Patent Number: 
Section: claims

1. An X-ray fluoroscopic apparatus, that collects an X-ray fluoroscopic radiograph including a specific region of a subject and detects a position of the specific region, and sends a therapeutic beam irradiation signal to a radiation irradiation device while tracking a movement of said specific region, said X-ray fluoroscopic apparatus, further comprising:an X-ray tube;an X-ray detector that detects an X-ray that is irradiated from said X-ray tube and transmits through said subject;an irradiation area projection element that generates a projection area denoting a therapeutic beam irradiation area by performing a virtual fluoroscopic projection simulating a geometric fluoroscopic condition between said X-ray tube and said X-ray detector relative to an initial set of CT image data based on said therapeutic beam irradiation area registered in said CT image data of said subject generated when an initial therapy planning is created;a specific region projection element that generates a specific projection area denoting a specific regional area by performing a virtual fluoroscopic projection simulating a geometric fluoroscopic condition between said X-ray tube and said X-ray detector relative to said initial set of CT image data based on the specific region registered on said CT image data of said subject generated when said therapy planning is created;a superimposition element that both superimposes the projection area denoting said therapeutic beam irradiation area onto said X-ray fluoroscopic radiograph, and superimposes the specific projection area denoting said specific-regional area to said X-ray fluoroscopic radiograph at said specific-regional position detected based on said X-ray fluoroscopic radiograph; anda gating element that sends the therapeutic beam irradiation signal to the radiation irradiation apparatus when the projection area denoting the specific-regional area superimposed onto the X-ray fluoroscopic radiograph by said superimposition element are placed in the projection area denoting the therapeutic beam irradiation area superimposed to the X-ray fluoroscopic radiograph by the superimposition element. 2. The X-ray fluoroscopic apparatus, according to claim 1, further comprising:an image display element that displays the X-ray fluoroscopic radiograph and the projection area denoting said therapeutic beam irradiation area superimposed on said X-ray fluoroscopic radiograph by said superimposition element and the projection area denoting said specific-regional area superimposed to said X-ray fluoroscopic radiograph by said superimposition element. 3. The X-ray fluoroscopic apparatus, according to claim 1, further comprising:a template area selection element that selects an area including said specific region from said X-ray fluoroscopic radiograph;a template generation element that generates a template indicating said specific region from the area including said specific region selected by said template area selection element; anda position detection element that detects a position of said specific region relative to said fluoroscopic radiograph by performing template matching by using the template generated by using said X-ray fluoroscopic radiograph and said template generation element. 4. The X-ray fluoroscopic apparatus, according to claim 3, wherein:said template area selection element selects an area including said specific region from said X-ray fluoroscopic radiograph by a DRR (digital reconstructed radiography) image generated by one of a step of:performing the virtual fluoroscopic projection simulating a geometric fluoroscopic condition between said X-ray tube and said X-ray detector relative to said CT image data; andmachine learning learned using an X-ray fluoroscopic radiograph obtained by an X-ray fluoroscopy of said subject in advance. 5. The X-ray fluoroscopic apparatus, according to claim 4, wherein:said machine learning that is one selected from the group consisting of:a support vector machine, a decision tree, a boosting and a neural network. 6. The X-ray fluoroscopic apparatus, according to claim 3, further comprising:a DRR image generation element that generates a DRR image including said specific region by performing a virtual fluoroscopic projection simulating a geometric fluoroscopic condition between said X-ray tube and said X-ray detector relative to CT image data of said subject generated when a therapy planning is created; andan image display element that displays an image including said specific region selected by said template area selection element and an image obtained by superimposing a projection area denoting said specific region generated by said specific region projection element to a DRR image generated by said DRR image generation element. 7. The X-ray fluoroscopic apparatus, according to claim 1, further comprising:a DRR image generation element that generates a DRR image including said specific region by performing a virtual fluoroscopic projection simulating a geometric fluoroscopic condition between said X-ray tube and said X-ray detector relative to CT image data of said subject generated when said initial therapy planning is created; andan image display element that displays said X-ray fluoroscopic radiograph and an image obtained by superimposing a projection area denoting said specific region generated by said specific region projection element to a DRR image generated by said DRR image generation element. 8. The X-ray fluoroscopic apparatus, according to claim 6, wherein:said CT image data is a four-dimensional CT image data, further comprising:a group of three-dimensional CT image data including said specific region relative to a plurality of continuous breathing phases of said subject; andsaid DRR image generation element generates a DRR image including said specific region based on CT image data of phases in association with said X-ray fluoroscopic radiograph. 9. The X-ray fluoroscopic apparatus, according to claim 1, further comprising:said CT image data is a four-dimensional CT image data, further comprising:a group of three-dimensional CT image data including said specific region relative to a plurality of continuous breathing phases of said subject; andsaid specific region projection element generates a projection area denoting said specific region based on CT image data of phases in association with said X-ray fluoroscopic radiograph. 10. An x-ray fluoroscopic apparatus, comprising:an X-ray tube;an X-ray detector that detects an X-ray that is irradiated from said X-ray tube and transmits through a subject; wherein:said X-ray fluoroscopic apparatus collects an X-ray fluoroscopic radiograph including a specific region of said subject and detects a position of the specific region, and sends a therapeutic beam irradiation signal to a radiation irradiation device while tracking a movement of said specific region;a specific region projection element that generates a projection area denoting said specific-regional area by performing a virtual fluoroscopic projection simulating a geometric fluoroscopic condition between said X-ray tube and said X-ray detector relative to an initial set of CT image data of said subject based on said specific region registered on said CT image data of said subject generated when an initial therapy planning is created;a DRR image generation element that generates a DRR image including said specific region by performing a virtual fluoroscopic projection simulating a geometric fluoroscopic condition between said X-ray tube and said X-ray detector relative to CT image data of said subject generated when said initial therapy planning is created;a template area selection element that selects an area including said specific region from said X-ray fluoroscopic radiograph;an image display element that displays an image of an area including said specific region in said X-ray fluoroscopic radiograph selected by said template area selection element, and an image obtained by superimposing a projection area denoting said specific region generated by said specific region projection element to a DRR image generated by said DRR image generation element;a template generation element that generates a template indicating said specific region from an area including said specific region selected by said template area selection element; anda position detection element that detects a position of said specific region relative to said fluoroscopic radiograph by performing template matching by using said X-ray fluoroscopic radiograph and a template generated by said template generation element. 11. The X-ray fluoroscopic apparatus, according to claim 10, wherein:said template area selection element selects a DRR image generated by a step of performing a virtual fluoroscopic projection simulating a geometric fluoroscopic condition between said X-ray tube and said X-ray detector relative to said CT image data, or selecting an area including said specific region from said X-ray fluoroscopic radiograph by machine learning learned using an X-ray fluoroscopic radiograph obtained by an initial X-ray fluoroscopy of said subject in advance. 12. The X-ray fluoroscopic apparatus, according to claim 11, wherein:said machine learning that is one selected from the group consisting of:a support vector machine, a decision tree, a boosting and a neural network.