Dynamic bowtie filter for cone-beam/multi-slice ct

What is claimed is: 1 . A dynamic bowtie filter for computed tomography (CT), comprising: a highly-attenuating bowtie (HB) comprising a liquid contained within a first container; and a weakly-attenuating bowtie (WB) immersed within the liquid of the HB and comprising a second container. 2 . The dynamic bowtie filter according to claim 1 , wherein the WB comprises air within the second container, such that the WB is an air chamber. 3 . The dynamic bowtie filter according to claim 1 , wherein the WB is configured to rotate in synchrony with a radiation source during CT scanning 4 . The dynamic bowtie filter according to claim 1 , wherein the WB is configured to translate in synchrony with an object to be imaged during CT scanning 5 . The dynamic bowtie filter according to claim 1 , wherein the WB is a scaled-down version of an object to be imaged during CT scanning 6 . The dynamic bowtie filter according to claim 5 , wherein the WB is a ⅓ to ⅕ scale version of an object to be imaged during CT scanning 7 . The dynamic bowtie filter according to claim 1 , wherein the first container is an aluminum container. 8 . The dynamic bowtie filter according to claim 7 , wherein each wall of the first container has a thickness of 0.5 millimeters (mm) or less. 9 . The dynamic bowtie filter according to claim 1 , wherein the second container is a plastic container. 10 . The dynamic bowtie filter according to claim 9 , wherein each wall of the second container has a thickness of 0.2 millimeters (mm) or less. 11 . The dynamic bowtie filter according to claim 1 , wherein the liquid of the HB has a density that is greater than that of water. 12 . The dynamic bowtie filter according to claim 1 , wherein the liquid of the HB is CeCl 3 . 13 . The dynamic bowtie filter according to claim 1 , wherein the WB comprises air within the second container, such that the WB is an air chamber, wherein the WB is configured to rotate in synchrony with a radiation source during CT scanning, wherein the WB is further configured to translate in synchrony with an object to be imaged during CT scanning, wherein the WB is a scaled-down version of an object to be imaged during CT scanning, and wherein the liquid of the HB has a density that is greater than that of water. 14 . The dynamic bowtie filter according to claim 13 , wherein the WB is a ⅓ to ⅕ scale version of an object to be imaged during CT scanning, wherein the first container is an aluminum container, wherein the second container is a plastic container, and wherein the liquid of the HB is CeCl 3 . 15 . A computed tomography (CT) imaging device, comprising: a radiation source; a detector to receive radiation after it passes through an object to be imaged; and a dynamic bowtie filter disposed between the radiation source and the detector such that radiation from the radiation source is attenuated by the dynamic bowtie filter, wherein the dynamic bowtie filter comprises: a highly-attenuating bowtie (HB) comprising a liquid contained within a first container; and a weakly-attenuating bowtie (WB) immersed within the liquid of the HB and comprising a second container. 16 . The CT imaging device according to claim 15 , wherein the WB comprises air within the second container, such that the WB is an air chamber, wherein the WB is configured to rotate in synchrony with a radiation source during CT scanning, wherein the WB is further configured to translate in synchrony with an object to be imaged during CT scanning, wherein the WB is a scaled-down version of an object to be imaged during CT scanning, and wherein the liquid of the HB has a density that is greater than that of water. 17 . The CT imaging device according to claim 16 , wherein the WB is a ⅓ to ⅕ scale version of an object to be imaged during CT scanning, wherein the first container is an aluminum container, wherein the second container is a plastic container, wherein the liquid of the HB is CeCl 3 , and wherein the radiation source is an X-ray source. 18 . A method of imaging an object using CT, the method comprising: positioning the object within the field of view of the CT imaging device according to claim 15 ; and providing radiation from the radiation source such that the detector receives at least a portion of the radiation after it passes through the object, wherein the WB rotates in synchrony with the radiation source while the radiation source provides radiation, and wherein the WB translates in synchrony with the object while the radiation source provides radiation. 19 . The method according to claim 18 , wherein the WB comprises air within the second container, such that the WB is an air chamber, wherein the WB is a scaled-down version of the object, wherein the liquid of the HB has a density that is greater than that of water, and wherein the object is a human patient. 20 . The method according to claim 18 , further comprising, before providing radiation from the radiation source: performing three-dimensional (3D) surface scanning on the object to obtain a 3D surface scan of the object; and fabricating the WB of the dynamic bowtie filter of the CT imaging device by 3D printing a scaled-down version of the object based on the 3D surface scan of the object.