A capsule for the transfer of a target material in a conveying system between a target irradiation station and a collecting station comprising: a beamline channel for the passage of an energetic beam irradiating the target material, a target holder holding the target material or a substrate backing the target material at a glancing angle with respect to the beamline channel axis, a degrader foil positioned across the beamline channel for degrading an energy of the energetic beam upstream of the target material, a target cooling inlet and a target cooling outlet for passage of a cooling fluid in a target cooling duct in a vicinity of the target holder such that the target material can be cooled during an irradiation, and a degrader foil cooling inlet and a degrader foil cooling outlet for passage of a cooling gas in a vicinity of the degrader foil.

Medical systems, devices, and methods provide improved radiosurgical techniques for treatment of anxiety disorders (such as Post-Traumatic Stress Disorder (PTSD), Generalized Anxiety Disorder (GAD), Panic Disorder, Social Phobia, Specific Phobia, and the like). Radiation can be directed from a radiation source outside the patient toward a target tissue deep within the patient's brain using a stereotactic radiosurgical platform, typically without having to impose the surgical trauma associated with accessing deep brain tissues. The target will often include at least a portion of the amygdala, with exemplary treatments being directed to targets that are limited to a sub-region of the amygdala. Rather than applying sufficient radiation to kill the neural tissue within the target, a cellularly sub-lethal dose of the radiation may be applied. Without imposing frank cell death throughout the target, the radiation can mitigate the anxiety disorder, obesity, or the like, often by modulating the level of neural activity within the target and in associated tissues.

A semi-flexible rod may have a rounded tip having exposed metal conductor elements that produce an adaptive electrical field or an adaptive magnetic field. The adaptive electrical field or the adaptive magnetic field may be adjusted in order to capture a stray x-ray photon near an in-vivo target area of cancer cells.

An X-ray system for providing a converging X-rays comprises: (a) an X-ray source having an optical axis thereof; and an X-ray lens comprising at least one ring having a Bragg reflecting surface formed by a plurality of single-crystal tiles. Each tile individually comprises an adjusting arrangement enabling a tridimensional individual displacement thereof in angular and translational manner.

A treatment planning system for generating a plan for treatment by radiation with charged particles beams applied by pencil beam scanning onto a target tissue comprising tumoral cells is provided. The treatment planning system performs a dose definition stage defining the doses to be deposited within the peripheral surface, a beam definition stage defining positions and dimensions of the beamlets of the PBS during the at least one high rate fraction, the beams definition stage including a dose rate definition stage comprising at least one high rate fraction, and a beamlets scanning sequence stage defining a scanning sequence of irradiation of the beamlets. The beamlets scanning sequence stage optimizes a time sequence of beamlets emission such that at the end of a fraction j, a dose is deposited onto at least a predefined fraction of each specific volume at a mean deposition rate superior or equal to a predefined value.

The dose rate of voxels within a particle beam (e.g., proton beam) treatment field delivered using pencil beam scanning (PBS) is calculated, and a representative dose rate for the PBS treatment field is reported. The calculations account for dose accumulation in a local region or sub-volume (e.g., a voxel) as a function of time.

A control circuit access information corresponding to patient geometry information for a particular patient. The control circuit then provides that information, along with at least one variable that is unrelated to that particular patient, as input to a field geometry generator. The field geometry generator can comprise a neural network trained in a conditional generative adversarial networks (GAN) framework as a function of previously-developed field geometry solutions for a plurality of different patients. In such a case the information corresponding to the patient geometry information for the particular patient can serve as conditional input to the neural network. So configured, the control circuit can then process the foregoing input using the field geometry generator to thereby generate the therapeutic radiation delivery field geometry for the particular patient.

A control circuit forms a radiation therapy treatment plan by automatically generating a base dose that references dosing information from multiple sources and then using that base dose to optimize a radiation therapy treatment plan. That radiation therapy treatment plan is then used to administer radiation therapy to a patient. That automatically generated base dose can represent any or all of earlier radiation therapy treatments for the patient, a same fraction as a dose presently being optimized per the radiation therapy treatment plan, and future planned fractions for the patient.

An imaging apparatus and associated methods are provided to efficiently estimate scatter during multi-fraction treatments for improved quality and workflow. Estimated scatter from one fraction during a treatment course can be utilized during subsequent fractions, allowing for measurements with higher scatter-to-primary ratios. The quality of scatter estimates can be maintained, while workflow improves and dosage decreases. Scan configuration limits can be utilized to maintain a minimum level of scatter measurement quality. Patient information can be monitored to ensure that prior fraction scatter estimates are still applicable to current patient status.

A self-shielded and computer controlled system for performing non-invasive stereotactic radiosurgery and precision radiotherapy using a linear accelerator mounted within a two degree-of-freedom radiation shield coupled to a three-degree of freedom patient table is provided. The radiation shield can include an axial shield rotatable about an axial axis and an oblique shield independently rotatable about an oblique axis, thereby providing improved range of trajectories of the therapeutic and diagnostic radiation beams. Such shields can be balanced about their respective axes of rotation and about a common support structure to facilitate ease of movement. Such systems can further include an imaging system to accurately deliver radiation to the treatment target and automatically make corrections needed to maintain the anatomical target at the system isocenter. Various subsystems to automate controlled and coordinated movement of the movable shield components and operation of the treatment related subsystems to optimize performance and ensure safety are also provided.