JP2021171483A - Treatment support apparatus and treatment support program - Google Patents

Abstract

To suppress deterioration in image.SOLUTION: A treatment support apparatus includes an acquisition unit and a deformation processing unit. The acquisition unit acquires CT image data and MRI image data which are captured targeting an identical subject to be treated. The deformation processing unit, if there is any posture change between at the time of imaging CT image data and at the time of imaging MRI image data, causes the MRI image data before distortion correction to be subjected to non-rigid body deformation processing and aligns the MRI image data and the CT image data before distortion correction.SELECTED DRAWING: Figure 2

Description

The embodiments disclosed herein and in the drawings relate to treatment support devices and treatment support programs.

Conventionally, in a treatment plan in radiotherapy, a composite image obtained by synthesizing a CT image captured by a CT (Computed Tomography) device for treatment planning and an MRI image captured by an MRI (Magnetic Resonance Imaging) device for treatment planning is used. May be used. For example, in the case of tumor contouring (extraction of the boundary region), in cases where it is difficult to identify the tumor boundary with a CT image, a composite image with an MRI image that has good tissue contrast and makes it easy to identify the shape of the tumor. Is used.

Here, when the CT image and the MRI image are combined, the distortion of the MRI image is first corrected, and then the deviation between the coordinate system in the CT image and the coordinate system in the MRI image is corrected. Further, after the deviation between the images due to the difference between the body position at the time of CT image imaging and the body position at the time of MRI image imaging and the deviation between the images due to the difference in the respiratory phase at the time of imaging are corrected, the corrected image is corrected. The MRI image and the CT image are combined. Then, based on the composite image, diagnosis and treatment planning are performed.

Special Table 2019-500110

One of the problems to be solved by the embodiments disclosed in the present specification and the drawings is to suppress the deterioration of the image. However, the problems to be solved by the embodiments disclosed in the present specification and the drawings are not limited to the above problems. It is also possible to position the problem corresponding to each effect of each configuration shown in the embodiment described later as another problem.

The treatment support device according to the embodiment includes an acquisition unit and a deformation processing unit. The acquisition unit acquires CT (Computed Tomography) image data and MRI (Magnetic Resonance Imaging) image data imaged on the same subject to be treated. When there is a change in posture between the time of capturing the CT image data and the time of capturing the MRI image data, the deformation processing unit performs the non-rigid body deformation processing of the MRI image data before the distortion correction before the distortion correction. MRI image data and the CT image data are aligned.

FIG. 1 is a diagram showing an example of the configuration of the treatment support system according to the first embodiment. FIG. 2 is a diagram showing an example of the configuration of the treatment support device according to the first embodiment. FIG. 3 is a flowchart showing a processing procedure by the treatment support device according to the first embodiment. FIG. 4A is a diagram showing an example of a composite image according to the first embodiment. FIG. 4B is a diagram showing an example of a composite image according to the first embodiment.

Hereinafter, embodiments of the treatment support device and the treatment support program according to the present application will be described in detail with reference to the accompanying drawings. The treatment support device and the treatment support program according to the present application are not limited to the embodiments shown below. Further, the embodiment can be combined with other embodiments or conventional techniques as long as the processing contents do not conflict with each other.

(First Embodiment)
First, a treatment support system including a treatment support device according to the present embodiment will be described. FIG. 1 is a diagram showing an example of the configuration of the treatment support system 1 according to the first embodiment. As shown in FIG. 1, the treatment support system 1 according to the first embodiment includes a treatment planning CT (Computed Tomography) device 100, a treatment planning MRI (Magnetic Resonance Imaging) device 200, and a PACS (Picture Archiving and). Communication Systems) 300, a radiotherapy information system 400, a treatment support device 500, a treatment planning device 600, and a radiotherapy device 700. The treatment planning CT device 100, the treatment planning MRI device 200, the PACS 300, the radiotherapy information system 400, the treatment support device 500, the treatment planning device 600, and the radiotherapy device 700 can communicate with each other via the network 2. It is connected to the. The configuration shown in FIG. 1 is merely an example, and the embodiment is not limited to this. For example, various other devices (CT devices, other modalities such as MRI devices) and systems (various departments). System) may be included in the treatment support system 1.

The treatment planning CT device 100 has a pedestal, a bed device having a top plate, and a console, and collects CT image data including a treatment target site (tumor, etc.) of the subject to be treated lying on the top plate. , The collected CT image data is transmitted to the PACS 300, the treatment support device 500, the treatment planning device 600, and the like. Specifically, the treatment planning CT device 100 collects projection data while rotating the X-ray tube and the X-ray detector provided on the gantry around the object to be treated, and based on the collected projection data. The three-dimensional CT image data is reconstructed. Here, the top plate of the treatment planning CT device 100 has a planar shape similar to the top plate of the radiotherapy device.

The treatment planning MRI apparatus 200 has a pedestal, a sleeper apparatus having a top plate, and a console, and collects MRI image data including a treatment target site (tumor, etc.) of the subject to be treated lying on the top plate. , The collected MRI image data is transmitted to the PACS 300, the treatment support device 500, the treatment planning device 600, and the like. Specifically, the treatment planning MRI apparatus 200 reconstructs three-dimensional MRI image data based on the magnetic resonance signal obtained by scanning the subject to be treated. Here, the top plate of the treatment planning MRI apparatus 200 has a planar shape similar to the top plate of the radiotherapy apparatus.

The PACS 300 receives, stores, and manages medical image data collected by various modality including the treatment planning CT device 100 and the treatment planning MRI device 200 via the network 2. For example, the PACS 300 stores and manages CT image data and MRI image data collected from the same subject by the treatment planning CT device 100 and the treatment planning MRI device 200.

The radiotherapy information system 400 stores and manages various information related to radiotherapy. Specifically, the radiotherapy information system 400 provides various information related to the progress of treatment, such as treatment plans, actual information (irradiation history), various reports, and records of the status of the treated body, for each treated body. Memorize and manage. The radiotherapy information system 400 can provide information to be accessed and managed from each device connected to the network 2.

The treatment support device 500 acquires CT image data and MRI image data from the treatment planning CT device 100, the treatment planning MRI device 200, or the PACS 300, and uses the acquired CT image data and MRI image data to make a treatment plan. Generate the image data to be used. Specifically, the treatment support device 500 generates MRI image data in which alignment is corrected with respect to the CT image data. Then, the treatment support device 500 transmits the corrected MRI image data and the CT image data to the treatment planning device 600. The correction by the treatment support device 500 will be described in detail later.

The treatment planning device 600 uses the three-dimensional CT image data of the treated body collected by the treatment planning CT device 100 and the three-dimensional MRI image data of the same treated body collected by the treatment planning MRI device 200. Then, a treatment plan for radiotherapy using the radiotherapy device 700 is made. For example, the treatment planning device 600 is corrected by the treatment support device 500, and the combined CT image data and MRI image data are used to identify the position of the treatment target site in the treated body and determine the irradiation area. ..

For example, in determining the radiation irradiation area, first, a risk organ to avoid radiation irradiation is set based on CT image data collected by the treatment planning CT device 100 and the like. Then, a gross tumor volume (GTV), which is a three-dimensional region in which the growth and existence of the tumor can be visually confirmed, is set, and the set GTV and a potential tumor region that cannot be visually confirmed are set. A clinical target volume (CTV) including is set. Here, a composite image obtained by synthesizing CT image data and MRI image data is used for GTV setting. For example, by setting the GTV for the MRI image data, the GTV is set at the corresponding position in the CT image data. The risk organs, GTV and CTV are set by, for example, contouring (contour extraction), which can be performed by either manual processing by a doctor or automatic processing by image processing technology. ..

Then, in determining the irradiation area of radiation, ITV (internal target volume) including an internal margin (IM) for absorbing the influence of movement of internal organs such as respiration, swallowing, heartbeat, and peristalsis. Is set for CTV. Further, the irradiation region of radiation is determined by setting the planned target volume (PTV: planning target volume) including the setting error (SM: set-up margin) in each irradiation with respect to the ITV.

Then, the treatment planning device 600 makes a plan such as the irradiation angle of the radiation irradiated by the radiation therapy device 700 with respect to the determined irradiation region of the radiation, the dose and the shape of the irradiation field for each irradiation angle, and the number of times of irradiation. .. Then, the treatment planning device 600 transmits the treatment plan to the radiotherapy information system 400 and the radiotherapy device 700.

The radiotherapy apparatus 700 irradiates the object to be treated with radiation according to the treatment plan by the treatment planning apparatus 600, and executes the radiotherapy. Specifically, the radiation therapy device 700 includes a radiation generator, a radiation diaphragm, a pedestal having an imaging device, and a sleeper device having a top plate, and performs radiation therapy based on control from a console. conduct. For example, in the radiation therapy device 700, irradiation conditions such as an irradiation angle of radiation, a dose for each irradiation angle, a shape of an irradiation field, and the number of irradiations are set according to a treatment plan. Here, the shape of the irradiation field is formed by, for example, a multi-leaf collimator (MLC) which is a radiation diaphragm. The MLC has a plurality of radiation shielding plates that set the irradiation range of radiation, and each shielding plate is independently driven based on the treatment plan, so that the irradiation field that matches the shape of the radiation irradiation region (PTV) Can be formed.

In this way, the radiation therapy device 700 irradiates the subject to be treated lying on the top plate with radiation according to the received treatment plan. Here, the top plate of the radiotherapy apparatus 700 has a planar shape, and has the same shape as the treatment planning CT apparatus 100 and the treatment planning MRI apparatus 200.

As described above, in the treatment plan in radiotherapy, a composite image obtained by synthesizing CT image data and MRI image data is used. In this synthesis, distortion correction, image coordinate system correction, body position and respiration at the time of imaging are used. Corrections for misalignment due to phase differences are implemented step by step. All of these corrections are transformation processes. In the transformation process, the position of each pixel before correction is not at the center position of the pixel after correction, so interpolation processing is required. Since the interpolation processing is a kind of low-pass filter processing, the image quality after the interpolation processing deteriorates. Therefore, when such correction is performed a plurality of times in a stepwise manner, the deterioration becomes remarkable.

In particular, in the treatment plan of radiotherapy, risk organs are identified from CT image data, and the pixel values of CT image data are converted into electron density or physical density in a dose calculation simulation. Furthermore, although the irradiation area (tumor and margin) of radiation is identified, it is often the case that the tumor area cannot be clearly identified by the CT image, and in such a case, an MRI image that can clearly identify the tumor area may be used. In this case, when the MRI image and the CT image that have been corrected a plurality of times are combined and the tumor region is identified on the corrected MRI image, the tumor region is identified on the corresponding CT image. However, at this time, since the corrected MRI image is deformed a plurality of times, the edge of the tumor region, which was originally sharp, is slightly blunted. As a result, the boundary of the tumor region on the MRI image may be recognized with a slight width due to blurring or blurring.

Therefore, the treatment support device 500 according to the present embodiment suppresses deterioration of image quality by performing the correction process only once instead of performing the correction process a plurality of times in a stepwise manner. Specifically, in the treatment support device 500, when the anatomical structure of the treated body included in the CT image data and the anatomical structure of the treated body included in the MRI image data are substantially the same. A composite image is generated by synthesizing the CT image data and the MRI image data in one correction process. As a result, the treatment support device 500 can generate a composite image by one interpolation process, and can suppress deterioration of image quality.

FIG. 2 is a diagram showing an example of the configuration of the treatment support device 500 according to the first embodiment. As shown in FIG. 2, the treatment support device 500 according to the first embodiment includes a communication interface 510, an input interface 520, a display 530, a storage circuit 540, and a processing circuit 550.

The communication interface 510 is connected to the processing circuit 550 and controls the transmission and communication of various data performed with each device connected via the network 2. For example, the communication interface 510 is realized by a network card, a network adapter, a NIC (Network Interface Controller), or the like.

The input interface 520 is connected to the processing circuit 550, converts the input operation received from the operator (medical worker) into an electric signal, and outputs the input operation to the processing circuit 550. Specifically, the input interface 520 converts the input operation received from the operator into an electric signal and outputs it to the processing circuit 550. For example, the input interface 520 includes a trackball, a switch button, a mouse, a keyboard, a touch pad for performing input operations by touching an operation surface, a touch screen in which a display screen and a touch pad are integrated, and a non-optical sensor. It is realized by a contact input circuit, a voice input circuit, and the like. In the present specification, the input interface 520 is not limited to the one provided with physical operating parts such as a mouse and a keyboard. For example, an example of the input interface 520 includes an electric signal processing circuit that receives an electric signal corresponding to an input operation from an external input device provided separately from the device and outputs the electric signal to a control circuit.

The display 530 is connected to the processing circuit 550 and displays various information and various image data output from the processing circuit 550. For example, the display 530 is realized by a liquid crystal display, a CRT (Cathode Ray Tube) display, an organic EL display, a plasma display, a touch panel, or the like. In the present embodiment, for example, the display 530 displays a composite image obtained by combining CT image data and MRI image data.

The storage circuit 540 is connected to the processing circuit 550 and stores various data. Further, the storage circuit 540 stores various programs for realizing various functions by being read and executed by the processing circuit 550. For example, the storage circuit 540 is realized by a semiconductor memory element such as a RAM (Random Access Memory) or a flash memory, a hard disk, an optical disk, or the like. As an example, the storage circuit 540 stores CT image data 541, MRI image data 542, corrected data 543, and the like. Further, the storage circuit 534 stores the treatment plan received from the radiotherapy information system 400, various processing results, and the like.

The CT image data 541 is three-dimensional CT image data collected by the treatment planning CT device 100 or a CT device (not shown). Here, the CT image data 541 includes the same region as the region included in the MRI image data 542 collected from the same treated body for the treatment target region in the treated body. For example, the CT image data 541 is acquired from the treatment planning CT device 100, the CT device (not shown) or the PACS 300 via the communication interface 510, and is stored in the storage circuit 540.

The MRI image data 542 is three-dimensional MRI image data collected by a treatment planning MRI apparatus 200 or an MRI apparatus (not shown). Here, the MRI image data 542 includes the same region as the region included in the CT image data 541 collected from the same treated body for the treatment target region in the treated body. For example, the MRI image data 542 is acquired from the treatment planning MRI apparatus 200, the MRI apparatus (not shown) or the PACS 300 via the communication interface 510, and is stored in the storage circuit 540.

The corrected data 543 is MRI image data after the correction process is executed by the processing circuit 550. Specifically, the corrected data 543 is MRI image data that has been deformed by the processing circuit 550.

The processing circuit 550 controls the operation of the entire treatment support device 500 according to the input operation received from the operator via the input interface 520. For example, the processing circuit 550 is realized by a processor. As shown in FIG. 2, the processing circuit 550 executes the control function 551, the identification function 552, the deformation processing function 553, and the synthesis function 554. Here, the control function 551 is an example of the acquisition unit. The identification function 552 is an example of a determination unit. The deformation processing function 553 is an example of the deformation processing unit. The synthesis function 554 is an example of a synthesis unit.

The control function 551 controls to execute processing according to various requests input via the input interface 532. Specifically, the control function 551 controls transmission / reception of information via the communication interface 510, storage of information in the storage circuit 540, display of information on the display 530, and the like.

For example, the control function 551 acquires CT image data 541 from the treatment planning CT device 100, the CT device (not shown), or the PACS 300 via the communication interface 510, and stores the CT image data 541 in the storage circuit 540. Further, the control function 551 acquires MRI image data 542 from the treatment planning MRI apparatus 200, the MRI apparatus (not shown) or the PACS 300 via the communication interface 510, and stores the MRI image data 542 in the storage circuit 540. Here, the control function 551 acquires CT image data 541 and MRI image data 542 imaged on the same subject in response to an image data acquisition request input via the input interface 532. Further, the control function 551 causes the display 530 to display the composite image synthesized by the composite function 554.

The identification function 552 determines whether or not the anatomical structure of the imaging site at the time of imaging the CT image data and the anatomical structure of the imaging site at the time of imaging the MRI image data substantially match. Specifically, the identification function 552 changes between the anatomical structure in the treated body at the time when the CT image data is imaged and the anatomical structure in the treated body at the time when the MRI image data is imaged. Determine if it has occurred.

For example, when the identification function 552 is instructed to synthesize the CT image data and the MRI image data, the identification function 552 acquires the imaging date from the incidental information of the CT image data and the MRI image data to be combined. Then, the identification function 552 provides the anatomical structure of the imaging site at the time of imaging the CT image data when the number of days between the imaging date of the acquired CT image data and the imaging date of the MRI image data is equal to or less than the threshold value. And, it is determined that the anatomical structure of the imaging site at the time of imaging the MRI image data substantially matches.

For example, in the treatment of tumors, in addition to radiation therapy, chemotherapy using an anticancer drug may be performed in parallel. In such cases, the body shape of the subject to be treated may change significantly due to the side effects of the anticancer drug. Therefore, the identification function 552 determines that the anatomical structure in the treated body has not changed when the number of days between the imaging date of the CT image data and the imaging date of the MRI image data is equal to or less than the threshold value. .. On the other hand, when the number of days between the imaging date of the CT image data and the imaging date of the MRI image data exceeds the threshold value, the identification function 552 determines that the anatomical structure in the treated body has changed. do. The threshold value for comparison can be set arbitrarily.

Further, the identification function 552 is used when the CT image data is captured when the anatomical structure of the imaging site changes between the imaging date of the CT image data and the imaging date of the MRI image data. It is determined that the anatomical structure of the imaging site in the above image is different from the anatomical structure of the imaging site at the time of imaging the MRI image data. For example, the identification function 552 acquires information related to the progress of treatment of the treated body and changes the anatomical structure such as surgery between the imaging date of the CT image data and the imaging date of the MRI image data. Determine if there was an event.

Here, when there is an event that changes the anatomical structure such as surgery between the imaging date of the CT image data and the imaging date of the MRI image data, the identification function 552 performs the anatomy in the treated body. It is determined that the anatomical structure has changed. On the other hand, if there is no event that changes the anatomical structure, the identification function 552 determines that the anatomical structure in the treated body has not changed.

Then, the identification function 552 further determines that there is no change between the anatomical structure of the imaging site at the time of imaging the CT image data and the anatomical structure of the imaging site at the time of imaging the MRI image data. By identifying the correlation of anatomically corresponding pixels between the MRI image data before distortion correction and the CT image data, information on the distortion of the MRI image data and the posture in the CT image data and the MRI image data. Make corrections in combination with information about changes.

Here, the identification function 552 determines whether or not there is a deviation due to a change in posture between the MRI image data before the distortion correction and the CT image data. That is, the identification function 552 controls so that only the distortion correction of the MRI image is performed when the deviation due to the change in posture does not occur. For example, the identification function 552 outputs a map for performing distortion correction to the deformation processing function 553. On the other hand, when the deviation due to the change in posture occurs, the identification function 552 executes the following processing.

When determining the deviation due to the change in posture, the identification function 552 determines, for example, by the difference in the outer shape drawn in the image data. In addition, when determining the deviation due to the change in posture, the MRI image data after the distortion correction and the CT image data may be compared. That is, in order to determine the deviation due to the change in posture, the identification function 552 performs distortion correction once, acquires the MRI image data after the distortion correction, and compares the acquired MRI image data with the CT image data. Judge the deviation due to the change in posture.

When there is a deviation due to a change in posture, for example, the identification function 552 uses the mutual information amount between the CT image data and the MRI image data as the degree of similarity, and the MRI image data and the CT image data before distortion correction are used. Identify the correlation of the corresponding pixels between. In such a case, for example, the identification function 552 performs various conversions on the MRI image data before distortion correction, and calculates the mutual information amount for each conversion. Then, the identification function 552 determines the voxel correspondence relationship (correspondence map) between the data, which maximizes the mutual information amount. That is, the identification function 552 repeats the calculation of the similarity and the update of the relative position, and searches for the relative position where the similarity is maximized.

Here, the identification function 552 may perform conversion in consideration of distortion on the MRI image data before distortion correction to calculate the mutual information amount. Since the MRI image data is distorted due to reasons such as non-uniformity of the static magnetic field, the identification function 552 determines the correspondence between the data for performing the alignment including the correction of the distortion. For example, the identification function 552 adds the displacement of voxels based on the field map showing the state of non-uniform static magnetic field to the above-mentioned transformation matrix, and calculates the mutual information amount using the transformation matrix. As a result, a corresponding map for correcting the distortion of the MRI image data and the positional deviation between the image data can be obtained by searching the relative position once.

The calculation of the degree of similarity between the CT image data and the MRI image data is not limited to the method using the mutual information amount described above, and any method may be used. For example, deep learning that creates CT image data from MRI image data may be used. Alternatively, for example, when calculating the similarity, an algorithm that identifies the correlation in the global search range and further identifies the local correlation from the correlation may be used.

Further, for example, the identification of the correlation may be performed by deep learning. In such a case, for example, a trained model that outputs a voxel correspondence (correspondence map) to the input of CT image data and MRI image data before distortion correction is generated. Then, the identification function 552 acquires the corresponding map by inputting the CT image data and the MRI image data before distortion correction into the trained model. As deep learning, for example, U-Net or the like is used.

When the identification function 552 determines that the anatomical structure in the body to be treated has changed, the process is interrupted because the CT image and the MRI image cannot be accurately aligned.

The deformation processing function 553 performs MRI before distortion correction on the condition that the anatomical structure of the imaging site at the time of capturing the CT image data and the anatomical structure of the imaging site at the time of capturing the MRI image data substantially match. By performing non-rigid deformation processing on the image data, the MRI image data before the distortion correction and the CT image data are aligned. That is, the deformation processing function 553 aligns the CT image data and the MRI image data before the distortion correction by using the corresponding map including the distortion correction and the positional deviation correction identified by the identification function 552.

For example, the deformation processing function 553 generates CT image data and MRI image data before distortion correction by generating corrected MRI image data obtained by applying a corresponding map to the MRI image data and performing non-rigid deformation processing. Align. Then, the deformation processing function 553 stores the generated corrected MRI image data as the corrected data 543 in the storage circuit 540.

The compositing function 554 generates a composite image in which the CT image data and the MRI image data aligned by the deformation processing function 553 are combined. For example, the compositing function 554 generates a composite image in which the CT image is shown in the first layer and the MRI image is shown in the second layer from each of the aligned image data. That is, the synthesis function 554 generates a CT image and an MRI image showing the same cross section from the image data after the alignment.

The control function 551 causes the display 530 to display the composite image generated by the composite function 554. For example, the control function 551 displays the CT image on the first layer, displays the MRI image on the second layer, changes the transparency of each layer, and displays them in an overlapping manner. Further, for example, the control function 551 causes the display 530 to display the CT image and the MRI image in parallel.

Hereinafter, an example of processing by the treatment support device 500 will be described with reference to FIG. FIG. 3 is a flowchart showing a processing procedure by the treatment support device 500 according to the first embodiment. Here, step S101 in FIG. 3 is realized, for example, by the processing circuit 550 reading a program corresponding to the control function 551 from the storage circuit 540 and executing the program. Further, steps S102 and S103 are realized, for example, by the processing circuit 550 reading a program corresponding to the identification function 552 from the storage circuit 540 and executing the program. Further, steps S104 and S106 are realized, for example, by the processing circuit 550 reading a program corresponding to the deformation processing function from the storage circuit 540 and executing the program. Further, step S105 is realized, for example, by the processing circuit 550 reading a program corresponding to the control function 551 and the synthesis function 554 from the storage circuit 540 and executing the program.

In the treatment support device 500 according to the first embodiment, the operator first acquires CT image data to be synthesized from the treatment planning CT device 100 or the PACS 300 (step S101). Further, the operator acquires the MRI image data to be synthesized from the treatment planning MRI apparatus 200 or the PACS 300 (step S101).

Then, the operator contours (extracts the boundary region) the risk organ on the CT image. Next, the operator contours the tumor region in the same manner, but when the tumor region cannot be clearly identified by the CT image, the operator instructs the image synthesis for contouring using the MRI image.

When image synthesis is instructed by the operator, can the identification function 552 change between the anatomical morphology contained in the CT image data and the anatomical morphology contained in the MRI image data? It is determined whether or not (step S102). For example, the identification function 552 determines the number of days between the imaging date of the CT image data and the imaging date of the MRI image data, and whether or not there is an operation or the like during that period.

Here, if it is determined that there is no possibility of change in morphology (step S102, denial), the identification function 552 determines whether or not there is a change in posture (step S103). For example, the identification function 552 determines whether or not there is a difference in the outer shape between the image data. Here, when there is a change in posture (step S103, affirmative), the identification function 552 identifies a corresponding map for correcting the distortion of the MRI image data and the positional deviation between the image data, and the deformation processing function 553. Output to. The deformation processing function 553 corrects the posture change and the distortion by the warping process based on the received correspondence map (step S104).

On the other hand, when there is no change in posture (step S103, negation), the identification function 552 outputs a field map for performing distortion correction to the deformation processing function 553. The deformation processing function 553 corrects the distortion by the warping process based on the received field map (step S106).

When the correction process is executed in step S104 or step S106, the composition function 554 synthesizes the corrected image data, and the control function 551 displays the composite image (step S105). 4A and 4B are diagrams showing an example of a composite image according to the first embodiment. For example, as shown in FIG. 4A, the control function 551 displays a CT image on the first layer, displays an MRI image on the second layer, and displays a composite image in which the transparency of each image is changed on the display 530. Let me.

Further, for example, as shown in FIG. 4B, the control function 551 divides the display area of the display 530 into the first quadrant to the fourth quadrant, displays the MRI image in the first quadrant (and the third quadrant), and displays the MRI image in the second quadrant. A composite image showing a CT image is displayed in the quadrant (and the fourth quadrant). Further, for example, the control function 551 displays the MRI image and the CT image side by side, and defines a common coordinate system on the two images. Then, for example, when the coordinate system of one image is moved by the cursor, the control function 551 controls so that the coordinate system of the other image is also moved in synchronization.

As described above, according to the first embodiment, the control function 551 acquires CT image data and MRI image data imaged on the same subject to be treated. The identification function 552 determines whether or not the anatomical structure of the imaging site at the time of imaging the CT image data and the anatomical structure of the imaging site at the time of imaging the MRI image data substantially match. The deformation processing function 553 performs MRI before distortion correction on the condition that the anatomical structure of the imaging site at the time of capturing the CT image data and the anatomical structure of the imaging site at the time of capturing the MRI image data substantially match. By performing non-rigid deformation processing on the image data, the MRI image data before the distortion correction and the CT image data are aligned. Therefore, the treatment support device 500 according to the first embodiment can perform the correction related to the distortion of the MRI image data and the correction related to the positional deviation between the MRI image data and the CT image data with one correction. It is possible to suppress the deterioration of image quality due to the above. Further, the treatment support device 500 can save time by simultaneously correcting the distortion of the MRI image data and the positional deviation between the MRI image data and the CT image data with one correction. To.

Further, according to the first embodiment, the identification function 552 captures the CT image data at the time of imaging when the number of days between the imaging date of the CT image data and the imaging date of the MRI image data is equal to or less than the threshold value. It is determined that the anatomical structure of the site and the anatomical structure of the imaged site at the time of imaging the MRI image data substantially match. Therefore, the treatment support device 500 according to the first embodiment makes it possible to make corrections in consideration of changes in the anatomical structure due to treatment.

Further, according to the first embodiment, the identification function 552 includes an event in which the anatomical structure of the imaging site changes between the imaging date of the CT image data and the imaging date of the MRI image data. In this case, it is determined that the anatomical structure of the imaging site at the time of imaging the CT image data and the anatomical structure of the imaging site at the time of imaging the MRI image data are different.

Further, according to the first embodiment, in the identification function 552, the anatomical structure of the imaging site at the time of imaging the CT image data and the anatomical structure of the imaging site at the time of imaging the MRI image data are substantially the same. In some cases, further, the information on the distortion of the MRI image data and the information on the positional deviation in the CT image data and the MRI image data are combined, and the corresponding pixels of the MRI image data before the distortion correction and the CT image data are combined. Identify the correlation. The deformation processing function 553 aligns the MRI image data and the CT image data before distortion correction based on the correlation. Therefore, the treatment support device 500 according to the first embodiment makes it possible to correct the distortion of the MRI image data and the positional deviation between the MRI image data and the CT image data with one correction. ..

Further, according to the first embodiment, the compositing function 554 generates a composite image in which the CT image data and the MRI image data aligned by the deformation processing function 553 are combined. Therefore, the treatment support device 500 according to the first embodiment makes it possible to generate a composite image in which the MRI image data and the CT image data are aligned with high accuracy.

(Other embodiments)
By the way, although the first embodiment has been described so far, it may be implemented in various different forms other than the above-mentioned first embodiment.

In the above-described embodiment, the case where the image data related to the radiotherapy is aligned has been described. However, the embodiment is not limited to this, and a CT image and an MRI image may be combined for the purpose of diagnosis. In such a case, the control function 551 acquires CT image data collected by a CT device (not shown) from a CT device (not shown) or a PACS 300. Further, the control function 551 acquires MRI image data collected by an MRI apparatus (not shown) from an MRI apparatus (not shown) or a PACS 300.

Then, the identification function 552 performs the above-mentioned identification process in response to an instruction of image synthesis by the operator. Further, the transformation processing function 553 performs alignment with the CT image data by transforming the MRI image data acquired by the control function 551 based on the correspondence map identified by the identification function 552. The compositing function 554 generates a composite image of the MRI image data and the CT image data after the transformation process, and the control function 551 displays the composite image on the display 530.

In the above-described embodiment, each processing function of the processing circuit 550 has been described. Here, for example, each of the above-mentioned processing functions is stored in the storage circuit 540 in the form of a program that can be executed by a computer. The processing circuit 550 reads each program from the storage circuit 540 and executes each read program to realize a processing function corresponding to each program. In other words, the processing circuit 550 in the state where each program is read has each processing function shown in FIG.

Note that FIG. 2 has described an example in which each processing function is realized by a single processing circuit 550, but the embodiment is not limited to this. For example, the processing circuit 550 may be configured by combining a plurality of independent processors, and each processor may execute each program to realize each processing function. Further, each processing function of the processing circuit 550 may be realized by being appropriately distributed or integrated into a single processing circuit or a plurality of processing circuits.

Further, the word "processor" used in the description of each of the above-described embodiments is, for example, a CPU (Central Processing Unit), a GPU (Graphics Processing Unit), or an integrated circuit for a specific application (Application Specific Integrated Circuit: ASIC). , Programmable logic devices (eg, Simple Programmable Logic Device (SPLD), Complex Programmable Logic Device (CPLD), and Field Programmable Gate Array (FPGA)). Means. Here, instead of storing the program in the storage circuit, the program may be configured to be directly embedded in the circuit of the processor. In this case, the processor realizes the function by reading and executing the program embedded in the circuit. Further, each processor of the present embodiment is not limited to the case where each processor is configured as a single circuit, and a plurality of independent circuits may be combined to be configured as one processor to realize its function. good.

Here, the treatment support program executed by the processor is provided in advance in a ROM (Read Only Memory), a storage unit, or the like. This treatment support program is a file in a format that can be installed or executed on these devices, and is a CD (Compact Disk) -ROM, FD (Flexible Disk), CD-R (Recordable), DVD (Digital Versatile Disk). ) And the like may be stored and provided on a computer-readable storage medium. Further, this treatment support program may be provided or distributed by being stored on a computer connected to a network such as the Internet and downloaded via the network. For example, this treatment support program is composed of modules including each functional part. In actual hardware, the CPU reads a program from a storage medium such as a ROM and executes it, so that each module is loaded on the main storage device and generated on the main storage device.

According to at least one embodiment described above, deterioration of the image can be suppressed.

Although some embodiments have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other embodiments, and various omissions, replacements, changes, and combinations of embodiments can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, as well as in the scope of the invention described in the claims and the equivalent scope thereof.

500 Treatment support device 551 Control function 552 Identification function 553 Deformation processing function 554 Synthesis function

Claims (7)

An acquisition unit that acquires CT (Computed Tomography) image data and MRI (Magnetic Resonance Imaging) image data imaged on the same subject to be treated.
When there is a change in posture between the time of capturing the CT image data and the time of capturing the MRI image data, the MRI image data before distortion correction is subjected to non-rigid deformation processing to obtain the MRI image data before distortion correction. A deformation processing unit that aligns the CT image data,
A treatment support device equipped with. Further provided, a determination unit for determining whether or not the anatomical structure of the imaging site at the time of imaging the CT image data and the anatomical structure of the imaging site at the time of imaging the MRI image data substantially match.
The treatment support device according to claim 1, wherein the deformation processing unit aligns the MRI image data before distortion correction and the CT image data based on the determination result by the determination unit. When the number of days between the imaging date of the CT image data and the imaging date of the MRI image data is equal to or less than the threshold value, the determination unit determines the anatomical structure of the imaging site at the time of imaging the CT image data. The treatment support device according to claim 2, wherein it is determined that the anatomical structure of the imaging site at the time of imaging the MRI image data is substantially the same. When the determination unit includes an event in which the anatomical structure of the imaging site changes between the imaging date of the CT image data and the imaging date of the MRI image data, the determination unit determines the CT image data. The treatment support device according to claim 2 or 3, wherein it is determined that the anatomical structure of the imaging site at the time of imaging is different from the anatomical structure of the imaging site at the time of imaging the MRI image data. When the anatomical structure of the imaging site at the time of capturing the CT image data and the anatomical structure of the imaging site at the time of capturing the MRI image data substantially match, the determination unit further obtains the MRI image. The correlation of the corresponding pixels between the MRI image data before the distortion correction and the CT image data, which is a combination of the information on the distortion of the data and the information on the positional deviation in the CT image data and the MRI image data, is determined. Identify and
The treatment support device according to any one of claims 2 to 4, wherein the deformation processing unit aligns the MRI image data before distortion correction and the CT image data based on the correlation. The treatment support device according to any one of claims 1 to 5, further comprising a compositing unit that generates a composite image obtained by combining CT image data and MRI image data aligned by the deformation processing unit. An acquisition function for acquiring CT (Computed Tomography) image data and MRI (Magnetic Resonance Imaging) image data imaged on the same subject to be treated,
When there is a change in posture between the time of capturing the CT image data and the time of capturing the MRI image data, the MRI image data before distortion correction is subjected to non-rigid deformation processing to obtain the MRI image data before distortion correction. A transformation processing function that aligns the CT image data,
A treatment support program that lets a computer execute.

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