An applicator for intraoperative radiotherapy with low-energy X-ray radiation includes an applicator body, an air-permeable outer surface with a circumferential outer face and with a distal end, a receiving device which is arranged at a proximal end and with which the applicator can be secured to an X-ray irradiation device, and an inner recess which has an opening at the proximal end and into which an X-ray radiation source is insertable. The applicator has a solid porous structure on its outer surface which provides the air-permeable outer surface with a rigid shape. The solid porous structure forms a continuous air-permeable channel structure which is connected in an air-conducting manner to the proximal end of the applicator.

According to an embodiment, a particle beam treatment system includes a storage, an estimator, a target value generator, and a particle beam treatment device. The storage stores therein a respiratory movement model obtained by synchronizing amount of displacement of an affected area of a subject with a signal related to respiration of the subject and performing modeling. The estimator estimates, based on the measured signal related to respiration and the respiratory movement model, amount of displacement of the affected area corresponding to the measured signal. The target value generator generates a target value, which is used for performing movement control on a platform on which the subject is lying down, corresponding to the estimated amount of displacement of the affected area. The particle beam treatment device irradiates, with particle beams, the affected area of the subject on the platform subjected to movement control according to the target value.

A jaw position detection apparatus is configured to detect position information of at least one jaw moving in an arc, and includes a connecting component, a conversion mechanism, and a displacement sensor. The connecting component is fixed on a jaw. The conversion mechanism is connected to the connecting component, and the conversion mechanism is configured to convert an arc motion of the connecting component into a linear motion when the connecting component moves in an arc with the jaw. The displacement sensor is connected to the conversion mechanism, and configured to detect displacement information of the linear motion of the conversion mechanism.

Methods, devices and systems for ultra-high dose radiotherapy are disclosed. The described techniques rely in-part on active switching control of a photoconductive switch during the time the accelerator is accelerating charged particles to produce the output radiation at the desired dose rates. One radiotherapy system includes a particle accelerator configured to receive charged particles from a pulsed source. The particle accelerator includes a pipe configured to allow the charged particles to pass through as a beam, a magnetic core positioned proximate to the pipe and coupled to the pulsed source, and at least one multilayer insulator positioned adjacent to the pipe and the magnetic core. The system also includes a photoconductive switch coupled to the particle accelerator and configured to supply the particle accelerator with a plurality of voltage pulses.

A coolant having a set temperature is fed into the nuclear reactor core of a medical neutron source, which is in a subcritical state. The nuclear reactor core is transitioned from the subcritical state to a critical state until the nominal power of the nuclear reactor is achieved. A neutron output channel is opened in order to conduct a neutron therapy session, and the operation of the reactor is maintained at nominal power while the neutron therapy session is conducted. At the end of the session, the neutron output channel is closed at the same time as the reactor core is transitioned to a subcritical state. The temperature of the coolant entering the core is maintained unchanged and equal to a set temperature, both when the core is transitioned to a critical state and during the operation of the nuclear reactor at nominal power.

A neutron capture therapy system may prevent deformation and damage of a material of a beam shaping assembly (20), thereby improving flux and quality of a neutron source. A boron neutron capture therapy system (100) includes a neutron generating device (10) and a beam shaping assembly (20), where the neutron generating device (10) includes an accelerator (11) and a target (T), a charged particle beam (P) generated by acceleration of the accelerator (11) interacts with the target (T) to generate neutrons, the neutrons form a neutron beam (N), the neutron beam (N) defines a main axis (X); the beam shaping assembly (20) includes a moderator (231), a reflector (232), and a radiation shield (233); and the beam shaping assembly (20) further includes a frame (21) accommodating the moderator (231).

In a magnetic device 1, on faces opposite to a middle plane 2 between an upper magnetic pole 8 and a lower magnetic pole 9, recesses 21a, 21b, 21c, and 21d and projections 22a, 22b, 22c, and 22d are alternately placed along a beam circling direction. In the projections 22a, 22b, 22c, and 22d, angle widths θ of the projections 22a, 22b, 22c, and 22d when viewed from the center O1 of a beam closed orbit is narrowed as beam energy is increased. On the outer circumferential region of the recess 21a on the upper magnetic pole 8 and the lower magnetic pole 9, the inlet of an extraction channel 1019 that extracts a beam accelerated to a predetermined energy to outside an accelerator 1004 is provided.

A radiation delivery system that includes a gantry to extend along one or more axes. The gantry is to provide a continuous rotation. The radiation delivery system includes a linear accelerator (LINAC) coupled to the gantry. The LINAC is to generate a treatment beam. The radiation delivery system includes a rotary joint coupled to the gantry. The rotary joint provides a physical connection from the LINAC to an external system that is positioned off the gantry. The physical connection is to transport at least one of a cooling liquid or air.

Provided is a particle beam therapeutic device, a particle beam therapeutic system, an irradiation planning device, and a particle beam irradiation method. In a particle beam therapeutic system 1, while a magnetic field generation device 9 generates a magnetic field that affects a particle beam in the vicinity of a target of a subject, a particle beam extracted from an ion source 2 is accelerated by an accelerator 4, transported by a beam transport system 5, and applied from an irradiation device 6. In the irradiation of the particle beam, an irradiation planning device 20 creates an irradiation plan of the particle beam in consideration of the influence of the magnetic field, and applies the particle beam based on this irradiation plan.

A device and a method for measuring proton beam source position and beamline center are disclosed. The device includes N quadrupole magnets, a laser, a target and a scintillation screen; the target and the scintillation screen are arranged in front of and behind the N-quadrupole lens, respectively; the N-quadrupole lens can be converted to a M-quadrupole lens; the position of proton beam after being focused by the N- or M-quadrupole lens on the scintillation screen is measured; according to the amplification factor and the proton beam position, the offset of the proton beam source from the beamline center, as well as the position of the beamline center on the scintillation screen are calculated; the disclosure can accurately determine the position of the beamline center and the proton beam source by the use of N quadrupole magnets, combined with a scintillation screen.