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Accelerated two‐dimensional phase‐contrast for cardiovascular MRI using deep learning‐based reconstruction with complex difference estimation

Julio Oscanoa, Matthew J. Middione, Ali Syed, Christopher M. Sandino, Shreyas Vasanawala, Daniel B. Ennis

2022Magnetic Resonance in Medicine22 citationsDOI

Abstract

Purpose To develop and validate a deep learning‐based reconstruction framework for highly accelerated two‐dimensional (2D) phase contrast (PC‐MRI) data with accurate and precise quantitative measurements. Methods We propose a modified DL‐ESPIRiT reconstruction framework for 2D PC‐MRI, comprised of an unrolled neural network architecture with a Complex Difference estimation (CD‐DL). CD‐DL was trained on 155 fully sampled 2D PC‐MRI pediatric clinical datasets. The fully sampled data () was retrospectively undersampled (6–11) and reconstructed using CD‐DL and a parallel imaging and compressed sensing method (PICS). Measurements of peak velocity and total flow were compared to determine the highest acceleration rate that provided accuracy and precision within . Feasibility of CD‐DL was demonstrated on prospectively undersampled datasets acquired in pediatric clinical patients () and compared to traditional parallel imaging (PI) and PICS. Results The retrospective evaluation showed that 9 accelerated 2D PC‐MRI images reconstructed with CD‐DL provided accuracy and precision (bias, [95 confidence intervals]) within . CD‐DL showed higher accuracy and precision compared to PICS for measurements of peak velocity (2.8 [, 4.5] vs. 3.9 [, 4.9]) and total flow (1.8 [, 3.4] vs. 2.9 [, 6.9]). The prospective feasibility study showed that CD‐DL provided higher accuracy and precision than PICS for measurements of peak velocity and total flow. Conclusion In a retrospective evaluation, CD‐DL produced quantitative measurements of 2D PC‐MRI peak velocity and total flow with error in both accuracy and precision for up to 9 acceleration. Clinical feasibility was demonstrated using a prospective clinical deployment of our 8 undersampled acquisition and CD‐DL reconstruction in a cohort of pediatric patients.

Topics & Concepts

Compressed sensingAccelerationContrast (vision)Nuclear medicineMagnetic resonance imagingAccuracy and precisionComputer scienceDiagnostic accuracyArtificial intelligenceAlgorithmPhase contrast microscopyIterative reconstructionConfidence intervalMathematicsPattern recognition (psychology)MedicineRadiologyPhysicsStatisticsOpticsClassical mechanicsAdvanced MRI Techniques and ApplicationsAtomic and Subatomic Physics ResearchCardiovascular Function and Risk Factors