Abstract
In contrast to commonly used approaches to improve data quality in diffusion weighted imaging, position-orientation adaptive smoothing (POAS) provides an edge-preserving post-processing approach. This study aims to investigate its potential and effects on image quality, diffusion metrics, and fiber tractography of the corticospinal tract in relation to non-post-processed and averaged data. 22 healthy volunteers were included in this study. For each volunteer five clinically applicable diffusion weighted imaging data sets were acquired and post-processed by standard averaging and POAS. POAS post-processing led to significantly higher signal-to-noise-ratios (p < 0.001), lower fractional anisotropy across the whole brain (p < 0.05) and reduced intra-subject variability of diffusion weighted imaging signal intensity and fractional anisotropy (p < 0.001, p = 0.006). Fiber tractography of the corticospinal tract resulted in significantly (p = 0.027, p = 0.014) larger tract volumes while fiber density was the lowest. Similarity across tractography results was highest for POAS post-processed data (p < 0.001). POAS post-processing enhances image quality, decreases the intra-subject variability of signal intensity and fractional anisotropy, increases fiber tract volume of the corticospinal tract, and leads to higher reproducibility of tractography results. Thus, POAS post-processing supports a reliable and more accurate fiber tractography of the corticospinal tract, being mandatory for the clinical use.
Highlights
Diffusion weighted imaging (DWI) in combination with fiber tractography is currently the most commonly used approach to map white matter tracts non-invasively in-vivo [1,2,3,4,5] and has been used to evaluate the changes of microstructural properties in brain disorders [6, 7]
We investigated the contribution of position-orientation adaptive smoothing (POAS) post-processing on the improvement of image quality and signal to noise ratios (SNR), diffusion characteristics and fiber tractography in comparison
While within the b0-images no obvious alterations were found among the different groups, more obvious differences were seen within the high-b-value images
Summary
Diffusion weighted imaging (DWI) in combination with fiber tractography is currently the most commonly used approach to map white matter tracts non-invasively in-vivo [1,2,3,4,5] and has been used to evaluate the changes of microstructural properties in brain disorders [6, 7]. DWI gained wide applications in clinical settings, such as fiber tractography and analysis of diffusion metrics [8,9,10,11,12]. Due to the growing interest in DWI and its clinical and scientific applications it is essential to consider factors affecting the quality of data acquisition, diffusion metrics, and fiber tractography. Position-orientation adaptive smoothing—From diffusion metrics to fiber tractography
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