Disclosed herein are radiotherapy methods and systems that can display a workflow-oriented graphical user interface(s). In an embodiment, a method comprises presenting, by a server, a graphical user interface for display on a screen positioned on a gantry of a radiotherapy machine, wherein the graphical user interface comprises a page corresponding to a radiotherapy treatment of a patient, wherein the page comprises a first graphical element indicating at least one attribute of alignment data corresponding to the radiotherapy treatment of the patient.

A radiation dose received by a patient from a radiation therapy system can be verified by acquiring a cine stream of image frames from an electronic portal imaging device (EPID) that is arranged to detect radiation exiting the patient during irradiation. The cine stream of EPID image frames can be processed in real-time to form exit images providing absolute dose measurements at the EPID (dose-to-water values), which is representative of the characteristics of the radiation received by the patient. Compliance with predetermined characteristics for the field can be determined during treatment by periodically comparing the absolute dose measurements with the predetermined characteristics, which can include a predicted total dose in the field after full treatment and/or a complete irradiation area outline (CIAO). The system operator can be alerted or the irradiation automatically stopped when non-compliance is detected.

The present invention is a method or system for acceptance testing and commissioning of a LINAC and treatment planning system (TPS). For a LINAC commissioning, the present invention collects reference data from a fully calibrated LINAC and compares the reference data with machine performance data collected from LINAC. The compared results are analyzed to assess accuracy of the testing LINAC. For a TPS commissioning, the present invention collects standard reference data from standard treatment plans and standard input data and compares the standard reference data with results from standard tests that are performed by a testing treatment plan system. The compares results are analyzed to assess accuracy of the testing treatment plan system.

The present invention is a method or system for acceptance testing and commissioning of a LINAC and treatment planning system (TPS). For a LINAC commissioning, the present invention collects reference data from a fully calibrated LINAC and compares the reference data with machine performance data collected from LINAC. The compared results are analyzed to assess accuracy of the testing LINAC. For a TPS commissioning, the present invention collects standard reference data from standard treatment plans and standard input data and compares the standard reference data with results from standard tests that are performed by a testing treatment plan system. The compares results are analyzed to assess accuracy of the testing treatment plan system.

A radiotherapy apparatus is disclosed, having an imaging system and a therapeutic radiation source, an imageable volume into which therapeutic radiation may be provided, a first imaging means for providing an image resulting from the imaging system and a second imaging means for providing an image resulting from the therapeutic radiation, and a patient support moveable relative to the volume, wherein the patient support is provided with a calibration portion comprising at least one object of a material capable of appearing in the image produced by the first imaging means and at least one object of a material capable of appearing in the image produced by the second imaging means, the at least one object being fixed in a pre-determined position relative to the calibration portion and the calibration portion being fixed in a pre-determined position relative to the patient support, the patient support being moveable so that the at least one object portion may optionally be positioned within or outside the volume.

A particle portal imaging (PPI) system and method are provided that can be used to provide a “beam’s eye view” of a patient’s anatomy as a charged particle beam is delivered to a target region of the patient’s body. The PPI system is capable of performing real-time image acquisition and in-situ dose monitoring using at least exit neutrons generated within the patient. The PPI system can perform charged particle treatment (PT) monitoring to monitor the particle beam being used for PT.

Disclosed herein is an imaging system for a radiotherapy device which is configured to provide therapeutic radiation to a patient via a source of therapeutic radiation. The imaging system comprises a source of imaging radiation, a CBCT panel detector, and a CT detector, wherein the source of imaging radiation is configured to be adjustable such that in a first configuration it is configured to emit imaging radiation towards the CT detector and in a second configuration it is configured to emit imaging radiation towards the CBCT detector.

The present invention is a method or system for acceptance testing and commissioning of a LINAC and treatment planning system (TPS). For a LINAC commissioning, the present invention collects reference data from a fully calibrated LINAC and compares the reference data with machine performance data collected from LINAC. The compared results are analyzed to assess accuracy of the testing LINAC. For a TPS commissioning, the present invention collects standard reference data from standard treatment plans and standard input data and compares the standard reference data with results from standard tests that are performed by a testing treatment plan system. The compares results are analyzed to assess accuracy of the testing treatment plan system.

The invention relates to a method and apparatus for control of a charged particle cancer therapy system. A treatment delivery control system is used to directly control multiple subsystems of the cancer therapy system without direct communication between selected subsystems, which enhances safety, simplifies quality assurance and quality control, and facilitates programming. For example, the treatment delivery control system directly controls one or more of: an imaging system, a positioning system, an injection system, a radio-frequency quadrupole system, a ring accelerator or synchrotron, an extraction system, a beam line, an irradiation nozzle, a gantry, a display system, a targeting system, and a verification system. Generally, the control system integrates subsystems and/or integrates output of one or more of the above described cancer therapy system elements with inputs of one or more of the above described cancer therapy system elements.

A particle portal imaging (PPI) system and method are provided that can be used to provide a “beam's eye view” of a patient's anatomy as a charged particle beam is delivered to a target region of the patient's body. The PPI system is capable of performing real-time image acquisition and in-situ dose monitoring using at least exit neutrons generated within the patient. The PPI system can perform charged particle treatment (PT) monitoring to monitor the particle beam being used for PT.