Patent Number: 
Section: claims

1. A bolus that is disposed in a particle beam therapy system and modulates energy distribution of a particle beam in accordance with a to-be-irradiated portion,wherein the shape of the bolus is set in such a way that, when a first reference point and a second reference point, which is at the downstream side of the first reference point, are given on a beam axis of a particle beam that enters the bolus at the upstream side thereof, and when an irradiation orbit of a particle beam that penetrates the bolus and reaches the to-be-irradiated portion is defined by a first slant from the beam axis with respect to a first axis that starts from the first reference point, that is perpendicular to the beam axis, and that includes the first reference point and by a second slant from the beam axis with respect to a second axis that is perpendicular to the beam axis and the first axis and includes the second reference point, a path length within the bolus of a particle beam in each of the irradiation orbits defined for combinations within a predetermined range of combinations of the first slant and the second slant, compensates a path length from a body surface situated at the upstream side of the to-be-irradiated portion to the to-be-irradiated portion. 2. The bolus according to claim 1, wherein the shape of the bolus is set in such a way that the following relationship is satisfied:LB(α, β)+LK(α, β)=R whereα denotes the first slant,β denotes the second slant,LB(α, β) denotes the path length, of a particle beam, within the bolus in an irradiation orbit defined by a combination of the first slant and the second slant,LK(α, β) denotes the path length from the body surface to the to-be-irradiated portion in the irradiation orbit defined by the combination of the first slant and the second slant, andR denotes the attainable depth corresponding to the energy of a particle beam that enters the bolus, respectively. 3. A bolus manufacturing method for manufacturing the bolus according to claim 2, comprising the steps of:acquiring inner-body depth data, which is the path length from the body surface to the to-be-irradiated portion, for each of combinations of the first slant and the second slant;setting the shape of a bolus in such a way that the path length is obtained by compensating the acquired inner-body depth data;creating bolus machining data, based on the set bolus shape; andmachining a bolus, based on the created machining data. 4. A particle beam therapy system comprising:an irradiation nozzle that scans a particle beam supplied from an accelerator by means of two electromagnets that range in the traveling direction of the particle beam and whose scanning directions are different from each other, and that irradiates the particle beam in such a way as to enlarge the irradiation field thereof; andthe bolus according to claim 2, disposed in a particle beam irradiated from the irradiation nozzle, wherein the bolus is disposed in such a way that the first axis for setting the shape of the bolus coincides with the scanning axis of the upstream electromagnet out of the two electromagnets and the second axis coincides with the scanning axis of the other electromagnet. 5. The particle beam therapy system according to claim 4, wherein the irradiation nozzle enlarges the irradiation field utilizing a spiral wobbling method. 6. A treatment planning apparatus comprising:a three-dimensional data creation unit for creating three-dimensional data from image data of a body including the to-be-irradiated portion;an irradiation condition setting unit for setting an irradiation condition, based on the created three-dimensional data; anda bolus data creation unit for creating shape data on a bolus in the particle beam therapy system according to claim 5, based on the set irradiation condition, wherein the three-dimensional data creation unit creates the three-dimensional data by utilizing at least the first slant corresponding to beam deflection angle by the upstream electromagnet and the second slant corresponding to beam deflection angle by said the other electromagnet. 7. The particle beam therapy system according to claim 4, wherein the irradiation nozzle enlarges the irradiation field utilizing a scanning method. 8. A treatment planning apparatus comprising:a three-dimensional data creation unit for creating three-dimensional data from image data of a body including the to-be-irradiated portion;an irradiation condition setting unit for setting an irradiation condition, based on the created three-dimensional data; anda bolus data creation unit for creating shape data on a bolus in the particle beam therapy system according to claim 7, based on the set irradiation condition, wherein the three-dimensional data creation unit creates the three-dimensional data by utilizing at least the first slant corresponding to beam deflection angle by the upstream electromagnet and the second slant corresponding to beam deflection angle by said the other electromagnet. 9. The particle beam therapy system according to claim 4, wherein scanning for one direction out of the two directions is performed by a deflection electromagnet that deflects the direction of a beam axis, and by regarding that the scanning axis of the deflection electromagnet passes through a point on the beam axis of a particle beam that enters the bolus, the scanning axis of the deflection electromagnet is made to coincide with the first axis or the second axis. 10. A treatment planning apparatus comprising:a three-dimensional data creation unit for creating three-dimensional data from image data of a body including the to-be-irradiated portion;an irradiation condition setting unit for setting an irradiation condition, based on the created three-dimensional data; anda bolus data creation unit for creating shape data on a bolus in the particle beam therapy system according to claim 9, based on the set irradiation condition, wherein the three-dimensional data creation unit creates the three-dimensional data by utilizing at least the first slant corresponding to beam deflection angle by the upstream electromagnet and the second slant corresponding to beam deflection angle by said the other electromagnet. 11. A treatment planning apparatus comprising:a three-dimensional data creation unit for creating three-dimensional data from image data of a body including the to-be-irradiated portion;an irradiation condition setting unit for setting an irradiation condition, based on the created three-dimensional data; anda bolus data creation unit for creating shape data on a bolus in the particle beam therapy system according to claim 4, based on the set irradiation condition, wherein the three-dimensional data creation unit creates the three-dimensional data by utilizing at least the first slant corresponding to beam deflection angle by the upstream electromagnet and the second slant corresponding to beam deflection angle by said the other electromagnet. 12. A bolus manufacturing method for manufacturing the bolus according to claim 1, comprising the steps of:acquiring inner-body depth data, which is the path length from the body surface to the to-be-irradiated portion, for each of combinations of the first slant and the second slant;setting the shape of a bolus in such a way that the path length is obtained by compensating the acquired inner-body depth data;creating bolus machining data, based on the set bolus shape; andmachining a bolus, based on the created machining data. 13. A particle beam therapy system comprising:an irradiation nozzle that scans a particle beam supplied from an accelerator by means of two electromagnets that range in the traveling direction of the particle beam and whose scanning directions are different from each other, and that irradiates the particle beam in such a way as to enlarge the irradiation field thereof; andthe bolus according to claim 1, disposed in a particle beam irradiated from the irradiation nozzle, wherein the bolus is disposed in such a way that the first axis for setting the shape of the bolus coincides with the scanning axis of the upstream electromagnet out of the two electromagnets and the second axis coincides with the scanning axis of the other electromagnet. 14. The particle beam therapy system according to claim 13, wherein the irradiation nozzle enlarges the irradiation field utilizing a spiral wobbling method. 15. A treatment planning apparatus comprising:a three-dimensional data creation unit for creating three-dimensional data from image data of a body including the to-be-irradiated portion;an irradiation condition setting unit for setting an irradiation condition, based on the created three-dimensional data; anda bolus data creation unit for creating shape data on a bolus in the particle beam therapy system according to claim 14, based on the set irradiation condition, wherein the three-dimensional data creation unit creates the three-dimensional data by utilizing at least the first slant corresponding to beam deflection angle by the upstream electromagnet and the second slant corresponding to beam deflection angle by said the other electromagnet. 16. The particle beam therapy system according to claim 13, wherein the irradiation nozzle enlarges the irradiation field utilizing a scanning method. 17. A treatment planning apparatus comprising:a three-dimensional data creation unit for creating three-dimensional data from image data of a body including the to-be-irradiated portion;an irradiation condition setting unit for setting an irradiation condition, based on the created three-dimensional data; anda bolus data creation unit for creating shape data on a bolus in the particle beam therapy system according to claim 16, based on the set irradiation condition, wherein the three-dimensional data creation unit creates the three-dimensional data by utilizing at least the first slant corresponding to beam deflection angle by the upstream electromagnet and the second slant corresponding to beam deflection angle by said the other electromagnet. 18. The particle beam therapy system according to claim 13, wherein scanning for one direction out of the two directions is performed by a deflection electromagnet that deflects the direction of a beam axis, and by regarding that the scanning axis of the deflection electromagnet passes through a point on the beam axis of a particle beam that enters the bolus, the scanning axis of the deflection electromagnet is made to coincide with the first axis or the second axis. 19. A treatment planning apparatus comprising:a three-dimensional data creation unit for creating three-dimensional data from image data of a body including the to-be-irradiated portion;an irradiation condition setting unit for setting an irradiation condition, based on the created three-dimensional data; anda bolus data creation unit for creating shape data on a bolus in the particle beam therapy system according to claim 18, based on the set irradiation condition, wherein the three-dimensional data creation unit creates the three-dimensional data by utilizing at least the first slant corresponding to beam deflection angle by the upstream electromagnet and the second slant corresponding to beam deflection angle by said the other electromagnet. 20. A treatment planning apparatus comprising:a three-dimensional data creation unit for creating three-dimensional data from image data of a body including the to-be-irradiated portion;an irradiation condition setting unit for setting an irradiation condition, based on the created three-dimensional data; anda bolus data creation unit for creating shape data on a bolus in the particle beam therapy system according to claim 13, based on the set irradiation condition, wherein the three-dimensional data creation unit creates the three-dimensional data by utilizing at least the first slant corresponding to beam deflection angle by the upstream electromagnet and the second slant corresponding to beam deflection angle by said the other electromagnet.