OBJECTIVE: To provide a new approach to spectral quantification for magnetic resonance spectroscopic imaging (MRSI), incorporating both spatial and spectral priors. METHODS: A novel signal model is proposed, which represents the spectral distributions of each molecule as a subspace and the entire spectrum as a union of subspaces. Based on this model, the spectral quantification can be solved in two steps: 1) subspace estimation based on the empirical distributions of the spectral parameters estimated using spectral priors; and 2) parameter estimation for the union-of-subspaces model incorporating spatial priors. RESULTS: The proposed method has been evaluated using both simulated and experimental data, producing impressive results. CONCLUSION: The proposed union-of-subspaces representation of spatiospectral functions provides an effective computational framework for solving the MRSI spectral quantification problem with spatiospectral constraints. SIGNIFICANCE: The proposed approach transforms how the MRSI spectral quantification problem is solved and enables efficient and effective use of spatiospectral priors to improve parameter estimation. The resulting algorithm is expected to be useful for a wide range of quantitative metabolic imaging studies using MRSI.
OBJECTIVE: To provide a new approach to spectral quantification for magnetic resonance spectroscopic imaging (MRSI), incorporating both spatial and spectral priors. METHODS: A novel signal model is proposed, which represents the spectral distributions of each molecule as a subspace and the entire spectrum as a union of subspaces. Based on this model, the spectral quantification can be solved in two steps: 1) subspace estimation based on the empirical distributions of the spectral parameters estimated using spectral priors; and 2) parameter estimation for the union-of-subspaces model incorporating spatial priors. RESULTS: The proposed method has been evaluated using both simulated and experimental data, producing impressive results. CONCLUSION: The proposed union-of-subspaces representation of spatiospectral functions provides an effective computational framework for solving the MRSI spectral quantification problem with spatiospectral constraints. SIGNIFICANCE: The proposed approach transforms how the MRSI spectral quantification problem is solved and enables efficient and effective use of spatiospectral priors to improve parameter estimation. The resulting algorithm is expected to be useful for a wide range of quantitative metabolic imaging studies using MRSI.
Authors: B Michael Kelm; Frederik O Kaster; Anke Henning; Marc-André Weber; Peter Bachert; Peter Boesiger; Fred A Hamprecht; Bjoern H Menze Journal: NMR Biomed Date: 2011-04-28 Impact factor: 4.044
Authors: Lihong Tang; Yibo Zhao; Yudu Li; Rong Guo; Bryan Clifford; Georges El Fakhri; Chao Ma; Zhi-Pei Liang; Jie Luo Journal: Magn Reson Med Date: 2020-07-29 Impact factor: 4.668
Authors: Yudu Li; Yibo Zhao; Rong Guo; Tao Wang; Yi Zhang; Matthew Chrostek; Walter C Low; Xiao-Hong Zhu; Zhi-Pei Liang; Wei Chen Journal: IEEE Trans Med Imaging Date: 2021-11-30 Impact factor: 10.048