Interventional X-ray system with automatic iso-centering

The invention claimed is: 1. An interventional X-ray system, comprising: a processing unit, a table for receiving a patient, an X-ray image acquisition device having an X-ray source and an X-ray detector and at least one optical camera adapted for acquiring optical images of the patient received on the table and for providing optical image data to the processing unit, wherein the processing unit is adapted for segmenting an outline of a patient from a three-dimensional model, receiving acquired images from the at least one optical camera for determining an optical outline of the patient, registering the optical outline to the outline obtained in the segmentation and determining a translation vector representing a required movement of the table for aligning an anatomy of interest in the three-dimensional model with an iso-center of a rotational X-ray scan that will be performed. 2. The interventional X-ray system of claim 1 , wherein the at least one camera is mounted to a gantry, which is adapted for moving the camera around the table to provide different viewing directions. 3. The interventional X-ray system of claim 1 , wherein the X-ray image acquisition device is a C-arm system and wherein the at least one camera is mounted to a frame of the X-ray image acquisition device. 4. The interventional X-ray system of claim 1 , wherein the at least one optical camera comprises a first camera and a second camera, wherein the first camera and the second camera are mounted on a gantry with fixed positions relative to the table, such that their optical axes are at an angle to each other. 5. The interventional X-ray system of claim 1 , wherein obtaining the optical outline of the patient is conducted through reconstructing a three-dimensional depth map from the set of optical images. 6. The interventional X-ray system of claim 5 , wherein the three-dimensional model is based on a set of pre-interventional images. 7. The interventional X-ray system of claim 5 , wherein the three-dimensional model is a general patient model, which is adapted to the optical outline of the patient. 8. The interventional X-ray system of claim 7 , wherein the processing unit is adapted for generating an effective center of anatomy, which is a point between a center of anatomy of an organ of interest and a needle entrance point on the body of the patient. 9. The interventional X-ray system of claim 1 , further comprising a collision avoidance system, wherein the processing unit is adapted for minimizing the distance between the iso-center and the X-ray detector under avoiding a collision with the patient on the table. 10. The interventional X-ray system of claim 9 , wherein the processing unit is adapted for coinciding a center of the anatomy of interest given in the three-dimensional model with the iso-center of the rotational X-ray scan that will be performed for aligning the anatomy of interest. 11. Method for iso-centering a patient lying on a table to be examined by an interventional X-ray system, comprising: providing a three dimensional model of a patient to a processing unit, acquiring a plurality of optical images from at least one camera of the patient, segmenting the model to determine a segmented outline of the patient, determining, from the optical images, an optical outline of the patient, registering the optical outline to the segmented outline and determining a movement vector required for aligning an anatomy of interest in the three dimensional model with an iso-center for a rotational X-ray scan to be performed. 12. Method according to claim 11 , further comprising obtaining a depth map of the optical images for obtaining the optical outline of the patient. 13. A non-transitory computer-readable medium, in which a computer program for iso-centering an object of interest to be examined with an interventional X-ray system is stored which, when being executed by a processing unit, causes the processing unit to carry out the method of claim 11 . 14. A processing unit for iso-centering an object of interest to be examined with an X-ray image acquisition device, the processing unit comprising: a memory for storing a three-dimensional model of the object of interest, wherein the processing unit is adapted for segmenting an outline of a patient from the three-dimensional model and for determining an optical outline of the patient from a plurality of optical images acquired from different viewing angles, and wherein the processing unit is adapted for registering the optical outline to the outline obtained in the segmentation and for determining a translation vector representing a required movement for coinciding a center of an anatomy of interest given in the three-dimensional model with an iso-center of a rotational X-ray scan that will be performed. 15. An interventional X-ray system, comprising: an X-ray source and an X-ray detector mounted to a gantry configured to rotate the X-ray source and detector around an iso-center; a table configured to support a patient with anatomy of interest at the iso-center; at least one optical camera configured to generate optical image data of the patient supported on the table; one or more processors configured to: segment a patient model outline from a three-dimensional model, receive the optical image data from the at least one optical camera, determine an optical outline of the patient from the optical image data, register the optical outline to the patient model outline, determine a translation vector representing movement between the table and the gantry which aligns the anatomy of interest in the three-dimensional model with the iso-center, and control at least one of the gantry and the table in accordance with the translation vector. 16. The interventional X-ray system of claim 15 , wherein the gantry includes a C-arm. 17. The interventional X-ray system of claim 15 , wherein the one or more processors are further configured to: after controlling one of the gantry and the table in accordance with the translation vector, activate the X-ray source and the X-ray detector to generate diagnostic image data; reconstruct the diagnostic image data into a diagnostic image; and control a display device to display the diagnostic image.