Assessment of different fitting methods for in-vivo bi-component T2* analysis of human patellar tendon in magnetic resonance imaging

Abstract: SummaryPurpose: To investigate the robustness of four fitting methods for bi-component effective spin-spin T2 (T2*) relaxation time analysis of human patellar tendon. Methods: A three-dimensional (3D) cone ultrashort echo-time (UTE) sequence was performed on the knees of ten healthy volunteers at 3.0T. Four fitting methods incorporating either Gaussian or Rician noise distribution were used for voxel-by-voxel bi-component T2* analysis of the patellar tendon. The T2* for the short relaxing (T**,s) and long rela… Show more

“…This may be the result of the increased uncertainty and higher sensitivity to noise of T Ã 2 S parameter estimation due to the relatively small fraction of the slow relaxing water component in tendon, which provides little MRI signal at later echoes. 21 Single component UTE-T Ã 2 mapping techniques have been previously used to detect tendon degeneration and have shorter scan times and less complex reconstruction algorithms when compared to bicomponent UTE-T Ã 2 mapping techniques. 7 In fact, our study found that patients with patellar tendinopathy had significantly higher T Ã 2 when compared to healthy volunteers.…”

Bicomponent ultrashort echo time analysis for assessment of patients with patellar tendinopathy

“…This may be the result of the increased uncertainty and higher sensitivity to noise of T Ã 2 S parameter estimation due to the relatively small fraction of the slow relaxing water component in tendon, which provides little MRI signal at later echoes. 21 Single component UTE-T Ã 2 mapping techniques have been previously used to detect tendon degeneration and have shorter scan times and less complex reconstruction algorithms when compared to bicomponent UTE-T Ã 2 mapping techniques. 7 In fact, our study found that patients with patellar tendinopathy had significantly higher T Ã 2 when compared to healthy volunteers.…”

Bicomponent ultrashort echo time analysis for assessment of patients with patellar tendinopathy

“…Unique k-space trajectories were used in the UTE-Cones sequences that sampled data along evenly spaced twisted paths in the form of multiple cones. [29][30][31] Data sampling began from the center of k-space and continued outward. It began as soon as practical after the RF excitation with a minimal nominal delay time of 32 µs.…”

“…We have demonstrated that the proposed 3D UTE-Cones AFI-VFA method can accurately measure T 1 values for most major tissues of the whole knee joint. Simulation shows that the proposed 3D UTE-Cones AFI-VFA method provides accurate T 1 measurements for tissues with T 2 values longer than 1 ms. Because most knee tissues have T 2 s longer than 1 ms (meniscus: 5-8 ms, ligament and tendon: 4-10 ms, cartilage: 27-43 ms, muscle: 32-50 ms, and fat: ~133 ms), 11,[27][28][29][30][31][32][33] accurate T 1 maps were obtained using the proposed method to provide in vivo knee measurements in 16 healthy volunteers.…”

“…22 However, UTE AFI-VTR would require a long scan time for 3D high resolution knee imaging, making it unacceptable for clinical use. 22 Because all major knee tissues other than bone have a T 2 value longer than 1 ms, 11,[27][28][29][30][31][32][33] the B 1 map generated by the UTE-AFI method can still be used for B 1 correction of the faster VFAbased T 1 measurement for these tissues. Therefore, the UTE AFI-VFA method would be expected to provide accurate T 1 measurements of the soft tissues of the whole knee joint with much less scan time than the UTE AFI-VTR method.…”

Whole knee joint T₁ values measured in vivo at 3T by combined 3D ultrashort echo time cones actual flip angle and variable flip angle methods

“…Although the noise in spectroscopic acquisitions can accurately be modeled as Gaussian, the noise distribution in magnitude MR images obtained with single coil acquisition is Rician; this approaches the Gaussian distribution only for high signal-to-noise ratio (SNR) (11,(20)(21)(22). Therefore, incorporation of Rician noise into CRLB analysis is especially important in settings of limited SNR, as is often the case in clinical imaging (11,(23)(24)(25)(26).…”

Fisher information and Cramér‐Rao lower bound for experimental design in parallel imaging