Abstract: In a method of performing magnetic resonance imaging and a magnetic resonance apparatus, first MR data are acquired of a region of interest of a subject in the absence of a B1 field. Second MR data are acquired of the region of interest in the presence of a B1 field, and within a short time interval after generation of the B1 field. The first and second MR data are processed to determine a B1 field map, and a T1 map is generated using the B1 field map. The T1 map is a B1 corrected T1 map. The first and second MR data 103, 109 may be acquired as part of a T1 mapping sequence, such as a MOLLI or SASHA type cardiac T1 mapping sequence.

Abstract: In a method for determining a complex sensitivity factor of an RF reception coil, which is part of an arrangement of a number of RF reception coils of a magnetic resonance scanner, which are operates to simultaneously acquire magnetic resonance spectroscopy data, FID signals from a volume of interest are acquired simultaneously with each of the RF reception coils, and one of the RF reception coils is designated as a reference coil and its FID signal is designated as a reference signal. A complex sensitivity factor for each other RF reception coil is determined by minimizing the differences between a number of data points of its FID signal, weighted with the complex sensitivity factor, and the corresponding data points of the FID signal of the reference coil.

Abstract: In a method and magnetic resonance (MR) apparatus for acquiring an MR signal from an examination subject according to a pulse sequence, a first radio-frequency pulse is applied with a first phase and a gradient field is simultaneously applied in a first direction. Second and third radio-frequency pulses, with second and third phases, respectively, are applied simultaneously with a gradient field in a second direction. A fourth and a fifth radio-frequency pulse, with a fourth and a fifth phase, respectively, are applied and simultaneously with a gradient field in a third direction. A signal with a receiver phase is acquired =. The pulse sequence is repeated a number of times under phase rotation, wherein the third and fourth radio-frequency pulses in each repetition have the same phase, and the signals acquired in the repetition are added.

Abstract: In a method and apparatus for generating magnetic resonance spectroscopy data from a VOI, in particular in the liver, image data are acquired from an examination area, which contains an organ affected by breathing, and the image data are evaluated until the position of the organ lies within a specific region. One or more of the eight acquisition cycles of an ISIS sequence are executed in order to acquire magnetic resonance spectroscopy data from the VOI, with repetitions until all eight acquisition cycles of the ISIS sequence have been executed. The magnetic resonance spectroscopy data acquired with the ISIS sequence are reconstructed to form a spectrum. The data acquisition has an ultra-short echo time.

Abstract: In a computerized method and apparatus to automatically determine an acquisition volume of an examination region for the acquisition of a magnetic resonance data set, at least one magnetic resonance image data set is acquired that at least partially images an examination region, and the magnetic resonance image data set is processed into at least one magnetic resonance image. The examination region is segmented and at least one envelope enclosing a segment is determined. At least one rectangle including the envelope is determined. The acquisition volume is calculated using the rectangle.

Abstract: In a method and magnetic resonance (MR) apparatus for acquiring MR signals from an examination object an RF excitation pulse is directed into the examination object while activating magnetic field gradients in two different spatial directions, such that a magnetization in the examination object in the two different spatial directions is limited by the RF excitation pulse and the switching of the magnetic field gradients. The magnetization is excited in one of the two spatial directions, of a slice selection direction, in a number of periodic layers, so MR signals are generated in the multiple periodic slices. The MR signals in the multiple periodic layers are read out using multiple reception coils of the MR scanner.

Abstract: In a method and apparatus for acquiring magnetic resonance image data, improved preparation of nuclear spins is achieved by radiating at least one inversion pulse, which acts site-selectively on at least one inversion pulse range, with the at least one inversion pulse range being situated at least partially outside the area under examination, radiation of at least one excitation pulse, read-out of magnetic resonance signals from the area under examination, and reconstruction of magnetic resonance image data from the read-out magnetic resonance signals, the magnetic resonance image data depicting the area under examination.

Abstract: In a method for determining a complex sensitivity factor of an RF reception coil, which is part of an arrangement of a number of RF reception coils of a magnetic resonance scanner, which are operates to simultaneously acquire magnetic resonance spectroscopy data, FID signals from a volume of interest are acquired simultaneously with each of the RF reception coils, and one of the RF reception coils is designated as a reference coil and its FID signal is designated as a reference signal. A complex sensitivity factor for each other RF reception coil is determined by minimizing the differences between a number of data points of its FID signal, weighted with the complex sensitivity factor, and the corresponding data points of the FID signal of the reference coil.

Abstract: In a method and apparatus for generating magnetic resonance spectroscopy data from a VOI, in particular in the liver, image data are acquired from an examination area, which contains an organ affected by breathing, and the image data are evaluated until the position of the organ lies within a specific region. One or more of the eight acquisition cycles of an ISIS sequence are executed in order to acquire magnetic resonance spectroscopy data from the VOI, with repetitions until all eight acquisition cycles of the ISIS sequence have been executed. The magnetic resonance spectroscopy data acquired with the ISIS sequence are reconstructed to form a spectrum. The data acquisition has an ultra-short echo time.

Abstract: In a method and magnetic resonance (MR) apparatus for acquiring an MR signal from an examination subject according to a pulse sequence, a first radio-frequency pulse is applied with a first phase and a gradient field is simultaneously applied in a first direction. Second and third radio-frequency pulses, with second and third phases, respectively, are applied simultaneously with a gradient field in a second direction. A fourth and a fifth radio-frequency pulse, with a fourth and a fifth phase, respectively, are applied and simultaneously with a gradient field in a third direction. A signal with a receiver phase is acquired =. The pulse sequence is repeated a number of times under phase rotation, wherein the third and fourth radio-frequency pulses in each repetition have the same phase, and the signals acquired in the repetition are added.

Abstract: In a computerized method and apparatus to automatically determine an acquisition volume of an examination region for the acquisition of a magnetic resonance data set, at least one magnetic resonance image data set is acquired that at least partially images an examination region, and the magnetic resonance image data set is processed into at least one magnetic resonance image. The examination region is segmented and at least one envelope enclosing a segment is determined. At least one rectangle including the envelope is determined. The acquisition volume is calculated using the rectangle.