Ensemble average propagator-based detection of microstructural alterations after stroke

• Published in: International journal for computer assisted radiology and surgery Vol. 11; no. 9; pp. 1585 - 1597
• Main Authors: Brusini, Lorenza, Obertino, Silvia, Galazzo, Ilaria Boscolo, Zucchelli, Mauro, Krueger, Gunnar, Granziera, Cristina, Menegaz, Gloria
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.09.2016; Springer Nature B.V
• Subjects: Anisotropy; Brain - pathology; Computer Imaging; Computer Science; Diffusion Magnetic Resonance Imaging - methods; Female; Health Informatics; Humans; Imaging; Male; Medicine; Medicine & Public Health; Middle Aged; Original Article; Pattern Recognition and Graphics; Radiology; Stroke - diagnosis; Surgery; Vision; 3D-SHORE; Stroke; Biomarker; GFA
• ISSN: 1861-6410; 1861-6429
• DOI: 10.1007/s11548-016-1442-z

Purpose New analytical reconstruction techniques of diffusion weighted signal have been proposed. A previous work evidenced the exploitability of some indices derived from the simple harmonic oscillator-based reconstruction and estimation (3D-SHORE) model as numerical biomarkers of neural plasticity after stroke. Here, the analysis is extended to two additional indices: return to the plane/origin (RTPP/RTOP) probabilities. Moreover, several motor networks were introduced and the results were analyzed at different time scales. Methods Ten patients underwent three diffusion spectrum imaging (DSI) scans [1 week ( tp1 ), 1 month ( tp2 ) and 6 months ( tp3 ) after stroke]. Ten matched controls underwent two DSI scans 1 month apart. 3D-SHORE was used for reconstructing the signal and the microstructural indices were derived. Tract-based analysis was performed along motor cortical, subcortical and transcallosal networks in the contralesional area. Results The optimal intra-class correlation coefficient (ICC) was obtained in the subcortical loop for propagator anisotropy (ICC  =  0.96), followed by generalized fractional anisotropy (ICC  =  0.94). The new indices reached the highest stability in the transcallosal network and performed well in the cortical and subcortical networks with the exception of RTOP in the cortical loop (ICC  =  0.59). They allowed discriminating patients from controls at the majority of the timescales. Finally, the regression model using indices calculated along the subcortical loop at tp1 resulted in the best prediction of clinical outcome. Conclusions The whole set of microstructural indices provide measurements featuring high precision. The new indices allow discriminating patients from controls in all networks, except for RTPP in the cortical loop. Moreover, the 3D-SHORE indices in subcortical connections constitute a good regression model for predicting the clinical outcome at 6 months, supporting their suitability as numerical biomarkers for neuronal plasticity after stroke.