Apparatus and method for forming prescribed radiation therapy treatment instructions

What is claimed is: 1. A method for formulating patient treatment prescription instructions for radiation therapy, which patient treatment prescription instructions are configured for use to determine corresponding radiation treatment plan optimization objectives for creation of an optimized radiation treatment plan for a particular patient using a particular radiation treatment platform, wherein the patient treatment prescription instructions do not accommodate technical details and specifications of the particular radiation treatment platform, the method comprising: providing a user interface; presenting on the user interface a plurality of radiation-treatment prescription instructions that prescribe a particular radiation dosage for particular parts of the particular patient, wherein each of the radiation-treatment prescription instructions has an initial-state relative priority as compared to others of the plurality of radiation-treatment prescription instructions; determining a pre-optimization first fluence-based radiation dose distribution for the particular patient as a function of the plurality of radiation-treatment prescription instructions and the initial-state relative priority for each of the plurality of radiation-treatment prescription instructions and presenting pre-optimization information regarding the pre-optimization first fluence-based radiation dose distribution for the particular patient; automatically saving, as a corresponding first state, pre-optimization information regarding relative priorities amongst the plurality of radiation-treatment prescription instructions and the corresponding pre-optimization first fluence-based radiation dose distribution for the particular patient; in response to a user changing, via the user interface, a relative priority for at least one of the plurality of radiation-treatment prescription instructions to thereby provide a changed relative priority amongst the plurality of radiation-treatment prescription instructions, dynamically determining a pre-optimization second fluence-based radiation dose distribution for the particular patient as a function of the plurality of radiation-treatment prescription instructions and the changed relative priority amongst the plurality of radiation-treatment prescription instructions and presenting pre-optimization information regarding the pre-optimization second fluence-based radiation dose distribution for the particular patient; automatically saving, as a corresponding second state, pre-optimization information regarding the changed relative priority amongst the plurality of radiation-treatment prescription instructions and the corresponding pre-optimization second fluence-based radiation dose distribution for the particular patient; displaying, on the user interface, visual information regarding changes to fluence-based dose distribution information that occur in response to changes to relative prioritization amongst the plurality of radiation-treatment prescription instructions to thereby illustrate, prior to optimizing a corresponding radiation treatment plan, dosing tradeoffs that correspond to prioritization amongst the radiation-treatment prescription instructions. 2. The method of claim 1 wherein presenting on the user interface the plurality of radiation-treatment prescription instructions comprises presenting the radiation-treatment prescription instructions in an order of presentation, wherein a relative position of a particular one of the radiation-treatment prescription instructions establishes the relative priority for that particular one of the radiation-treatment prescription instructions. 3. The method of claim 2 further comprising: detecting the user selectively changing, via the user interface, a relative priority for at least one of the plurality of radiation-treatment prescription instructions. 4. The method of claim 3 wherein the detecting the user selectively changing a relative priority for at least one of the plurality of radiation-treatment prescription instructions comprises detecting the user selecting and moving, on the user interface, a relative position of at least one of the radiation-treatment prescription instructions. 5. The method of claim 4 wherein the selecting and moving comprises clicking-and-dragging one of the plurality of radiation-treatment prescription instructions. 6. The method of claim 1 further comprising: switching back and forth between a display of information corresponding to the first state and the second state on the user interface. 7. The method of claim 1 further comprising: canceling, via the user interface, all changes to the relative priority for any of the radiation-treatment prescription instructions and, in response thereto, presenting the plurality of radiation-treatment prescription instructions using the initial-state relative priority along with the information regarding the first fluence-based radiation dose distribution for the particular patient. 8. The method of claim 1 wherein automatically saving, as a corresponding state, pre-optimization information regarding the corresponding fluence-based radiation dose distribution for the particular patient comprises storing fluence information but not corresponding calculated dose distribution results. 9. The method of claim 1 wherein at least one of the plurality of radiation-treatment prescription instructions clinical goals constitutes a goal for a treatment volume and at least one of the plurality of radiation-treatment prescription instructions constitutes a goal for an organ-at-risk. 10. The method of claim 1 further comprising: protecting, via the user interface, an achieved fluence-based radiation dose distribution that corresponds to one of the plurality of radiation-treatment prescription instructions notwithstanding subsequent changes to the relative priority for at least one of the plurality of radiation-treatment prescription instructions. 11. A method for formulating patient treatment prescription instructions for radiation therapy, which patient treatment prescription instructions are configured for use to determine corresponding radiation treatment plan optimization objectives for creation of an optimized radiation treatment plan for a particular patient using a particular radiation treatment platform, using automatically-iterated radiation treatment plan optimization, wherein the patient treatment prescription instructions do not accommodate technical details and specifications of the particular radiation treatment platform, the method comprising: providing a user interface; presenting on the user interface a plurality of radiation-treatment prescription instructions that prescribe a particular radiation dosage for particular parts of the particular patient, wherein each of the radiation-treatment prescription instructions has an initial-state relative priority as compared to others of the plurality of radiation-treatment prescription instructions; obtaining a first set of rules that define a pre-optimization fluence-based radiation dose distribution as a function of the plurality of radiation-treatment prescription instructions and the relative priority for each of the plurality of radiation-treatment prescription instructions; obtaining a second set of rules that specify automatically saving, as corresponding states, pre-optimization information regarding relative priorities amongst the plurality of radiation-treatment prescription instructions and corresponding fluence-based radiation dose distributions as a function of detecting changes to the relative priority of any of the plurality of radiation-treatment prescription instructions; generating a pre-optimiz