Sensitivity enhancement of (Hyper‐)CEST image series by exploiting redundancies in the spectral domain

CEST has proven to be a valuable technique for the detection of hyperpolarized xenon‐based functionalized contrast agents. Additional information can be encoded in the spectral dimension, allowing the simultaneous detection of multiple different biosensors. However, owing to the low concentration of dissolved xenon in biological tissue, the signal‐to‐noise ratio (SNR) of Hyper‐CEST data is still a critical issue. In this work, we present two techniques aiming to increase SNR by exploiting the typically high redundancy in spectral CEST image series: PCA‐based post‐processing and sub‐sampled acquisition with low‐rank reconstruction. Each of them yields a significant SNR enhancement, demonstrating the feasibility of the two approaches. While the first method is directly applicable to proton CEST experiments as well, the second one is particularly beneficial when dealing with hyperpolarized nuclei, since it distributes the non‐renewable initial polarization more efficiently over the sampling points. The results obtained are a further step towards the detection of xenon biosensors with spectral Hyper‐CEST imaging in vivo. Copyright © 2014 John Wiley & Sons, Ltd. CEST imaging can be used for the highly sensitive detection of functionalized contrast agents or biosensors. In spectral CEST image series, data is typically highly correlated along the saturation frequency dimension. We efficiently utilize these correlations to enhance Hyper‐CEST images.
Source: Contrast Media and Molecular Imaging - Category: Radiology Authors: Tags: Full Paper Source Type: research