Abstract: A system proton treatment system including a proton accelerator structured to generate a proton beam, a plurality of beamline pathways configured to direct the proton beam from the proton accelerator to a corresponding plurality of treatment rooms, a rotatable bending magnet located between the proton accelerator and the plurality of treatment rooms, the rotatable bending magnet being structured to selectively rotate between multiple treatment rooms, and an upright patient positioning mechanism disposed in each of the treatment rooms, the upright patient positioning mechanism being structured to support a patient within a particular treatment room and to rotate the patient between a fixed imaging source and imaging panel.

Abstract: A system proton treatment system including a proton accelerator structured to generate a proton beam, a plurality of beamline pathways configured to direct the proton beam from the proton accelerator to a corresponding plurality of treatment rooms, a rotatable bending magnet located between the proton accelerator and the plurality of treatment rooms, the rotatable bending magnet being structured to selectively rotate between multiple treatment rooms, and an upright patient positioning mechanism disposed in each of the treatment rooms, the upright patient positioning mechanism being structured to support a patient within a particular treatment room and to rotate the patient between a fixed imaging source and imaging panel.

Abstract: A computer controlled robot system for positioning a patient for radiation therapy or other medical procedures and the like. The robot is mounted at the top of a vertical shaft extending from the treatment room floor and includes horizontal arms arranged to maximize the available work envelope and eliminate “dead spots” in the envelope that the robot cannot reach. A double redundant coupling system for coupling devices to the robot is provided. A vision based docking system is employed for automatically coupling devices to the robot. Various enhanced safety features are provided, including device specific collision avoidance.

Abstract: A computer controlled robot system for positioning a patient for radiation therapy or other medical procedures and the like. The robot is mounted at the top of a vertical shaft extending from the treatment room floor and includes horizontal arms arranged to maximize the available work envelope and eliminate “dead spots” in the envelope that the robot cannot reach. A double redundant coupling system for coupling devices to the robot is provided. A vision based docking system is employed for automatically coupling devices to the robot. Various enhanced safety features are provided, including device specific collision avoidance.

Abstract: A computer controlled robot system for positioning a patient for radiation therapy or other medical procedures and the like. The robot is mounted at the top of a vertical shaft extending from the treatment room floor and includes horizontal arms arranged to maximize the available work envelope and eliminate “dead spots” in the envelope that the robot cannot reach. A double redundant coupling system for coupling devices to the robot is provided. A vision based docking system is employed for automatically coupling devices to the robot. Various enhanced safety features are provided, including device specific collision avoidance.

Abstract: A theater system for a proton treatment system, including a tunnel structure configured around an isocenter of a proton treatment system, and one or more devices mounted on the tunnel structure to communicate with a patient located on a treatment bed of the proton treatment system.

Abstract: Systems and methods of tracking location of an internal bodily structure of a patient in a radiation treatment room, including a fiducial marker having a unique center point, an offset structure detachably connected to the fiducial marker, the offset structure having unique three dimensional offset coordinates relative to the center point, a means for detachably mounting the offset structure to the patient, an imaging unit to measure location information of the offset structure relative to a target internal bodily structure of the patient, and a detection unit to detect location information of the offset structure and to calculate an offset distance between the target internal bodily structure and the center point.

Abstract: An imaging positioning system having a robotically positioned support structure is provided. By utilizing a robotic arm, imaging along multiple planes within a patient treatment room without having to move the patient is provided. Such a configuration allows multiple axis x-ray imaging, cone beam CT acquisitions having a dynamic field of view, and PET imaging within the treatment room. Rotation of the imaging panel on the support structure allows the imaging system to simulate a gantry rotation when a fixed beam is used for treatment. Beam line x-ray imaging is also provided by tilting the imaging panel or by moving the support structure on which the x-ray source is positioned. Laser distance scanning for collision avoidance and force torque sensing movement enhance the safety thereof. The support structure may be in the form of a ring along which the imaging components may move.

Abstract: A computer controlled robot system for positioning a patient for radiation therapy or other medical procedures and the like. The robot is mounted at the top of a vertical shaft extending from the treatment room floor and includes horizontal arms arranged to maximize the available work envelope and eliminate “dead spots” in the envelope that the robot cannot reach. A double redundant coupling system for coupling devices to the robot is provided. A vision based docking system is employed for automatically coupling devices to the robot. Various enhanced safety features are provided, including device specific collision avoidance.

Abstract: An imaging positioning system having a robotically positioned support structure is provided. By utilizing a robotic arm, imaging along multiple planes within a patient treatment room without having to move the patient is provided. Such a configuration allows multiple axis x-ray imaging, cone beam CT acquisitions having a dynamic field of view, and PET imaging within the treatment room. Rotation of the imaging panel on the support structure allows the imaging system to simulate a gantry rotation when a fixed beam is used for treatment. Beam line x-ray imaging is also provided by tilting the imaging panel or by moving the support structure on which the x-ray source is positioned. Laser distance scanning for collision avoidance and force torque sensing movement enhance the safety thereof. The support structure may be in the form of a ring along which the imaging components may move.