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Abstract
State-of-the-art MR-PET scanners allow simultaneous data acquisition. However, image
reconstruction is performed separately and results are only combined at the visualization
stage. PET images are reconstructed using a variant of EM and MR data are reconstructed
using an inverse Fourier transform or iterative algorithms for parallel imaging or
compressed sensing. We propose a new iterative joint reconstruction framework based
on multi-sensor compressed sensing that exploits anatomical correlations between MR
and PET.
Joint reconstruction is motivated by the fact that MR and PET are based on the same
anatomy. High resolution MR information can be used to enhance the PET reconstruction
and MR artifacts are not present in the PET image. Therefore a dedicated reconstruction
can exploit the incoherence of artifacts in the joint space. Our approach uses a nonlinear
constrained optimization problem. In each iteration OSEM enforces data consistency
of the current solution with measured PET rawdata. An l1-norm based joint sparsity
term exploits anatomical correlations. MR data consistency is enforced with the MR
forward operator, consisting of coil sensitivity modulation and a (non-uniform) Fourier
transform. Data were acquired on a clinical 3T MR-PET unit (Siemens Biograph mMR).
10 mCi 18F-FDG were injected followed by a 60min list mode scan. 3D MP-RAGE was used
for MR data acquisition: TR=2300ms, TE=2.98ms, TI=900ms, FA=9°, acceleration factor
2, 24 ACS lines, 256 matrix, voxel size=1×1×1mm3, 192 slices.
Joint MR-PET reconstruction improves resolution in PET images when structures are
aligned with MR. PET signal information cannot be improved in regions showing no distinctive
MR contrast, but it is also not influenced falsely. The availability of simultaneously-acquired
MR and PET data will also enable incorporation of dynamic correlations and motion
correction into the joint reconstruction framework. We expect that this provides additional
enhancements to the information content of multimodality studies.
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