Abstract: A system for performing magnetic resonance tomography is disclosed. A control system creates a speech data stream from an acquired linguistic expression and generates a command library, which contains a selection of speech commands, to each of which one or more linguistic expressions are assigned. The selection of speech commands is loaded from a command database depending on a current system status of a magnetic resonance (MR) scanner. The control system applies a speech recognition algorithm to the speech data stream to determine whether a linguistic expression contained in the command library can be assigned to the speech data stream. If so, the acquired linguistic expression is recognized, a speech command from the command library assigned to the recognized linguistic expression is established, and a control command for controlling the MR scanner in accordance with the speech command is created.

Abstract: In a method and apparatus for identifying an organ structure of an examined object in magnetic resonance image data, magnetic resonance measurement data for the organ structure of the examined object are acquired by operation of a magnetic resonance scanner using a magnetic resonance sequence that specifies a sampling scheme of k-space. Magnetic resonance image data are reconstructed from the magnetic resonance measurement data. The organ structure is identified in the magnetic resonance image data. The sampling scheme of k-space is selected so as to support the subsequent identification of the organ structure in the magnetic resonance image data reconstructed from the magnetic resonance measurement data.

Abstract: Techniques are disclosed for preparing a repeat intervention on the skin of a patient. This may include acquiring first image data of an intervention region during a first intervention on the skin of the patient. At least two landmarks may be identified on the skin of the patient on the basis of the acquired first image data. A position of the first intervention is then determined with the aid of the landmarks as reference points. In addition, the position of the first intervention and of the landmarks may be stored in a data memory unit. A position of the second intervention is subsequently localized on the basis of the stored position and of the at least two landmarks.

Abstract: A magnetic resonance tomograph and a method for tracking a marker in an examination subject by a magnetic resonance tomograph are disclosed. The magnetic resonance tomograph includes a first image recording mode for acquiring the position of the marker. In one act of the method, data for acquiring the position of the marker is recorded with the first image recording mode. In a further act, a position of the marker is determined from the data and a first image with a location-accurate reproduction of the marker is prepared. The recording of the data for acquiring the position of the marker takes place depending on an event.

Abstract: In a method and apparatus for visualizing the position of a medical object in a body of an examination object, a stack of sectional images through the body, acquired by operation of a magnetic resonance imaging system, is provided to a processor, which implements sectional-image-specific pixel coding of the sectional images. This is followed by the creation of a combination image composed of a combination of a number of coded sectional images from the stack, and representation of the combination image.

Abstract: In a method and magnetic resonance (MR) apparatus for monitoring an interventional procedure with an intervention tool in a vessel of an examination subject, the intervention tool is moved in an insertion direction in the vessel and the position of a front end of the intervention tool in the insertion direction is determined. A first volume segment is determined dependent on the position and the flow direction of a fluid within the vessel. An RF saturation pulse is radiated into the first volume segment that saturates nuclear spins in the fluid within the first volume segment. MR data are acquired in a second volume segment, which contains the front end of the intervention tool and a region in front of the intervention tool in the insertion direction. An MR image is generated from the acquired MR data.

Abstract: A method for post processing and displaying a three-dimensional angiography image data set of a blood vessel tree of a patient, wherein two-dimensional display images are rendered from the angiography image data set and displayed, wherein two display images are rendered from the angiography image data set using viewing directions forming an angle suited for stereoscopic perception of the display images and both display images are simultaneously displayed on a display screen in a display presentation that causes each display image to be viewed by one eye of a person viewing the display screen.

Abstract: Techniques are disclosed for preparing a repeat intervention on the skin of a patient. This may include acquiring first image data of an intervention region during a first intervention on the skin of the patient. At least two landmarks may be identified on the skin of the patient on the basis of the acquired first image data. A position of the first intervention is then determined with the aid of the landmarks as reference points. In addition, the position of the first intervention and of the landmarks may be stored in a data memory unit. A position of the second intervention is subsequently localized on the basis of the stored position and of the at least two landmarks.

Abstract: A magnetic resonance facility is operated by an external control device. The magnetic resonance facility includes an interface for communicating with the external control device and establishes a communications link between the external control device and the magnetic resonance facility via the interface, acquire an instruction from the external control device via the interface, and carries out the instruction on the magnetic resonance facility.

Abstract: In a method, computer and magnetic resonance imaging system for determining a control sequence for operating the magnetic resonance imaging system to generate magnetic resonance image data of a region to be imaged of an examination subject, from which magnetic resonance raw data are acquired, information describing the anatomical structure of the region to be imaged is made available in the computer, and a surrounding area and a central area are specified in the region to be imaged dependent on the determined anatomical structure. Furthermore, a one-dimensional water/fat saturation pulse sequence for saturating the surrounding areas is determined and a multidimensional water/fat saturation pulse sequence for saturating the central area is determined.

Abstract: In a method and magnetic resonance (MR) apparatus for monitoring an interventional procedure with an intervention tool in a vessel of an examination subject, the intervention tool is moved in an insertion direction in the vessel and the position of a front end of the intervention tool in the insertion direction is determined. A first volume segment is determined dependent on the position and the flow direction of a fluid within the vessel. An RF saturation pulse is radiated into the first volume segment that saturates nuclear spins in the fluid within the first volume segment. MR data are acquired in a second volume segment, which contains the front end of the intervention tool and a region in front of the intervention tool in the insertion direction. An MR image is generated from the acquired MR data.

Abstract: In a method and magnetic resonance (MR) apparatus for recording MR signals in a recording volume of an examination object with an imaging sequence, the recording volume has a first recording region in which at least one system component of the scanner of the MR apparatus has a first homogeneity, which is greater than a homogeneity of the at least one scanner component in a second recording region of the recording volume. A magnetization of nuclear spins in the recording volume is produced by at least one RF pulse, with the RF pulse being determined such that the magnetization produced in the first recording region by the at least one RF pulse is greater than magnetization produced in the second recording region by the at least one RF pulse.

Abstract: In order to determine the position of a reception coil in a magnetic resonance (MR) scanner of an MR apparatus, wherein the instrument has a reception coil, MR data are acquired from the reception coil along one direction in the scanner, and are provided to a processor that determines a position specification from the acquired MR data. The processor determines the position specification by initially executing a training period, using a first position specification establishment method, in order to produce a training period dataset, and then the training period dataset is used to establish a final position specification with a second position specification establishment method that differs from the first position specification establishment method.

Abstract: In a method and apparatus for visualizing the position of a medical object in a body of an examination object, a stack of sectional images through the body, acquired by operation of a magnetic resonance imaging system, is provided to a processor, which implements sectional-image-specific pixel coding of the sectional images. This is followed by the creation of a combination image composed of a combination of a number of coded sectional images from the stack, and representation of the combination image.

Abstract: A magnetic resonance system that is designed to carry out an examination of an examination object, and has an RF controller, a gradient controller and an image sequence controller, which are designed to acquire MR data of a volume portion of the examination object. An arithmetic unit of the magnetic resonance system is designed to reconstruct MR images from the acquired MR data. A standardized REST-based HTTP radio interface of the magnetic resonance system is designed to establish a standardized wireless connection to at least one external device.

Abstract: In a computer-implemented method for scheduling customer appointments in one or more service centers, wherein at least some of the customers was a mobile device having a location tracking function and a message transmission function, a central appointments scheduling system manages customer appointments, which has assigned an available time window to at least one customer. A default of a customer appointment of a first customer is recorded. The position of at least one second customer, whose available time window overlaps with the defaulted customer appointment, is detected through the use of the location tracking function of the mobile device and communication of the position to the central appointments scheduling system. The expected travel time of the second customer to the service center is calculated and, if the travel time is shorter than the time remaining up to the start time of the defaulted appointment, an offer is sent to the second customer to accept the defaulted appointment.

Abstract: In a method and apparatus for identifying an organ structure of an examined object in magnetic resonance image data, magnetic resonance measurement data for the organ structure of the examined object are acquired by operation of a magnetic resonance scanner using a magnetic resonance sequence that specifies a sampling scheme of k-space. Magnetic resonance image data are reconstructed from the magnetic resonance measurement data. The organ structure is identified in the magnetic resonance image data. The sampling scheme of k-space is selected so as to support the subsequent identification of the organ structure in the magnetic resonance image data reconstructed from the magnetic resonance measurement data.

Abstract: In a method and magnetic resonance apparatus for determination of radio-frequency pulses, a time-parallel transmission of a radio-frequency pulse influences the transverse magnetization of an object under examination in a specified spatial region. The spatial region is depicted as a vector and approximated by decomposition into a finite number of weighted basis functions of the decomposition. As a result, the length of the approximated vector is less than the length of the original vector. The radio-frequency pulse is determined as a function of the approximated vector. This method can be used to determine a multichannel RF pulse.

Abstract: In a method and apparatus for planning and/or controlling a medical imaging examination using a mobile terminal, a data connection is established between a medical imaging apparatus and the mobile terminal by a data network unit. Examination-specific data are transmitted to the mobile terminal. A command-relevant input is detected by at least one sensor of the mobile terminal. A planning command and/or a control command is generated in the mobile terminal on the basis of the detected signal and as a function of the examination-specific data. The planning command and/or control command is/are transmitted to a control computer of the medical imaging apparatus. The planning command and/or control command is/are executed by the control computer in order to plan and/or control the medical imaging examination.

Abstract: A method for determining a current remaining time during a measurement for the purpose of medical imaging, an evaluation unit, a medical imaging device, and a computer program product are provided. The method provides for a permitted operating range and an item of extrapolation information regarding the critical event to be provided. The current remaining time is determined by an evaluation unit based on the permitted operating range and the item of extrapolation information.