Extended field-of-view x-ray imaging using multiple x-ray sources and one or more laterally offset x-ray detectors

The invention claimed is: 1. An imaging system, comprising: a gantry that is rotatably coupled to a drive stand and is configured to rotate through an imaging arc about a bore; a first x-ray source mounted on the gantry and configured to direct x-rays of a first beam energy through a peripheral portion of a target volume disposed in the bore and toward a first x-ray detector mounted on the gantry laterally offset from the center of the target volume; a second x-ray source mounted on the gantry angularly offset from the first x-ray source and configured to direct x-rays of a second beam energy higher than the first beam energy through a portion of the target volume including the center of the target volume and toward a second x-ray detector mounted on the gantry; and a processor configured to: cause the gantry to perform a rotation including an imaging arc; receive first x-ray measurement data from the first x-ray detector; receive second x-ray measurement data from the second x-ray detector; and reconstruct an image of the target volume from the first and second x-ray measurement data, wherein the image has an extended field-of-view; wherein the processor reconstructs the image from the first and second x-ray measurement data by: applying a mono-energizing transform correction to the first and second x-ray measurement data, generating output as monoenergetic projection data; and reconstructing the image from the monoenergetic projection data. 2. The imaging system of claim 1 , wherein the first x-ray beam energy is in a kilovolt (kV) range. 3. The imaging system of claim 1 , wherein the second x-ray beam energy is in a megavolt (MV) range. 4. The imaging system of claim 1 , wherein the second x-ray source comprises a linear accelerator (LINAC) source that is operable to generate a therapeutic radiation beam in addition to x-rays of the second beam energy. 5. The imaging system of claim 1 , wherein the first x-ray source is configured to generate the first x-ray beam such that the first x-ray beam does not pass through the center of the target volume. 6. The imaging system of claim 1 , wherein the reconstructed image is non-truncated. 7. The imaging system of claim 1 , wherein the first x-ray source and the second x-ray source are arranged relative to each other such that the first x-ray beam and the second x-ray beam partially overlap. 8. The imaging system of claim 1 , wherein the second x-ray detector comprises multiple scintillator and photodiode layers. 9. The imaging system of claim 8 , wherein each scintillator layer is composed of GdO 2 S 2 :Tb. 10. The imaging system of claim 8 , wherein each photodiode layer is composed of Si:H. 11. The imaging system of claim 1 , wherein the first x-ray detector and second x-ray detector each have widths no greater than 43 cm. 12. The imaging system of claim 1 , wherein reconstructing the image further includes applying an edge-preserving noise reduction algorithm to reduce noise in the image. 13. The imaging system of claim 1 , wherein the mono-energizing transform correction comprises: reducing noise in the first and second x-ray measurement data; converting the first x-ray measurement data and the second x-ray measurement data to a common energy by modeling the target volume as a composition of a first material through which density projections can be pre-estimated from an approximate prior image reconstruction, and a second material whose density projections can be estimated by minimizing an objective function based in part on a poly-energetic beam model. 14. The imaging system of claim 13 , wherein minimizing the objective function comprises minimizing a roughness penalized likelihood function. 15. The imaging system of claim 1 , wherein the first and second x-ray sources are integrated into a cone-beam computed tomography system. 16. The imaging system of claim 1 , wherein the processor determines three-dimensional (3D) dose maps from the first and second x-ray measurement data and provides the 3D dose maps to an adaptive radiotherapy treatment system. 17. A computer-implemented method of imaging in an imaging system that includes a gantry that is configured to rotate in an imaging arc about a bore, a first x-ray source mounted on the gantry and configured to direct x-rays of a first beam energy through a peripheral portion of a target volume disposed in the bore and toward a first x-ray detector mounted on the gantry laterally offset from the center of the target volume, and a second x-ray source mounted on the gantry angularly offset from the first x-ray source and configured to direct x-rays of a second beam energy higher than the first energy through a portion of the target volume including the center of the target volume and toward a second x-ray detector mounted on the gantry, the method comprising: receiving first x-ray measurement data from the first x-ray detector while the gantry is rotating through the imaging arc; receiving second x-ray measurement data from the second x-ray detector while the gantry is rotating through the imaging arc; and reconstructing an image of the target volume from the first and second x-ray measurement data using a computer system, wherein the image depicts an extended field-of-view region; wherein reconstructing the image further comprises applying a mono-energizing transform correction and edge-preserving noise reduction algorithm to the first and second x-ray measurement data. 18. The method of claim 17 wherein the first x-ray beam is directed so as to not pass through the center of the target volume. 19. The method of claim 17 , wherein the reconstructed image is non-truncated. 20. The method of claim 17 , wherein the first x-ray beam and second x-ray beam are directed to partially overlap. 21. The method of claim 17 , further comprising determining 3D dose maps from the first and second volumetric image data and providing the determined dose maps to an adaptive radiotherapy treatment system. 22. A method of reconstructing an image from x-ray measurement data, the method comprising: (a) accessing first x-ray measurement data with a computer system, the first x-ray measurement data corresponding to a first x-ray beam having a first x-ray beam energy passing through a peripheral portion of a target volume along a beam axis that is laterally offset from a center of the target volume; (b) accessing second x-ray measurement data with the computer system, the second x-ray measurement data corresponding to a second x-ray beam having a second x-ray beam energy higher than the first x-ray beam energy and passing through a portion of the target volume including the center of the target volume; (c) converting the first x-ray measurement data and the second x-ray measurement data to monoenergetic projection data corresponding to a common x-ray beam energy using the computer system; and (d) reconstructing an image from the monoenergetic projection data with the computer system, wherein the image depicts an extended field-of-view of the target volume. 23. The method of claim 22 , wherein converting the first x-ray measurement data and the second x-ray measurement data to monoenergetic projection data comprises modeling the target volume as a composition of a first material through which density projections can be pre-estimated from an approximate prior image reconstruction, and a second material whose density projections can be estimated by minimizing an obje