Disclosed are a neutron dose measurement apparatus and a neutron capturing treatment device. The neutron dose measurement apparatus includes a measurement unit for receiving neutrons and outputting signals, a signal processing unit for processing the signals output from the measurement unit, a counter for counting the signals output from the signal processing unit to obtain a count rate, and a count rate correction unit for correcting the count rate.

Systems and methods are disclosed for performing operations comprising: receiving first and second images depicting an anatomy of a subject; obtaining a segmentation associated with the first image; applying a trained neural network to estimate the adapted segmentation corresponding to the anatomy depicted in the second image, the trained network consisting of three sub-networks: a registration sub-network, generating an initial segmentation estimate representing a deformation of the segmentation associated with the first image to fit the anatomy depicted in the second image, a segmentation sub-network, generating a second initial segmentation estimate for the second image, and a third refinement sub-network, combining the two initial segmentations and generating a refined segmentation for the second image.

Systems and methods for efficient and automatic determination of radiation beam configurations for patient-specific radiation therapy planning are disclosed. According to an aspect, a method includes receiving data based on patient information and geometric characterization of one or more organs at risk proximate to a target volume of a patient. The method includes determining automatically one or more radiation treatment beam configuration sets. Further, the method includes presenting the determined one or more radiation beam configuration sets via a user interface.

Disclosed herein are systems and methods for real-time monitoring of patient position and/or location during a radiation treatment session. Images acquired of a patient during a treatment session can be used to calculate the patient's position and/or location with respect to the components of the radiation therapy system. One variation of a radiation therapy system includes a circular gantry with a rotatable ring coupled to a stationary frame, a therapeutic radiation source mounted on the rotatable ring, and a patient-monitoring imaging system mounted on the rotatable ring. The patient-monitoring system may have one or more image sensors or cameras disposed on the rotatable ring within a bore region of the radiation therapy system, and may be configured to acquire image data as the ring rotates.

A template matching is performed on two fluoroscopic images by using a template image prepared in advance and a position corresponding to a high matching score is listed as a candidate for the position of a marker 29. From two lists of the candidates of the position of the marker 29, the lengths of common vertical lines for all combinations are calculated. Then, the position of the marker 29 is detected based on the matching score and the common vertical line. Then, based on the detected position of the marker 29, an amount of a proton beam to be irradiated to a target is controlled. Therefore, a tracking target can be accurately detected even when the conditions for X-ray fluoroscopy is severe, e.g., a thick object.

A system includes a computing system with a processor and computer readable storage medium with computer readable and executable instructions, including a radiation plan module, a radiation plan optimization module and a radiation plan visualization module. The processor is configured to execute the instructions, which causes the processor to construct and visually present, via a display monitor, a two-dimensional plot with three-dimensions of data from a radiation plan, and two dimensions along two axes of the plot and a third dimension represented through intensity.

A system and method for optimizing fractionation schemes in planning radiation therapy are provided, as well as a computer program and a computer program product for carrying out the method, and an arrangement for planning radiation therapy. For optimizing the fractionation schemes, the following steps are performed. Anatomical image data of a subject to be treated is received by a biological impact calculation module as well as a predetermined radiation therapy treatment plan comprising a dose distribution to be delivered to the subject. A first set of reference parameters of a fractionation scheme is received, and also a second set of parameters of a fractionation scheme is received. Based on this, the module calculates the biological impact of the radiation therapy treatment. The calculated biological impact results are provided simultaneously for the first and the second sets of received parameters.

A method of customized breathing maneuver guidance during radiotherapy treatment by configuring to a treatment couch an augmented reality system that includes a mounting assembly, a position measurement module to measure a distance from a fixed position to a patient anatomic region during a breathing cycle, and a breath monitoring and instruction screen viewable by the patient disposed proximal to the fixed position, where the patient monitors and controls a state of their breathing cycle in real time from breath state information displayed on the instruction screen, and determining the anatomic region for monitoring to measure the distance from the fixed position, determining a patient-customized breath hold amplitude by measuring a distance between a baseline exhale position a maximum inhale position, and entering breath hold amplitude data to a computer for subsequent breath hold guidance regardless of the treatment couch model setup and patient weight variations.

New techniques are described herein for providing a user-friendly interface for adjusting dose distribution values during optimization of a radiation application plan. In an embodiment, a graphical user interface is provided that provides an image of a target area for a radiation application, and a graphical overlay of a dose distribution disposed over the target area that visually represents the optimized dose distribution according to the input dose parameters. In one or more embodiments, the dose distribution may be automatically calculated from input parameters supplied by a user through the graphical user interface prior to optimization. A user (such as a clinician, radiation oncologist, or radiation therapy operator, etc.) is able to modify the visualization of the dose distribution volume during optimization via a user input device in conjunction with the graphical user interface and have the modification adjusted in real-time.

The present disclosure relates a multi-leaf collimator. The multi-leaf collimator may include a plurality of leaf modules. Each leaf module of the plurality of leaf modules may include a leaf configured to shield a portion of beams emitted by a radiation source. The leaf may be movable along a guide rail of the multi-leaf collimator. Each leaf module may also include a drive mechanism including a first drive component and a second drive component. The first drive component and the second drive component may be both connected to the leaf. The first drive component and the second drive component may jointly actuate the leaf to move along the guide rail.