Compressed sensing acceleration of biexponential 3D-T relaxation mapping of knee cartilage. Academic Article uri icon

Overview

abstract

  • PURPOSE: Use compressed sensing (CS) for 3D biexponential spin-lattice relaxation time in the rotating frame (T ) mapping of knee cartilage, reducing the total scan time and maintaining the quality of estimated biexponential T parameters (short and long relaxation times and corresponding fractions) comparable to fully sampled scans. METHODS: Fully sampled 3D-T -weighted data sets were retrospectively undersampled by factors 2-10. CS reconstruction using 12 different sparsifying transforms were compared for biexponential T -mapping of knee cartilage, including temporal and spatial wavelets and finite differences, dictionary from principal component analysis (PCA), k-means singular value decomposition (K-SVD), exponential decay models, and also low rank and low rank plus sparse models. Synthetic phantom (N = 6) and in vivo human knee cartilage data sets (N = 7) were included in the experiments. Spatial filtering before biexponential T parameter estimation was also tested. RESULTS: Most CS methods performed satisfactorily for an acceleration factor (AF) of 2, with relative median normalized absolute deviation (MNAD) around 10%. Some sparsifying transforms, such as low rank with spatial finite difference (L + S SFD), spatiotemporal finite difference (STFD), and exponential dictionaries (EXP) significantly improved this performance, reaching MNAD below 15% with AF up to 10, when spatial filtering was used. CONCLUSION: Accelerating biexponential 3D-T mapping of knee cartilage with CS is feasible. The best results were obtained by STFD, EXP, and L + S SFD regularizers combined with spatial prefiltering. These 3 CS methods performed satisfactorily on synthetic phantom as well as in vivo knee cartilage for AFs up to 10, with median error below 15%.

publication date

  • September 19, 2018

Research

keywords

  • Cartilage, Articular
  • Image Processing, Computer-Assisted
  • Knee Joint
  • Magnetic Resonance Imaging

Identity

PubMed Central ID

  • PMC6289851

Scopus Document Identifier

  • 85053530456

Digital Object Identifier (DOI)

  • 10.1002/mrm.27416

PubMed ID

  • 30230588

Additional Document Info

volume

  • 81

issue

  • 2