Dose reduction for cardiac computed tomography

What is claimed is: 1. A method of reducing radiation dose in computed tomography (CT) imaging, comprising: positioning a region of interest of an imaging target proximate to an isocenter of a CT scanner; and adjusting a fluence of X-ray radiation produced by an X-ray source of the CT scanner using a beam-shaping filter, wherein the beam-shaping filter is disposed between the X-ray source of the CT scanner and the region of interest, and wherein the beam-shaping filter is configured to attenuate the X-ray radiation on areas of the imaging target located outside of the region of interest and simultaneously transmit the X-ray radiation to the areas of the imaging target located outside of the region of interest to provide a fluence of the X-ray radiation on the areas of the imaging target located outside of the region of interest at a level less than a predetermined fraction of a fluence of the X-ray radiation within the region of interest, and wherein the beam-shaping filter has a first part including a first material and a second part including a second material different from the first material. 2. The method of claim 1 , wherein the positioning the region of interest of the imaging target is such that the isocenter of the CT scanner is within the region of interest. 3. The method of claim 1 , wherein the beam-shaping filter is a static filter. 4. The method of claim 3 , wherein geometry of the filter is selected using at least one of: age, sex, or body mass index of a person. 5. The method of claim 1 , wherein the beam-shaping filter is configured to attenuate the fluence of X-ray radiation produced by the X-ray source as a function of a distance from the isocenter. 6. The method of claim 5 , wherein the beam-shaping filter is configured to provide a first degree of fluence attenuation for the distances from the isocenter within a first range of distances and provide a second degree of fluence attenuation for the distances from the isocenter outside the first range of distances, wherein the first degree of fluence attenuation is different from the second degree of fluence attenuation. 7. The method of claim 1 , comprising modulating a current of the X-ray source, and wherein the modulation is generated based on the region of interest. 8. The method of claim 7 , wherein the modulation is a function of X-ray attenuation characteristics of the imaging target only for X-rays that pass through the region of interest. 9. The method of claim 8 , wherein the modulation is obtained based on equalizing an average value of an inverse square root of a photon count in the region of interest over a range of view angles. 10. The method of claim 1 , wherein the region of interest is a heart. 11. The method of claim 1 , wherein the first material has a varying thickness across the first part in order to tune the degree of attenuation of X-ray radiation across the first part and the second material has a varying thickness across the second part in order to tune the degree of attenuation of X-ray radiation across the second part. 12. A computed tomography (CT) scanner, comprising: an X-ray source; and a beam-shaping filter disposed between the X-ray source and a location where a region of interest of an imaging target is placed, wherein: the CT scanner is configured such that an isocenter of the CT scanner is proximate to the region of interest wherein the CT scanner is further configured to adjust a fluence of X-ray radiation produced by the X-ray source using the beam-shaping filter, and wherein the beam-shaping filter is configured to attenuate the X-ray radiation on areas of the imaging target located outside of the region of interest and, at the same time, transmit the X-ray radiation to the areas of the imaging target located outside of the region of interest to provide a fluence of the X-ray radiation on the areas of the imaging target located outside of the region of interest at a level less than a predetermined fraction of a fluence of the X-ray radiation within the region of interest, and wherein the beam-shaping filter has a first part including a first material and a second part including a second material different from the first material such that a thickness of the first part decreases from a center of the beam-shaping filter toward an edge of the beam-shaping filter. 13. The computed tomography scanner of claim 12 , wherein the scanner is configured such that the isocenter of the scanner is within the region of interest, or wherein the scanner is configured to modulate a current of the X-ray source. 14. The computed tomography scanner of claim 13 , wherein the modulation is a function of X-ray attenuation characteristics of the imaging target only for X-rays that pass through the region of interest. 15. The computed tomography scanner of claim 13 , wherein the scanner is configured to obtain the modulation based on equalizing an average value of an inverse square root of a photon count in the region of interest over a range of view angles. 16. The computed tomography scanner of claim 12 , wherein the beam-shaping filter is a static filter. 17. The computed tomography scanner of claim 12 , wherein the beam-shaping filter is configured to attenuate the fluence of X-ray radiation produced by the X-ray source as a function of a distance from the isocenter. 18. The computed tomography scanner of claim 17 , wherein the beam-shaping filter is configured to provide a first degree of fluence attenuation for the distances from the isocenter within a first range of distances and provide a second degree of fluence attenuation for the distances from the isocenter outside the first range of distances, wherein the first degree of fluence attenuation is different from the second degree of fluence attenuation. 19. The computed tomography scanner of claim 12 , wherein the region of interest is a heart. 20. The computed tomography scanner of claim 12 , wherein the first material has a varying thickness across the first part in order to tune the degree of attenuation of X-ray radiation across the first part and the second material has a varying thickness across the second part in order to tune the degree of attenuation of X-ray radiation across the second part.