Although ultra-short TE spectroscopy sequences enhance the information content of the spectrum, they are, in their nature, prone to quantification biases if the macromolecular (MM) components are not taken into account The aim of this study, was to 1) perform macromolecule mapping at 9.4T using an ultra-short TE double-inversion recovery (DIR) MRSI sequence, 2) model and parametrize the individual MM components, and 3) extract high resolution maps of individual MM components using the modelled MM basis set
Purpose Reliable detection and fitting of macromolecules (MM) are crucial for accurate quantificatio...
Macromolecular signals are crucial constituents of short echo-time 1 H MR spectra with potential cli...
Purpose: Ultrahigh field MRS has improved characterization of the neurochemical profile. To compare ...
Although ultra-short TE spectroscopy sequences enhance the information content of the spectrum, they...
AbstractLong echo time (TE) MR spectroscopy (MRS) sequences are sensitive only to metabolites of low...
Purpose/Introduction: At ultra-short TE and TR, macromolecule quantification becomes extremely impor...
Short TE MRS and very short TR (TR < 300) MRSI are popular methods to capture snapshots of the neuro...
Magnetic resonance spectroscopic imaging (MRSI) is a promising technique for mapping the spatial dis...
Purpose Macromolecular resonances (MM) arise mainly from cytosolic proteins and overlap with metabol...
From the literature it is clear that information on the macromolecular baseline can contain valuable...
In order to determine the T1 relaxation times of the metabolites in human brain including the ones t...
1H MRSI is a powerful technique for mapping the spatial distribution of metabolites in the human bod...
Purpose/Introduction: Macromolecular resonances (MM) arise mainly from cytosolic proteins overlappin...
1H MRSI is a powerful technique for mapping the spatial distribution of metabolites in the human bod...
Purpose: Macromolecular peaks underlying metabolite spectra influence the quantification of metaboli...
Purpose Reliable detection and fitting of macromolecules (MM) are crucial for accurate quantificatio...
Macromolecular signals are crucial constituents of short echo-time 1 H MR spectra with potential cli...
Purpose: Ultrahigh field MRS has improved characterization of the neurochemical profile. To compare ...
Although ultra-short TE spectroscopy sequences enhance the information content of the spectrum, they...
AbstractLong echo time (TE) MR spectroscopy (MRS) sequences are sensitive only to metabolites of low...
Purpose/Introduction: At ultra-short TE and TR, macromolecule quantification becomes extremely impor...
Short TE MRS and very short TR (TR < 300) MRSI are popular methods to capture snapshots of the neuro...
Magnetic resonance spectroscopic imaging (MRSI) is a promising technique for mapping the spatial dis...
Purpose Macromolecular resonances (MM) arise mainly from cytosolic proteins and overlap with metabol...
From the literature it is clear that information on the macromolecular baseline can contain valuable...
In order to determine the T1 relaxation times of the metabolites in human brain including the ones t...
1H MRSI is a powerful technique for mapping the spatial distribution of metabolites in the human bod...
Purpose/Introduction: Macromolecular resonances (MM) arise mainly from cytosolic proteins overlappin...
1H MRSI is a powerful technique for mapping the spatial distribution of metabolites in the human bod...
Purpose: Macromolecular peaks underlying metabolite spectra influence the quantification of metaboli...
Purpose Reliable detection and fitting of macromolecules (MM) are crucial for accurate quantificatio...
Macromolecular signals are crucial constituents of short echo-time 1 H MR spectra with potential cli...
Purpose: Ultrahigh field MRS has improved characterization of the neurochemical profile. To compare ...