Patent Number: 
Section: claims

1. A charged particle beam irradiation system comprising:an irradiation unit configured to irradiate an irradiation target with a charged particle beam;a radiation resistance state measuring section configured to measure a radiation resistance state of the irradiation target;a region dividing section configured to divide the irradiation target into a plurality of radiation resistance regions based on a measurement result of the radiation resistance state measuring section;a radiation dose computing section configured to compute a planned value of a radiation dose of the charged particle beam for each of the plurality of radiation resistance regions divided by the region dividing section; andan irradiation planning section configured to create an irradiation plan of the charged particle beam with respect to the irradiation target based on a computation result of the radiation dose computing section. 2. The charged particle beam irradiation system according to claim 1, further comprising:a pre-irradiation planning section configured to create a pre-irradiation plan of the charged particle beam with respect to the irradiation target based on a captured image of the irradiation target,wherein the irradiation planning section corrects the pre-irradiation plan based on the computation result of the radiation dose computing section to create the irradiation plan. 3. The charged particle beam irradiation system according to claim 1,wherein the irradiation planning section creates the irradiation plan based on a captured image of the irradiation target and the computation result of the radiation dose computing section. 4. The charged particle beam irradiation system according to claim 1,wherein the radiation resistance state measuring section includes a gamma-ray detector, andwherein the region dividing section divides the irradiation target into the plurality of radiation resistance regions based on a measurement result of the gamma-ray detector that uses FMISO as a tracer. 5. The charged particle beam irradiation system according to claim 1,wherein the radiation resistance state measuring section includes a gamma-ray detector, andwherein the region dividing section divides the irradiation target into the plurality of radiation resistance regions based on a measurement result of the gamma-ray detector that uses FAZA as a tracer. 6. The charged particle beam irradiation system according to claim 1,wherein the radiation resistance state measuring section includes a gamma-ray detector, andwherein the region dividing section divides the irradiation target into the plurality of radiation resistance regions based on a measurement result of the gamma-ray detector that uses IAZA as a tracer. 7. The charged particle beam irradiation system according to claim 1,wherein the radiation resistance state measuring section includes a gamma-ray detector, andwherein the region dividing section divides the irradiation target into the plurality of radiation resistance regions based on a measurement result of the gamma-ray detector that uses FETNIM as a tracer. 8. A charged particle beam irradiation planning method comprising:a radiation resistance state measuring step of measuring a radiation resistance state of an irradiation target;a region dividing step of dividing the irradiation target into a plurality of radiation resistance regions based on a measurement result of the radiation resistance state measuring step;a radiation dose computing step of computing a planned value of a radiation dose of a charged particle beam for each of the plurality of radiation resistance regions divided in the region dividing step; andan irradiation planning step of creating the irradiation plan of the charged particle beam with respect to the irradiation target based on a computation result of the radiation dose computing step. 9. The charged particle beam irradiation planning method according to claim 8, further comprising:a pre-irradiation planning step of creating a pre-irradiation plan of the charged particle beam with respect to the irradiation target based on a captured image of the irradiation target before the radiation resistance state measuring step,wherein in the irradiation planning step, the pre-irradiation plan is corrected based on the computation result of the radiation dose computing step to create the irradiation plan. 10. The charged particle beam irradiation planning method according to claim 8,wherein in the irradiation planning step, the irradiation plan is created based on a captured image of the irradiation target and the computation result of the radiation dose computing step. 11. The charged particle beam irradiation planning method according to claim 8,wherein in the radiation resistance state measuring step, the radiation resistance state of the irradiation target is measured based on a gamma-ray detection that uses FMISO as a tracer. 12. The charged particle beam irradiation planning method according to claim 8,wherein in the radiation resistance state measuring step, the radiation resistance state of the irradiation target is measured based on a gamma-ray detection that uses FAZA as a tracer. 13. The charged particle beam irradiation planning method according claim 8,wherein in the radiation resistance state measuring step, the radiation resistance state of the irradiation target is measured based on a gamma-ray detection that uses IAZA as a tracer. 14. The charged particle beam irradiation planning method according to claim 8,wherein in the radiation resistance state measuring step, the radiation resistance state of the irradiation target is measured based on a gamma-ray detection that uses FETNIM as a tracer.