Abstract: An MRI apparatus includes: a data processor configured to acquire a first set of T2-weighted imaging data and a second set of T2-weighted imaging data; a pulse sequence controller configured to generate a pulse sequence and apply the generated pulse sequence to a gradient coil assembly and RF coil assembly, the generated pulse sequence including: T2-preparation modules and associated imaging modules to acquire the first set of T2-weighted imaging data, and a saturation pulse sequence and an associated saturation imaging module to acquire the second set of T2-weighted imaging data; a curve fitter configured to apply the first and second sets of T2-weighted imaging data to a three-parameter model for T2 decay, to determine a T2 value at a plurality of locations; and an image processor configured to generate a T2 map of the object based on the T2 value determined at the plurality of locations.

Abstract: A system and method for acquiring magnetic resonance imaging (MRI) images with an MRI system is provided. The system and method directs the MRI system first to produce an inversion recovery radio frequency (RF) pulse, wait for a time period, produce a T2-preparation RF pulse, wait for another time period, and then acquire data of a part of a subject. The first produced RF pulse rotates net magnetization 180 degrees about an axis. The pulse sequence used to acquire data can be any two-dimensional or three-dimensional sequence used to acquire a volume in the subject. The two waiting time periods are chosen such that the signals of two or more tissues of the subject are nulled.

Abstract: An MRI method includes performing a first image acquisition module of a pulse sequence to acquire a first MR data from slices disposed at different locations in a region of interest (ROI) of an object; performing a second image acquisition module of the pulse sequence, to acquire a second MR data from the slices disposed at the different locations of the ROI, with a T2 preparation time different than that of the first image acquisition module; and generating a T2 map based on the acquired first MR data and the acquired second MR data.

Abstract: A method and apparatus for reducing scan time, eddy currents and image factors in dynamic magnetic resonance (MR) imaging associated with at least a portion a k-space. The method includes scanning at least a portion of the k-space with an Echo-Planar Imaging (EPI) pulse sequence technique, acquiring a randomly under-sampled k-space; and reconstructing the under-sampled k-space utilizing a constrained reconstruction technique. A dynamic image is constructed of the at least a portion of the k-space based on EPI and the randomly undersampled k-space techniques to each segment of the EPI pulse sequence technique.

Abstract: A system and method for acquiring magnetic resonance imaging (MRI) images with an MRI system is provided. The system and method directs the MRI system first to produce an inversion recovery radio frequency (RF) pulse, wait for a time period, produce a T2-preparation RF pulse, wait for another time period, and then acquire data of a part of a subject. The first produced RF pulse rotates net magnetization 180 degrees about an axis. The pulse sequence used to acquire data can be any two-dimensional or three-dimensional sequence used to acquire a volume in the subject. The two waiting time periods are chosen such that the signals of two or more tissues of the subject are nulled.

Abstract: An MRI method includes performing a first image acquisition module of a pulse sequence to acquire a first MR data from slices disposed at different locations in a region of interest (ROI) of an object; performing a second image acquisition module of the pulse sequence, to acquire a second MR data from the slices disposed at the different locations of the ROI, with a T2 preparation time different than that of the first image acquisition module; and generating a T2 map based on the acquired first MR data and the acquired second MR data.

Abstract: An MRI apparatus includes: a data processor configured to acquire a first set of T2-weighted imaging data and a second set of T2-weighted imaging data; a pulse sequence controller configured to generate a pulse sequence and apply the generated pulse sequence to a gradient coil assembly and RF coil assembly, the generated pulse sequence including: T2-preparation modules and associated imaging modules to acquire the first set of T2-weighted imaging data, and a saturation pulse sequence and an associated saturation imaging module to acquire the second set of T2-weighted imaging data; a curve fitter configured to apply the first and second sets of T2-weighted imaging data to a three-parameter model for T2 decay, to determine a T2 value at a plurality of locations; and an image processor configured to generate a T2 map of the object based on the T2 value determined at the plurality of locations.

Abstract: A system and method for initiating a specific reconstruction or processing method is provided. After an MRI scan is completed, an operator of the MRI scanner can choose the processing to occur on the scanner machine or on a different remote station on the network or even on a central processing unit (CPU) cluster or graphics processing unit (GPU) server on the same network. During the processing, the server can connect with the remote processing workstation and update the progress of the operation. After finishing, the results may be automatically or manually retrieved from the remote processing unit and directly sent to the scanner database, where the results can be viewed and stored similar to images reconstructed by a vendor reconstruction system.

Abstract: A method and apparatus for reducing scan time, eddy currents and image factors in dynamic magnetic resonance (MR) imaging associated with at least a portion a k-space. The method includes scanning at least a portion of the k-space with an Echo-Planar Imaging (EPI) pulse sequence technique, acquiring a randomly under-sampled k-space; and reconstructing the under-sampled k-space utilizing a constrained reconstruction technique. A dynamic image is constructed of the at least a portion of the k-space based on EPI and the randomly undersampled k-space techniques to each segment of the EPI pulse sequence technique.