Methods for optimizing treatment time and plan quality for radiotherapy

The invention claimed is: 1 . A graphical user interface for radiotherapy planning, the graphical user interface comprising: a bounded dose volume histogram (bDVH) for a target region comprising a lower bound DVH and an upper bound DVH that represent a range of radiation dose values to the target region over a range of treatment delivery times; a treatment time selector configured to receive user input that specifies a treatment delivery time within the range of treatment times; and a variable dose volume histogram (DVH) for the target region that represents a radiation dose to the target region that corresponds to the specified treatment delivery time, wherein the lower bound DVH corresponds to a lower-limit treatment delivery time value and the upper bound DVH corresponds to an upper-limit treatment delivery time value, wherein the lower-limit treatment delivery time value is a minimum treatment delivery time value, and the upper-limit treatment delivery time value is a maximum treatment delivery time value, and wherein the minimum treatment delivery time value is determined by generating a fluence map comprising a set of beamlet values by iteratively adjusting the beamlet values based on a cost function comprising a treatment time penalty function such that the fluence map delivers a prescribed dose to the target region and changes of a cost function value between iterations of the beamlet values is less than a selected threshold, and calculating an amount of time to deliver the generated fluence map. 2 . A graphical user interface for radiotherapy planning, the graphical user interface comprising: a bounded dose volume histogram (bDVH) for a target region comprising a lower bound DVH and an upper bound DVH that represent a range of radiation dose values to the target region over a range of treatment delivery times; a treatment time selector configured to receive user input that specifies a treatment delivery time within the range of treatment times; and a variable dose volume histogram (DVH) for the target region that represents a radiation dose to the target region that corresponds to the specified treatment delivery time, wherein the lower bound DVH corresponds to a lower-limit treatment delivery time value and the upper bound DVH corresponds to an upper-limit treatment delivery time value, wherein the lower-limit treatment delivery time value is a minimum treatment delivery time value, and the upper-limit treatment delivery time value is a maximum treatment delivery time value, and wherein the maximum treatment delivery time value is determined by generating a fluence map comprising a set of beamlet values by iteratively adjusting the beamlet values based on a cost function comprising an organ-at-risk (OAR) dose penalty function such that the fluence map delivers a prescribed dose to the target region and changes of a mean dose to the OAR between iterations of the beamlet values is less than a selected threshold, and calculating an amount of time to deliver the generated fluence map. 3 . A graphical user interface for radiotherapy planning, the graphical user interface comprising: a bounded dose volume histogram (bDVH) for a target region comprising a lower bound DVH and an upper bound DVH that represent a range of radiation dose values to the target region over a range of treatment delivery times; a treatment time selector configured to receive user input that specifies a treatment delivery time within the range of treatment times; a variable dose volume histogram (DVH) for the target region that represents a radiation dose to the target region that corresponds to the specified treatment delivery time; a treatment time axis; a lower limit indicator on the treatment time axis, wherein the lower-limit indicator is at a minimum treatment time in the range of treatment times; an upper limit indicator on the treatment time axis, wherein the upper-limit indicator is at a maximum treatment time in the range of treatment times; and wherein the treatment time selector is located on the treatment time axis between the lower limit indicator and the upper limit indicator, wherein the treatment time indicator is at an initial treatment time for delivering a prescribed dose to the target region. 4 . The graphical user interface of claim 3 , wherein the initial treatment time is calculated by generating a fluence map comprising a set of radiation beamlet values by iteratively adjusting the beamlet values based on a cost function comprising an OAR penalty function such that the fluence map delivers the prescribed dose to the target region and changes of a cost function value between iterations of the beamlet values is less than a selected threshold; and calculating an amount of time to deliver the generated fluence map. 5 . The graphical user interface of claim 3 , wherein the minimum treatment time is determined by generating a fluence map comprising a set of beamlet values by iteratively adjusting the beamlet values based on a cost function comprising a treatment time penalty function such that the fluence map delivers the prescribed dose to the target region and changes of a cost function value between iterations of the beamlet values is less than a selected threshold, and calculating an amount of time it takes to deliver the generated fluence map. 6 . The graphical user interface of claim 3 , wherein the maximum treatment time is determined by generating a fluence map comprising a set of beamlet values by iteratively adjusting the beamlet values based on a cost function comprising an organ-at-risk (OAR) dose penalty function such that the fluence map delivers a prescribed dose to the target region and changes of a mean dose to the OAR between iterations of the beamlet values is less than a selected threshold, and calculating an amount of time to deliver the generated fluence map. 7 . The graphical user interface of claim 3 , wherein the lower bound DVH corresponds to a lower-limit treatment delivery time value and the upper bound DVH corresponds to an upper-limit treatment delivery time value. 8 . The graphical user interface of claim 7 , wherein the lower-limit treatment delivery time value is a minimum treatment delivery time value, and the upper-limit treatment delivery time value is a maximum treatment delivery time value. 9 . The graphical user interface of claim 3 , wherein the bDVH for the target region further comprises shading between the upper bound DVH curve and the lower bound DVH curve. 10 . The graphical user interface of claim 3 , wherein the variable DVH curve for the target region changes between the upper bound DVH curve and the lower bound DVH curve according to the user input to the treatment time selector. 11 . The graphical user interface of claim 3 , wherein the treatment time selector is a graphical slider that is movable between a first limit that corresponds to a low-threshold treatment delivery time value and a second limit that corresponds to a high-threshold treatment delivery time value, and wherein moving the slider to a position between the first and second limits corresponds to selecting the treatment delivery time. 12 . The graphical user interface of claim 3 , wherein the treatment time selector is a graphical dial that is rotatable between a first limit corresponding to a low-threshold treatment delivery time and a second limit corresponding to a high-threshold treatment delivery time, and wherein setting the dial to a position between the first and second limits corresponds to selecting the treatment delivery time. 13 . The graphical user interface of claim 3 , further c