A particle therapy system includes: an accelerator that accelerates a particle beam; an irradiation system that applies the beam accelerated by the accelerator to a target; and a controller that controls the accelerator and the irradiation system. The controller has a treatment execution system that generates a control parameter which controls the accelerator and the irradiation system based on a treatment plan and has a treatment execution controller that controls the accelerator and the irradiation system based on the control parameter generated by the treatment execution system. When irradiation to the target by the irradiation system is suspended due to a failure or an artificial manipulation, the treatment execution system calculates an irradiated dose of the particle beam and an unirradiated dose of the particle beam, and the treatment execution system delivers at least the unirradiated dose to the treatment execution controller.

A planning apparatus (70) determines irradiation parameter data (67) for a charged particle irradiation system (1), which radiates charged particles generated by an ion source (2) to a target (80) by accelerating the charged particles by means of a linear accelerator (4) and a synchrotron (5). The planning apparatus is provided with: a planning program (73), which determines the irradiation parameter data (67) with respect to one target (80) by combining charged particles of a plurality of kinds of ion species; and a CPU (71) for executing the planning program. Consequently, the irradiation planning apparatus capable of performing irradiation with desirable dose distribution with respect to the target, the irradiation planning program, an irradiation plan determining method, and the charged particle irradiation system are provided.

A method of assisting designing of a particle beam therapy facility includes: a local-concave region calculation step of calculating a volume of a local concave region which is a concave region between two treatment-room models arranged most adjacent to each other, among multiple treatment-room models arranged in a model space corresponding to a target space for arrangement, or a projected area of the local concave region; a concave-region calculation-result display step of displaying the volume or the projected area of the local concave region calculated in the local-concave region calculation step, on a display device of a design assisting device; and a treatment-room model displacement step of displacing the treatment-room model in the model space in response to a displacement instruction for that treatment-room model, when no operation-termination instruction is issued after the concave-region calculation-result display step; wherein the above three steps are repeated until an operation-termination instruction is issued.

A radiation therapy system comprises a treatment pod having an internal treatment room, and a beam delivery system comprising a particle accelerator for generating a radiation beam. The beam delivery system is carried by the treatment pod with the particle accelerator outside of the pod, and is configured to deliver the radiation beam to the treatment room. The beam delivery system, including the accelerator is movable around the treatment pod in order to adjust the position of the radiation beam with respect to the treatment room. The movement of the beam delivery system is counterbalanced. The treatment pod, together with the beam delivery system, may be moved in order to service multiple waiting rooms.

A system proton treatment system including a proton accelerator structured to generate a proton beam, a plurality of beamline pathways configured to direct the proton beam from the proton accelerator to a corresponding plurality of treatment rooms, a rotatable bending magnet located between the proton accelerator and the plurality of treatment rooms, the rotatable bending magnet being structured to selectively rotate between multiple treatment rooms, and an upright patient positioning mechanism disposed in each of the treatment rooms, the upright patient positioning mechanism being structured to support a patient within a particular treatment room and to rotate the patient between a fixed imaging source and imaging panel.

Described herein are methods for beam station delivery of radiation treatment, where the patient platform is moved to a series of discrete patient platform locations or beam stations that are determined during treatment planning, stopped at each of these locations while the radiation source rotates about the patient delivering radiation to the target regions that intersect the radiation beam path, and then moving to the next location after the prescribed dose of radiation (e.g., in accordance with a calculated fluence map) for that location has been delivered to the patient.

An example method of treating a target using particle beam includes directing the particle beam along a path at least part-way through the target, and controlling an energy of the particle beam while the particle beam is directed along the path so that the particle beam treats at least interior portions of the target that are located along the path. While the particle beam is directed along the path, the particle beam delivers a dose of radiation to the target that exceeds one (1) Gray-per-second for a duration of less than five (5) seconds. A treatment plan may be generated to perform the method.

A beam delivery system for a radiotherapy system comprises a particle accelerator for generating a radiation beam and a positioning apparatus for moving the particle accelerator. The positioning apparatus comprises a counterbalanced lever carrying the particle accelerator. The particle accelerator may be a proton accelerator producing a proton beam.

Embodiments of the present invention describe systems and methods for providing proton therapy treatment using a beam line where the ESS is reduced or eliminated. For multi-room configurations, a beam line is included having quadrupole and steerer magnets to align and focus a particle beam extracted by an accelerator and guided by a bend section. A degrader is disposed between the bend section and the treatment room, and the energy analyzing functionality is performed by the gantry.

A beam delivery system for a radiotherapy system comprises a particle accelerator for generating a radiation beam and a positioning apparatus for moving the particle accelerator. The positioning apparatus comprises a counterbalanced lever carrying the particle accelerator. The particle accelerator may be a proton accelerator producing a proton beam.