Abstract: In a magnetic resonance apparatus and an operating method therefore, a data acquisition sequence for operating the apparatus is repeatedly reviewed in a number of ascertainment passes executed in a processor, each ascertainment pass involving a calculation step, and in each calculation step a determination is made as to other respective values of data elements used in a previous calculation step have changed. If no change has occurred, a re-calculation in the current calculation step is not implemented, thereby reducing the time and computing capacity that are needed to generate a final data acquisition sequence.

Abstract: A magnetic resonance (MR) method and apparatus use simultaneous multislice imaging, with different excitations being effective for different slices in respective iterations of a single scanning sequence, in order to acquire raw MR data from different multiple slices, with respectively different contrasts, in the single scanning sequence. Single band excitation of a first slice among the multiple slices takes place in a first iteration of the single scanning sequence, with multi-band excitation then occurring for all of the multiple slices. Raw data are then acquired from the first slice, and at least one other slice among the multiple slices, that respectively exhibit different contrasts due to only the first slice being affected by the single band excitation. In a second iteration of the single scanning sequence, another slice is excited with single band excitation, and the first slice is among the multiple slices excited with multi-band excitation.

Abstract: A method is provided for recording, with a magnetic resonance device, magnetic resonance data of a target region of a patient moved by their breathing. An optical camera arranged in a bore of the magnetic resonance device directed onto the patient is used. Image data of the patient recorded by the camera before and/or during the recording of the magnetic resonance data is evaluated to form breathing information describing the breathing state and the breathing information is used for triggering and/or movement correction and/or assessment of a process in which a patient holds their breath.

Abstract: A method for the simultaneous reception of magnetic resonance signals from two or more slices, a magnetic resonance apparatus, and a computer program product are provided. The method includes exciting first magnetic resonance signals of at least one first slice at a first excitation time. Further magnetic resonance signals of at least one further slice are excited at a further excitation time. The first and the further magnetic resonance signals are received simultaneously at one reception time.

Abstract: In a method for a direct positioning of a region of interest of a patient inside a basic field magnet of a canner of a magnetic resonance imaging apparatus, a patient is positioned on a patient table, and at least one local RF-coil is positioned on or close to the patient on a region of interest that is to be examined. A distance between the position of the at least one local RF-coil and the isocenter of the basic field magnet is determined. The local RF-coil together with the patient table is moved automatically along the z-direction for at least the determined distance, so that a center of the local RF-coil is in or at least at the z-position of the isocenter.

Abstract: A monitoring method and system for monitoring a magnetic resonance apparatus having a scanner with an examination region, a video camera obtains images from an acquisition region that includes at least one of accesses to the examination room in which the scanner is situated, and a region upstream of the examination region. The images are evaluated in a processor to determine whether an alarm condition, which is different from only detecting a person, is met. When the alarm condition is met, the processor causes an alarm to be emitted that is perceptible within the examination room.

Abstract: A method for adapting activation parameters used to generate a pulse sequence when activating a magnetic resonance system is provided. The method includes determining stimulation values for the pulse sequence based on predefined activation parameters. The stimulation values represent a stimulation exposure of a patient. Test regions that exhibit stimulation maxima are identified in the pulse sequence, and the identified test regions are tested with respect to compliance with a predefined stimulation limit value.

Abstract: In a magnetic resonance (MR) imaging apparatus and control method therefor, multiple frequency spectra of a material of the examination object are detected using at least one radio-frequency coil of and MR scanner, the coil having a number of coil elements and at least two of the frequency spectra are detected individually detected by respective, different coil elements. A number of resonant frequencies of at least one molecule in the material are established in the number of frequency spectra. Control information is formulated based on the number of resonant frequencies. The magnetic resonance scanner is controlled using the control information.

Abstract: In order to provide an effective optimization of a magnetic resonance sequence, particularly with regard to optimizing the slew rates of gradient switching sequences of the magnetic resonance sequence, in a method for optimizing a magnetic resonance sequence of a magnetic resonance apparatus, wherein the magnetic resonance sequence includes multiple pre-set gradient switching sequences with multiple pre-set slew rates, the multiple pre-set slew rates are provided to a computer wherein the multiple pre-set slew rates are evaluated. At least one optimization measure for the magnetic resonance sequence is defined based on the evaluation of the multiple pre-set slew rates. The magnetic resonance sequence is optimized based on the at least one pre-set optimization measure, wherein the optimized magnetic resonance sequence has multiple optimized gradient switching sequences with multiple optimized slew rates, and the multiple optimized slew rates being optimized in relation to the multiple pre-set slew rates.

Abstract: In a method and magnetic resonance apparatus for reconstructing an MR image of a volume segment within an examination object, MR data within the volume segment are acquired according to a separation method by MR data for a k-space line being acquired respectively in steps while a readout gradient is activated in the same readout direction. An image of a first substance and an image of a second substance are thereby reconstructed. A shift length, by which the image of the first substance and the image of the second substance are displaced relative to one another due to the chemical shift in the readout direction is determined. The image of the first substance and/or the image of the second substance is shifted as a function of the shift length, to compensate for the relative displacement between the images of the first and second substances in the readout direction due to the chemical shift. An MR image is generated by combining the images of the first and second substances.

Abstract: In a magnetic resonance apparatus and an operating method therefor, an MR image data record is provided to a computer, wherein at least one image of the magnetic resonance image data record is distorted. The computer generates a selection symbol for selecting a measurement volume, wherein the selection symbol is distorted so as to have a rectangular cross section after a distortion correction, and superimposing the selection symbol onto an image of the magnetic resonance image data record.

Abstract: A magnetic resonance imaging method and imaging device are disclosed. The magnetic resonance imaging method includes dividing the current slab of an imaging region into an initial number of detection sub-slabs, and expanding the encoded thickness of each detection sub-slab according to a predetermined initial expansion factor, subjecting each expanded detection sub-slab to deformation detection using the first fast spin echo sequence, and determining the position of each imaging sub-slab of the current slab and an expansion factor corresponding to each imaging sub-slab, wherein the readout gradient of the first fast spin echo sequence is applied in the direction of the slice selection gradient, expanding the encoded thickness of each imaging sub-slab of the current slab of the imaging region on the basis of the determined position of each imaging sub-slab and the corresponding expansion factor, and performing an imaging scan of each expanded imaging sub-slab using a second fast spin echo sequence.

Abstract: A method for generating a spatially resolved magnetic resonance dataset using a coil arrangement includes providing at least one correction datum based on receiver characteristics of the coil arrangement. The method also includes providing a magnetic resonance dataset with spatially resolved signal intensity data, and correcting the at least one signal intensity datum in the magnetic resonance dataset by the correction datum before or after providing the magnetic resonance dataset.

Abstract: In a method and apparatus for detecting magnetic resonance (MR) data a slice is slice-selectively excited followed by irradiation of a refocusing pulse and activation of first and second phase encoding gradients, and a readout gradient, in order to read out MR data that are entered into a line of k-space. MR data for further multiple lines of k-space are acquired without the first phase encoding gradient being activated again, and follow radiation of another refocusing pulse.

Abstract: A method for operating a magnetic resonance apparatus by a safety unit, taking into account persons fitted with an implant, a safety unit, a safety system, a magnetic resonance apparatus, and a computer program product are provided. The magnetic resonance apparatus includes a first part and a second part. The first part is operated separately from the second part and includes the safety unit. During an examination of a person fitted with an implant, the safety unit checks that the magnetic resonance apparatus, in a restricted operating mode, is complying with implant-conformant limit values.

Abstract: In a method and apparatus for generating a magnetic resonance (MR) image MR data are acquired from a subject as datasets in parallel with multiple RF coils, with first parallel dataset being acquired with a first parameter set and at least one further parallel dataset being acquired with a second parameter set. A first intermediate image dataset and at least one further intermediate image dataset are reconstructed with at least one of (a) the first intermediate image dataset being reconstructed from said first parallel dataset using a calibration data item derived from said at least one further parameter set, and (b) said at least one further intermediate image dataset is reconstructed from said at least one further parallel dataset using a calibration data item derived from said first parameter set. A combination image dataset is generated by combining said first intermediate image dataset and said at least one further intermediate dataset.

Abstract: A method for recording a magnetic resonance data set relating to a region that is moved at least partly and periodically includes prompting a trigger signal. The method also includes emitting a saturation pulse to at least partially saturate magnetization of an examination region as a function of the trigger signal.

Abstract: In a method and magnetic resonance (MR) scanner for acquiring an MR data set of multiple slices of a volume of interest of an examination object (patient), on receipt of a trigger signal relating to the patient's respiration and indicating the start of an acquisition time window, a fat saturation technique is begun and, in one of a number of acquisition blocks having a number of echo trains each relating to a single slice and a single portion of k-space, wherein all the echo trains of each individual acquisition block relate to different slices, magnetic resonance data for the different slices are acquired. A magnetic resonance image of each slice is determined for that slice by combining magnetic resonance data acquired in different acquisition blocks and relating to a portion of k-space. For at least two of the acquisition blocks, a different sequence of the slices to be acquired by the echo trains is used within the acquisition block.

Abstract: In a magnetic resonance facility and operating method for acquiring image data of a patient in a manner defined by acquisition parameters, the acquisition of the image data is preceded by the performance of at least one alignment operation for adjusting operating parameters of the magnetic resonance facility that influence acquisition conditions for the current patient. At least one result data item describing the result of the alignment used for an at least partially automatic determination of at least one acquisition parameter not relating to the pulse shape of a radio-frequency pulse to be used during the acquisition.

Abstract: In a method and magnetic resonance (MR) apparatus for creating a maximum intensity projection of a volume of an examination subject, MR data are acquired for a number of slices of the volume, and an MR image is reconstructed for each of the slices that MR data have acquired in order to create a maximum intensity projection for each of the slices. The maximum intensity projection of the respective slice is shown on a display. The slices, which have a thickness of at least 15 mm, have various slice directions, in order to display the maximum intensity projections from various directions.