Method and magnetic resonance apparatus to generate a series of MR images to monitor a position of an interventional device

We claim as our invention: 1. A method to generate a series of magnetic resonance (MR) images in order to monitor a position of an interventional device located in an examination region within an examination subject, comprising: operating an MR data acquisition unit to acquire MR data from an examination region of an examination subject in which an interventional device is located, by executing a first MR data acquisition procedure that comprises: (a) activating at least two phase-coding gradients in respective, different spatial directions with a gradient coil system of said MR data acquisition unit, (b) after the activated phase-coding gradients reach full strength, radiating a non-slice-selective radio-frequency (RF) excitation pulse with an RF transmission antenna of said MR data acquisition unit, (c) following a time t 1 after the radiated RF excitation pulse, acquiring echo signals, resulting from nuclear spins excited by the radiated RF excitation pulse, with an RF reception antenna, and entering raw data points, representing said echo signals, into a memory representing k-space, along a radial k-space trajectory predetermined by the strength of the phase-coding gradients, k-space in said memory comprising an imaging area, corresponding to said examination region, and (d) repeating (a) through (c) with respectively different phase-coding gradients until a first region of k-space, dependent on t 1 , within said imaging area is filled with respective raw data points entered along respective radial k-space trajectories; operating said MR data acquisition unit to also acquire MR data from the examination region of the examination subject in which the interventional device is located, by executing a second MR data acquisition procedure that differs from said first MR data acquisition procedure, and making data entries of the MR data acquired in said second MR data acquisition procedure into a remainder of said imaging area in k-space, not covered by said first region, and comprising the center of k-space; in a computer, implementing a Fourier transformation of said raw data points in said first region and in said remainder of k-space to generate image data representing said examination region; repeating said operation of said MR data acquisition unit and said reconstruction of image data to generate multiple MR images of said examination region; and displaying said multiple MR images of said examination region at a monitor to allow visual determination therein of a current position of said interventional device. 2. A method as claimed in claim 1 comprising entering said raw data points in said remainder of k-space in said second MR data acquisition procedure according to a Cartesian arrangement. 3. A method as claimed in claim 1 comprising entering said raw data points into said remainder of k-space in said second MR data acquisition procedure according to a single point imaging method. 4. A method as claimed in claim 1 wherein said MR data acquisition unit exhibits a minimum switchover time between a transmission mode, in which said at least one RF excitation pulse is radiated, and a reception mode, in which said echo signals are detected, and setting said time t 1 to be equal to said minimum switchover time. 5. A method as claimed in claim 1 wherein radiating said at least one RF excitation pulse comprises radiating at least a first RF excitation pulse that produces at least one echo signal during which raw data points in said imaging region are acquired, and a second RF excitation pulse that produces echoes during which additional raw data points of said imaging region are acquired. 6. A method as claimed in claim 1 comprising activating said phase-coding gradients to cause said image data reconstructed from the acquired raw data points to be projection image data. 7. A method as claimed in claim 6 comprising activating said phase coding gradients to cause a projection direction of said projection image data to be parallel to or perpendicular to said interventional device in said examination region. 8. A method as claimed in claim 6 comprising activating said phase-coding gradients to cause a projection direction of said projection image data to proceed along a predetermined axis. 9. A method as claimed in claim 1 comprising generating and displaying at least one of said multiple MR images per second. 10. A method as claimed in claim 1 wherein said interventional device comprises an RF reception coil, and employing said RF reception coil as said reception coil to detect said raw data points from said echo signals. 11. A magnetic resonance (MR) apparatus to generate a series of MR images in order to monitor a position of an interventional device located in an examination region within an examination subject, comprising: an MR data acquisition unit in which an examination subject is located, said subject comprising an examination subject in which an interventional device is located; a control computer configured to operate said MR data acquisition unit to execute a first MR data acquisition procedure that comprises: (a) activation of at least two phase-coding gradients in respective, different spatial directions with a gradient coil system of said MR data acquisition unit, (b) after the activated phase-coding gradients reach full strength, radiation of a non-slice-selective radio-frequency (RF) excitation pulse with an RF transmission antenna of said MR data acquisition unit, (c) following a time t 1 after the radiated RF excitation pulse, acquisition of echo signals, resulting from nuclear spins excited by the radiated RF excitation pulse, with an RF reception antenna, and enter raw data points, representing said echo signals, into a memory representing k-space, along a radial k-space trajectory predetermined by the strength of the phase-coding gradients, k-space in said memory comprising an imaging area, corresponding to said examination region, and (d) repetition of (a) through (c) with respectively different phase-coding gradients until a first region of k-space, dependent on t 1 , within said imaging area is filled with respective raw data points entered along respective radial k-space trajectories; said control computer being configured to operate said MR data acquisition unit to also acquire MR data from the examination region of the examination subject in which the interventional device is located, by executing a second MR data acquisition procedure that differs from said first MR data acquisition procedure, and making data entries of the MR data acquired in said second MR data acquisition procedure into a remainder of said imaging area in k-space, not covered by said first region, and comprising the center of k-space; said control computer being configured to implement a Fourier transformation of said raw data points in said first region and in said remainder of k-space to generate image data representing said examination region; said control computer being configured to repeat said operation of said MR data acquisition unit and said reconstruction of image data to generate multiple MR images of said examination region; and a display monitor in communication with said control computer at which said control computer is configured to cause said multiple MR images of said examination region to be displayed in order to allow visual determination therein of a current position of said interventional device. 12. A non-transitory, computer-readable data storage medium encoded with programming instructions that, when said data storage medium is loaded into a computerized control and evaluation system of a magnetic resonance (MR) apparatus, which comprise