Radiation therapy planning and follow-up system with large bore nuclear and magnetic resonance imaging or large bore CT and magnetic resonance imaging

Having thus described the preferred embodiments, the invention is now claimed to be: 1. A radiation therapy planning and follow-up system, comprising: a magnetic resonance (MR) scanner with a first bore which defines an MR imaging region configured to receive a subject along an MR longitudinal axis; a second imaging scanner with a second bore which defines a second imaging region configured to receive the subject along a second longitudinal axis, the second longitudinal axis being aligned with the MR longitudinal axis; and a radiation therapy type couch configured to move linearly through the MR and second imaging regions and configured to position the subject sequentially in the MR and second imaging regions, the radiation therapy type couch including a tabletop surface and mounting structures configured to accept restraint device which reproducibly constrain a subject in a selected, fixed position with an extremity elevated; wherein the first and second bores have a diameter of at least 70 cm to accommodate a subject constrained on the tabletop surface with the elevated extremity; a plurality of registration marks disposed at least one of on the flat tabletop surface, incorporated in the radiation therapy type couch, on the restraint devices or on the subject; a registration system configured to determine the location of the registration marks in three dimensions with the subject in each of the first bore and the second bore and generate a feedback signal which instructs at least one of an MR scan controller and a second imaging scanner scan controller to adjust a position of the radiation therapy type couch and/or slice or slab positions for aligned image acquisition; a fusion processor configured to combine an image representation generated from data collection in the MR imaging region and an image representation generated from data collection in the second imaging region into a composite image representation; and a planning processor configured to generate a radiation therapy treatment plan according to the composite image; wherein the second scanner includes a PET scanner, the PET scanner with a PET bore which defines a PET imaging region including: a ring of optical detectors dispose adjacent to the PET imaging region optical coupled to a scintillator layer, the ring of optical detectors being configured to generate nuclear imaging data in response to emitted radiation in the PET imaging region; and a heater configured to heat the scintillator; and a controller configured to place the PET scanner in a quiescent mode in which the PET scanner does not emit electrical or RF noise during MR imaging and returns the PET scanner to an active mode after the MR imaging including controlling the heater to heat the scintillator layer to an operating temperature. 2. The radiation therapy planning and follow-up system according to claim 1 , wherein the patient registration system includes: at least one laser having a precise relationship to an isocenter of the MR and second imaging regions and configured to generate a signal representative of a location of each of a plurality registration marks disposed on the subject, on fixation devices attached to the patient, and/or the radiation therapy couch; and a registration processor configured to determine a three-dimensional coordinate position of each registration mark according to the generated signal. 3. The radiation therapy planning and follow-up system according to claim 2 , wherein the second scanner is a nuclear scanner and the registration processor is configured to generate a feedback signal based on an actual coordinate position and an expected coordinate position of each registration mark and at least one of: displays the generated feedback signal on a graphical user interface; instructs at least one of a MR scan controller and a nuclear scan controller to adjust the position of the radiation therapy couch and/or the slice or slab positions for image acquisition; and provides the feedback signal to a fusion processor configured to combine the nuclear and MR image representations. 4. A radiation therapy planning and follow-up system comprising: a magnetic resonance (MR) scanner with a first bore which defines an MR imaging region configured to receive a subject along an MR longitudinal axis, the first bore having a diameter of at least 70 cm; a second imaging scanner with a second bore which defines a second imaging region configured to receive the subject along a second longitudinal axis, the second longitudinal axis being aligned with the MR longitudinal axis and the second bore having a diameter at least 70 cm; a radiation therapy type couch configured to move linearly through the MR and second imaging regions and configured to position the subject sequentially in the MR and second imaging regions, the radiation therapy type couch including a flat tabletop surface and mounting structures configured to accept restraint devices which reproducibly constrain a subject in a selected, fixed position with an extremity elevated; wherein the second scanner includes a PET scanner, the PET scanner with a PET bore which defines a PET imaging region including: a ring of optical detectors dispose adjacent to the PET imaging region optical coupled to a scintillator layer, the ring of optical detectors being configured to generate nuclear imaging data in response to emitted radiation in the PET imaging region; a radio-frequency shield disposed between the scintillator layer and the PET imaging region and configured to shield the MR scanner from radio frequency noise emanating from the PET scanner; a heating element adjacent to the optical detectors configured to heat the optical detectors and associated circuitry; one or more circuits configured to temporarily lower an operating voltage in photo-multiplier tube optical detectors to place the PET scanner in a quiescent state in which the PET scanner emits a reduced amount of the radio frequency noise when the MR scanner is generating image data and to control the operating voltage and control the heating element to raise the optical detector to a nominal operating temperature to place the PET scanner in an active state to prepare the PET scanner to generate image data. 5. The radiation therapy planning and follow-up system according to claim 1 , wherein the radiation therapy planning and follow-up system is disposed on a mobile platform configured to be transported from one location to another. 6. A method for generating or updating a radiation therapy plan, comprising: with an MR scanner or a second scanner, acquiring an MR or second image representation of a target volume supported on a flat radiation therapy couch in one of an MR imaging region of the MR scanner and a second imaging region of the second scanner, and localizing the target volume relative to the corresponding imaging region, the radiation therapy type couch including a flat tabletop surface and mounting structures configured to accept restraint device which reproducibly constrain a subject in a selected, fixed position with an extremity elevated; with one or more computers, registering the localized target volume to the flat radiation therapy couch and determining an expected coordinate position of the target volume relative to the flat radiation therapy couch; with guide rails, re-positioning the flat radiation therapy couch linearly from one of the MR imaging region and second imaging region to the other imaging region of the second scanner and MR scanner which shares a common longitudinal axis therewith; acquiring an image representation of the target volume with the other one of the second and MR scanners; with the one or more computers, combining the MR and second image representations in a combined image repre