Image data reformatting

What is claimed is: 1. A method for reformatting image data, comprising: obtaining volumetric image data indicative of an anatomical structure of interest; receiving a first user input identifying a surface of interest of the anatomical structure of interest in the volumetric image data; receiving a second user input providing a thickness of interest for a sub-volume of the anatomical structure of interest, wherein the thickness includes a first depth for a first projection of the sub-volume and a second depth for a second projection of the sub-volume, wherein the first and second projections are different projections, and the first and second depths are different depths; shaping the sub-volume such that at least one of its sides follows the surface of interest; and generating, via a processor, a maximum intensity projection (MIP) or direct volume rendering (DVR) beginning at the surface of interest and extending into the anatomical structure of interest of a distance to the provided thickness, wherein the first projection extends from the surface to the first depth in the MIP or DVR, and the second projection extends from the surface to the second depth in the MIP or DVR. 2. The method of claim 1 , further comprising: adjusting the thickness of interest; and updating the MIP or DVR based on the adjusted thickness. 3. The method of claim 1 , further comprising: identifying a viewing angle of interest for the anatomical structure of interest; and generating the MIP or DVR based on the sub-volume and the viewing angle of interest. 4. The method of claim 3 , further comprising: adjusting the viewing angle of interest; and updating the MIP or DVR based on the adjusted view angle of interest. 5. The method of claim 1 , wherein the structure of interest includes at least one other surface, wherein a set of vessels of interest is located nearer the surface of interest relative to the at least one other surface. 6. The method of claim 5 , wherein the set of vessels include smaller peripheral vessels and larger central vessel are located nearer the at least one other surface. 7. The method of claim 6 , wherein the thickness includes the smaller peripheral vessels and not the larger central vessel. 8. The method of claim 1 , wherein the surface of interest is a curved surface. 9. A reformatter, comprising: a processor that generates at least one of a maximum intensity projection (MIP) or direct volume rendering (DVR) for a sub-portion of an anatomical structure of interest from volumetric image data indicative of the anatomical structure of interest based on a surface of interest of the anatomical structure of interest identified in the volumetric image data through a first input and a thickness of a sub-volume of the anatomical structure provided by a second input, wherein the thickness includes a first depth for a first projection of the sub-volume and a second depth for a second projection of the sub-volume, the first and second projections are different projections, the first and second depths are different depths, the MIP or DVR is generated beginning at the surface of interest and extending into the anatomical structure of interest to the provided thickness, and the first projection extends from the surface to the first depth in the MIP or DVR, and the second projection extends from the surface to the second depth in the MIP or DVR. 10. The reformatter of claim 9 , wherein the processor generates the MIP or DVR based on a region of data defined by the surface of interest and the sub-volume of interest. 11. The reformatter of claim 9 , wherein the processor generates the MIP or DVR based on a viewing angle of interest. 12. The reformatter of claim 11 , wherein the viewing angle is generally perpendicular to a projection plane. 13. The reformatter of claim 11 , wherein the viewing angle is oblique to a projection plane. 14. The reformatter of claim 9 , further comprising: a segmentor that segments the anatomical structure of interest from volumetric image data. 15. The reformatter of claim 9 , further comprising: an interface for receiving a signal indicative of a change of a thickness of the sub-volume of interest, wherein the processor updates the MIP or DVR based on the signal. 16. The reformatter of claim 9 , wherein the anatomical structure of interest includes a first set of vessels of interest and a second set of vessels, and the first set of vessels of interest are located nearer to the surface of interest than the second set of vessels. 17. The reformatter of claim 16 , wherein the sub-volume of interest includes a substantial portion of the first set of vessels of interest. 18. A non-transitory computer readable storage medium encoded with instructions which, when executed by a processor of a computer, cause the computer to perform the step of: obtain volumetric image data indicative of an anatomical structure of interest; receive a first user input identifying a surface of interest of the anatomical structure of interest in the volumetric image data; receive a second user input providing a thickness of interest for a sub-volume of the anatomical structure of interest, wherein the thickness includes a first depth for a first projection of the sib-volume and a second depth for a second projection of the sub-volume, the first and second projections are different projections, and the first and second depths are different depths; shape the sub-volume such that at least one of its sides follows the surface of interest; and generate a maximum intensity projection (MIP) or direct volume rendering (DVR) beginning at the curved surface of interest and extending into the anatomical structure of interest to the provided thickness, wherein the first projection extends from the surface to the first depth in the MIP or DVR, and the second projection extends from the surface to the second depth in the MIP or DVR.