <b> 12, and is disposed inside the O-ring 312 so as to be concentric with the O-ring 312. The radiotherapy device 13 further includes a travel drive device (not shown), and the travel gantry 313 rotates about the rotation axis A12 with power from the travel drive device.
When the traveling gantry 313 rotates, the traveling gantry 313 integrally rotates components such as the imaging radiation source 341 and the sensor array 361, the imaging radiation source 342 and the sensor array 362.

  The swing mechanism 321 is fixed inside the ring of the traveling gantry 313 and supports the irradiation unit 330 on the traveling gantry 313. The head swing mechanism 321 supports the irradiation unit 330 so that the direction of the irradiation unit 330 can be changed, and changes the direction of the irradiation unit 330 according to the control of the radiation therapy apparatus control device 12. Specifically, the swing mechanism 321 rotates the irradiation unit 330 around a pan axis A21 parallel to the rotation axis A12. Further, the swing mechanism 321 rotates the irradiation unit 330 around the tilt axis A22 orthogonal to the pan axis A21.

The irradiation unit 330 is arranged inside the traveling gantry 313 and supported by the swing mechanism 321 and irradiates therapeutic radiation and imaging radiation.
The radiation irradiation apparatus 331 irradiates therapeutic radiation toward the affected part of the patient T11 according to the control of the radiotherapy apparatus control apparatus 12.
The multi-leaf collimator 332 shields part or all of the therapeutic radiation by opening and closing the leaf according to the control of the radiotherapy apparatus controller 12. Thereby, the multi-leaf collimator 332 adjusts the irradiation field when the therapeutic radiation is irradiated to the patient T11.

  The imaging radiation source 341 emits imaging radiation (X-rays) toward the sensor array 361 under the control of the radiation therapy apparatus control device 12. The imaging radiation source 342 emits imaging radiation toward the sensor array 362 under the control of the radiation therapy apparatus control device 12. The imaging radiation sources 341 and 342 are fixed to the irradiation unit 330 (for example, the housing of the multi-leaf collimator 332) in a direction in which the irradiated radiation is orthogonal.

  The sensor array 351 is arranged at the position where the therapeutic radiation from the radiation irradiation apparatus 331 is applied, facing the radiation irradiation apparatus 331, and is fixed inside the ring of the traveling gantry 313. The sensor array 351 receives the therapeutic radiation transmitted through the patient T11 and the like for confirmation of the irradiation position and recording of treatment. In addition, light reception here is receiving radiation.

The sensor array 361 is arranged at the position where the imaging radiation from the imaging radiation source 341 is applied, facing the imaging radiation source 341, and is fixed inside the ring of the traveling gantry 313. The sensor array 361 receives the imaging radiation irradiated from the imaging radiation source 341 and transmitted through the patient T11 and the like for specifying the affected part position.
The sensor array 361 receives imaging radiation from the imaging radiation source 341, whereby a radiation image is obtained.

The sensor array 362 is arranged at the position where the imaging radiation from the imaging radiation source 342 strikes and faces the imaging radiation source 342 and is fixed inside the ring of the traveling gantry 313. The sensor array 362 receives the imaging radiation irradiated from the imaging radiation source 342 and transmitted through the patient T11 and the like for specifying the affected part position.
The sensor array 362 receives imaging radiation from the imaging radiation source 342, whereby a radiation image is obtained. In particular, the combination of the imaging radiation source 342 and the sensor array 362 provides a radiation image from a different direction from the combination of the imaging radiation source 341 and the sensor array 361.

  Information indicating the position of the irradiation target is obtained when a model for moving body tracking irradiation is generated by a combination of the imaging radiation source 341 and the sensor array 361 or a combination of the imaging radiation source 342 and the sensor array 362. . Specifically, by capturing a fluoroscopic image of the irradiation target with a combination of the imaging radiation source 341 and the sensor array 361 or a combination of the imaging radiation source 342 and the sensor array 362, a three-dimensional image of the irradiation target is obtained. Location information is obtained. The combination of the imaging radiation source 341 and the sensor array 361 and the combination of the imaging radiation source 342 and the sensor array 362 correspond to an example of an irradiation target position information acquisition apparatus.

  However, the configuration of the irradiation target position information acquisition apparatus is not limited to the combination of the imaging radiation source 341 and the sensor array 361 and the combination of the imaging radiation source 342 and the sensor array 362, and acquires the irradiation target position information. Various possible configurations are possible. For example, as the irradiation target position information acquisition device, a positioning device that outputs position information may be embedded in the vicinity of the irradiation target.

  The couch 381 is used for the patient T11 to lie down and supports the patient T11. The couch 381 is installed so that the longitudinal direction thereof faces the direction of the rotation axis A12. The couch 381 can be moved in various directions with the longitudinal direction thereof directed toward the rotation axis A12.

  An infrared (IR) camera 391 receives infrared rays and captures infrared images. In particular, the infrared camera 391 is installed toward the patient T11 lying on the couch 381. And the infrared camera 391 images the infrared marker provided in the body surface near the affected part of patient T11, and acquires the positional information on the said infrared marker in real time. In particular, the infrared camera 391 acquires position information of the infrared marker at the time in association with the time information.

  FIG. 3 is an explanatory diagram showing an arrangement example of the infrared markers imaged by the infrared camera 391. In the example of the figure, an infrared marker M11 is provided on the abdominal surface of the patient T11. The infrared marker M11 periodically moves in synchronization with the breathing of the patient T11, and the position information obtained by the infrared camera 391 imaging the infrared marker M11 is a signal of a respiratory signal that is generated in synchronization with the breathing. This is an example.

  At the time of irradiation of therapeutic radiation, the radiation therapy apparatus control device 12 calculates the position of the irradiation target in real time based on the respiratory signal obtained by the infrared camera 391 imaging the infrared marker M11, and the therapeutic radiation becomes the irradiation target. The head swing mechanism 321 is controlled so as to irradiate.

  When generating a model indicating the relationship between the respiratory signal and the position of the irradiation target, the infrared camera 391 captures the infrared marker M11, the combination of the imaging radiation source 341 and the sensor array 361, and the imaging radiation. The position information of the target part is acquired by a combination of the source 342 and the sensor array 362. Thereby, the relationship between the respiratory signal and the position of the irradiation target is shown, and the model can be generated.

  FIG. 4 is a schematic block diagram showing a functional configuration of the radiation therapy apparatus control apparatus 12. In the figure, the radiotherapy device control apparatus 12 includes a communication unit 210, a storage unit 220, and a processing unit 230. The storage unit 220 includes a reference model storage unit 221 and a template storage unit 222. The processing unit 230 includes a position information acquisition control unit 231 and a model generation unit 232. The model generation unit 232 includes a position history information generation unit 233 and a parameter setting unit 234.

The communication unit 210 communicates with the treatment planning device 11 (FIG. 1) and the radiation treatment device 13. In particular, the communication unit 210 acquires a treatment plan from the treatment planning device 11. The communication unit 210 also receives a respiratory signal obtained by the infrared camera 391 imaging the infrared marker M11 from the radiotherapy device 13, a combination of the imaging radiation source 341 and the sensor array 361, and an imaging radiation source 342. And a sensor array 362 are used to acquire a fluoroscopic image of an irradiation target to be imaged.
The communication unit 210 corresponds to an example of a respiratory signal acquisition unit.

The memory | storage part 220 is comprised using the memory | storage device with which the radiotherapy apparatus control apparatus 12 is provided, and memorize | stores various information.
The reference model storage unit 221 stores a reference model of the movement of the irradiation target that moves periodically. The reference model stored in the reference model storage unit 221 is used to interpolate the position information of the irradiation target obtained from the fluoroscopic image of the irradiation target in the time direction. The interpolation can reduce the imaging frequency of the irradiation target to reduce the exposure amount of the normal part, and the model generation unit 232 can generate the irradiation target position model with higher accuracy. The irradiation target position model here is a model indicating the relationship between the respiratory signal and the position of the irradiation target.

FIG. 5 is an explanatory diagram illustrating an example of a reference model stored in the reference model storage unit 221. The horizontal axis of the graph in the figure represents time, and the vertical axis represents amplitude.
The reference model storage unit 221 stores a reference model for one cycle of respiration divided into a reference for inspiration, a model, and a reference model for expiration. Thereby, the reference model can be easily enlarged or reduced at different magnifications at the time of inspiration and at the time of exhalation, and it is possible to easily cope with the case where the amplitude differs for each period.

The reference model is obtained by extracting one period from the measured value of the position of the irradiation target.
FIG. 6 is an explanatory diagram illustrating an acquisition example of an irradiation target. The horizontal axis of the graph in the figure represents time, and the vertical axis represents amplitude.
In the figure, the upper graph showing the respiratory signal and the lower graph showing the position of the irradiation target are shown with the time aligned. A line L211 indicates a respiratory signal. A line L221 indicates the horizontal movement of the irradiation target. A line L222 indicates the movement of the irradiation subject in the dorsoventral direction. A line L223 indicates the movement of the irradiation target in the head-to-tail direction.

The acquisition of the reference model may be performed automatically by the radiation therapy apparatus control apparatus 12, or may be performed manually.
First, the peak position (maximum position or minimum position) of the respiratory signal is detected. Normally, human respiration takes about 4 seconds on average, and therefore, for example, the position where the respiration signal is maximized or minimized is detected within a 4-second width. In the example of FIG. 6, points P21 to P29 at which the respiratory signal is minimized are extracted.

Next, a period is obtained for each of the detected peak positions. In the example of FIG. 6, the time from the point P21 to the point P22, the time from the point P22 to the point P23, the time from the point P23 to the point P24,.
And the section of the period used as the median among the obtained periods is selected. At that time, an extremely short period or an extremely long period such as 2 seconds or less or 10 seconds or more may be excluded.
In the example of FIG. 6, the period from the points P24 to P25 is the median value, and the section of time T21 is selected.
For each of the lines L221 to L223, the waveform obtained in the section of time T21 is divided into inspiration and expiration to be a reference model.

  The median period is taken to obtain standard data. Not only the method of taking the median, but also the method of taking the average of multiple waveforms, preparing a number of patterns as a reference model in advance, and selecting the pattern that best matches the measured value by pattern matching, etc. May be used.

  Returning to FIG. 4, the template storage unit 222 stores the template of the irradiation target position model. By setting the template parameters stored in the template storage unit 222, an irradiation target position model that outputs the position of the irradiation target with the position and change amount (speed and acceleration) of the infrared marker M11 as an input can be obtained.

The processing unit 230 performs various functions by controlling each unit of the radiation therapy apparatus control device 12. The processing unit 230 is configured, for example, by a CPU (Central Processing Unit) included in the radiation therapy apparatus control device 12 reading out and executing a program from the storage unit 220.
The position information acquisition control unit 231 controls the imaging timing of the fluoroscopic image to be irradiated by the combination of the imaging radiation source 341 and the sensor array 361 and the combination of the imaging radiation source 342 and the sensor array 362. Specifically, the position information acquisition control unit 231 causes imaging at the timing when the position of the infrared marker M11 captured by the infrared camera 391 reaches a peak (the highest position and the lowest position). In this way, the position information acquisition control unit 231 provides information indicating the position of the irradiation target at a predetermined timing indicated by the phase of the respiratory signal to the irradiation target position information acquisition apparatus that acquires information indicating the position of the irradiation target. To get.
By approximating the peak of the position of the irradiation target with the peak of the position of the infrared marker M11, the position information acquisition control unit 231 does not need to perform a complicated calculation to obtain the position of the irradiation target. In this respect, the load on the position information acquisition control unit 231 can be relatively reduced.

The model generation unit 232 generates an irradiation target position model indicating the relationship between the respiratory signal and the position of the irradiation target based on the reference model, the respiratory signal, and information indicating the position of the irradiation target.
Specifically, first, the position history information generation unit 233 combines the reference model at the time of inspiration and the reference model at the time of expiration based on the information indicating the position of the irradiation target acquired by the communication unit 210, so that the irradiation target History information of the position of is generated.
Then, the parameter setting unit 234 sets the template parameters of the irradiation target position model stored in the template storage unit 222 so as to match the irradiation target position history information generated by the position history information generation unit 233. .

  FIG. 7 is an explanatory diagram illustrating an example of the history information of the position of the irradiation target acquired by the position history information generation unit 233. The horizontal axis of the graph in the figure represents time, and the vertical axis represents amplitude. Points P11 to P17 are irradiation targets obtained by imaging the irradiation target by the combination of the imaging radiation source 341 and the sensor array 361 and the combination of the imaging radiation source 342 and the sensor array 362, respectively. Indicates the position. The position history information generation unit 233 acquires history information of the position of the irradiation target by interpolating between the points with the reference model.

  At this time, as described with reference to FIG. 5, the position history information generation unit 233 uses a reference model in which one cycle is divided into inspiration and expiration. In the example of FIG. 7, the position history information generation unit 233 interpolates between points P31 and P32 using the reference model for intake air of FIG. Further, the point P32 and the point P33 are interpolated with the reference model of expiration in FIG.

  By dividing the reference model into inspiration and expiration, inspiration and expiration can be enlarged or reduced at different magnifications, and variations in amplitude and period can be easily handled. For example, in the example of FIG. 7, the amplitude from the point P33 to the point P34 is larger than the amplitude from the point P32 to the point P33. Therefore, when the position history information generation unit 233 interpolates the section from the point P33 to the point P34 with the reference model of inspiration, the position history information generation unit 233 expands and contracts the reference model so that the amplitude is larger than that in the section from the points P32 to P33. Use.

Next, with reference to FIG. 8, the flow of radiotherapy in the radiotherapy system 1 will be described.
FIG. 8 is an explanatory diagram showing an example of the flow of treatment when performing multiple times of tracking irradiation for the same patient using the radiotherapy system 1. In the example shown in the figure, an irradiation target position model (a model for obtaining the position of the irradiation target from the respiration signal) is generated every time before performing the tracking irradiation in order to improve the radiation irradiation accuracy.

  In the generation of the first irradiation target position model (step S101) for the first tracking irradiation (step S102), the reference model has not yet been obtained. In this case, for example, a fluoroscopic image of the irradiation target is captured at a short time interval such as every 80 milliseconds (msec), and the position information history of the irradiation target is obtained in detail. By obtaining detailed data in step S101, a reference model can be obtained as described with reference to FIG.

In the generation of the second irradiation target position model (step S103) for the second tracking irradiation (step S104), since the reference model is obtained, the irradiation target is described as described with reference to FIG. Can be interpolated using the reference model. Therefore, it is only necessary to capture the fluoroscopic image of the irradiation target only at the timing when the position of the irradiation target reaches the peak, and the number of imaging can be greatly reduced. Thereby, the exposure of a normal site | part can be reduced and an irradiation object position model can be obtained accurately.
Similarly, the generation of the irradiation target position model for the third and subsequent times (step S105,...) Can also reduce the exposure of the normal part and obtain the irradiation target position model with high accuracy.

Next, with reference to FIG. 9, operation | movement of the radiotherapy apparatus control apparatus 12 is demonstrated.
FIG. 9 is a flowchart illustrating a processing procedure in which the radiation therapy apparatus control device 12 acquires an irradiation target position model using a reference model.
In the processing of the figure, the communication unit 210 acquires a respiratory signal from the infrared camera 391 (step S201). Then, the position information acquisition control unit 231 determines whether or not it is the timing when the respiration signal reaches a peak (step S202). When it is determined that it is not the timing when the respiratory signal reaches a peak (step S202: NO), the process returns to step S201.

  On the other hand, when it is determined that the timing at which the respiratory signal reaches a peak (step S202: YES), the position information acquisition control unit 231 includes a combination of the imaging radiation source 341 and the sensor array 361, and the imaging radiation source 342. And the sensor array 362 are instructed to capture images, and position information of the irradiation target is acquired (step S203).

Then, the position information acquisition control unit 231 determines whether a predetermined amount of data (amount of data that can accurately generate the irradiation target position model) has been obtained (step S204). If it is determined that a predetermined amount of data has not been obtained (step S204: NO), the process returns to step S201.
On the other hand, when it is determined that a predetermined amount of data has been obtained (step S204: YES), the position history information generation unit 233 interpolates the irradiation target position information obtained in step S203 with the reference model, and Position history information is generated (step S205). Then, the parameter setting unit 234 sets the parameters of the template of the irradiation target position model stored in the template storage unit 222 so as to match the irradiation target position history information obtained in step S205, An irradiation target position model is acquired (step S206).
After step S206, the process of FIG. 9 ends. Thereafter, tracking irradiation can be performed using the obtained irradiation target position model.

Next, with reference to FIG. 10, the usage example of the irradiation object position model which the radiotherapy apparatus control apparatus 12 produces | generates is demonstrated.
FIG. 10 is an explanatory diagram illustrating a prediction example of the position of the irradiation target using the irradiation target position model obtained by the processing procedure performed by the radiotherapy apparatus control apparatus 12. The horizontal axis of the graph in the figure represents time, and the vertical axis represents amplitude.

In FIG. 10, the upper graph showing the actual value of the position of the irradiation target, and the lower side showing the predicted value (calculated value) of the position of the irradiation target calculated using the irradiation target position model obtained by the processing procedure described above. The side graph is shown with the time aligned. A line L411 indicates the actual value of the movement of the irradiation target in the left-right direction. A line L412 indicates an actual value of the movement of the irradiation target in the dorsoventral direction. A line L413 indicates the actual value of the movement of the irradiation target in the head-to-tail direction. On the other hand, a line L421 indicates the predicted value of the movement of the irradiation target in the left-right direction. A line L422 indicates a predicted value of the movement of the irradiation target in the dorsoventral direction. A line L423 indicates the predicted value of the movement of the irradiation target in the head-to-tail direction.
As shown in FIG. 10, the actual value and the predicted value are similar in waveform, amplitude, and period, and the irradiation target position model can be obtained with high accuracy.

As described above, the reference model storage unit 221 stores the reference model of the movement of the irradiation target that moves periodically. In addition, the communication unit 210 acquires a respiratory signal, which is a signal generated in synchronization with respiration, from the infrared camera 391. In addition, the position information acquisition control unit 231 is an irradiation target position information acquisition device (a combination of the imaging radiation source 341 and the sensor array 361, and the imaging radiation source 342 and the sensor array) that acquires information indicating the position of the irradiation target. Information indicating the position of the irradiation target at the timing of the respiratory signal peak. And the model production | generation part 232 produces | generates the irradiation object position model which shows the relationship between a respiration signal and the position of irradiation object based on the reference | standard model, a respiration signal, and the information which shows the position of irradiation object.
The model generation unit 232 interpolates the position information of the irradiation target using the reference model, thereby reducing the number of times the position information of the irradiation target is acquired and generating a more accurate irradiation target position model. it can. Thereby, the frequency | count of imaging of the fluoroscopic image of a normal site | part can be reduced, and the exposure amount of a normal site | part can be reduced. Moreover, the load of the irradiation target position information acquisition device can be reduced.

The radiotherapy apparatus control apparatus 12 includes a reference model storage unit 221, a communication unit 210, a position information acquisition control unit 231, and a model generation unit 232, and corresponds to an example of a model generation apparatus.
However, the model generation device is not limited to a configuration configured as a part of the radiotherapy device control device 12, but configured as a single device, or configured as a part of a CT (Computed Tomography) device, It can be configured in various ways.

Further, the reference model storage unit 221 stores a reference model at the time of inspiration and a reference model at the time of expiration. Then, the position history information generation unit 233 combines the reference model at the time of inspiration and the reference model at the time of expiration based on the information indicating the position of the irradiation target acquired by the communication unit 210 (a fluoroscopic image of the irradiation target). History information on the position of the irradiation target is generated. Then, the parameter setting unit 234 sets parameters of the irradiation target position model based on the history information of the irradiation target position.
As described above, the position history information generation unit 233 uses the reference model divided into the time of exhalation and the time of exhalation, whereby the exhalation and the inspiration can be enlarged / reduced at different magnifications. Thereby, the position history information generation unit 233 can easily generate the history information of the position of the irradiation target even when the amplitude or the period in the position information of the irradiation target varies.

  In the above, the position information acquisition control unit 231 performs the irradiation target position information acquisition device (the combination of the imaging radiation source 341 and the sensor array 361 and the imaging radiation source 342 at the timing of the peak position of the respiratory signal). The case where information indicating the position of the irradiation target is acquired by the combination with the sensor array 362 has been described as an example. In this case, the position information acquisition control unit 231 can detect timing for acquiring information indicating the position of the irradiation target by a relatively simple process of detecting the peak position of the respiratory signal. In this respect, an increase in the load on the position information acquisition control unit 231 can be avoided.

On the other hand, the method for detecting the timing at which the position information acquisition control unit 231 acquires information indicating the position of the irradiation target is not limited to the method for detecting the timing of the peak position of the respiratory signal. For example, the position information acquisition control unit 231 causes the irradiation target position information acquisition apparatus to acquire information indicating the position of the irradiation target at the timing of the peak position of the irradiation target predicted from the timing of the peak position of the respiratory signal. Also good. For example, the position information acquisition control unit 231 stores in advance an offset between the timing of the peak position of the respiratory signal and the timing of the peak position of the irradiation target, and the timing at which the offset is increased or decreased from the timing of the peak position of the respiratory signal. Thus, the irradiation target position information acquisition device is made to acquire information indicating the position of the irradiation target.
Thereby, the radiotherapy apparatus control apparatus 12 can obtain more accurately the timing and amplitude of the peak position of the irradiation target.

Further, the position information acquisition control unit 231 may suppress the acquisition of information indicating the position of the next irradiation target for a predetermined time after the irradiation target position information acquisition apparatus acquires the information indicating the position of the irradiation target. Good.
As a result, when there is an adjacent extreme value (maximum value or minimum value), such as when the position of the irradiation target fluctuates near the peak, the peak period can be reduced by detecting both of these adjacent extreme values. It is possible to avoid erroneous detection.

Alternatively, the position information acquisition control unit 231 may cause the irradiation target position information acquisition device to acquire information indicating the position of the irradiation target in a predetermined time range corresponding to the timing of the peak position of the respiratory signal.
Thereby, even when the offset between the timing of the peak position of the respiratory signal and the timing of the peak position of the irradiation target is not constant or unknown, the timing and amplitude of the peak position of the irradiation target can be obtained more accurately. . In addition, during the time other than the predetermined time range, it is possible to suppress the acquisition of information indicating the position of the irradiation target by the irradiation target position information acquisition device and reduce the exposure amount of the normal part. The load on the acquisition device can be reduced.

A program for realizing all or part of the functions of the radiotherapy apparatus controller 12 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 12 Radiotherapy apparatus control apparatus 210 Communication part 220 Storage part 221 Reference model storage part 222 Template storage part 230 Processing part 231 Position information acquisition control part 232 Model generation part 233 Position history information generation part 234 Parameter setting part

Claims (10)

A reference model storage unit that stores a reference model of the movement of the irradiation object that moves periodically;
A respiratory signal acquisition unit that acquires a respiratory signal that is a signal generated in synchronization with respiration;
A position information acquisition control unit for acquiring information indicating the position of the irradiation target at a predetermined timing indicated by the phase of the respiratory signal in an irradiation target position information acquisition device that acquires information indicating the position of the irradiation target;
A model generation unit that generates an irradiation target position model indicating a relationship between the respiratory signal and the position of the irradiation target based on the reference model, the respiratory signal, and information indicating the position of the irradiation target;
Equipped with,
The reference model storage unit stores the reference model at the time of inspiration and the reference model at the time of expiration,
The model generation unit
Based on the information indicating the position of the irradiation target acquired by the irradiation target position information acquisition device, the history model of the position of the irradiation target is generated by combining the reference model at the time of inspiration and the reference model at the time of expiration. A position history information generating unit to
Based on the history information of the position of the irradiation target, a parameter setting unit for setting parameters of the irradiation target position model;
A model generation apparatus comprising: The model generation apparatus according to claim 1 , wherein the position information acquisition control unit causes the irradiation target position information acquisition apparatus to acquire information indicating the position of the irradiation target at a timing of a peak position of the respiratory signal. The position information acquisition control unit causes the irradiation target position information acquisition device to acquire information indicating the position of the irradiation target at the timing of the peak position of the irradiation target, which is predicted from the timing of the peak position of the respiratory signal. The model generation apparatus according to claim 1 . A reference model storage unit that stores a reference model of the movement of the irradiation object that moves periodically;
A respiratory signal acquisition unit that acquires a respiratory signal that is a signal generated in synchronization with respiration;
A position information acquisition control unit for acquiring information indicating the position of the irradiation target at a predetermined timing indicated by the phase of the respiratory signal in an irradiation target position information acquisition device that acquires information indicating the position of the irradiation target;
A model generation unit that generates an irradiation target position model indicating a relationship between the respiratory signal and the position of the irradiation target based on the reference model, the respiratory signal, and information indicating the position of the irradiation target;
Equipped with,
The position information acquisition control unit causes the irradiation target position information acquisition device to acquire information indicating the position of the irradiation target at the timing of the peak position of the irradiation target, which is predicted from the timing of the peak position of the respiratory signal .
Model generator.   The position information acquisition control unit suppresses acquisition of information indicating the position of the next irradiation target for a predetermined time after causing the irradiation target position information acquisition device to acquire information indicating the position of the irradiation target. The model generation device according to any one of 1 to 4. The position information acquisition control unit, at a predetermined time range according to the timing of the peak position of the respiration signal, and acquires information indicating the position of the irradiation target to the irradiation object position information obtaining device, according to claim 1 Model generation device. A reference model storage unit that stores a reference model of the movement of the irradiation object that moves periodically;
A respiratory signal acquisition unit that acquires a respiratory signal that is a signal generated in synchronization with respiration;
An irradiation target position information acquisition device for acquiring information indicating the position of the irradiation target;
A position information acquisition control unit that causes the irradiation target position information acquisition device to acquire information indicating the position of the irradiation target at a predetermined timing indicated by the phase of the respiratory signal;
A model generation unit that generates an irradiation target position model indicating a relationship between the respiratory signal and the position of the irradiation target based on the reference model, the respiratory signal, and information indicating the position of the irradiation target;
Equipped with,
The reference model storage unit stores the reference model at the time of inspiration and the reference model at the time of expiration,
The model generation unit
Based on the information indicating the position of the irradiation target acquired by the irradiation target position information acquisition device, the history model of the position of the irradiation target is generated by combining the reference model at the time of inspiration and the reference model at the time of expiration. A position history information generating unit to
Based on the history information of the position of the irradiation target, a parameter setting unit for setting parameters of the irradiation target position model;
A radiotherapy apparatus control apparatus comprising: A breathing signal acquisition step of acquiring a breathing signal that is a signal generated in synchronization with breathing;
A position information acquisition step of acquiring information indicating the position of the irradiation target at a predetermined timing indicated by the phase of the respiratory signal;
Irradiation target position model indicating the relationship between the respiration signal and the position of the irradiation target based on a reference model of the movement of the irradiation target that moves periodically, the respiratory signal, and information indicating the position of the irradiation target A model generation step for generating
I have a,
The model generation step includes:
A step on the basis of the information indicating the position of the irradiation target, in combination with the reference model in the reference model and the expiratory during inspiration, generates history information of the position of the irradiation target,
A step based on the history information of the position of the irradiation object, to set the parameters of the irradiation target position model,
A model generation method comprising: A reference model storage unit that stores a reference model of the movement of the irradiation object that moves periodically;
A respiratory signal acquisition unit that acquires a respiratory signal that is a signal generated in synchronization with respiration;
An irradiation target position information acquisition device for acquiring information indicating the position of the irradiation target;
A position information acquisition control unit that causes the irradiation target position information acquisition device to acquire information indicating the position of the irradiation target at a predetermined timing indicated by the phase of the respiratory signal;
A model generation unit that generates an irradiation target position model indicating a relationship between the respiratory signal and the position of the irradiation target based on the reference model, the respiratory signal, and information indicating the position of the irradiation target;
Equipped with,
The position information acquisition control unit causes the irradiation target position information acquisition device to acquire information indicating the position of the irradiation target at the timing of the peak position of the irradiation target, which is predicted from the timing of the peak position of the respiratory signal .
Radiotherapy device control device. A breathing signal acquisition step of acquiring a breathing signal that is a signal generated in synchronization with breathing;
A position information acquisition step of acquiring information indicating the position of the irradiation target at a predetermined timing indicated by the phase of the respiratory signal;
Irradiation target position model indicating the relationship between the respiration signal and the position of the irradiation target based on a reference model of the movement of the irradiation target that moves periodically, the respiratory signal, and information indicating the position of the irradiation target A model generation step for generating
I have a,
In the position information acquisition step, the information indicating the position of the irradiation target is acquired at the timing of the peak position of the irradiation target, which is predicted from the timing of the peak position of the respiratory signal .
Model generation method.

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