Adaptive water-fat shift in non-Cartesian magnetic resonance imaging

The invention claimed is: 1. A medical system comprising: a memory storing configured to store machine executable instructions; a computational system, wherein execution of the machine executable instructions causes the computational system to: receive initial pulse sequence commands, wherein the initial pulse sequence commands are configured for controlling a magnetic resonance imaging system to acquire k-space data following a non-Cartesian k-space sampling pattern, wherein the initial pulse sequence commands are configured for controlling the magnetic resonance imaging system to sample the non-Cartesian k-space sampling pattern by repeatedly sampling a Cartesian k-space sampling pattern that is rotated for each acquisition, wherein the non-Cartesian k-space sampling pattern has an effective water-fat shift direction being representative for the direction in which the water-fat shift occurs; receive a chosen water-fat shift direction; and construct modified pulse sequence commands by rotating the non-Cartesian k-space sampling pattern such that the effective water-fat shift direction is aligned with the water-fat shift direction. 2. The medical system of claim 1 , wherein the Cartesian sampling pattern has a readout direction, wherein the modified pulse sequence commands comprise readout gradient commands for each rotation of the Cartesian k-space sampling pattern, wherein each rotation of the Cartesian k-space sampling pattern has a spatial water-fat shift, wherein execution of the machine executable instructions further causes the computational system to modify the readout gradient commands to cause a reduction in the spatial water-fat shift as the Cartesian k-space sampling pattern is rotated away from the chosen water-fat shift direction. 3. The medical system of claim 2 , wherein the spatial water-fat shift is decreased as the Cartesian k-space sampling pattern is rotated away from the chosen water-fat shift direction by applying a view angle tilting gradient during the readout gradient commands. 4. The medical system of claim 3 , wherein the view angle tilting gradient is a variable amplitude view angle tilting gradient, wherein an amplitude of the variable view angle tilting gradient increases as the Cartesian k-space sampling pattern is rotated away from the chosen water-fat shift direction. 5. The medical system of claim 2 , wherein the spatial water-fat shift is decreased as the Cartesian k-space sampling pattern is rotated away from the chosen water-fat shift direction by modifying the readout gradient commands to reduce an acquisition voxel size in the readout direction of the Cartesian k-space sampling pattern. 6. The medical system of claim 2 , wherein execution of the machine executable instructions further causes the computational system to determine the effective water-fat direction by averaging the readout direction for each rotation of the Cartesian k-space sampling pattern. 7. The medical system of claim 1 , wherein gradient encodings during read-out are adapted to decrease the spatial water-fat shift s with the rotating away from the chosen water-fat shift direction of the Cartesian k-space sampling pattern away. 8. The medical system of claim 7 , wherein the spatial water-fat shift is decreased as the Cartesian k-space sampling pattern is rotated away from the chosen water-fat shift direction by modifying the readout gradient commands to have an increasing bandwidth. 9. The medical system of claim 8 , wherein the increasing bandwidth is caused by increasing an amplitude of the readout gradient commands while decreasing a duration of the readout gradient commands. 10. The medical system of claim 1 , wherein the medical system further comprises a magnetic resonance imaging system, wherein execution of the machine executable instructions further causes the computational system to: acquire the k-space data by controlling the magnetic resonance imaging system with the modified pulse sequence commands, and reconstruct magnetic resonance imaging data from the k-space data. 11. The medical system of claim 10 , wherein the magnetic resonance imaging system comprises multiple receive channels, wherein the modified pulse sequence commands are according to a parallel imaging magnetic resonance imaging protocol, wherein the pulse sequence commands are configured to control the magnetic resonance imaging system to acquire k-space data for each of the multiple receive channels, wherein execution of the machine executable instructions further causes the computational system to repeatedly reconstruct channel magnetic resonance images from the k-space data for each of the multiple receive channels, wherein the magnetic resonance imaging data is reconstructed from the channel magnetic resonance images according to the parallel imaging magnetic resonance imaging protocol. 12. The medical system of claim 1 , wherein the modified pulse sequence commands are configured to reconstruct the k-space data according to an iterative compressed sensing algorithm, wherein the iterative compressed sensing algorithm is applied to the entire k-space data or for k-space data acquired for each rotation of the Cartesian k-space sampling pattern. 13. The medical system of claim 1 , wherein the Cartesian k-space sampling pattern is any one of the following: a k-space line and a blade of k-space lines. 14. A computer program comprising machine executable instructions stored on a non-transitory computer readable medium for execution by a computational system, wherein execution of the machine executable instructions causes the computational system to: receive initial pulse sequence commands, wherein the initial pulse sequence commands are configured for controlling a magnetic resonance imaging system to acquire k-space data following a non-Cartesian k-space sampling pattern, wherein the initial pulse sequence commands are configured for controlling the magnetic resonance imaging system to sample the non-Cartesian k-space sampling pattern by repeatedly sampling a Cartesian k-space sampling pattern that is rotated for each acquisition, wherein the non-Cartesian k-space sampling pattern has an effective water-fat shift direction being representative for the direction in which the water-fat shift occurs; receive a chosen water-fat shift direction; and construct modified pulse sequence commands by rotating the non-Cartesian k-space sampling pattern such that the effective water-fat shift direction is aligned with the water-fat shift direction. 15. A method of operating a medical system, wherein the method comprises: receiving initial pulse sequence commands, wherein the initial pulse sequence commands are configured for controlling a magnetic resonance imaging system to acquire k-space data following a non-Cartesian k-space sampling pattern, wherein the initial pulse sequence commands are configured for controlling the magnetic resonance imaging system to sample the non-Cartesian k-space sampling pattern by repeatedly sampling a Cartesian k-space sampling pattern that is rotated for each acquisition, wherein the non-Cartesian k-space sampling pattern has an effective water-fat shift direction being representative for the direction in which the water-fat shift occurs; receiving a chosen water-fat shift direction; and constructing modified pulse sequence commands by rotating the non-Cartesian k-space sampling pattern such that the effective water-fat shift direction is aligned with the chosen water-fat shift direction.