Method and system for improving image contrast in fast driven equilibrium inversion recovery imaging

The invention claimed is: 1 . A magnetic resonance imaging (MRI) method for improving an MRI signal generated by a magnetization of interest when imaging an object placed in an examination volume of an MRI system, the method comprises the steps of: performing, by the MRI system, an MRI pulse sequence containing three consecutive radio frequency (RF) elements, namely, a first element being an inversion-recovery pulse sequence characterized by a time of inversion), a second element being an image-encoding pulse sequence starting at the time of inversion with an excitation RF pulse followed by at least one image-encoding gradient and at least one data sampling, the second element being followed by a third element, the third element being a modified driven-equilibrium (hereafter “mDE”) pulse sequence configured for achieving a conversion of a transverse magnetization component of the magnetization of interest into positive longitudinal magnetization, aligned with positive z-axis and B0-field direction; acquiring, by the MRI system, an MRI signal generated by the object and sampled by image readout blocks applied to the object by the MRI system during each repetition time; and reconstructing, from the MRI signal, an image of the object. 2 . The MRI method according to claim 1 , wherein the mDE pulse sequence ends by a phase shifted flip-back pulse characterized by a +90 degree flip angle. 3 . The MRI method according to claim 1 , wherein the first element is a STIR pulse sequence. 4 . The MRI method according to claim 1 , wherein the second element contains a single or multiple data samplings. 5 . The MRI method according to claim 1 , wherein the second element is a sequence configured for generating at least one multiple gradient or spin echo. 6 . The MRI method according to claim 1 , wherein the second element is a sequence configured for generating a combination of gradient and spin echoes. 7 . The MRI method according to claim 1 , wherein the second element is a turbo-spin-echo-based pulse sequence. 8 . A magnetic resonance imaging (MRI) system, comprising: a processor configured for carrying out the MRI method according to claim 1 . 9 . The MRI method according to claim 2 , wherein the phase shifted flip-back pulse is characterized by a 90° phase shift relative to a refocusing RF pulse, or non phase shifted relative to the excitation RF pulse, or 180° phase shift relative to a flip-back pulse of a driven-equilibrium pulse sequence. 10 . The MRI method according to claim 2 , wherein the mDE pulse sequence contains a first RF pulse temporally located in a middle of a time period separating a time at which the +90° phase shifted flip-back pulse is applied and a last time at which a magnetization was refocused. 11 . The MRI method according to claim 2 , wherein the mDE pulse sequence contains a first RF pulse that is a 180-degree RF pulse applied at a time equal to half an echo spacing after a last echo signal of an echo train, and the +90° flip-back pulse is applied at a time equal to half the echo spacing after the first 180-degree RF pulse.