Nian Wang1, Yang Xia. 1. Department of Physics and Center for Biomedical Research, Oakland University, Rochester, MI 48309, USA.
Abstract
OBJECTIVE: To study the orientational dependencies of T(2) and T(1ρ) in native and trypsin-degraded bovine nasal cartilage, with and without the presence of 1 mM Gd-DTPA(2-). MATERIALS AND METHODS: Sixteen specimens were prepared in two orthogonal fibril directions (parallel and perpendicular), treated using different protocols (native, Gd treated, trypsin-treated, and combination), and imaged using μMRI at 0° and 55° (the magic angle) fibril orientations with respect to the magnetic field B(0). Two-dimensional (2D) T(2) and T(1ρ) images were then calculated quantitatively. RESULTS: Without Gd, native perpendicular tissues demonstrated significant T(1ρ) dispersion (including T(2) at the zero spin-lock field) at 0° and less dispersion at 55°, while native parallel specimens exhibited smaller T(1ρ) dispersion at both 0° and 55°. Trypsin degradation caused a minimum 50% increase in T(1ρ). With Gd, trypsin degradation caused significant reduction in T(1ρ) values up to 60%. CONCLUSION: The collagen orientation in nasal cartilage can influence T(2) and T(1ρ) MRI of cartilage. Without Gd, T(1ρ) was sensitive to the proteoglycan content and its sensitivity was nearly constant regardless of fibril orientation. In comparison, the T(2) sensitivity to proteoglycan was dependant upon fibril orientation, i.e., more sensitive at 55° than 0°. When Gd ions were present, both T(2) and T(1ρ) became insensitive to the proteoglycan content.
OBJECTIVE: To study the orientational dependencies of T(2) and T(1ρ) in native and trypsin-degraded bovinenasal cartilage, with and without the presence of 1 mM Gd-DTPA(2-). MATERIALS AND METHODS: Sixteen specimens were prepared in two orthogonal fibril directions (parallel and perpendicular), treated using different protocols (native, Gd treated, trypsin-treated, and combination), and imaged using μMRI at 0° and 55° (the magic angle) fibril orientations with respect to the magnetic field B(0). Two-dimensional (2D) T(2) and T(1ρ) images were then calculated quantitatively. RESULTS: Without Gd, native perpendicular tissues demonstrated significant T(1ρ) dispersion (including T(2) at the zero spin-lock field) at 0° and less dispersion at 55°, while native parallel specimens exhibited smaller T(1ρ) dispersion at both 0° and 55°. Trypsin degradation caused a minimum 50% increase in T(1ρ). With Gd, trypsin degradation caused significant reduction in T(1ρ) values up to 60%. CONCLUSION: The collagen orientation in nasal cartilage can influence T(2) and T(1ρ) MRI of cartilage. Without Gd, T(1ρ) was sensitive to the proteoglycan content and its sensitivity was nearly constant regardless of fibril orientation. In comparison, the T(2) sensitivity to proteoglycan was dependant upon fibril orientation, i.e., more sensitive at 55° than 0°. When Gd ions were present, both T(2) and T(1ρ) became insensitive to the proteoglycan content.
Authors: Kenneth W Fishbein; Kyle W Sexton; Hasan Celik; David A Reiter; Mustapha Bouhrara; Richard G Spencer Journal: Magn Reson Med Date: 2019-01-22 Impact factor: 4.668
Authors: Kathryn E Keenan; Thor F Besier; John M Pauly; R Lane Smith; Scott L Delp; Gary S Beaupre; Garry E Gold Journal: Cartilage Date: 2015-04 Impact factor: 4.634