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Deep learning–guided weighted averaging for signal dropout compensation in DWI of the liver

Purpose To develop an algorithm for the retrospective correction of signal dropout artifacts in abdominal DWI resulting from cardiac motion. Methods Given a set of image repetitions for a slice, a locally adaptive weighted averaging is proposed that aims to suppress the contribution of image regions...

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Bibliographic Details
Published in:Magnetic resonance in medicine 2022-12, Vol.88 (6), p.2679-2693
Main Authors: Gadjimuradov, Fasil, Benkert, Thomas, Nickel, Marcel Dominik, Führes, Tobit, Saake, Marc, Maier, Andreas
Format: Article
Language:English
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Summary:Purpose To develop an algorithm for the retrospective correction of signal dropout artifacts in abdominal DWI resulting from cardiac motion. Methods Given a set of image repetitions for a slice, a locally adaptive weighted averaging is proposed that aims to suppress the contribution of image regions affected by signal dropouts. Corresponding weight maps were estimated by a sliding‐window algorithm, which analyzed signal deviations from a patch‐wise reference. In order to ensure the computation of a robust reference, repetitions were filtered by a classifier that was trained to detect images corrupted by signal dropouts. The proposed method, named Deep Learning–guided Adaptive Weighted Averaging (DLAWA), was evaluated in terms of dropout suppression capability, bias reduction in the ADC, and noise characteristics. Results In the case of uniform averaging, motion‐related dropouts caused signal attenuation and ADC overestimation in parts of the liver, with the left lobe being affected particularly. Both effects could be substantially mitigated by DLAWA while preventing global penalties with respect to SNR due to local signal suppression. Performing evaluations on patient data, the capability to recover lesions concealed by signal dropouts was demonstrated as well. Further, DLAWA allowed for transparent control of the trade‐off between SNR and signal dropout suppression by means of a few hyperparameters. Conclusion This work presents an effective and flexible method for the local compensation of signal dropouts resulting from motion and pulsation. Because DLAWA follows a retrospective approach, no changes to the acquisition are required.
ISSN:0740-3194
1522-2594
DOI:10.1002/mrm.29380