Relaxometry and quantification in simultaneously acquired single and triple quantum filtered sodium MRI.

Purpose: Sodium imaging delivers valuable information about in vivo metabolism and pathophysiology. Image quantification can benefit the diagnosis and characterization of existing pathologies and the clinical course of a disease. An enhanced SISTINA sequence is proposed for sodium imaging and for the estimation of sodium tissue parameters for a 2-compartment model of the brain, such as relaxation times in intracellular space and tissue, intracellular volume fraction, and intracellular molar fraction. The aim of the research is to demonstrate how a 2-compartment model can be parameterized to sufficiently describe tissue sodium concentrations and dynamics by performing relaxometry with such a sequence.

Methods: Multiple quantum filtered sodium signals were detected using an enhanced SISTINA sequence (consisting of 3 consecutive RF pulses) by placing a readout train between the first and second RF pulse, and 1 after the third pulse. Semiautomatic segmentation using singular value decomposition and manual segmentation was applied to the images.

Results: Analysis was performed on 40 healthy volunteers in a 4T scanner, yielding bi-exponential relaxation times of brain tissue, intracellular sodium molar and volume fraction, intracellular sodium concentration, as well as sodium tissue concentration in the scope of a considered model. Two models with either purely mono-exponential or bi-exponential relaxing extracellular sodium were used with and without a potential contribution of triple quantum-filtered signal from extracellular space.

Conclusion: An estimation of relaxation properties and concentrations limited to the assumed model is possible from a single sequence. The achieved results agree well with those reported in literature.