Patent Number: 
Section: claims

1. A method for acquiring a computed tomography (CT) image of a person's breast using a scanner system comprising:from a plurality of CT data sets of a plurality of persons, defining a plurality of different breast volume classes, each breast volume class corresponding to a different range of breast volume percentile groups;based on at least one of a shape and a size of the person's breast, assigning the person's breast to a breast volume class;from a plurality of immobilizers each corresponding to a different breast volume class, selecting an immobilizer corresponding to the breast volume class assigned to the person's breast;from a plurality of 3D-beam modulation filters each corresponding to a different breast volume class, selecting a 3D-beam modulation filter corresponding to the breast volume class assigned to the person's breast;coupling the selected immobilizer to the scanner system;positioning the person's breast in the selected immobilizer; andacquiring a computed tomography (CT) image of the person's breast using the scanner system with the selected 3D-beam modulation filter and the selected immobilizer,wherein each 3D-beam modulation filter has a three-dimensional shape corresponding to at least one of a size and a three-dimensional shape of one of said breast volume classes so as to equalize intensities of individual x-rays within an x-ray beam after said x-ray beam passes through said person's breast. 2. The method of claim 1, wherein the selected 3D-beam modulation filter is configured to reduce a dose of radiation toward anterior and peripheral regions of the person's breast based on at least one of a shape and a size of the breast volume class assigned to the person's breast. 3. The method of claim 1, wherein acquiring the CT image of the person's breast further comprises:collecting x-rays beams emitted from an x-ray source of the scanner system on a detector panel of the scanner system, wherein the x-ray beams emitted by the x-ray source are filtered by the selected 3D-beam modulation filter prior to traveling through the person's breast. 4. The method of claim 1, further comprising:based on at least one of the shape and the size of the person's breast in addition to the assigned breast volume class, dynamically adjusting a position of the selected 3D-beam modulation filter between the person's breast and an x-ray source of the scanner system, prior to acquiring the computed tomography (CT) image of the person's breast. 5. The method of claim 1, further comprising:identifying a predetermined profile among a plurality of predetermined profiles based on the shape or size of the person's breast, wherein each of the plurality of 3D-beam modulation filters are generated for only one of the plurality of predetermined profiles, wherein each of the plurality of immobilizers are generated for only one of the plurality of predetermined profiles. 6. The method of claim 1 wherein the selected 3D-beam modulation filter comprises a combined filter, the method further comprising:selecting a bowtie-shaped filter among a plurality of bowtie-shaped filters based on the breast volume class assigned to the person's breast;selecting a wedge-shaped filter among a plurality of wedge-shaped filters based on the breast volume class assigned to the person's breast; andcombining the selected bowtie-shaped filter with the selected wedge-shaped filter into the combined filter. 7. The method of claim 1, wherein coupling the selected immobilizer to the scanner system further comprises:attaching a first end of an attachment element to a surface of the scanner system, andattaching second end of the attachment element to the selected immobilizer. 8. The method of claim 7, wherein the attachment element includes a flange or a fastener. 9. The method of claim 1, further comprising:acquiring two orthogonal scout views of the person's breast;adjusting a position of at least one of the 3D-beam modulation filter and the person's breast based on the acquired orthogonal scout views of the person's breast. 10. A computing device including a non-transitory storage medium storing instructions, and a processor executing the instructions stored on the non-transitory storage medium to perform the method of claim 1. 11. A computed tomography (CT) scanner system, comprising:an x-ray production system including an x-ray source configured to emit x-rays;an x-ray detector system constructed and arranged to receive the x-rays emitted by the x-ray source;a filter positioning system configured to select a 3D-beam modulation filter among a plurality of 3D-beam modulation filters each corresponding to a different breast volume class in a plurality of breast volume classes, said selected 3D-beam modulation filter corresponding to a breast volume class assigned to a body part to be imaged, said assigning based on at least one of a shape and a size of the body part, and further configured to position the selected 3D-beam modulation filter between the x-ray source and the x-ray detector system,wherein each 3D-beam modulation filter has a three-dimensional shape corresponding to at least one of a size and a three-dimensional shape of one of said breast volume classes so as to equalize intensities of individual x-rays within an x-ray beam after said x-ray beam passes through the body part, andwherein said plurality of breast volume classes are defined from a plurality of CT data sets of a plurality of persons, each breast volume class corresponding to a different range of breast volume percentile groups; anda gantry assembly system including a table for receiving the body part. 12. The CT scanner system of claim 11 further comprising:a scanner control computer coupled to the x-ray production system and the gantry assembly system for sending control signals to the x-ray production system and the gantry assembly system. 13. The CT scanner system of claim 11, wherein the selected 3D-beam modulation filter comprises a combined filter, wherein the filter positioning system is further configured to:select a bowtie-shaped filter among a plurality of bowtie-shaped filters based on the volume class assigned to said body part;select a wedge-shaped filter among a plurality of wedge-shaped filters based on the volume class assigned to said body part; andcombine the selected bowtie-shaped filter and the selected wedge-shaped filter into the combined filter. 14. The CT scanner system of claim 11 further comprising:an image acquisition computer for receiving image data from the x-ray detector system;an image reconstruction computer for reconstructing a CT image of the body part based on the image data received from the image acquisition computer; anda display for displaying the reconstructed CT image of the body part. 15. The CT scanner system of claim 14, wherein the image reconstruction computer receives data from a scanner control computer and the image acquisition computer, the data including at least one of x-ray beam intensity data, x-ray beam emission timing data, gantry assembly system positioning data, and projection images of the body part being imaged. 16. The CT scanner system of claim 11, wherein the body part is a breast and the selected 3D-beam modulation filter is configured to reduce a dose of radiation toward anterior and peripheral regions of the breast based on at least one of a shape and a size of the volume class assigned to the breast. 17. The CT scanner system of claim 11, further comprising an immobilizer coupled to the gantry assembly system, wherein the immobilizer is coupled to the gantry assembly system using one or more attachment elements. 18. The CT scanner system of claim 11, further comprising an immobilizer selection system configured to select a breast immobilizer from a plurality of breast immobilizers, each breast immobilizer corresponding to a different breast volume class out of the plurality of breast volume classes, each immobilizer structured to be connectable to and disconnectable from said table. 19. The CT scanner system of claim 18, further comprising said plurality of breast immobilizers. 20. The CT scanner system of claim 18, wherein the immobilizer selection system is further configured to position the person's breast in the selected immobilizer and perform a check for the immobilizer fit with a laser-based system. 21. The CT scanner system of claim 11, further comprising said plurality of 3D-beam modulation filters. 22. The CT scanner system of claim 11, wherein said filter positioning system is further configured to receive scout view data of the body part and to dynamically a position of at least one of the selected 3D-beam modulation filter and the body part, based on the scout view data and at least one of the shape of the body part, the size of the body part, and the assigned breast volume class. 23. The CT scanner system of claim 22, wherein said scout view data is x-ray scout view data. 24. The CT scanner system of claim 22, wherein said scout view data is optical scout view data. 25. The CT scanner system of claim 11, further comprising a laser-evaluating system configured to determine the breast volume class that best fits the person's breast. 26. A cone-beam breast computed tomography (CT) system, comprising:a table arranged to support a person to lie prone with the person's breast extending through an aperture defined by the table;a plurality of breast immobilizers, each corresponding to a different breast volume class out of a corresponding plurality of breast volume classes, each breast immobilizer structured to be connectable to and disconnectable from said table at said aperture to immobilize said person's breast when it extends through said aperture;a gantry disposed proximate to said table;a cone-beam x-ray source attached to said gantry and positioned to be able to irradiate said person's breast with a cone beam of x-rays;a plurality of modulation filters, each corresponding to one of said plurality of breast volume classes, and each adapted to be connected to and disconnected from said gantry at a position between said cone-beam x-ray source and said person's breast; anda flat-panel detector attached to said gantry and positioned to be able to receive at least a portion of said cone beam of x-rays after passing through said person's breast,wherein said gantry is rotatable about an axis that intercepts said person's breast such that said cone-beam x-ray source and said flat-panel detector rotate with said gantry in unison, andwherein said plurality of breast volume classes are defined from a plurality of CT data sets of a plurality of persons, each breast volume class corresponding to a different range of breast volume percentile groups, andwherein at least one modulation filter of said plurality of modulation filters is a 3D-beam modulation filter that has a three-dimensional shape corresponding to at least one of a size and a three-dimensional shape of one of said breast volume classes so as to equalize intensities of individual x-rays within an x-ray beam after said x-ray beam passes through said person's breast. 27. The cone-beam breast computed tomography (CT) system according to claim 26,wherein each said modulation filter compensates for different x-ray path lengths through different portions of said person's breast of the corresponding breast volume class to reduce a total amount of x-ray dose,wherein each said modulation filter, when connected to said gantry, is rotatable with said gantry in unison with said cone-beam x-ray source and said flat-panel detector. 28. An accessory kit for a cone-beam breast computed tomography (CT) system, comprising:a plurality of breast immobilizers, each corresponding to a different breast volume class out of a corresponding plurality of breast volume classes, and each being structured to be connectable to and disconnectable from a table of said cone-beam breast CT system at an aperture defined by said table; anda plurality of modulation filters, each corresponding to a different breast volume class out of the corresponding plurality of breast volume classes, and each adapted to be connected to and disconnected from a gantry at a position between a cone-beam x-ray source and said person's breast,wherein the plurality of breast volume classes are defined from a plurality of CT data sets of a plurality of persons, each breast volume class corresponding to a different range of breast volume percentile groups,wherein each breast immobilizer is configured to immobilize a person's breast when it extends through said aperture, andwherein at least one modulation filter of said plurality of modulation filters is a 3D-beam modulation filter that has a three-dimensional shape corresponding to at least one of a size and a three-dimensional shape of one of said breast volume classes so as to equalize intensities of individual x-rays within an x-ray beam after said x-ray beam passes through said person's breast. 29. The accessory kit according to claim 28, further comprising:wherein each said modulation filter compensates for different x-ray path lengths through different portions of said person's breast of the corresponding breast volume class to reduce a total amount of x-ray dose,wherein each said modulation filter, when connected to said gantry, is rotatable with said gantry in unison with said cone-beam x-ray source and a flat-panel detector. 30. An accessory kit for a cone-beam breast computed tomography (CT) system, comprising:a plurality of modulation filters, each corresponding to a different breast volume class out of a corresponding plurality of breast volume classes, and each adapted to be connected to and disconnected from a gantry at a position between a cone-beam x-ray source and a person's breast,wherein the plurality of breast volume classes are defined from a plurality of CT data sets of a plurality of persons, each breast volume class corresponding to a different range of breast volume percentile groups,wherein each said modulation filter compensates for different x-ray path lengths through different portions of said person's breast of the corresponding breast volume class to reduce a total amount of x-ray dose,wherein each said modulation filter, when connected to said gantry, is rotatable with said gantry in unison with said cone-beam x-ray source and a flat-panel detector, andwherein at least one modulation filter of said plurality of modulation filters is a 3D-beam modulation filter that has a three-dimensional shape corresponding to at least one of a size and a three-dimensional shape of one of said breast volume classes so as to equalize intensities of individual x-rays within an x-ray beam after said x-ray beam passes through said person's breast. 31. The accessory kit according to claim 30, wherein each modulation filter of said plurality of modulation filters comprises a first filter for filtering along a first dimension and a second filter for filtering along a second dimension that is orthogonal to the first dimension. 32. The accessory kit according to claim 31, wherein at least one of said first filter or said second filter is formed from titanium.