High-resolution diffusivity imaging at 3.0 T for the detection of degenerative changes: a trypsin-based arthritis model
- PMID: 12821861
- DOI: 10.1097/01.rli.0000078762.72335.57
High-resolution diffusivity imaging at 3.0 T for the detection of degenerative changes: a trypsin-based arthritis model
Abstract
Rationale and objectives: To establish whether it is possible to quantitatively characterize the degenerative changes in cartilage that typify arthritis on a sub-150-microm resolution scale using a 3.0 T whole body MR-scanner with a reasonable measurement time.
Materials and methods: This problem is addressed through diffusion-microimaging investigations on an arthritis model based on the enzymatic destruction of the proteoglycans in cartilage specimen. A 35-mm birdcage resonator made high spatial resolution possible, and diffusion-micro-imaging was achieved with the use of a strong gradient system.
Results: Diffusion-weighted and quantitative parameter maps were acquired with 117 x 234 microm2 pixel resolution in less than 9 minutes. Diffusivity profiles and parameter images exhibit an increase in diffusivity in degenerated tissue.
Conclusion: In a trypsin-based arthritis model, the spatial localization and quantification of damaged areas have been shown to be possible on a whole body 3.0 T MR system. Measurement times achieved for these high spatial resolution studies make in vivo investigations feasible.
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