Hybrid detection systems and methods for C-arm interventional x-ray systems

The invention claimed is: 1. A C-arm x-ray imaging system comprising: a gantry formed as a C-arm configured to pivot about a pivot axis; an x-ray source coupled to a first end of the C-arm, the x-ray source configured to emit x-rays along a path extending to define an axial axis; and a changeable x-ray detector system coupled to a second end of the C-arm arranged in the axial axis, the changeable x-ray detector system configured to receive x-rays emitted from the x-ray source along the path, the changeable x-ray detector system including: an energy-integrating x-ray detector having an array of x-ray sensing elements that are configured to sense x-rays emitted from the x-ray source; a photon-counting detector having another array of x-ray sensing elements configured to determine an interaction between individual x-ray photons from the x-ray source and individual sensing elements of the another array of x-ray sensing elements; a mounting system configured to move at least one of the energy-integrating detector or the photon-counting detector between a first position in the path to receive the x-rays emitted from the x-ray source and a second position removed from the path to not receive the x-rays emitted from the x-ray source, wherein only one of the energy-integrating detector and the photon-counting detector is configured to receive the x-rays emitted from the x-ray source at a time. 2. The C-arm x-ray imaging system of claim 1 , wherein mounting system includes one of a hinge, a rail system, a bracket system, or a socket to secure the at least one of the energy-integrating detector or the photon-counting detector in the first position in the path to receive the x-rays emitted from the x-ray source. 3. The C-arm x-ray imaging system of claim 1 , wherein the mounting system translates the photon-counting detector in a direction substantially perpendicular to the axial axis into the second position. 4. The C-arm x-ray imaging system of claim 3 , wherein the array of x-ray sensing elements of the energy-integrating x-ray detector defines a first sensing area having a peripheral edge, wherein the another array of x-ray sensing elements of the photon-counting detector defines a second sensing area, wherein the first sensing area is substantially parallel to the second sensing area, and wherein the photon-counting detector is configured to move from the second position to the first position, such that in moving from the first position to the second position, the entire first sensing area is clearing and being positioned away from the peripheral edge of the first sensing area. 5. The C-arm x-ray imaging system of claim 4 , wherein in the first configuration a gap is defined between the peripheral edge of the first sensing area, and another peripheral edge of the second sensing area. 6. The C-arm x-ray imaging system of claim 4 , wherein the first sensing area is larger than the second sensing area. 7. The C-arm x-ray imaging system of claim 4 , wherein individual x-ray sensor elements of the energy-integrating x-ray detector are larger than individual x-ray sensing elements of the photon-counting detector. 8. The C-arm x-ray imaging system of claim 4 , further comprising a mounting structure that is coupled to and secures the changeable x-ray detector assembly to the second end of the C-arm. 9. The C-arm x-ray imaging system of claim 8 , wherein the mounting structure is configured to constrain translational movement of the photon-counting detector towards the x-ray source along the axial axis, and wherein the mounting structure includes: a track coupled to the C-arm; and a supporting beam coupled to the photon-counting detector, and to the track, and wherein the track guides translation of the photon-counting detector. 10. The C-arm x-ray imaging system of claim 9 , further comprising a wheel coupled to the support beam, the wheel received within the track, and wherein the wheel rolls along the track to translate the photon-counting detector. 11. The C-arm x-ray imaging system of claim 8 , wherein the mounting structure is pivotally coupled to the C-arm at one end, and is coupled to the photon-counting detector at an opposing end. 12. The C-arm x-ray imaging system of claim 1 , wherein the energy-integrating x-ray detector is removably coupled to the second end of the C-arm, and wherein the photon-counting detector is removably coupled to the second end of the C-arm, wherein when the energy-integrating x-ray detector is coupled to the second end of the C-arm, the photon-counting detector cannot be coupled to the second end of the C-arm, and wherein when the photon-counting detector is coupled to the second end of the C-arm, the energy-integrating x-ray detector cannot be coupled to the second end of the C-arm. 13. The C-arm x-ray imaging system of claim 12 , wherein the energy-integrating x-ray detector and the photon-counting detector are in electrical communication with a processor of the C-arm x-ray imaging system. 14. The C-arm x-ray imaging system of claim 12 , wherein when the energy-integrating x-ray detector is coupled to the another end of the C-arm: the energy-integrating x-ray detector is in electrical communication with a processor of the C-arm x-ray imaging system; and the photon-counting detector is not in electrical communication with the processor of the C-arm X-ray imaging system, and wherein when the photon-counting detector is coupled to the another end of the C-arm: the photon-counting detector is in electrical communication with a processor of the C-arm x-ray imaging system; and the energy-integrating x-ray detector is not in electrical communication with the processor of the C-arm X-ray imaging system. 15. A method of controlling a C-arm x-ray imaging system including a gantry formed as a C-arm, an x-ray source, and a changeable x-ray detector assembly having an energy-integrating detector and a photon-counting detector, the method comprising: acquiring first x-ray imaging data, using a processor in communication with the C-arm x-ray imaging system, and only the energy-integrating x-ray detector; and acquiring second x-ray imaging data, using the processor, and only the photon-counting detector. 16. The method of claim 15 , wherein the x-ray source assembly defines an axial axis, wherein the axial axis intersects the photon-counting detector and energy-integrating x-ray detector, and further comprising moving the photon-counting detector so that the axial axis no longer intersects the photon-counting detector, prior to acquiring the first x-ray imaging data. 17. The method of claim 16 , wherein the energy-integrating x-ray detector has a peripheral edge, and further comprising moving the entire photon-counting detector past the peripheral edge of energy-integrating x-ray detector. 18. The method of claim 16 , further comprising moving the photon-counting detector so that the axial axis intersects the photon-counting detector, prior to acquiring second x-ray imaging data. 19. The method of claim 18 , further comprising calibrating the photon-counting detector after moving the photon-counting detector, and prior to acquiring the second x-ray imaging data. 20. The method of claim 15 , further comprising: forming a first image using the first x-ray imaging data; presenting the first image on a display; forming a second image using the second x-ray imaging data; presenting the second image on the display. 21. A method of retrofitting a C-arm x-ra