Age and gender differences in lumbar intervertebral disk strain using mechanical loading magnetic resonance imaging

Abstract

AbstractThe objective of the current study was to investigate age‐ and gender‐related differences in lumbar intervertebral disk (IVD) strain with the use of static mechanical loading and continuous three‐dimensional (3D) golden‐angle radial sparse parallel (GRASP) MRI. A continuous 3D‐GRASP stack‐of‐stars trajectory of the lumbar spine was performed on a 3‐T scanner with static mechanical loading. Compressed sensing reconstruction, motion deformation maps, and Lagrangian strain maps during loading and recovery in the X‐, Y‐, and Z‐directions were calculated for segmented IVD segments from L1/L2 to L5/S1. Mean IVD height was measured at rest. Spearman coefficients were used to evaluate the associations between age and global IVD height and global IVD strain. Mann–Whitney tests were used to compare global IVD height and global IVD strain in males and females. The prospective study enrolled 20 healthy human volunteers (10 males, 10 females; age 34.6 ± 11.4 [mean ± SD], range 22–56 years). Significant increases in compressive strain were observed with age, as evidenced by negative correlations between age and global IVD strain during loading (ρ = −0.76, p = 0.0046) and recovery (ρ = −0.68, p = 0.0251) in the loading X‐direction. There was no significant correlation between age and global IVD height, global IVD strain during loading and recovery in the Y‐direction, and global IVD strain during loading and recovery in the Z‐direction. There were no significant differences between males and females in global IVD height and global IVD strain during loading and recovery in the X‐, Y‐, and Z‐directions. It was concluded that our study demonstrated the significant role aging plays in internal dynamic strains in the lumbar IVD during loading and recovery. Older healthy individuals have reduced IVD stiffness and greater IVD compression during static mechanical loading of the lumbar spine. The GRASP‐MRI technique demonstrates the feasibility to identify changes in IVD mechanical properties with early IVD degeneration due to aging.