Adaptive method for generating artifact-reduced CT image data

What is claimed is: 1. An adaptive method for generating CT image data, comprising: acquiring projection measurement data of an examination region of an examination object; generating uncorrected image data of the examination region; determining artifact-affected subregions of the examination region based upon at least one part of the uncorrected image data; carrying out an artifact-reduced image reconstruction in the artifact-affected subregions of the examination region, only artifact-reduced subimage data of the artifact-affected subregions being generated; and generating artifact-reduced image data of an entirety of the examination region by combining at least one part of the uncorrected image data and the artifact-reduced subimage data, wherein the uncorrected image data includes at least one of topogram image data and real-time image data, wherein at least one of the real-time image data and the topogram image data is used in determining whether or not to perform an artifact-affected reconstruction, and wherein, after reconstruction for the generating of the artifact-reduced image data, reconstructed, uncorrected image data is buffered only in an event of a determination that an artifact reduction has to be carried out. 2. The method of claim 1 , wherein in the generating of the uncorrected image data, uncorrected image data is reconstructed based upon the projection measurement data acquired and at least one part of the reconstructed, uncorrected image data is combined with the artifact-reduced subimage data in the generating of the artifact-reduced image data. 3. The method of claim 2 , wherein the uncorrected image data includes at least one of topogram image data and real-time image data. 4. The method of claim 2 , wherein, in generating the artifact-reduced image data, only the uncorrected image data from artifact-free subregions is used. 5. The method of claim 1 , wherein, in generating the artifact-reduced image data, only the uncorrected image data from artifact-free subregions is used. 6. The method of claim 5 , wherein the uncorrected image data includes at least one of topogram image data and real-time image data and wherein the artifact-affected subregions are determined based upon at least one of the real-time image data and the topogram image data. 7. The method of claim 5 , wherein the uncorrected image data includes at least one of topogram image data and real-time image data and wherein potential subregions, which may be artifact-affected, are determined in advance via at least one of the real-time image data and the topogram image data and wherein artifact-affected subregions are determined based upon reconstructed, uncorrected image data, assigned to the potential subregions determined. 8. The method of claim 5 , wherein the uncorrected image data includes at least one of topogram image data and real-time image data and wherein at least one of the real-time image data and the topogram image data is used in determining whether or not to perform an artifact-affected reconstruction. 9. The method of claim 1 , wherein the determining of the artifact-affected subregions includes: determining whether metal objects are located in the examination region, and determining the artifact-affected subregions of the examination region in which the metal objects are located. 10. The method of claim 9 , wherein the uncorrected image data includes at least one of topogram image data and real-time image data and wherein the artifact-affected subregions are determined based upon at least one of the real-time image data and the topogram image data. 11. The method of claim 9 , wherein the uncorrected image data includes at least one of topogram image data and real-time image data, wherein potential subregions, which may be artifact-affected, are determined in advance via at least one of the real-time image data and the topogram image data and wherein artifact-affected subregions are determined based upon reconstructed, uncorrected image data, assigned to the potential subregions determined. 12. The method of claim 9 , wherein the uncorrected image data includes at least one of topogram image data and real-time image data and wherein at least one of the real-time image data and the topogram image data is used in determining whether or not to perform an artifact-affected reconstruction. 13. The method of claim 1 , wherein the artifact-affected subregions are determined based upon at least one of the real-time image data and the topogram image data. 14. The method of claim 1 , wherein potential subregions, which may be artifact-affected, are determined in advance via at least one of the real-time image data and the topogram image data and wherein artifact-affected subregions are determined based upon reconstructed, uncorrected image data, assigned to the potential subregions determined. 15. The method of claim 1 , wherein with an internal data transmission between an image data reconstruction device used to reconstruct the artifact-reduced image data and an image display device per image display, only one data record, including the artifact-reduced image data, is transmitted. 16. A non-transitory memory storing a computer program, directly loadable into a computing unit of a computed tomography system, including program portions to carry out the method of claim 1 when the computer program is executed in the computing unit. 17. A non-transitory computer-readable medium storing executable program portions, configured to be executable by a computer unit to carry out the method of claim 1 when the program portions are executed by the computer unit. 18. The method of claim 1 , wherein, in generating the artifact-reduced image data, only the uncorrected image data from artifact-free subregions is used. 19. An image data reconstruction device, comprising: an input interface to acquire projection measurement data of an examination region of an examination object; a reconstruction unit to reconstruct uncorrected image data based upon the projection measurement data; a subregion determination unit to determine artifact-affected subregions of the examination region based upon uncorrected image data; a correction unit to carry out an artifact-reduced image reconstruction in the artifact-affected subregions of the examination region, only artifact-reduced subimage data of the artifact-affected subregions being generated; and an image generation unit to generate artifact-reduced image data of an entirety of the examination region by combining at least one part of the uncorrected image data and the artifact-reduced subimage data, wherein the uncorrected image data includes at least one of topogram image data and real-time image data, used in determining whether or not to perform an artifact-affected reconstruction and wherein, after reconstruction to generate the artifact-reduced image data, uncorrected image data is buffered only after a determination that artifact reduction is necessary. 20. A computed tomography system, comprising: a scanner unit to capture a region, to be examined, of an examination object; a control device to control the scanner unit; and the image data reconstruction device of claim 19 . 21. An image data reconstruction device, comprising: an input interface to acquire projection measurement data of an examination region of an examination object; and a processor, configured to reconstruct uncorrected image data based upon the projection measurement data, determine art