Comparison of Data-driven and General Temporal Constraints on Compressed Sensing for Breast DCE MRI

Overview

Journal Magn Reson Med

Publisher Wiley

Specialty Radiology

Date 2020 Dec 11

PMID 33306217

Citations 2

Authors

Ping N Wang

Julia V Velikina

Roberta M Strigel

Leah C Henze Bancroft

Alexey A Samsonov

Ty A Cashen

Kang Wang

Frederick Kelcz

Kevin M Johnson

Frank R Korosec

Ali Ersoz

James H Holmes

Affiliations

Soon will be listed here.

Abstract

Purpose: Current breast DCE-MRI strategies provide high sensitivity for cancer detection but are known to be insufficient in fully capturing rapidly changing contrast kinetics at high spatial resolution across both breasts. Advanced acquisition and reconstruction strategies aim to improve spatial and temporal resolution and increase specificity for disease characterization. In this work, we evaluate the spatial and temporal fidelity of a modified data-driven low-rank-based model (known as MOCCO, model consistency condition) compressed-sensing (CS) reconstruction compared to CS with temporal total variation with radial acquisition for high spatial-temporal breast DCE MRI.

Methods: Reconstruction performance was characterized using numerical simulations of a golden-angle stack-of-stars breast DCE-MRI acquisition at 5-second temporal resolution. Specifically, MOCCO was compared with CS total variation and conventional SENSE reconstructions. The temporal model for MOCCO was prelearned over the source data, whereas CS total variation was performed using a first-order temporal gradient sparsity transform.

Results: The MOCCO reconstruction was able to capture rapid lesion kinetics while providing high image quality across a range of optimal regularization values. It also recovered kinetics in small lesions (1.5 mm) in line-profile analysis and error images, whereas g-factor maps showed relatively low and constant values with no significant artifacts. The CS-TV method demonstrated either recovery of high spatial resolution with reduced temporal accuracy using large regularization values, or recovery of rapid lesion kinetics with reduced image quality using low regularization values.

Conclusion: Simulations demonstrated that MOCCO with radial acquisition provides a robust imaging technique for improving temporal fidelity, while maintaining high spatial resolution and image quality in the setting of bilateral breast DCE MRI.

Citing Articles

The Influence of Data-Driven Compressed Sensing Reconstruction on Quantitative Pharmacokinetic Analysis in Breast DCE MRI.

Wang P, Velikina J, Bancroft L, Samsonov A, Kelcz F, Strigel R Tomography. 2022; 8(3):1552-1569.

PMID: 35736876 PMC: 9227412. DOI: 10.3390/tomography8030128.

An Anthropomorphic Digital Reference Object (DRO) for Simulation and Analysis of Breast DCE MRI Techniques.

Henze Bancroft L, Holmes J, Bosca-Harasim R, Johnson J, Wang P, Korosec F Tomography. 2022; 8(2):1005-1023.

PMID: 35448715 PMC: 9031444. DOI: 10.3390/tomography8020081.

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