Patent Application
20180099151
The present disclosure relates generally to controlling radiation treatments, and more particularly systems and methods to controlling the operation of the treatment delivery system.
Conventional radiation therapies of tumors are structured to accomplish two objectives, first removing of the tumor, and second preventing of damage to healthy tissue and organs-at-risk (OAR) near the tumor. Most tumors can be removed completely if an appropriate radiation dose is delivered to the tumor. Unfortunately, delivering certain amounts of doses of radiation to eliminate a tumor can likely result in complications, due to damaging healthy tissue and OAR's surrounding the tumor. One conventional technique to address this problem is a three-dimensional (3D) conformal radiation therapy that uses beams of radiation in treatment shaped to match the tumor to confine the delivered radiation dose to only the tumor volume defined by the outer surfaces of the tumor, while minimizing the dose of radiation to surrounding healthy tissue or adjacent healthy organs.
Typically, to perform these radiation treatment therapy plans, involves defining an exact type, locations, distribution and intensity of radiation sources so as to deliver a desired spatial radiation distribution. Radiation treatment therapy planning begins with a set of Computed Tomography (CT) images of a patient's body in the region of the tumor, i.e. CT images.
During the planning of the radiation treatment therapy the spatial distribution of radiation can be determined, usually by simulation, in terms of the dose of radiation, i.e. number of grays of radiation, that is deposited in each CT data voxels. The quality of planning radiation distribution is evaluated by comparing it to the desired plan goals, i.e. high radiation dose to the tumor and low radiation dose to the OARs. For example, a high quality plan can be one that achieves all of the desired plan goals, while a lower quality plan will fail to achieve some or all of the plan goals, for instance, by having a radiation dose delivered to a portion of an OAR that is in excess of the plan goals.
It is not uncommon to have an inherent conflict between the desire to have high dose in the tumor and low dose in a nearby OAR. However, certain OAR types may be redundant in their function and substantial portions of the OAR volume can be completely removed while retaining their function. Other OAR types lose their function if any of the structure is completely removed. For example, OARs may be an optic nerve or a brain stem, whose damage or destruction by radiation would be highly detrimental to the person undergoing therapy. Therefore, depending upon the radiation sensitivity of the OAR, the more sensitive OAR volumes that receive a measured dose of radiation, essentially depends upon no portion of the OAR being subjected to a lethal dose.
Conventional radiation treatment planning fail during the planning process, in part, because due to the tumor volume and/or the OAR volume are irregularly shaped having irregular spatial configurations with concave/contoured boarders, which result in the radiation beam being successful only part of the time. For example, because of the irregularly tumor shape, the relative arrangement of the tumor within 3D space can have twists or outer surfaces pointing inward, relative to a plane parallel to the path of the radiation beam, such that healthy tissue or OARs can be disposed approximate the concavities formed by the outer tumor concave surfaces. Specifically, given that the OAR anatomic structure is non-uniform, some important parts of OAR may be overdosed. Another problem with the planning process of conventional radiation treatment planning is that the user is not provided an explicit local control of trade-offs, i.e. parts of the OAR that are over exposed.
Some embodiments of present disclosure are based on a realization that when the dose optimization is infeasible there is no need to directly approximate all the constraints for either the tumor or the Organ-At-Risk (OAR), to obtain a dose constraint set. Instead, it is advantageous to efficiently determine the dose constraints that will be in conflict, notably, it is necessary to identify the subset of voxels that are in conflict.
Specifically, when a dose optimization is infeasible it is necessary to adjust one or more constraints in either the tumor or the OAR to obtain a constraint set, which may or may not result in a feasible constraint set. The effect of adjusting constraints is to allow some tumor voxels to receive a dose below the desired minimum dose, or to allow some OAR voxels to receive a dose above the desired maximum dose. These constraints are used as part of a technique in determining dose optimization, that the total dose is minimized subject to a set of constraints on some of the CT voxels. When regarding tumor voxels, it is necessary to constrain the dose to lie within an acceptable range of values, while for OAR voxels, the dose is constrained to lie below a maximum value. In other words, we observed that only some of these constraints will be in conflict, the constraints on tumor voxels far from an OAR can be satisfied with no effect on OAR dose, as can constraints on OAR voxels far from tumor voxels.
Having understood only some of these constraints will be in conflict, we further realized it is necessary to identify and potentially visualize a representation of the subset of voxels in conflict, for assisting in evaluating and controlling the tradeoff between constraints that are in conflict. Because constraints are interdependent, change in one constraint can effect another one. We recognized the dependency among the constraints is a function of distances between the voxels corresponding to those constraints.
Embodiments of present disclosure are based on a realization that a distance between the tumor and OAR can be a single parameter of optimization of the dose of radiation. Specifically, our realization is that constraints within the tumor and OARs can be set using so-called “distance fields” of the tumor and OAR.
For example, a value of a distance field of an object, e.g., a tumor and/or OAR, at a point in space (p) can be a Euclidean distance, or shortest distance, from the point (p) to a boundary of the object. Points that are on the boundary of the object have distance field values of zero. Wherein, the distance field is “signed” such that for point within the boundary of the object the distance field has one sign, for example positive, and outside the boundary the distance field has the opposite sign, for example negative. For each object, i.e. tumor and/or OAR, there is a unique distance field that is determined by the object's shape, in particular, the shape of the object's boundary. In other words, the unique distance field is specific to the shape of the object's boundary, so as to create isocontours (curves of constant distance) for the object, i.e. tumor and/or OAR. Therefore, it is useful to have methods and systems to assign initial constraint values that take into account the non-uniform sensitivity of the tumor to radiation. At least one aspect to using the tumor's distance field, is that it becomes possible to compensate for the biological effects of the tumor's non-uniformity by determining the initial dose constraints for the tumor voxels through a mathematical function of the distance field of the tumor. Essentially, the present disclosure provides for methods and systems to identify and control the constraints specific to the tumor and the OARs, and control a tradeoff between constraints that are in conflict.
Another realization the present disclosure is based upon is that the dose constraints of the tumor voxels and the OARs voxels can be determined as a function of the distance fields both the tumor and the OARs, as well as of the radiation dose to the voxels of the tumor and OARs. The determining of the constraints using the value of the radiation dose is useful when dealing with infeasible dose optimization.
To better understand this realization, imagine transforming an analogy of the tumor being thermally hot into a display form, where the thermally hot tumor and the thermally affected healthy tissue and OARs could be visualized. We would then be able to visually identify the constraints in conflict merely by the varying degrees of the thermally affected areas. However, implementing this realization presented challenges, such that despite overcoming the challenge of how to identify and control the constraints distributed in a 3D space, we still needed to address how to actually visualize and control the set of conflicting constraints on the tumor and OARs in the 3D space.
We discovered that rather than trying to visualize and control the set of conflicting constraints in 3D space, it is much easier to do so in a one-dimensional (1D) space. Then, the 1D space could make it possible to graph the constraint values via the 1D coordinate, so as to identify the set of constraints in conflict and to affect a modification. Using the Euclidean distance, i.e., the shortest distance from a given voxel to the boundary of the tumor or OAR, transforms the 3D space of the constraint values into a 1D space. By making it possible to graph the constraint values via the 1D coordinate system, we are able to visualize the constraint conflict. In other words, we plot the OAR constraints verses distance to a tumor boundary and tumor constraints verses the distance to an OAR boundary on the same graph. After plotting the OAR constraints and the tumor constraints on the same graph, we are able to construct a user interface, i.e. a slider or control point, that causes a shift of the characteristic of the curve along the distance axis and a corresponding localized change to the tumor and OAR constraints.
In particular, we are able to construct systems and methods that are able to make minimal adjustments to the constraints as necessary to obtain a feasible optimization problem, as well as, generate a graphical representation illustrating simultaneously the constraints in conflict. Specifically, we are able to simultaneously illustrate visually, the effects of the specific dose of radiation to the tumor, along with the corresponding damaging effects to the surrounding healthy tissue and OARs for the specific radiation dose. By providing a visual display to the user, the user now has the ability to have explicit local control of constraint trade-offs, i.e., parts of OAR that are overdosed via the slider. For example, the user could be a dosimetrist, doctor or person associated with determining dosing or medical issues for the patient. Wherein the user, via the slider of the present disclosure, will have the ability to visually see each potential radiation dose to the tumor and the corresponding damaging effects to the OARs, and after having reviewed all the possible radiation dosing options, make an informed dosing radiation decision necessary to obtain a feasible constraint set or specific dose of radiation for the patient. Essentially, the present disclosure provides for the user or doctor to not only be able to identify and control the constraints specific to the tumor and the OARs, but just as importantly, also be able to graphically visualize controlling a tradeoff between constraints that are in conflict. In part, the slider in combination with the features of the present disclosure is able to provide the doctor with informed radiation dosing decisions, as well as have provide for an increased accuracy in understanding how the proposed dosing of radiation will have on the tumor and OARs of the patient.
According to an embodiment of the present disclosure, a radiation treatment method for determining a dose of radiation. The method including determining, for a tumor voxel in a set of tumor voxels from stored data, a value of a maximum dose constraint and a minimum dose constraint, for treating the tumor voxel based on a distance function of at least one distance field of the tumor and distance fields of organs at risk (OARs). Wherein each dose constraint on each tumor voxel is a function of a distance from the tumor voxel to a boundary of the tumor, and distances to boundaries of OARs. Determining, for an OAR voxel in a set of OAR voxels in an OAR of interest of the OARs, a value of a maximum dose constraint based on the at least one distance field of the tumor. Wherein each dose constraint on each OAR voxel is a function of a distance from the OAR voxel to the boundary of the tumor. Determining a tumor dose constraint and a corresponding OAR dose constraint to obtain a dose constraint set according to a threshold dose constraint set. Determine the dose of radiation, according to the dose constraint set, wherein the dose of radiation is used for managing the radiation treatment planning system.
According to another embodiment of the present disclosure, a radiation treatment planning system for determining a dose of radiation. The system including at least one processor and at least one non-transitory storage memory having stored data and computer readable instructions executable by the at least one processor. Wherein the execution of the computer readable instructions by the at least one processor is configured to determine, for a tumor voxel in a set of tumor voxels from patient imaging data of the stored data, a value of a maximum dose constraint and a minimum dose constraint, for treating the tumor voxel based on a distance function of at least one distance field of the tumor and distance fields of organs at risk (OARs) in a set of OARs. Wherein each dose constraint on each tumor voxel is a function of a distance from the tumor voxel to a boundary of the tumor, and distances to boundaries of OARs in the set of OARs. Determine, for an OAR voxel in a set of OAR voxels in an OAR of interest from the set of OARs, a value of a maximum dose constraint based on the at least one distance field of the tumor. Wherein each dose constraint on each OAR voxel is a function of a distance from the OAR voxel to the boundary of the tumor. Determining a tumor dose constraint and a corresponding OAR dose constraint to obtain a dose constraint set according to a threshold dose constraint set. Determine the dose of radiation, according to the dose constraint set, wherein the dose of radiation is used for managing the radiation treatment planning system.
The presently disclosed embodiments will be further explained with reference to the attached drawings. The drawings shown are not necessarily to scale, with emphasis instead generally being placed upon illustrating the principles of the presently disclosed embodiments.
While the above-identified drawings set forth presently disclosed embodiments, other embodiments are also contemplated, as noted in the discussion. This disclosure presents illustrative embodiments by way of representation and not limitation. Numerous other modifications and embodiments can be devised by those skilled in the art which fall within the scope and spirit of the principles of the presently disclosed embodiments.
The following description provides exemplary embodiments only, and is not intended to limit the scope, applicability, or configuration of the disclosure. Rather, the following description of the exemplary embodiments will provide those skilled in the art with an enabling description for implementing one or more exemplary embodiments. Contemplated are various changes that may be made in the function and arrangement of elements without departing from the spirit and scope of the subject matter disclosed as set forth in the appended claims.
Specific details are given in the following description to provide a thorough understanding of the embodiments. However, understood by one of ordinary skill in the art can be that the embodiments may be practiced without these specific details. For example, systems, processes, and other elements in the subject matter disclosed may be shown as components in block diagram form in order not to obscure the embodiments in unnecessary detail. In other instances, well-known processes, structures, and techniques may be shown without unnecessary detail in order to avoid obscuring the embodiments. Further, like reference numbers and designations in the various drawings indicated like elements.
Also, individual embodiments may be described as a process which is depicted as a flowchart, a flow diagram, a data flow diagram, a structure diagram, or a block diagram. Although a flowchart may describe the operations as a sequential process, many of the operations can be performed in parallel or concurrently. In addition, the order of the operations may be re-arranged. A process may be terminated when its operations are completed, but may have additional steps not discussed or included in a figure. Furthermore, not all operations in any particularly described process may occur in all embodiments. A process may correspond to a method, a function, a procedure, a subroutine, a subprogram, etc. When a process corresponds to a function, the function's termination can correspond to a return of the function to the calling function or the main function.
Furthermore, embodiments of the subject matter disclosed may be implemented, at least in part, either manually or automatically. Manual or automatic implementations may be executed, or at least assisted, through the use of machines, hardware, software, firmware, middleware, microcode, hardware description languages, or any combination thereof. When implemented in software, firmware, middleware or microcode, the program code or code segments to perform the necessary tasks may be stored in a machine readable medium. A processor(s) may perform the necessary tasks.
According to the definition of terms with regard to the present disclosure, the term “Radiation therapy” is considered the treatment of medical diseases by the application of ionizing radiation, for example ion beams, alpha emitters, x-rays or gamma rays. An example application of radiation therapy is the treatment of cancer using beams of ions, such as protons or carbon ions, such that the cancer cells are killed by the dose of radiation while adjacent healthy tissue is spared.
Further, the term “radiation therapy planning” begins with a set of Computed Tomography (CT) images of the patient's body in the region of the tumor, hereafter referred to CT images. The set of CT images is composed of a plurality of 2D cross-section images of the body oriented in a plane nominally perpendicular to the spine, with each successive image in the set of CT images corresponding to successive adjacent positions along the axis of the body. Each picture element (pixel) in a single CT image corresponds to the amount of x-rays absorbed by the tissue at that 3D spatial location. Radiation therapy planning involves a specification of at least two categories of spatial regions within the patient's CT data: a first category, often called tumor, is where a high and possibly uniform radiation dose is desired, and a second category, often called organ-at-risk (OAR), is where it is desired that the radiation dose be as low as possible. The specification of a type for the CT data voxels can either be a tumor voxel or OAR voxel, that is commonly represented as one of the following: a second 3D array of voxel data, the segmentation voxel data, or co-located with the CT voxel data. Wherein, each voxel of the segmentation voxel data has a label, e.g. an integer, whose value indicates the type of the corresponding voxel in the CT voxel data.
The term “dose of radiation” can be understood that the amount radiation deposited in a voxel of the CT voxel data is called the dose of radiation. Dose is a well-defined physical quantity given in units called Gray, where 1. Gray corresponds to 1 joule of radiation energy deposited in 1 kilogram of tissue.
The term organ-at-risk (OAR) can be understood that each OAR may have a different sensitivity to radiation, or a different level of importance in comparison to other OARs, such that each may have a different maximum permitted dose.
The constraints are used as part of a technique in determining dose optimization, such that the total dose is minimized subject to a set of constraints on some of the CT voxels. When regarding tumor voxels, it is necessary to constrain the dose to lie within an acceptable range of values, while for OAR voxels, the dose is constrained to lie below a maximum value. Specifically, when a dose optimization is infeasible it is necessary to adjust one or more constraints in either the tumor voxel or the OAR voxel to obtain a constraint set that could later be determined as a feasible constraint set. The effect of adjusting constraints is to allow some tumor voxels to receive a dose below the desired minimum dose, or to allow some OAR voxels to receive a dose above the desired maximum dose. The constraints are interdependent, such that change in one constraint can effect another one. Dependency among the constraints is a function of distances between the voxels corresponding to those constraints.
Still referring to Step 110 of
Continuing with step 110 of
Step 115 of
Step 120 of
For example, it is possible for the doctor/user could be a dosimetrist, the dosimetrist selects the threshold dose constraint set based on making a compromise between: (1) sparing the OAR, but under dosing the tumor; (2) adequately irradiating the tumor, but overdosing some or all of an OAR; or (3) some tradeoff between the two. Further, the user selected threshold dose constraint set can also be based on, patient records, statistical models that are used to simplify creating new radiation treatment plans including dose of radiation treatments, as well as prior radiation treatment plans and/or experiences gained from each prior radiation treatment plan.
The user selected threshold dose constraint set may also be based on, one or a combination of: the determined dose constraints, i.e. the maximum and the minimum dose constraints for the tumor voxel and the maximum dose constraint for the OAR voxel; a compromise between an amount of tumor control of a specific tumor dose constraint versus an amount of damage control to an OAR voxel of a specific corresponding OAR dose constraint; stored historical radiation dose treatments for tumor types, tumor voxels and OARS similar to the set of tumor voxels and OARs from the stored data, among other things.
Step 125 of
The radiation treatment system 180 can include a radiation source 182 that emits a directed beam of radiation for treatment to the body 109. Examples of radiation sources may include, an X-ray source, a gamma ray source, an electron beam source, etc. The radiation source 182 may further comprise a multi-leaf collimator (MLC) to shape the beam. By adjusting the position of the leaves of the MLC, a radiotherapist can match the radiation field to a shape of the treatment volume of body. Other beam shaping and/or contouring can be included in some embodiments. The radiation source 182 can have a corresponding source model. The radiation system 180 may be controlled by the radiation treatment planning method 100, for example, to deliver intensity modulated radiation energy and to conform radiation treatment to the shape of the intended radiation treatment volume.
The computer 142 of
Optionally, the computer 142 of
The computer 142 of
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The computer 142A can include a power source 141, depending upon the application the power source 141 may be optionally located outside of the computer 142A. Linked through bus 145 can be a display interface 143 adapted to connect to a display device 147, wherein the display device 147 can include a computer monitor, camera, television, projector, or mobile device, among others. A printer interface 180 can also be connected through bus 145 and adapted to connect to a printing device 182, wherein the printing device 182 can include a liquid inkjet printer, solid ink printer, large-scale commercial printer, thermal printer, UV printer, or dye-sublimation printer, among others. A network interface controller 167 is adapted to connect through the bus 145 to a network 168. Medical data or related data, among other things, can be rendered on a display device, imaging device, and/or printing device.
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Using the tumor's distance field, it becomes possible to compensate for the biological effects of the tumor's non-uniformity by determining the initial dose constraints for the tumor voxels through a mathematical function of the distance field of the tumor. For example, if we denote the tumor distance field as dT(x, y, z) as the value of the tumor distance field at point (x, y, z), then we may choose that the tumor's initial minimum dose constraints are given by a linear mathematical function such as
D
tumor,min(x,y,z)=DT,min+kdT(x,y,z)
where DT, min is the minimum tumor dose at the tumor boundary, for example 50 Gray, and k is a scale parameter that can be either positive or negative depending on whether the tumor dose constraint should increase or decrease, respectively, within the tumor interior.
Alternately, the function can be non-linear. For example, the doctor may want to limit the maximum value that a tumor voxel's constraint can achieve to be ≦Dtumor, minmax to avoid other undesirable consequences of excessively high radiation dose. This can be achieved by using a min( ) function, where min(a, b) returns the lesser of the two input values, a or b. In this case our tumor constraint equation becomes
D
tumor,min(x,y,z)=min(DT,min+kdT(x,y,z),Dtumor,minmax).
This non-linear function will increase linearly as the value of the distance field increases with slope k from a value of DT, min at the boundary of the tumor, but be limited to no more than Dtumor, minmax. There are many other possible non-linear functions, e.g., Gaussian, exponential, logarithm, that are known in the art and may be optionally selected by the doctor for some reason outside the scope of this invention.
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Therefore, an additional feature of the present disclosure is that the dose constraints of the tumor voxels and the OARs voxels can be determined as a function of the distance fields both the tumor and the OARs, as well as of the radiation dose to the voxels of the tumor and OARs. The determining of the constraints using the value of the radiation dose is useful when dealing with infeasible dose optimization.
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Clearly only a subset of the set of tumor voxels and a subset of the set of OAR voxels need to be adjusted. We can select the sets of voxels and adjust their constraints by considering the distance fields of the tumor and the OARs as well as the dose of radiation that is computed using the initial constraints.
Upon an initial review of
Method 300 illustrates the realization of rather than trying to control the set of conflicting constraints in 3D space, that it is much easier to do so in a one-dimensional (1D) space, as noted above. Then, the 1D space could make it possible to graph the constraint values via the 1D coordinate, so as to identify the set of constraints in conflict and to affect a modification.
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Step 335 of
Specifically, we are able to simultaneously illustrate visually, i.e. by shifting the curve of irradiation along the axis of the distance, the effects of the specific dose of radiation to the tumor, along with the corresponding damaging effects to the surrounding healthy tissue and OARs for the specific radiation dose. By providing a visual display to the user, the user now has the ability to have explicit local control of constraint trade-offs, i.e., parts of OAR that are overdosed via the slider. For example, the user could be a dosimetrist, doctor or person associated with determining dosing or medical issues for the patient. Wherein the user, via the slider of the present disclosure, will have the ability to visually see each potential radiation dose and the corresponding damaging effects to the OARs, and after having reviewed all the possible radiation dosing options, make an informed dosing radiation decision necessary to obtain a constraint set or specific dose of radiation for the patient, i.e. the new position of the shifted curve of irradiation along the axis of the distance. The constraint set may eventually be later decided to be a feasible constraint set to be used to obtain a modified dose of radiation.
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Step 341 includes modifying a portion of at least one dose constraint violated by the shifted curve of irradiation to follow the shifted curve, to identify a modified tumor dose constraint and a corresponding modified OAR dose constraint from a location of the shifted curve along the axis of the distance.
Step 345 of method 300 includes changing the dose of radiation according to the modified dose constraints to a modified dose of radiation.
Step 350 of method 300 includes managing the radiation treatment planning system, according to the modified dose of radiation.
The processor 340AA initiates step 330 of method 300 by converting the dose of radiation determined via method 100 into a curve of irradiation in the body of the patient as a function of a distance to a border of the tumor, a border of the OAR, or both, to generate a graphical representation to identify the dose constraints in violation. Wherein upon converting the dose of radiation into the curve of irradiation, shifting the curve of irradiation along an axis of the distance to manipulate a graphical representation of the dose constraints in violation, via a user through a user interface connected with the processor.
Block 335A of
Block 340BB dose optimization and block 340CC fall-off curve of radiation can be accomplished by the utilizing block 335A. For example, the user is able to simultaneously illustrate visually, i.e. by shifting the curve of irradiation along the axis of the distance, the effects of the specific dose of radiation to the tumor, along with the corresponding damaging effects to the surrounding healthy tissue and OARs for the specific radiation dose. The visual display provides the user an ability to have explicit local control of constraint trade-offs, i.e., parts of OAR that are overdosed via the slider. The slider allows the user to visually see each potential radiation dose and the corresponding damaging effects to the OARs, and after having reviewed all the possible radiation dosing options, make an informed dosing radiation decision necessary to obtain a constraint set or specific dose of radiation for the patient, i.e. the new position of the shifted curve of irradiation along the axis of the distance. In essence, the user is able to optimize the dose of radiation 340BB via assistance of viewing the fall-off curve of radiation 340CC. Wherein a constraint set may eventually be later decided to be a feasible constraint set used to obtain a modified dose of radiation.
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Step 384 of
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Step 388 of
Step 390 of
The minimum OAR constraint is shown as DOAR, min, and the position of the OAR boundary along the axes of the distance is shown as dOAR, OD. Further still, the minimum distance between the tumor and the OAR is shown as d0. The position of the Tumor boundary along the axes of distance is shown as dTumor, UD. It is noted that “UD” means under dose and “OD” means over dose, such that under and over refer to the original constraint values.]
Because, it is not uncommon to have an inherent conflict between the desire to have high dose in the tumor and low dose in a nearby OAR. Radiation planning is usually an iterative process that involves repeated adjustments of the distribution and intensity of radiation sources, and repeated evaluation of the quality of the plan during the iterations. There are many complications in radiation planning that need to be considered, before implementing a specific radiation plan for a patient.
For example, determining a dose of radiation for a patient is further complicated, due to the technological limitations of radiation beams not being able to concisely target tumor and OAR areas. Sources of radiation are not able to produce a very sharp spatial change in the radiation distribution. For example, a beam of protons may be used in radiation therapy. The beam originates from a particle accelerator such as a synchrotron or cyclotron. As the beam emerges from the accelerator its spatial distribution in the direction transverse to its propagation direction is well approximated by a Gaussian whose size, as determined by its full width at half maximum, is often in the range of a few millimeters up to 15 mm. Additionally, the physics of the propagation of an ion beam in matter is such that it gives rise to a characteristic radiation distribution in its propagation direction known as a Bragg curve. The key feature of the Bragg curve is that the amount of dose deposited as a function of depth inside the matter has a sharp peak (the Bragg peak) at a distance inside the matter that is determined by the energy of the particles, as well as by the composition of the matter through which it propagates. Increasing the energy of the ions increases the depth of the Bragg peak. Likewise increasing the density of the matter reduces the depth of the Bragg peak.
The Bragg peak will occupy a volume of a few 10s of cubic millimeters, usually much smaller than the volume of the tumor. To treat the entire volume of the tumor it is necessary to irradiate it with many Bragg peaks arranged over the tumor volume. This can be achieved, for example, by scanning the particle beam in the direction perpendicular to its propagation direction with electromagnets. Likewise, the Bragg peak can be scanned in its propagation direction by changing the proton energy. During scanning the beam dwells at a multitude of individual locations in the transverse direction for varying times with varying energy such that the radiation dose from the many individual spots combines to produce a large volume of high radiation.
The task of determining the dwelling times for the beam scanning is called dose optimization. Mathematically we can compute the dose deposited by a set of N beams using the expression Di=Σj=0NAijwj, where Di is the dose to CT voxel i, Aij is a beam matrix that records the amount of dose deposited in CT voxel i by beam j, and wj is the weight, related to the dwelling time, for beam j. The total dose DT is obtained by summing the dose from all voxels, V, by DT(w)=Σi=0V Di.
During the dose optimization we seek to determine a set of values of the beam weights, wj, such that the total dose is minimized subject to a set of constraints on some of the CT voxels. In particular, for tumor voxels the dose is constrained to lie within an acceptable range of values Dtumor, min<=Dtumor<Dtumor, max sufficient to kill the tumor cells, while for OAR voxels the dose is constrained to lie below a maximum value, DOAR<DOAR, max which protects the OAR from permanent damage by the radiation. The optimization problem is stated mathematically as
argminwDT(w)s.t.Dtumor,min≦Dtumor<Dtumor,max and DOAR<DOAR,max
where the optimization algorithm iteratively modifies the weights, w, so as to minimizes the total radiation while satisfying the dose constraints on the tumor and OARs. Such an optimization algorithm for performing the dose optimization is Gradient Descent.
Procedurally, the doctor will determine the initial values of the constraints for every tumor and OAR voxel. Then a first dose optimization computation is performed using the dose optimization algorithm that iteratively adjusts the beam weights to attempt to satisfy constraints on the tumor and OAR voxels. However, because the methods and systems of the present disclosure provide for the distance fields of the tumor and the set of OARs to be combined with computed dose distribution or computed dose optimization algorithms, to form a user interface for visualization and control of constraint tradeoffs between the tumor and OARs. The methods and systems of the present disclosure provide doctors with a more informative and optimized approach for determining doses of radiation for patients, along with improving managing the radiation treatment planning system, among other things.
Another complication in determining the set of dose constraints, is that tumor growth is often very rapid with the consequence that the blood supply to the inner regions of the tumor is poor. A poor blood supply in a region of the tumor results in reduced oxygen levels to that region. The reduced oxygen levels can have the biology effect of causing tumor cells to have increased resistance to radiation. Therefore, to improve the tumor eradication by radiation therapy it is needed to increase the dose of radiation to inner parts of the tumor by increasing the corresponding dose constraints. Again, the methods and systems of the present disclosure provide doctors with a more informative and optimized approach in evaluating and controlling the tradeoff between dose constraints that are in conflict, when determining the set of dose constraints to be administered to the patient, among other things.
Still further, another complication it is not uncommon for the distance between the tumor and the OARs to be less than the size of the proton beam. Therefore, in general it is impossible to simultaneously satisfy both the tumor dose constraints and the OAR dose constraints. A radiation distribution that satisfies the dose constraints within the tumor can often produce a dose that is too high in a nearby OAR. Likewise producing a low dose in an OAR will most likely result in a low dose on the parts of the tumor near the OAR. In such a situation the optimization problem is known as “infeasible” as there exists no set of weights, w, which can simultaneously satisfy all of the tumor and OAR constraints. In other words, as noted above, the methods and systems of the present disclosure provide doctors with a more informative and optimized approach in evaluating and controlling the tradeoff between dose constraints that are in conflict, when determining the set of dose constraints to be administered to the patient, among other things.
According to aspects of the present disclosure, the modification of constraints begins after determining an initial dose optimization from determining the constraint set, i.e. the set of unsatisfied constraints, as well as the 3D dose distribution. From the dose distribution, the dose fall-off curve can be obtained by a number of methods.
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Alternately, a single characteristic dose fall-off curve can be created by taking the maximum dose value from the set of dose curves at each distance. The characteristic dose fall-off curve is then the worst case at every distance from the tumor.
Alternately, the spatial profile characteristic of the radiation source may be used as the characteristic dose fall-off curve. For example, an ion beam has a transverse profile, often modelled as a Gaussian, over which the dose falls from its maximum value to zero. If the maximum is scaled so that its value matches the mean value of the minimum and maximum tumor dose constraints it can then be used as the characteristic dose fall-off curve.
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For example, the graph of
If we consider the spatial relationship between the tumor boundary and an OAR boundary, we can observe that there is a minimum distance of closest approach between the two sets, hereafter referred to a do. Furthermore, the distance from the tumor boundary dT can be related to the distance from the OAR boundary dOAR by dT=d0−dOAR.
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In particular, the graph of
As
Therefore, a user interface can be constructed by placing a control point in the middle of the characteristic dose curve that the dosimetrist can move along the distance axis to choose the degree to which they favor either the tumor or the OAR. As a result of the dosimetrist's selection the tumor and OAR constraints are modified such that they are given values slightly greater than that of the characteristic dose curve. This implies that those voxels whose distance is closest to the opposing set have the greatest change in their constraint values.
Still referring to
A numerical gradient vector for the distance field is straightforward to compute by a number of standard numerical differentiation algorithms such as finite differences. The gradient vector of a distance field at a point p has a direction that points from p toward a point on the boundary that has the minimum distance from p to the boundary; it is the direction to go that gets to the boundary in the least distance. The gradient vectors are always perpendicular to the distance isocontours illustrated in
Also, the various methods or processes outlined herein may be coded as software that is executable on one or more processors that employ any one of a variety of operating systems or platforms. Additionally, such software may be written using any of a number of suitable programming languages and/or programming or scripting tools, and also may be compiled as executable machine language code or intermediate code that is executed on a framework or virtual machine. Typically, the functionality of the program modules may be combined or distributed as desired in various embodiments.
Also, the embodiments of the present disclosure may be embodied as a method, of which an example has been provided. The acts performed as part of the method may be ordered in any suitable way. Accordingly, embodiments may be constructed in which acts are performed in an order different than illustrated, which may include performing some acts concurrently, even though shown as sequential acts in illustrative embodiments. Further, use of ordinal terms such as “first,” “second,” in the claims to modify a claim element does not by itself connote any priority, precedence, or order of one claim element over another or the temporal order in which acts of a method are performed, but are used merely as labels to distinguish one claim element having a certain name from another element having a same name (but for use of the ordinal term) to distinguish the claim elements.
Although the present disclosure has been described with reference to certain preferred embodiments, it is to be understood that various other adaptations and modifications can be made within the spirit and scope of the present disclosure. Therefore, it is the aspect of the append claims to cover all such variations and modifications as come within the true spirit and scope of the present disclosure.
