Simultaneous motion correction and T1 estimation in quantitative T1 mapping: An ML restoration approach

In magnetic resonance imaging the spin-lattice relaxation time (T<sub>1</sub>) of tissues is estimated from a set of T<sub>1</sub>-weighted images. As the T<sub>1</sub> estimation is a voxel-wise estimation, correct alignment of the T<sub>1</sub>-weighted images is crucial for T<sub>1</sub> mapping. Therefore, to correct for motion, the T<sub>1</sub>-weighted images are often registered prior to the T<sub>1</sub> estimation. This two-step approach, however, does not provide an accurate motion detection due to the high dynamic contrast changes in the series of images. Moreover, interpolation effects during registration, propagate to the T<sub>1</sub> estimation. In this work, we propose a unified approach, where the motion estimation is integrated into the T<sub>1</sub> estimation procedure. The motion model parameters and T<sub>1</sub> parameters are jointly estimated using a Maximum Likelihood (ML) approach. Results on simulation and real data experiments show a substantial improvement in the precision and accuracy of the estimated T<sub>1</sub> map compared to the conventional two-step approach.

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