WO2021259977A1 - Corrélation d'informations de dose et de débit de dose à un volume pour une planification de radiothérapie - Google Patents

Corrélation d'informations de dose et de débit de dose à un volume pour une planification de radiothérapie Download PDF

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Publication number
WO2021259977A1
WO2021259977A1 PCT/EP2021/067101 EP2021067101W WO2021259977A1 WO 2021259977 A1 WO2021259977 A1 WO 2021259977A1 EP 2021067101 W EP2021067101 W EP 2021067101W WO 2021259977 A1 WO2021259977 A1 WO 2021259977A1
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WIPO (PCT)
Prior art keywords
dose
volume
sub
visualization
gui
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PCT/EP2021/067101
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English (en)
Inventor
Pierre LANSONNEUR
Perttu Niemela
Viljo Petaja
Simon Busold
Michiko ROSSI
Matti Sakari ROPO
Michael Folkerts
Jessica Perez
Christel Smith
Adam HARRINGTON
Eric Abel
Lauri Halko
Original Assignee
Varian Medical Systems International Ag
Varian Medical Systems Particle Therapy Gmbh & Co. Kg
Varian Medical Systems, Inc.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
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Priority claimed from US17/323,942 external-priority patent/US11992703B2/en
Application filed by Varian Medical Systems International Ag, Varian Medical Systems Particle Therapy Gmbh & Co. Kg, Varian Medical Systems, Inc. filed Critical Varian Medical Systems International Ag
Priority to CN202180044851.4A priority Critical patent/CN116209499A/zh
Priority to EP21739027.7A priority patent/EP4168113A1/fr
Publication of WO2021259977A1 publication Critical patent/WO2021259977A1/fr

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Classifications

    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61NELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
    • A61N5/00Radiation therapy
    • A61N5/10X-ray therapy; Gamma-ray therapy; Particle-irradiation therapy
    • A61N5/103Treatment planning systems
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61NELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
    • A61N5/00Radiation therapy
    • A61N5/10X-ray therapy; Gamma-ray therapy; Particle-irradiation therapy
    • A61N5/103Treatment planning systems
    • A61N5/1038Treatment planning systems taking into account previously administered plans applied to the same patient, i.e. adaptive radiotherapy
    • GPHYSICS
    • G16INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
    • G16HHEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
    • G16H10/00ICT specially adapted for the handling or processing of patient-related medical or healthcare data
    • G16H10/60ICT specially adapted for the handling or processing of patient-related medical or healthcare data for patient-specific data, e.g. for electronic patient records
    • GPHYSICS
    • G16INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
    • G16HHEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
    • G16H20/00ICT specially adapted for therapies or health-improving plans, e.g. for handling prescriptions, for steering therapy or for monitoring patient compliance
    • G16H20/40ICT specially adapted for therapies or health-improving plans, e.g. for handling prescriptions, for steering therapy or for monitoring patient compliance relating to mechanical, radiation or invasive therapies, e.g. surgery, laser therapy, dialysis or acupuncture
    • GPHYSICS
    • G16INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
    • G16HHEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
    • G16H40/00ICT specially adapted for the management or administration of healthcare resources or facilities; ICT specially adapted for the management or operation of medical equipment or devices
    • G16H40/60ICT specially adapted for the management or administration of healthcare resources or facilities; ICT specially adapted for the management or operation of medical equipment or devices for the operation of medical equipment or devices
    • G16H40/63ICT specially adapted for the management or administration of healthcare resources or facilities; ICT specially adapted for the management or operation of medical equipment or devices for the operation of medical equipment or devices for local operation
    • GPHYSICS
    • G16INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
    • G16HHEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
    • G16H50/00ICT specially adapted for medical diagnosis, medical simulation or medical data mining; ICT specially adapted for detecting, monitoring or modelling epidemics or pandemics
    • G16H50/50ICT specially adapted for medical diagnosis, medical simulation or medical data mining; ICT specially adapted for detecting, monitoring or modelling epidemics or pandemics for simulation or modelling of medical disorders
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61NELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
    • A61N5/00Radiation therapy
    • A61N5/10X-ray therapy; Gamma-ray therapy; Particle-irradiation therapy
    • A61N5/103Treatment planning systems
    • A61N2005/1041Treatment planning systems using a library of previously administered radiation treatment applied to other patients
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61NELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
    • A61N5/00Radiation therapy
    • A61N5/10X-ray therapy; Gamma-ray therapy; Particle-irradiation therapy
    • A61N5/1048Monitoring, verifying, controlling systems and methods
    • A61N2005/1074Details of the control system, e.g. user interfaces
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61NELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
    • A61N5/00Radiation therapy
    • A61N5/10X-ray therapy; Gamma-ray therapy; Particle-irradiation therapy
    • A61N2005/1085X-ray therapy; Gamma-ray therapy; Particle-irradiation therapy characterised by the type of particles applied to the patient
    • A61N2005/1087Ions; Protons

Definitions

  • radiation therapy involves directing a beam of high energy proton, photon, ion, or electron radiation (“therapeutic radiation”) into a target or volume in a treatment target (e.g., a volume that includes a tumor or lesion).
  • a treatment target e.g., a volume that includes a tumor or lesion.
  • the plan defines various aspects of the therapy using simulations and optimizations that may be based on past experiences.
  • the purpose of the treatment plan is to deliver sufficient radiation to the unhealthy tissue while minimizing exposure of surrounding healthy tissue to the radiation.
  • the planner’s goal is to find a solution that is optimal with respect to multiple clinical goals that may be contradictory in the sense that an improvement toward one goal may have a detrimental effect on reaching another goal. For example, a treatment plan that spares the liver from receiving a dose of radiation may result in the stomach receiving too much radiation.
  • FLASH RT FLASH radiation therapy
  • FLASH RT introduces important interdependencies that are not captured by conventional radiation treatment planning.
  • Current tools such as dose-volume histograms and dose-rate volume histograms do not capture the interdependence of dose and dose rate.
  • developing a dose rate distribution for a high-quality plan is not trivial from a clinician’s perspective because normal tissue might benefit from a low dose rate in certain regions if the dose is minimized in these regions.
  • irradiating a restricted number of spots in a treatment volume may lead to high dose rate delivery but low dose homogeneity at the level of the tumor, while on the other hand, plan quality could be improved by increasing the number of spots at the cost of lowering the dose rate.
  • the present invention provides a computer system as defined in claim 1 .
  • the present invention provides a non-transitory computer-readable storage medium having computer-executable instructions for causing a computer system to perform a method used for planning radiation treatment, as defined in claim 12.
  • the present invention provides a non- transitory computer-readable storage medium having computer-executable instructions for causing a computer system to perform a method used for planning radiation treatment, as defined in claim 17.
  • Optional features are specified in the dependent claims.
  • Some embodiments according to the present invention thus provide an improved method of generating and evaluating radiation treatment plans, and improved radiation treatment based on those plans, for FLASH radiation therapy (FLASH RT).
  • a computer-implemented method for planning radiation treatment includes accessing information that includes calculated doses and calculated dose rates for sub-volumes in a treatment target (e.g., any number of voxels in any three-dimensional shape, constituting a volume of sub-volumes), and also accessing information that includes values of a measure (e.g., a number, percentage, or fraction) of the sub-volumes as a function of the calculated doses and the calculated dose rates.
  • a graphical user interface that includes a rendering (e.g., a visual display) that is based on the calculated doses, the calculated doses rates, and the values of the measure is then displayed.
  • the rendering includes a visualization (e.g., a graphic element) of a dose-volume histogram as a first dimension (e.g., an element or aspect of the visualization, or a spatial dimension in virtual space) of the GUI, a visualization of a dose rate-volume histogram as a second dimension of the GUI, and a visualization of the values of the measure as a third dimension of the GUI.
  • the rendering can include a visualization of the calculated dose rate per sub- volume, a visualization of a calculated dose per sub-volume, and a visualization of the measure per sub-volume.
  • the rendering also includes a visualization of a prescription dose and a prescription dose rate.
  • the rendering also includes a visualization of normal tissue complication probability per sub-volume. In some embodiments, the rendering also includes a visualization of tumor control probability per sub-volume. In some embodiments, different attribute values (e.g., color, pattern, gray-scale, alphanumeric text, or brightness) are associated with elements of the visualizations.
  • IMRT intensity modulated radiation therapy
  • IMPT intensity modulated particle therapy
  • beam intensity is varied across each treatment region (volume in a treatment target) in a patient.
  • degrees of freedom available for intensity modulation include beam shaping (collimation), beam weighting (spot scanning), and angle of incidence (which may be referred to as beam geometry).
  • Some embodiments according to the invention improve radiation treatment planning and the treatment itself by expanding FLASH RT to a wider variety of treatment platforms and target sites (e.g., tumors).
  • Treatment plans generated as described herein are superior for sparing healthy tissue from radiation in comparison to conventional techniques for FLASH dose rates by optimizing the balance between the dose rate delivered to unhealthy tissue (e.g., a tumor) in a volume in a treatment target and the dose rate delivered to surrounding healthy tissue.
  • unhealthy tissue e.g., a tumor
  • management of patient motion is simplified because the doses are applied in a short period of time (e.g., less than a second).
  • Treatment planning while still a complex task, is improved relative to conventional treatment planning.
  • a GUI facilitates treatment planning by allowing a planner to readily visualize key elements of a proposed treatment plan, to readily visualize the effects on those elements of changes to the proposed plan and compare different plans, and to define and establish optimization objectives.
  • some embodiments according to this disclosure pertain to generating and implementing a treatment plan that is the most effective (relative to other plans) and with the least (or most acceptable) side effects (e.g., a lower dose rate outside of the region being treated).
  • some embodiments according to the invention improve the field of radiation treatment planning specifically and the field of radiation therapy in general.
  • Some embodiments according to the invention allow more effective treatment plans to be generated quickly.
  • some embodiments according to the invention help improve the functioning of computers because, for example, by reducing the complexity of generating treatment plans, fewer computational resources are needed and consumed, meaning also that computer resources are freed up to perform other tasks.
  • embodiments according to the invention can be used in spatially fractionated radiation therapy including high-dose spatially fractionated grid radiation therapy, minibeam radiation therapy, and microbeam radiation therapy.
  • Figure 1 is a block diagram of an example of a computer system upon which the embodiments described herein may be implemented.
  • Figure 2 is a block diagram illustrating an example of an automated radiation therapy treatment planning system in embodiments according to the present invention.
  • Figure 3 illustrates a knowledge-based planning system in embodiments according to the present invention.
  • Figure 4 is a block diagram showing selected components of a radiation therapy system upon which embodiments according to the present invention can be implemented.
  • Figures 5A and 5B illustrate examples of dose rate-volume histograms in an embodiment according to the present invention.
  • Figure 5C illustrates sub-volumes in a volume in a treatment target in an embodiment according to the present invention.
  • Figure 5D illustrates an example of an irradiation time-volume histogram in an embodiment according to the present invention.
  • Figure 6 is a flowchart of an example of computer-implemented operations for radiation treatment planning in embodiments according to the present invention.
  • Figure 7 illustrates an example of dose rate isolines in embodiments according to the present invention.
  • Figures 8, 9, and 10 are flowcharts of an example of computer- implemented operations for planning radiation treatment in embodiments according to the present invention.
  • Figures 11 , 12, 13A, 13B, 14-28, 29A, 29B, 30A, 30B, and 31-35 are examples of graphical user interfaces on a display device and used for planning radiation treatment in embodiments according to the present invention.
  • dose a dose has a value and can have different values.
  • dose may refer to a value of a dose, for example, unless otherwise noted or apparent from the discussion.
  • Embodiments described herein may be discussed in the general context of computer-executable instructions residing on some form of computer-readable storage medium, such as program modules, executed by one or more computers or other devices.
  • computer-readable storage media may comprise non-transitory computer storage media and communication media.
  • program modules include routines, programs, objects, components, data structures, etc., that perform particular tasks or implement particular abstract data types.
  • the functionality of the program modules may be combined or distributed as desired in various embodiments.
  • Computer storage media includes volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer-readable instructions, data structures, program modules or other data.
  • Computer storage media includes, but is not limited to, random access memory (RAM), read only memory (ROM), electrically erasable programmable ROM (EEPROM), flash memory or other memory technology, compact disk ROM (CD-ROM), digital versatile disks (DVDs) or other optical storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices, or any other medium that can be used to store the desired information and that can accessed to retrieve that information.
  • Communication media can embody computer-executable instructions, data structures, and program modules, and includes any information delivery media.
  • communication media includes wired media such as a wired network or direct-wired connection, and wireless media such as acoustic, radio frequency (RF), infrared and other wireless media. Combinations of any of the above can also be included within the scope of computer-readable media.
  • wired media such as a wired network or direct-wired connection
  • wireless media such as acoustic, radio frequency (RF), infrared and other wireless media. Combinations of any of the above can also be included within the scope of computer-readable media.
  • RF radio frequency
  • Figure 1 shows a block diagram of an example of a computer system 100 upon which the embodiments described herein may be implemented.
  • the system 100 includes at least one processing unit 102 and memory 104. This most basic configuration is illustrated in Figure 1 by dashed line 106.
  • the system 100 may also have additional features and/or functionality.
  • the system 100 may also include additional storage (removable and/or non-removable) including, but not limited to, magnetic or optical disks or tape. Such additional storage is illustrated in Figure 1 by removable storage 108 and non-removable storage 120.
  • the system 100 may also contain communications connection(s) 122 that allow the device to communicate with other devices, e.g., in a networked environment using logical connections to one or more remote computers.
  • the system 100 also includes input device(s) 124 such as keyboard, mouse, pen, voice input device, touch input device, etc.
  • Output device(s) 126 such as a display device, speakers, printer, etc., are also included.
  • a display device may be, for example, a cathode ray tube display, a light-emitting diode display, or a liquid crystal display.
  • the memory 104 includes computer-readable instructions, data structures, program modules, and the like associated with an “optimizer” model 150.
  • the optimizer model 150 may instead reside in any one of the computer storage media used by the system 100, or may be distributed over some combination of the computer storage media, or may be distributed over some combination of networked computers. The functionality of the optimizer model 150 is described below.
  • Figure 2 is a block diagram illustrating an example of an automated radiation therapy treatment planning system 200 in embodiments according to the present invention.
  • the system 200 includes an input interface 210 to receive patient- specific information (data) 201 , a data processing component 220 that implements the optimizer model 150, and an output interface 230.
  • the system 200 in whole or in part may be implemented as a software program, hardware logic, or a combination thereof on/using the computer system 100 ( Figure 1).
  • FIG. 3 illustrates a knowledge-based planning system 300 in embodiments according to the present invention.
  • the system 300 includes a knowledge base 302 and a treatment planning tool set 310.
  • the knowledge base 302 includes patient records 304 (e.g., radiation treatment plans), treatment types 306, and statistical models 308.
  • the treatment planning tool set 310 in the example of Figure 3 includes a current patient record 312, a treatment type 314, a medical image processing module 316, the optimizer model (module) 150, a dose distribution module 320, and a final radiation treatment plan 322.
  • the treatment planning tool set 310 searches through the knowledge base 302 (through the patient records 304) for prior patient records that are similar to the current patient record 312.
  • the statistical models 308 can be used to compare the predicted results for the current patient record 312 to a statistical patient.
  • a selected treatment type 306, and selected statistical models 308, the tool set 310 uses the current patient record 312, a selected treatment type 306, and selected statistical models 308, the tool set 310 generates a radiation treatment plan 322.
  • a treatment type that is used most often.
  • a first-step treatment type 314 can be chosen.
  • Patient outcomes which can include normal tissue complication probability as a function of dose rate and patient-specific treatment-type outcomes (e.g., local recurrent failure, and overall survival as a function of a dose and/or dose rate can be included in the treatment planning process.
  • the medical image processing module 316 provides automatic contouring and automatic segmentation of two-dimensional cross- sectional slides (e.g., from any imaging modality such as, but not limited to, computed tomography (CT), positron emission tomography-CT, magnetic resonance imaging, and ultrasound) to form a three-dimensional (3D) image using the medical images in the current patient record 312.
  • CT computed tomography
  • positron emission tomography-CT magnetic resonance imaging
  • ultrasound ultrasound
  • Dose distribution maps and dose rate distribution maps are calculated by the dose and dose rate distribution module 320, which may utilize the optimizer model 150.
  • the optimizer model 150 uses a dose prediction model to provide, for example, a 3D dose distribution, fluences, and dose rates, and associated dose-volume histograms (DVHs) and dose rate-volume histograms (DRVHs).
  • a dose prediction model to provide, for example, a 3D dose distribution, fluences, and dose rates, and associated dose-volume histograms (DVHs) and dose rate-volume histograms (DRVHs).
  • Figure 4 is a block diagram showing selected components of a radiation therapy system 400 upon which embodiments according to the present invention can be implemented.
  • the system 400 includes a beam system 404 and a nozzle 406.
  • the beam system 404 generates and transports a beam 401.
  • the beam 401 can be a proton beam, electron beam, photon beam, ion beam, or atom nuclei beam (e.g., carbon, helium, and lithium).
  • the beam system 404 includes components that direct (e.g., bend, steer, or guide) the beam system in a direction toward and into a nozzle 406.
  • the radiation therapy system may include one or more multileaf collimators (MLCs); each MLC leaf can be independently moved back-and-forth by the control system 410 to dynamically shape an aperture through which the beam can pass, to block or not block portions of the beam and thereby control beam shape and exposure time.
  • the beam system 404 may also include components that are used to adjust (e.g., reduce) the beam energy entering the nozzle 406.
  • the nozzle 406 is used to aim the beam toward various locations (a volume in a treatment target) (e.g., a volume in a patient) supported on the patient support device 408 (e.g., a chair or table) in a treatment room.
  • a volume in a treatment target may be an organ, a portion of an organ (e.g., a volume or region within the organ), a tumor, diseased tissue, or a patient outline.
  • a volume in a treatment target may include both unhealthy tissue (e.g., a tumor) and healthy tissue.
  • a volume in a treatment target may be divided (virtually) into a number of voxels.
  • a sub-volume can include a single voxel or multiple voxels.
  • the nozzle 406 may be mounted on or a part of a gantry that can be moved relative to the patient support device 408, which may also be moveable.
  • the beam system 404 is also mounted on or is a part of the gantry.
  • the beam system is separate from (but in communication with) the gantry.
  • the control system 410 of Figure 4 receives and implements a prescribed radiation treatment plan.
  • the control system 410 includes a computer system having a processor, memory, an input device (e.g., a keyboard), and perhaps a display in well-known fashion.
  • the control system 410 can receive data regarding operation of the system 400.
  • the control system 410 can control parameters of the beam system 404, nozzle 406, and patient support device 408, including parameters such as the energy, intensity, direction, size, and/or shape of the beam, according to data it receives and according to the prescribed radiation treatment plan.
  • the beam 401 entering the nozzle 406 has a specified energy.
  • the nozzle 406 includes one or more components that affect (e.g., decrease, modulate) the energy of the beam.
  • beam energy adjuster is used herein as a general term for a component or components that affect the energy of the beam, in order to control the range of the beam (e.g., the extent that the beam penetrates into a target), to control the dose delivered by the beam, and/or to control the depth-dose curve of the beam, depending on the type of beam.
  • the beam energy adjuster can control the location of the Bragg peak in the volume in a treatment target.
  • the beam energy adjuster 407 includes a range modulator, a range shifter, or both a range modulator and a range shifter.
  • IMRT intensity modulated radiation therapy
  • IMPT intensity modulated particle therapy
  • beam intensity is varied across each treatment region (volume in a treatment target) in a patient.
  • degrees of freedom available for intensity modulation include beam shaping (collimation), beam weighting (spot scanning), and angle of incidence (which may be referred to as beam geometry).
  • the beam 401 can have virtually any regular or irregular cross-sectional (e.g., beam’s eye view) shape.
  • the shape of the beam 401 can be defined using an MLC that blocks a portion or portions of the beam. Different beams can have different shapes.
  • the beam 401 includes a number of beam segments or beamlets (that also may be referred to as spots).
  • a maximum energy e.g. 80 MeV
  • an energy level is defined for each of the beam segments as a percentage or fraction of the maximum energy.
  • each of the beam segments is weighted in terms of its energy level; some beam segments are weighted to have a higher energy level than other beam segments.
  • the defined energy level or intensity can be realized for each beam segment using the beam energy adjuster 407.
  • Each beam segment can deliver a relatively high dose rate (a relatively high dose in a relatively short period of time).
  • each beam segment can deliver at least 40 grays (Gy) in less than one second, and may deliver as much as 120 Gy per second or more.
  • the beam segments are delivered sequentially. For example, a first beam segment is delivered to the volume in a treatment target (turned on) and then turned off, then a second beam segment is turned on then off, and so on. Each beam segment may be turned on for only a fraction of a second (e.g., on the order of milliseconds).
  • a single beam may be used and applied from different directions and in the same plane or in different planes.
  • multiple beams may be used, in the same plane or in different planes.
  • the directions and/or numbers of beam can be varied over a number of treatment sessions (that is, fractionated in time) so that a uniform dose is delivered across the volume in the treatment target.
  • the number of beams delivered at any one time depends on the number of gantries or nozzles in the radiation treatment system (e.g., the radiation treatment system 400 of Figure 4) and on the treatment plan.
  • a DRVH (which is different from a DVH) is generated for a volume in a treatment target.
  • the DRVH can be generated based on a proposed radiation treatment plan.
  • the DRVH can be stored in computer system memory and used to generate a final radiation treatment plan that will be used to treat a patient. Values of parameters that can have an effect on dose rate can be adjusted until the DRVH satisfies objectives of or associated with treatment of the patient.
  • Figure 5A illustrates an example of a DRVH 500 in an embodiment according to the present invention.
  • the DRVH plots a cumulative dose rate-to-volume in a treatment target frequency distribution that summarizes the simulated dose rate distribution within a volume in a treatment target of interest that would result from a proposed radiation treatment plan.
  • the simulated dose rate distribution can be determined using the optimizer model 150 of Figure 1.
  • the DRVH indicates dose rates and percentages of the volume in a treatment target that receive the dose rates.
  • 100 percent of the volume in a treatment target receives a dose rate of X or more (at least X), 50 percent of the volume in a treatment target receives a dose rate of Y or more (at least Y), and so on.
  • the DRVH 500 can be displayed as or as part of a graphical user interface (GUI) (see the discussion below).
  • GUI graphical user interface
  • the volume in a treatment target may include different organs, for example, or it may include both healthy tissue and unhealthy tissue (e.g., a tumor).
  • the DRVH 510 includes multiple curves 512 and 514, showing the simulated dose rate distribution for a first sub-volume 522 of the volume 504 in a treatment target (e.g., for one organ, or for the healthy tissue) and the simulated dose rate distribution for a second sub-volume 524 (e.g., for a second organ, or for the unhealthy tissue), respectively. More than two simulated dose rate distributions can be included in a DRVH.
  • the DRVH 510 can be displayed as or as part of a GUI.
  • an irradiation time-volume histogram (which is different from, but may be used with, a DVH and/or a DRVH) is generated for the volume in a treatment target.
  • the irradiation time-volume histogram can be stored in computer system memory and used to generate a radiation treatment plan, in combination with or in lieu of a DVH and/or a DRVH.
  • Figure 5D illustrates an example of an irradiation time-volume histogram 550 in an embodiment according to the present invention.
  • the irradiation time-volume histogram plots a cumulative irradiation time-to-volume in a treatment target frequency distribution that summarizes the simulated irradiation time distribution within a volume in a treatment target that would result from a proposed radiation treatment plan.
  • the simulated irradiation time distribution can be determined using the optimizer model 150 of Figure 1.
  • the irradiation time-volume histogram indicates irradiation times (lengths of times) and percentages of the volume that are irradiated for those lengths of time.
  • the DRVH 550 can be displayed as or as part of a GUI.
  • Figure 6 is a flowchart 600 of an example of computer-implemented operations for radiation treatment planning including generating a DVH, a DRVH, or an irradiation time-volume histogram in some embodiments according to the present invention.
  • the flowchart 600 can be implemented as computer-executable instructions (e.g., the optimizer model 150 of Figure 1) residing on some form of computer-readable storage medium (e.g., in memory of the computer system 100 of Figure 1).
  • a proposed radiation treatment plan is defined (e.g., using the optimizer model 150 of Figures 1 and 2), stored in a computer system memory, and accessed from that memory.
  • the proposed radiation treatment plan includes values of parameters that can affect dose and dose rate, as well as other parameters.
  • the parameters that can affect dose and dose rate include, but are not limited to, a number of irradiations of the volume in a treatment target, a duration of each of the irradiations (irradiation times), and a dose deposited in each of the irradiations.
  • the parameters may also include directions of beams to be directed into the volume in a treatment target, and beam energies for each of the beams.
  • the parameters may also include a period of time during which the irradiations are applied (e.g., a number of irradiations are applied over a period of time such as an hour, with each irradiation in the period of time separated from the next by another period of time) and an interval of time between each period of irradiations (e.g., each hour-long period is separated from the next by a day).
  • a period of time during which the irradiations are applied e.g., a number of irradiations are applied over a period of time such as an hour, with each irradiation in the period of time separated from the next by another period of time
  • an interval of time between each period of irradiations e.g., each hour-long period is separated from the next by a day.
  • Appropriate dose threshold curve(s) can be utilized in the optimization model 150 ( Figure 3) to establish dose limits for radiation treatment planning.
  • the appropriate (e.g., tissue-dependent) dose threshold curve can be used to determine beam directions (gantry angles) and beam segment weights. That is, parameters that affect dose can be adjusted during radiation treatment planning so that the limits in the dose threshold curve are satisfied.
  • the dose threshold curves can be tissue- dependent. For instance, the dose threshold curve for the lungs may be different from that for the brain.
  • Dose limits can include, but are not limited to: a maximum limit on irradiation time for each sub-volume (voxel) in the target (e.g., for each voxel of target tissue, treatment time less than x1 seconds); a maximum limit on irradiation time for each sub-volume (voxel) outside the target (e.g., for each voxel of normal tissue, treatment time less than x2 seconds; x1 and x2 may be the same or different); a minimum limit on dose rate for each sub-volume (voxel) in the target (e.g., for each voxel of target tissue, dose rate greater than y1 Gy/sec); and/or a minimum limit on dose rate for each sub-volume (voxel) outside the target (e.g., f or each voxel of normal tissue, dose rate greater than y2 Gy/sec; y1 and y2 may be the same or different).
  • the limits e.g
  • a DVH and a DRVH are generated based on the values of the parameters in the proposed radiation treatment plan.
  • a dose and a dose rate can be determined per sub-volume or voxel.
  • the dose rate is the sum of the dose deposited in each irradiation divided by the sum of the durations of the irradiation.
  • the dose rate can be determined and recorded using a fine time index (e.g., time increments on the order of a millisecond); that is, for example, the dose to each sub-volume or voxel can be recorded for time increments on the order of per- millisecond per beam and per fraction.
  • the dose and dose rate are cumulative.
  • the cumulative dose and dose rate for some portions (e.g., sub-volumes or voxels) of the volume in a treatment target may be higher than other portions, depending on the beam directions and energies, for example.
  • the dose and dose rate per sub-volume or voxel can be calculated to include ray tracing (and Monte Carlo-like simulations), where each beam particle is tracked to determine the primary, secondary, etc., scatters for each particle to get a realistic voxel-based or sub-volume-based dose rate over the course of each irradiation.
  • an irradiation time-volume histogram is generated.
  • An irradiation time-volume histogram can be generated essentially in the same manner as that just described for generating a DRVH.
  • the DVH, the DRVH, and/or the irradiation time-volume histogram can be evaluated by determining whether or not objectives (e.g., clinical goals) that are specified for treatment of a patient are satisfied by the proposed radiation treatment plan.
  • objectives e.g., clinical goals
  • the clinical goals or objectives may be expressed in terms of a set of quality metrics, such as target homogeneity, critical organ sparing, and the like, with respective target values for the metrics.
  • Another way to evaluate the histograms is a knowledge-based approach that incorporates and reflects present best practices gathered from multiple previous, similar treatments of other patients.
  • Yet another way to assist the planner is to use a multi-criteria optimization (MCO) approach for treatment planning.
  • MCO multi-criteria optimization
  • Pareto surface navigation is an MCO technique that facilitates exploration of the tradeoffs between clinical goals. For a given set of clinical goals, a treatment plan is considered to be Pareto optimal if it satisfies the goals and if none of the metrics can be improved without worsening at least one of the other metrics.
  • a DVH and a DRVH are defined a dose threshold value and a dose rate threshold value based on the FLASH RT dose rates, and to also specify threshold values in a treatment target for dose and dose rate.
  • a DVH and a DRVH can be evaluated by determining whether a measure (e.g., fraction, number, or percentage of sub-volumes or voxels) of the volume in a treatment target satisfies the dose and dose rate threshold values.
  • a dose-rate volume histogram may be considered to be satisfactory if 60 percent of the volume in a treatment target (specifically, the portion of the volume in a treatment target that includes the unhealthy tissue) receives a dose rate of at least 50 Gy per second.
  • some or all of the parameter values for the proposed radiation treatment plan can be iteratively adjusted to generate different DVHs, DRVHs, and/or irradiation time-volume histograms, to determine a final set of parameter values that produce a histogram (or histograms) that results in a prescribed (final) radiation treatment plan that best satisfies the objectives (clinical goals) for treatment of the patient or that satisfies the threshold values described above.
  • the final set of parameter values is then included in the prescribed radiation treatment plan used to treat the patient.
  • embodiments according to the invention optimize a radiation treatment plan based on dose, dose rate, and/or irradiation time. This is not to say that treatment plan optimization is based solely on dose, dose rate, and/or irradiation time.
  • FIGS 8, 9, and 10 are flowcharts 800, 900, and 1000 (800-1000) of examples of computer-implemented methods for planning radiation treatment in embodiments according to the present invention.
  • the flowcharts 800-1000 can be implemented as computer-executable instructions (e.g., the optimizer model 150 of Figure 1) residing on some form of computer-readable storage medium (e.g., in memory of the computer system 100 of Figure 1 ).
  • a GUI is generated and displayed.
  • the GUI visualizes, in a single rendering, calculated doses (e.g., total calculated doses) and calculated dose rates for sub-volumes in a treatment target, and values of a measure of the sub-volumes as a function of the calculated doses and the calculated dose rates, for example.
  • calculated doses e.g., total calculated doses
  • calculated dose rates for sub-volumes in a treatment target
  • values of a measure of the sub-volumes as a function of the calculated doses and the calculated dose rates
  • information that includes calculate doses (e.g., total calculated doses) and calculated dose rates for sub-volumes in a treatment target (e.g., any number of voxels in any three-dimensional shape, constituting a volume of sub-volumes), and also information that includes values of a measure (e.g., a number, percentage, or fraction) of the sub-volumes as a function of the calculated doses and the calculated dose rates, are accessed from computer system memory.
  • information that includes values of a measure (e.g., a number, percentage, or fraction) of the sub-volumes as a function of the calculated doses (e.g., total calculated doses) and the calculated dose rates is also accessed from computer system memory.
  • a measure e.g., a number, percentage, or fraction
  • a GUI that includes a rendering (e.g., a visual display) that is based on the calculated doses, the calculated doses rates, and the values of the measure, is displayed on the display device 126 ( Figure 1) of a computer system.
  • a rendering e.g., a visual display
  • a radiation treatment plan is accessed from computer system memory.
  • the radiation treatment plan includes, for example, a number of beams to be directed at and into a volume in a treatment target, directions of the beams, and a range of dose rates for each of the beams.
  • a dose (e.g., total dose) per sub-volume is calculated using the number and directions of the beams and the range of dose rates.
  • a dose rate per sub-volume is calculated using the number and directions of the beams and the range of dose rates.
  • a value of a measure e.g., number, fraction, or percentage of the sub-volumes that are calculated to receive at least a respective level of dose (e.g., total dose) and at least a respective level of dose rate is determined.
  • a GUI that includes a rendering (e.g., a visual display) that is based on the calculated doses, the calculated doses rates, and the values of the measure, is displayed on the display device 126 ( Figure 1).
  • a rendering e.g., a visual display
  • a DVH for a volume in a treatment target is generated.
  • a DRVH for the volume is generated.
  • a GUI that includes a combined rendering of the DVH and the DRVH is displayed on the display device 126 ( Figure 1) of a computer system.
  • the combined rendering visualizes a measure of the volume that is calculated to receive a given dose as a function of dose rate and also a measure of the volume that is calculated to receive a given dose rate as a function of dose.
  • the rendering in the GUI that is generated and displayed as described above includes a visualization (e.g., a graphic element) of a DVH as a first dimension (e.g., an element or aspect of the visualization, or a spatial dimension in virtual space) of the GUI, a visualization of a DRVH as a second dimension of the GUI, and a visualization of the values of the measure as a third dimension of the GUI.
  • the rendering can include a visualization of the calculated dose rate per sub-volume, a visualization of a calculated dose (e.g., calculated total dose) per sub-volume, and a visualization of the measure per sub volume.
  • the rendering also includes a visualization of a prescription dose and a prescription dose rate.
  • the rendering also includes a visualization of normal tissue complication probability (NTCP) per sub-volume.
  • the rendering also includes a visualization of tumor control probability (TCP) per sub-volume.
  • FIGS 11 , 12, 13A, 13B, and 14-28, 29A, 29B, 30A, 30B, and 31 -35 illustrate examples of GUIs that can be used to display information associated with a planning radiation treatment in embodiments according to the present invention.
  • the GUIs can be generated using the methods described above, and implemented using computer-executable instructions (e.g., the optimizer model 150 of Figure 1) residing on some form of computer-readable storage medium (e.g., memory of the computer system 100 of Figure 1), and can be displayed on the output device 126 of the computer system.
  • computer-executable instructions e.g., the optimizer model 150 of Figure 1
  • some form of computer-readable storage medium e.g., memory of the computer system 100 of Figure 1
  • Embodiments according to the present invention are not limited to the GUIs illustrated in Figures 11 , 12, 13A, 13B, and 14-28, 29A, 29B, 30A, 30B, and 31-35.
  • GUIs in embodiments according to the present invention allow the interdependencies between doses, dose rates, doses and dose rates per volume, and measures of volume as a function of dose and as a function of dose rate, to be readily visualized for radiation treatment planning.
  • the doses, dose rates, etc., in the discussion below are calculated values.
  • the disclosed GUIs can include information in addition to that included in the examples.
  • the GUIs can also be used to present information such as the directions of beams to be directed into each sub-volume, and beam energies for each of the beams.
  • drop-down menus or other types of GUI elements can be used to select and establish settings (e.g., attributes, thresholds, etc.) for the GUIs and the type(s) of information to be displayed at any one time.
  • settings e.g., attributes, thresholds, etc.
  • the GUIs are not necessarily static displays.
  • the information presented in the GUIs can be programmed to change over time or in response to user inputs to illustrate accumulated dose or dose rate versus time.
  • the GUIs can be programmed to present different cross-sectional slices of the volume in a treatment target in sequence to provide a depth dimension to a two- dimensional representation, or to manipulate (e.g., rotate) a virtual three-dimensional representation so that it can be viewed from different perspectives.
  • the GUI 1100 includes a two-dimensional rendering of dose rate versus dose.
  • the dose and dose rate per sub-volume e.g., voxel
  • the distribution (measure) of the sub-volumes is projected onto the dose axis to generate a DVH, and is also projected onto the dose rate axis to generate a DRVH.
  • the GUI 1200 includes a two-dimensional rendering of dose rate versus dose for normal tissue and for a tumor.
  • the dose and dose rate per sub-volume e.g., voxel
  • a tissue-specific filter is defined in the plot for the normal tissue
  • a tumor-specific filter is defined in the plot for the tumor tissue.
  • Different filters can be defined to account for different tissue responses to dose and dose rate.
  • Voxels can be color-coded to indicate a relative value of NTCP and TCP.
  • a color key is included in the GUI 1200 and associated with each of the plots as shown. The color of the voxel in a plot can be compared against the key to indicate the relative value of NTCP or TCP.
  • the GUI 1300 includes a visualization of dose and dose rate.
  • the GUI 1300 includes a rendering of a plane at the isocenter of a volume of a treatment target.
  • the total area of the plane is divided into different smaller areas, where the size of each smaller area is indicative of (e.g., proportional to) the volume of the target that receives a certain level of dose (Figure 13A) or dose rate ( Figure 13B).
  • the smaller areas can be color-coded to indicate the level of dose.
  • a color key is included in the GUI 1300 to associate colors in the rendering with the different levels of dose and the different levels of dose rate, respectively.
  • the color of each of the smaller areas can be compared to the colors in the key to determine the level of dose/dose rate for each of the smaller areas.
  • the GUI 1400 includes a rendering of dose along one axis and a measure (percentage) of a volume that receives a given dose along a corresponding axis, and of dose rate along another axis and a percentage of the volume that receives a given dose rate along a corresponding axis.
  • the GUI 1400 is useful for visualizing and identifying qualitative trends.
  • each “X” represents one voxel that has both a dose and a dose rate.
  • Each “X” has a certain transparency such that the density of points in the figure can be visualized.
  • the GUI 1500 includes a two-dimensional rendering of levels (ranges or bins) of dose rate on one axis and levels (ranges or bins) of dose on another axis.
  • a measure (percentage) of the volume that receives a given combination of dose and dose rate is projected into the rendering.
  • approximately nine percent of the volume receives a dose of at least approximately 17.5 Gy at a dose rate of approximately 250 Gy per second.
  • the projection of the volume can be color-coded to indicate the measure of the volume that receives a given dose and dose rate.
  • a color key is included in the GUI 1500 to associate colors in the rendering with the different measures of the volume. The color or colors of the projection of the volume can be compared to the colors in the key to determine the level of dose/dose rate for each of the smaller areas.
  • GUI 1500 allows gross quantitative properties to be readily visualized and identified. For instance, as shown by the circled areas in Figures 16, 17, and 18, a peak of 18 Gy and 260 Gy per second, in-field dose rate gradients, and field edges, respectively, are readily visualized.
  • the GUI 1900 includes a two-dimensional rendering of levels (ranges or bins) of dose rate on one axis and levels (ranges or bins) of dose on another axis.
  • the measure e.g., percentage
  • a color key is included in the GUI 1900 to associate colors in the rendering with the different measures of the volume.
  • horizontal slices represent the DVH of regions of the volume above a given dose rate.
  • the GUI 2000 includes a two-dimensional rendering of levels (ranges or bins) of dose rate on one axis and levels (ranges or bins) of dose on another axis.
  • each line in the rendering represents the measure (e.g., percentage) of the volume at or above a given dose level and dose rate.
  • each line is a different color, and a color key is included in the GUI 2000 to associate the colors of the lines in the rendering with the different measures of the volume. For instance, in the example of Figure 21 , approximately 60 percent of the volume is receiving at least 17.5 Gy at a dose rate of at least 250 Gy per second.
  • the GUI 2000 also includes a region 2010 representing a prescription dose and dose rate.
  • the prescription is for at least 150 Gy per second to 90 percent of the volume receiving more than 10 Gy.
  • the prescription is met because the region 2010 is surrounded by the line corresponding to 90 percent of the volume.
  • the GUI 2300 includes, for a given dose rate (e.g., at least 40 Gy per second), a two-dimensional rendering of levels (ranges or bins) of dose rate on one axis and a measure (fraction) of volume that receives a given dose on another axis.
  • each line in the rendering represents a different sub volume (e.g., a planning target volume (PTV), the right lung, and the spinal cord).
  • PTV planning target volume
  • each line is a different color
  • a color key is included in the GUI 2300 to associate the colors of the lines in the rendering with the associated sub volume.
  • 80 percent of the PTV receives a dose above 60 Gy and a dose rate of 40 Gy per second.
  • the GUI 2400 includes a two-dimensional rendering of levels (ranges or bins) of dose rate on one axis and a measure (percentage) of volume that receives a given dose on another axis.
  • the GUI 2400 represents a plot of the DVH for a region at or above a certain dose rate.
  • each line in the rendering represents a different dose rate.
  • each line is a different color, and a color key is included in the GUI 2400 to associate the colors of the lines in the rendering with the different dose rate.
  • the GUI 2500 includes, for a given dose rate (e.g., 150 Gy per second), a two-dimensional rendering of levels (ranges or bins) of dose rate on one axis and a measure (percentage) of volume that receives a given dose on another axis.
  • the GUI 2500 represents a visualization (plot) of the DVH for a region at or above the given dose rate.
  • the GUI 2500 also includes a region 2502 representing a prescription dose and dose rate.
  • the prescription is for at least 150 Gy per second to 90 percent of the volume receiving more than 10 Gy.
  • the GUI 2600 includes a rendering of a scatter plot of levels (ranges or bins) of dose rate on one axis and levels (ranges or bins) of dose on another axis, showing dose and dose rate distributions for different sub-volumes (e.g., spinal cord, right lung, and PTV).
  • each sub-volume is represented as a different color, and a color key is included in the GUI 2600 to associate the colors in the rendering with the different sub-volumes.
  • the GUIs 2700 and 2800 include a rendering of a volume (e.g., a CT image).
  • a volume e.g., a CT image
  • different colors of contour lines are used to outline portions (e.g., voxels) in the volume that have a dose and dose rate above a certain threshold, below a certain threshold, or within a certain range.
  • a color key is included in the GUIs 2700 and 2800 to associate the colors in the rendering with, for example, level of dose.
  • the dose distribution is shown in the delineated rectangular region only for the sub-volumes (voxels) with a dose rate between 40 and 120 Gy per second.
  • the delineated rectangular region encompasses voxels that have a dose above 10 Gy and a dose rate above 10 Gy per second.
  • the GUI 2900 includes a rendering of cumulative dose versus time.
  • the GUI 2900 is useful for determining a time interval (dt) needed to deliver a given level of dose (e.g., 90 percent).
  • Figure 29B illustrates an example of a GUI 2910 in which more than one dose rate is specified per voxel.
  • the corresponding dose is displayed.
  • the lower line in the figure (which can be displayed using a first color) represents the dose rate as a function of time
  • the upper line in the figure (which can be displayed as a second, different color) represents the cumulative dose as a function of time.
  • the slope of the upper line is the dose rate as a function of time.
  • the GUI 2910 provides a visualization of dose, mean dose rate, and the dose that would be delivered for a dose rate or range of dose rates.
  • the GUI 2910 shows that the dose is 60 Gy, the mean dose rate is about 40 Gy per second, and a dose of about 40 Gy is delivered with a dose rate in the range from 150 to 200 Gy per second.
  • the GUI 3000 includes a rendering of an overlay of isodose contour lines on a dose rate distribution in a volume (e.g., a CT image).
  • a volume e.g., a CT image
  • different colors are used to indicate different dose levels and different dose rates.
  • a color key is included in the GUI 3000 to associate the colors in the rendering with dose level and dose rate. The rendering can be manipulated using the key, by using the pointers shown in the figure to select different levels of dose and different dose rates to be rendered in the GUI 3000.
  • one color can be used to represent a dose in the range of 5-11 Gy, and different shades of that color can be used to represent different ranges of dose rate corresponding to that range of doses (e.g., 151-201 , 201-252, and 252-303 Gy per second).
  • a user can interactively change the positions of the pointers on either or both the vertical and horizontal axes. By changing the positions of those pointers, the respective ranges of dose and dose rate associated with a particular color or shading are also changed, and the isodose contour lines in the GUI 3000 would also be changed accordingly.
  • FIG 30B illustrates an example of a GUI 3010 in which a dose corresponding to a particular range of dose rates is rendered on top of a CT image (e.g., the CT image also shown in Figure 30A).
  • a dose rate range constraint is applied individually for each voxel, and the corresponding fraction of dose is visualized.
  • the dose rate distribution subject to a constraint of the accumulated dose in each voxel can be visualized; for example, a GUI may show, in each voxel, the dose rate at which X percent of the dose at each voxel has been accumulated. A user can select the dose percentage that is used to select the dose rate displayed per voxel.
  • a user can also interactively select and adjust the positions of pointers to associate a color with a dose range.
  • the user can also adjust the positions of pointers to select a dose rate range. Only the dose that would be delivered with the selected dose rate is rendered in the GUI 3010.
  • the example of Figure 30B shows isodose contour lines for doses that would be delivered for a dose rate range of 201-252 Gy per second.
  • the GUI 3100 includes, for a given volume or sub-volume (e.g., structure “S1”), a two-dimensional rendering of levels (ranges or bins) of dose rate on one axis of a plot and a measure (percentage) of volume that receives a given dose on another axis of the plot.
  • the lines in the plot delineate different regions of the visualization. Those lines bound regions representing different DVHs corresponding to different dose rates.
  • each region is represented by a different level of shading, and a key is included in the GUI 3100 to associate the level of shading in the visualization with dose level and dose rate.
  • different pointers are included in the rendering to indicate different goals (e.g., prescription dose and dose rate).
  • the GUI 3200 includes a rendering of regions where beams overlap in three dimensions. The number of times a voxel is traversed by a beam is color-coded.
  • the GUI 3200 includes x and y coordinates in the plane of the volume shown in the visualization, and also includes a z coordinate that indicates the depth of the plane in the volume.
  • a particular target in the volume is outlined in the example of Figure 32. In this example, five beams are shown, and a key is included in the GUI 3200 to associate a color of a voxel to the number of beams that reach that voxel.
  • the GUI 3300 includes a rendering of cumulative dose delivered above a certain dose rate threshold (e.g., above 40 Gy per second).
  • a certain dose rate threshold e.g., above 40 Gy per second.
  • different colors are used to indicate different cumulative doses.
  • a color key is included in the GUI 3300 to associate the colors in the rendering with dose level and dose rate.
  • a particular target in the volume is outlined in the example of Figure 33.
  • the GUI 3400 includes a rendering of cumulative dose delivered below a certain dose rate threshold (e.g., below 40 Gy per second).
  • a certain dose rate threshold e.g., below 40 Gy per second.
  • different colors are used to indicate different cumulative doses.
  • a color key is included in the GUI 3400 to associate the colors in the rendering with dose level and dose rate.
  • a particular target in the volume is outlined in the example of Figure 34.
  • the GUI 3500 includes a rendering of a DVH of dose delivered above a certain dose rate threshold (e.g., above 40 Gy per second).
  • a certain dose rate threshold e.g., above 40 Gy per second
  • dotted lines represent the total DVH
  • solid lines represent the DVH above a certain dose rate threshold (e.g., above 40 Gy per second).
  • the difference between each pair of solid and dotted lines indicate the portion of the organ at risk volume that was not delivered a sufficiently high dose rate.
  • different colors are used to indicate different organs or structures.
  • a color key is included in the GUI 3500 to associate the colors in the rendering with the different organs or structures.
  • some embodiments according to the invention improve radiation treatment planning and the treatment itself by expanding FLASH RT to a wider variety of treatment platforms and target sites.
  • Treatment plans generated as described herein are superior for sparing normal tissue from radiation in comparison to conventional techniques even for non-FLASH dose rates by reducing, if not minimizing, the magnitude (and the integral in some cases) of the dose to normal tissue (outside the target) by design.
  • management of patient motion is simplified because the doses are applied in a short period of time (e.g., less than a second).
  • Treatment planning while still a complex task of finding a balance between competing and related parameters, is simplified relative to conventional planning.
  • the techniques described herein may be useful for stereotactic radiosurgery as well as stereotactic body radiotherapy with single or multiple metastases.
  • a GUI facilitates treatment planning by allowing a planner to readily visualize key elements of a proposed treatment plan (e.g., the dose rate per sub-volume), to readily visualize the effects on those elements of changes to the proposed plan, and to readily visualize a comparison between different plans.
  • key elements of a proposed treatment plan e.g., the dose rate per sub-volume
  • embodiments according to the invention can be used in spatially fractionated radiation therapy including high-dose spatially fractionated grid radiation therapy, minibeam radiation therapy, and microbeam radiation therapy.

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Abstract

Procédé utilisé pour planifier une radiothérapie consistant à accéder (802) à des informations qui comprennent des doses calculées et des débits de dose calculés pour des sous-volumes dans une cible de traitement, et également à accéder (804) à des informations qui comprennent des valeurs d'une mesure des sous-volumes en fonction des doses calculées et des débits de dose calculés. Une interface utilisateur graphique comprend un rendu (806) qui est basé sur les doses calculées, les débits de dose calculés et les valeurs de la mesure.
PCT/EP2021/067101 2020-06-23 2021-06-23 Corrélation d'informations de dose et de débit de dose à un volume pour une planification de radiothérapie WO2021259977A1 (fr)

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