The present invention relates to a method for tracking the movement of particles through a geometric model so as to facilitate the development of a dosimetry plan, and more specifically to a methodology which includes the step of traversing a particle along the particle track, and across the boundary which separates regions of the geometric model which have different densities and/or compositions, while minimizing the use of a floating point calculation to determine the particle location at the boundary crossing.
The present invention relates generally to radiation therapy and more specifically to the analytical computations for the dosimetric planning thereof. In this regard, radiation transport calculations for radiotherapy applications have traditionally used Monte Carlo methods because of the highly complex geometry involved, and the inherent multiple particle nature of the calculations. In this regard, the use of medical image sets to define the calculation geometry allowed for more exact descriptions of tissues and organs in the patient. Most radiotherapy treatment planning systems define the organ/tissues by outlining the regions using some variant of a spline to define the region boundary. This requires the use of floating-point arithmetic to perform the particle tracking function.
In U.S. Pat. No. 6,175,761 the inventors disclosed a method that used medical images to define an array of uniform volume elements (univels), which are identical rectangular parallelepipeds, to model the patients' geometry. This methodology allowed the particle tracking functions to be formed using integer arithmetic, with the floating-point computations only required for the final location of the particle at a boundary crossing. This methodology greatly reduced the computation time involved in the tracking functions, by removing the need for expensive floating-point arithmetic at each stage of the particle tracking procedure.
While the methodology described in U.S. Pat. No. 6,175,761 has operated with a great deal of success, several shortcomings have been identified and which have detracted from its usefulness. For example, it has been recognized that the univel method of computation only achieved efficient operation when the average distance between the particle collisions, or mean free path was large relative to the size of the univel. This methodology therefore was ideal for neutron transport but was viewed as not any more efficient than conventional methodologies for the coupled photon-electron transport.
Therefore an improved method for tracking the movement of a particle through a geometric model so as to facilitate the development of a dosimetry plan, and which addresses the shortcomings attendant with the prior art methodology and practices utilized heretofore is the subject matter of the present application.
Therefore one aspect of the present invention relates to a method for tracking the movement of a particle through a geometric model so as to facilitate the development of a dosimetry plan, and which includes providing a particle with a short mean free path length; providing a geometric model which has a boundary which separates regions of the geometric model having different densities and/or compositions; arranging a first plurality of substantially uniform volume elements having a predetermined size into the geometric model; and arranging a second plurality of substantially uniform volume elements having a predetermined size less than that of the first plurality of substantially uniform volume elements, and in overlaying relation relative to the first plurality of substantially uniform volume elements.
Another aspect of the present invention relates to a method for rapidly tracking the movement of a particle through a geometric model so as to facilitate the development of a dosimetry plan, and which includes providing a geometric model which includes regions having different densities and/or compositions, and wherein a boundary is defined between the regions having the different densities and/or compositions; arranging a first plurality of substantially uniform volume elements into the geometric model; creating a particle with a short mean free path length in at least one of the first plurality of substantially uniform volume elements which is located in at least one of the regions; arranging a second plurality of substantially uniform volume elements which overlays at least one of the first plurality of substantially uniform volume elements where the particle having the short mean free path length is created, and wherein the second plurality of substantially uniform volume elements have a size which is small in relative comparison to the short mean free path length of the particle; describing the movement of the particle through the geometric model with a particle track which has a primary direction of movement; and traversing the particle having the short mean free path length along the particle track, and across the boundary which separates the regions having the different densities and/or compositions, by minimizing the use of a floating point computation, to determine the particle location at the boundary crossing.
Yet further, another aspect of the method for tracking the movement of a particle through a geometric model so as to facilitate the development of a dosimetry plan, which includes obtaining a medical image of a treatment volume and which includes a plurality of pixels of information; providing a particle with a short mean free path length; providing a geometric model which defines regions in the treatment volume having different densities and/or compositions, and wherein a boundary is defined between the regions having the different densities and/or compositions; converting the pixels of information derived from the treatment volume into a first plurality of substantially uniform volume elements having a predetermined size; arranging the first plurality of substantially uniform volume elements having predetermined dimensions into the geometric model which defines the regions having different densities and/or compositions, and wherein the particle having the short mean free path length is created in at least one of the first plurality of substantially uniform volume elements which is located in at least one of the regions; arranging a second plurality of substantially uniform volume elements which overlays at least one of the first plurality of uniform volume elements where the particle having the short mean free path length is created, and wherein the second plurality of uniform volume elements have a predetermined size which are less than the predetermined size of the first plurality of uniform volume elements, and are further small in size in relative comparison to the mean free path length of the particle; describing the movement of the particle in integer base increments through the geometric model with a particle track which has a primary direction of movement; traversing the particle along the particle track, and across the boundary which separates the regions of the geometric model which have different densities and/or compositions, while minimizing the use of a floating point calculation to determine the particle location at the boundary crossing; and calculating a dosimetry plan for conducting radiotherapy for an area of the treatment volume which is in juxtaposed relation relative to the boundary which separates the regions having the different densities and/or compositions by utilizing the particle location at the boundary location.
These and other aspects of the present invention will be described in greater detail hereinafter.
Preferred embodiments of the invention are described below with reference to the following accompanying drawings.
This disclosure of the invention is submitted in furtherance of the constitutional purposes of the U.S. Patent Laws “to promote the progress of science and useful arts” (Article 1, Section 8).
The method for tracking the movement of a particle through a geometric model so as to facilitate the development of a dosimetry plan is best indicated by the numeral 10 in
After the step of arranging the first plurality of substantially uniform volume elements, as referenced in the paragraph above, the methodology includes another step of arranging a second plurality of substantially uniform volume elements 50 as seen in
In the methodology of the present invention, the predetermined size of the second plurality of substantially uniform volume elements 50 is determined as the product of the ratio of the densities of the least dense region of all the regions in the geometric model 30, and the region of the geometric model in which the particle having the short mean free path length 21 was created, and the predetermined size of the individual first plurality of substantially uniform volume elements 40. Still further, in connection with the present methodology, and after the step of arranging the first plurality of substantially uniform volume elements 40, the methodology further includes the step of defining a material to be associated with each of the substantially uniform volume elements.
Therefore, the method 10 for tracking the movement of a particle through a geometric model 30 so as to develop a dosimetry plan includes, in its broadest aspect, providing a particle 21 with a short mean free path length; providing a geometric model 30 which has a boundary 16 (
Therefore it will be seen that the present method provides a convenient means whereby an accurate dosimetry plan can be developed for a treatment volume in a manner not possible heretofore, and by utilizing integer based arithmetic and minimizing the use of floating-point calculations to determine a particle location at a boundary crossing.
In compliance with the statute, the invention has been described in language more or less specific as to structural and methodical features. It is to be understood, however, that the invention is not limited to the specific features shown and described, since the means herein disclosed comprise preferred forms of putting the invention into effect. The invention is, therefore, claimed in any of its forms or modifications within the proper scope of the appended claims appropriately interpreted in accordance with the doctrine of equivalents.
The United States Government has rights in the following invention pursuant to Contract No. DE-AC07-99ID13727 between the U.S. Department of Energy and Bechtel BWXT Idaho, LLC.