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.

To implement downsizing of an apparatus and highly accurate beam irradiation. An irradiation nozzle 4 that irradiates a target object Pt with a radiotherapy beam includes: a nozzle base part 42 fixed on a beam axis 40 through which the radiotherapy beam passes; and a nozzle tip part that irradiates the target object with the radiotherapy beam that has passed through the nozzle base part, in which the nozzle tip part is fixed at a first position when the target object is irradiated with the radiotherapy beam and is fixed at a second position when the target object is imaged, and a curved movement path in which the nozzle tip part is movable between the first position and the second position is provided.

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).

Embodiments of the present invention describe systems and methods for providing radiotherapy treatment by focusing an electron beam on a target (e.g., a tungsten plate) to produce a high-yield x-ray output with improved field shaping. A modified electron beam spatial distribution is employed to scan the target, such as a 2D periodic beam path, which advantageously lowers the x-ray target temperature compared to the typical compact beam spatial distribution. As a result, the x-ray target can produce a high yield output without sacrificing the x-ray target life span. The use of a 2D periodic beam path allows a much colder target functioning regime such that more dosage can be applied in a short period of time compared to existing techniques.

Combined MRI and radiotherapy installations require complex Faraday cage structure that encloses the room, the MRI magnets, and the patient volume, but excludes the linear accelerator path and its supply cabling. A problem with this is that the MRI magnets tend to vibrate when in use, and if physically connected to a rigid structure then the vibrations will be passed to that structure also. To alleviate this, we propose that the Faraday cage be made of a mix of prefabricated conductive sections and flexible sections of a conductive sheet. The flexible conductive sheet can be copper or aluminium, in the form of a foil or mesh.

The present invention relates to the field of electron beam machines, such as linear straight through machines, and methods used for therapeutic uses. More particularly, the present invention relates to electron beam machines that incorporate a rotary coupling system to easily attach and manually or automatically rotate field defining members such as applicators and/or shields to the electron beam machines. The rotary coupling systems also incorporate functionality to automatically detect collisions involving the electron beam machines such as between an electron beam machine and other equipment or a patient.

The invention comprises a method and apparatus for treating a tumor of a patient, in a beam treatment center comprising a floor, with positively charged particles, comprising: (1) a synchrotron mounted to an elevated floor section above the floor of the beam treatment center; (2) a beam transport system, comprising: at least three fixed-position beam transport lines, where none of the synchrotron and the beam transport system penetrate through the floor of the beam treatment center; (3) the positively charged particles transported from the synchrotron, through the beam transport system, to a position above a patient positioning system during use; and (4) an optional repositionable nozzle system connected to a first, second, and third fixed-position beam transport line at a first, second, and third time, respectively, where the nozzle track forms an arc of a circle and the repositionable nozzle system moves along the nozzle track.

A neutron beam source generation system, a neutron beam source stabilization control system, and a neutron beam source generation method are provided. The neutron beam source generation system includes an accelerator, a target, and a calibration module. The accelerator is configured to generate a proton beam. A neutron beam source is generated by irradiating the target with the proton beam. The calibration module includes a pair of electromagnet components, a profile-measuring component, a current-measuring component, and a Faraday cup component. The calibration module uses the pair of electromagnet components to control the distribution of the proton beam according to the profile distribution of the proton beam as measured by the profile-measuring component. The calibration module adjusts the current of the proton beam according to the first current value as measured by the current-measuring component, the second current value as measured by the Faraday cup component, or both.

A system for delivering ultra-high dose rate irradiation to a target area of a patient, includes a pulsed charged-particle source along a beam axis; a collimator for shaping the beam of radiation; one or more cameras for imaging the target area of the patient; and a dosimetry controller for providing control signals to the charged-particle source one or more dosimeters positioned between an output of the charged-particle source and the collimator in beam fringes for measuring a radiation dosage provided by each pulse; and a beam scanning coil positioned between the collimator and the patient for directing the shaped beam. The dosimetry controller receives feedback from the one or more dosimeters and provides control signals to the particle source and the beam scanning coil that modulate final pulses in the series of pulses in real-time.

A method for radiotherapy may include generating an electrical impedance tomography (EIT) image of a patient. The method may also include generating a first image. The method may further include determining an EIT feature of the EIT image. The method may also include determining a position relationship between the EIT image and the first image. The method may further include locating an anatomical structure of interest (ASI) of the patient based on the position relationship. The method may further include delivering radiation to the ASI of the patient.