Abstract: A radiotherapy system is configured to determine in vivo dose deposition of a radiotherapy treatment beam. The system includes the following components. A bi-planar magnetic resonance imaging (MRI) apparatus comprising a pair of spaced apart magnets. One of the magnets includes a hole proximal the centre thereof. A treatment beam source configured to generate a radiotherapy treatment beam. The treatment beam source is positioned to transmit the treatment beam through the hole in the magnet. A patient support configured to position a patient with the system so that a treatment target is proximal the treatment beam. A Positron Emission Tomography (PET) detector configured to obtain PET data of the treatment beam impacting the patient. The PET detector is positioned so that a transverse section of the patient that includes the treatment target lies between opposing portions of the PET detector.

Abstract: A magnetic resonance imaging (MRI) and radiation therapy system is described. The system has a magnet gantry, an MRI apparatus, a patient support system and a radiation source head. The magnet gantry is configured to rotate about a magnet gantry axis. The MRI apparatus is coupled to the magnet gantry. The radiation source head is coupled to the MRI apparatus via a radiation source arm. The radiation source head is configured to emit a treatment beam at varying angles with respect to an azimuthal gantry axis. A method for performing stereotactic radiosurgery (SRS) using a magnetic resonance (MR)-SRS is also described.

Abstract: A magnetic resonance (MR)-radiotherapy (RT) hybrid system for treating a patient is disclosed. The MR-RT hybrid system includes a radiation source for supplying a radiation beam to treat the patient and an MR imaging (MRI) apparatus for generating a divergent gradient field shaped to match a divergent geometry of the radiation beam of the radiation source.

Abstract: A magnetic resonance imaging (MRI) and radiation therapy system is described. The system comprises a magnet gantry, an MRI apparatus, a patient support system and a radiation source head. The magnet gantry is configured to rotate about a magnet gantry axis. The MRI apparatus is coupled to the magnet gantry. The radiation source head is coupled to the MRI apparatus via a radiation source arm. The radiation source head is configured to emit a treatment beam at varying angles with respect to an azimuthal gantry axis. A method for performing stereotactic radiosurgery (SRS) using a magnetic resonance (MR)-SRS is also described.

Abstract: A radiotherapy system is configured to determine in vivo dose deposition of a radiotherapy treatment beam. The system includes the following components. A bi-planar magnetic resonance imaging (MRI) apparatus comprising a pair of spaced apart magnets. One of the magnets includes a hole proximal the centre thereof. A treatment beam source configured to generate a radiotherapy reatment beam. The treatment beam source is positioned to transmit the treatment beam through the hole in the magnet. A patient support configured to position a patient with the system so that a treatment target is proximal the treatment beam. A Positron Emission Tomography (PET) detector configured to obtain PET data of the treatment beam impacting the patient. The PET detector is positioned so that a transverse section of the patient that includes the treatment target lies between opposing portions of the PET detector.

Abstract: A mobile app generates and manages companion apps in a memory of the mobile computing device. The companion apps cooperate with one or more integrated tracker apps in a memory of a wearable device to provide a combined functionality to the wearable device. A companion app communicates with an integrated tracker app to provide at least extended capabilities for the integrated tracker app including adding connectivity to the Internet to access On-line services and gather data on behalf of the integrated tracker app via the integrated tracking app submitting a request to an application programming interface for the companion app. The mobile app coordinates activities between i) multiples instances of the companion app loaded in the memory of the mobile computing device and ii) the integrated tracker apps running in the memory of the wearable device.

Abstract: A magnetic resonance (MR)-radiotherapy (RT) hybrid system for treating a patient is disclosed. The MR-RT hybrid system includes a radiation source for supplying a radiation beam to treat the patient and an MR imaging (MRI) apparatus for generating a divergent gradient field shaped to match a divergent geometry of the radiation beam of the radiation source.

Abstract: A mobile app generates and manages companion apps in a memory of the mobile computing device. The companion apps cooperate with one or more integrated tracker apps in a memory of a wearable device to provide a combined functionality to the wearable device. A companion app communicates with an integrated tracker app to provide at least extended capabilities for the integrated tracker app including adding connectivity to the Internet to access On-line services and gather data on behalf of the integrated tracker app via the integrated tracking app submitting a request to an application programming interface for the companion app. The mobile app coordinates activities between i) multiples instances of the companion app loaded in the memory of the mobile computing device and ii) the integrated tracker apps running in the memory of the wearable device.

Abstract: A digital media management system is provided which includes a server configured to receive media from a plurality of wireless devices via a network. The server includes a metadata interpreter, a media database, and a web interface component. The metadata interpreter is configured to receive metadata associated with the received media, where the metadata includes time and location data. The media database is configured to store a plurality of media and its associated metadata. The web interface component is configured to automatically generate a display of media based upon time and location ranges corresponding to the associated metadata.

Abstract: A radiation therapy system comprises a radiation source generating a beam of radiation and a magnetic resonance imaging apparatus. An interface acts between the radiation source and the MRI apparatus that permits irradiation to be performed simultaneously with imaging. The MRI apparatus and radiation source are coupled such that the system can be used in a rotation mode whereby the radiation source can irradiate a subject from basically any angle without reducing MRI image quality.

Abstract: Disclosed herein is a magnet assembly that includes at least two magnets arranged in a fixed spaced relationship with one another thereby to define a space between the magnets that encompasses an imaging volume. Each of the magnets produces a variety of magnetic field strengths across inward-facing surfaces thereof that, in combination, produce an acceptably homogeneous magnetic field in the imaging volume. Also disclosed is a method of defining a magnetic field for an imaging volume. The method comprises generating an initial model of a magnet assembly; estimating a magnetic field for the imaging volume based on the model; calculating deviation between the estimated magnetic field and a target magnetic field for the imaging volume; and updating the model to reduce the deviation by modifying the magnet assembly to produce a variety of magnetic field strengths that, in combination, produce substantially the target magnetic field in the imaging volume.

Abstract: A radiation therapy System comprises a magnetic resonance imaging (MRI) apparatus and a linear accelerator capable of generating a beam of radiation. The linear accelerator is immersed in and oriented with respect to the MRI magnetic field to expose the linear accelerator to magnetic force that directs particles therein along a central axis thereof.

Abstract: A radiation therapy System comprises a magnetic resonance imaging (MRI) apparatus and a linear accelerator capable of generating a beam of radiation. The linear accelerator is immersed in and oriented with respect to the MRI magnetic field to expose the linear accelerator to magnetic force that directs particles therein along a central axis thereof.

Abstract: A radiation therapy treatment method comprises imaging a subject and simulating four-dimensional aspects of radiotherapy. A treatment plan based on the simulation is generated to permit real-time, three-dimensional dose reconstruction at the time of treatment. The simulation and treatment plan are used during treatment fractions to achieve real-time image guidance.

Abstract: Disclosed herein is a magnet assembly that includes at least two magnets arranged in a fixed spaced relationship with one another thereby to define a space between the magnets that encompasses an imaging volume. Each of the magnets produces a variety of magnetic field strengths across inward-facing surfaces thereof that, in combination, produce an acceptably homogeneous magnetic field in the imaging volume. Also disclosed is a method of defining a magnetic field for an imaging volume. The method comprises generating an initial model of a magnet assembly; estimating a magnetic field for the imaging volume based on the model; calculating deviation between the estimated magnetic field and a target magnetic field for the imaging volume; and updating the model to reduce the deviation by modifying the magnet assembly to produce a variety of magnetic field strengths that, in combination, produce substantially the target magnetic field in the imaging volume.

Abstract: A radiation therapy treatment method comprises imaging a subject and simulating four-dimensional aspects of radiotherapy. A treatment plan based on the simulation is generated to permit real-time, three-dimensional dose reconstruction at the time of treatment. The simulation and treatment plan are used during treatment fractions to achieve real-time image guidance.

Abstract: A radiation therapy treatment method comprises imaging a subject and simulating four-dimensional aspects of radiotherapy. A treatment plan based on the simulation is generated to permit real-time, three-dimensional dose reconstruction at the time of treatment. The simulation and treatment plan are used during treatment fractions to achieve real-time image guidance.

Abstract: A radiation therapy System comprises a magnetic resonance imaging (MRI) apparatus and a linear accelerator capable of generating a beam of radiation. The linear accelerator is immersed in and oriented with respect to the MRI magnetic field to expose the linear accelerator to magnetic force that directs particles therein along a central axis thereof.

Abstract: Disclosed herein is a magnet assembly that includes at least two magnets arranged in a fixed spaced relationship with one another thereby to define a space between the magnets that encompasses an imaging volume. Each of the magnets produces a variety of magnetic field strengths across inward-facing surfaces thereof that, in combination, produce an acceptably homogeneous magnetic field in the imaging volume. Also disclosed is a method of defining a magnetic field for an imaging volume. The method comprises generating an initial model of a magnet assembly; estimating a magnetic field for the imaging volume based on the model; calculating deviation between the estimated magnetic field and a target magnetic field for the imaging volume; and updating the model to reduce the deviation by modifying the magnet assembly to produce a variety of magnetic field strengths that, in combination, produce substantially the target magnetic field in the imaging volume.

Abstract: A radiation therapy treatment method comprises imaging a subject and simulating four-dimensional aspects of radiotherapy. A treatment plan based on the simulation is generated to permit real-time, three-dimensional dose reconstruction at the time of treatment. The simulation and treatment plan are used during treatment fractions to achieve real-time image guidance.