The need for T 2 correction on MRS‐based vertebral bone marrow fat quantification: implications for bone marrow fat fraction age dependence

Vertebral bone marrow fat quantification using single‐voxel MRS is confounded by overlapping water–fat peaks and the difference in T 2 relaxation time between water and fat components. The purposes of the present study were: (i) to determine the proton density fat fraction (PDFF) of vertebral bone marrow using single‐voxel multi‐TE MRS, addressing these confounding effects; and (ii) to investigate the implications of these corrections with respect to the age dependence of the PDFF. Single‐voxel MRS was performed in the L5 vertebral body of 86 subjects (54 women and 32 men). To reliably extract the water peak from the overlying fat peaks, the mean bone marrow fat spectrum was characterized based on the area of measurable fat peaks and an a priori knowledge of the chemical triglyceride structure. MRS measurements were performed at multiple TEs. The T 2 ‐weighted fat fraction was calculated at each TE. In addition, a T 2 correction was performed to obtain the PDFF and the T 2 value of water ( T 2w ) was calculated. The implications of the T 2 correction were investigated by studying the age dependence of the T 2 ‐weighted fat fractions and the PDFF. Compared with the PDFF, all T 2 ‐weighted fat fractions significantly overestimated the fat fraction. Compared with the age dependence of the PDFF, the age dependence of the T 2 ‐weighted fat fraction showed an increased slope and intercept as TE increased for women and a strongly increased intercept as TE increased for men. For women, a negative association between the T 2 value of bone marrow water and PDFF was found. Single‐voxel MRS‐based vertebral bone marrow fat quantification should be based on a multi‐TE MRS measurement to minimize confounding effects on PDFF determination, and also to allow the simultaneous calculation of T 2w , which might be considered as an additional parameter sensitive to the composition of the water compartment. Copyright © 2015 John Wiley & Sons, Ltd.