Removal of local field gradient artefacts in BOLD contrast imaging of head and neck tumours.

Monitoring of oxygenation in tumours is an important issue in predicting the success of anti-cancer treatments such as radiotherapy. Gradient echo (GE) imaging sequences can be used for monitoring changes in tumour blood flow and oxygenation. However, the application of this method in head and neck tumours is hampered by significant artefacts and losses of the MR signal near air-tissue interfaces. We investigated the usefulness of a gradient-echo slice excitation profile (GESEPI) sequence that should keep the oxygen contrast while recovering the signal loss caused by susceptibility artefacts. A tumour model was implanted in the neck and in the leg of mice. MR imaging was performed at 4.7 T. GE and GESEPI sequences were used for monitoring the blood oxygen level dependent (BOLD) contrast after carbogen breathing. The pO2 was also monitored in tumours using an OxyLite probe (Oxford Optronics). Using the tumours implanted in the leg, we found that the variations of signal intensity after carbogen breathing were similarin both sequences. In the tumour implanted in the neck, it was possible, using GESEPI sequences, to recover the signal loss caused by susceptibility artefacts and to monitor the effect of carbogen-induced changes in the tumour.

Multiple echo frequency-domain image contrast: improved signal-to-noise ratio and T2 (T2*) weighting.

Conventional T2- and T2*-weighted image contrasts are produced by waiting a TE period for the transverse magnetic resonance (MR) signals to decay to differentiate tissue types with distinct relaxation rates. Significant image signal-to-noise ratio (SNR) is compromised by this contrast-producing process. In this report, a multiple echo frequency-domain image contrast (MEFIC) method is presented. During the conventional TE period, a multiple echo train modulated by T2 or T2* decay is acquired. A third Fourier transform along the echo direction produces an image set with pixel signal intensity modulated by the spectrum of the decay curve. This method simultaneously enhances image contrast with a large increase in SNR. Experimental studies of cerebral vasogenic edema in immature rats and functional MR imaging studies of the human motor cortex have demonstrated that the MEFIC method produces superior image quality over conventional methods for generating T2- and T2* weighted images.

Removal of local field gradient artifacts in T2*-weighted images at high fields by gradient-echo slice excitation profile imaging.

Development of high magnetic field MRI techniques is hampered by the significant artifacts produced by B0 field inhomogeneities in the excited slices. A technique, gradient-echo slice excitation profile imaging (GESEPI), is presented for recovering the signal lost caused by intravoxel phase dispersion in T2*-weighted images. This technique superimposes an incremental gradient offset on the slice refocusing gradient to sample k-space over the full range of spatial frequencies of the excitation profile. A third Fourier transform of the initial two-dimensional image set generates an image set in which the artifacts produced by the low-order B0 inhomogeneity field gradients in the sample are separated and removed from the high-order microscopic field gradients responsible for T2* contrast. Application to high field brain imaging, at 3.0 T for human and at 9.4 T for immature rat imaging demonstrates the significant improvement in quality of the T2*-weighted contrast images.