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Prospective Deployment of Deep Learning Reconstruction Facilitates Highly Accelerated Upper Abdominal MRI

Jan M. Brendel, Johann Jacoby, Reza Dehdab, Stephan Ursprung, Victor Fritz, Sebastian Werner, Judith Herrmann, Andreas S. Brendlin, Sebastian Gassenmaier, Fritz Schick, Dominik Nickel, Konstantin Nikolaou, Saif Afat, Haidara Almansour

2024Academic Radiology14 citationsDOIOpen Access PDF

Abstract

Rationale and Objectives To compare a conventional T1 volumetric interpolated breath-hold examination (VIBE) with SPectral Attenuated Inversion Recovery (SPAIR) fat saturation and a deep learning (DL)-reconstructed accelerated VIBE sequence with SPAIR fat saturation achieving a 50 % reduction in breath-hold duration (hereafter, VIBE-SPAIR DL ) in terms of image quality and diagnostic confidence. Materials and Methods This prospective study enrolled consecutive patients referred for upper abdominal MRI from November 2023 to December 2023 at a single tertiary center. Patients underwent upper abdominal MRI with acquisition of non-contrast and gadobutrol-enhanced conventional VIBE-SPAIR (fourfold acceleration, acquisition time 16 s) and VIBE-SPAIR DL (sixfold acceleration, acquisition time 8 s) on a 1.5 T scanner. Image analysis was performed by four readers, evaluating homogeneity of fat suppression, perceived signal-to-noise ratio (SNR), edge sharpness, artifact level, lesion detectability and diagnostic confidence. A statistical power analysis for patient sample size estimation was performed. Image quality parameters were compared by a repeated measures analysis of variance, and interreader agreement was assessed using Fleiss' κ. Results Among 450 consecutive patients, 45 patients were evaluated (mean age, 60 years ± 15 [SD]; 27 men, 18 women). VIBE-SPAIR DL acquisition demonstrated superior SNR ( P < 0.001), edge sharpness ( P < 0.001), and reduced artifacts ( P < 0.001) with substantial to almost perfect interreader agreement for non-contrast (κ: 0.70–0.91) and gadobutrol-enhanced MRI (κ: 0.68–0.87). No evidence of a difference was found between conventional VIBE-SPAIR and VIBE-SPAIR DL regarding homogeneity of fat suppression, lesion detectability, or diagnostic confidence (all P > 0.05). Conclusion Deep learning reconstruction of VIBE-SPAIR facilitated a reduction of breath-hold duration by half, while reducing artifacts and improving image quality. Summary Deep learning reconstruction of prospectively accelerated T1 volumetric interpolated breath-hold examination for upper abdominal MRI enabled a 50 % reduction in breath-hold time with superior image quality. Key Results 1) In a prospective analysis of 45 patients referred for upper abdominal MRI, accelerated deep learning (DL)-reconstructed VIBE images with spectral fat saturation (SPAIR) showed better overall image quality, with better perceived signal-to-noise ratio and less artifacts (all P < 0.001), despite a 50 % reduction in acquisition time compared to conventional VIBE. 2) No evidence of a difference was found between conventional VIBE-SPAIR and accelerated VIBE-SPAIR DL regarding lesion detectability or diagnostic confidence.

Topics & Concepts

Software deploymentDeep learningArtificial intelligenceComputer scienceRadiologyMedicineOperating systemMRI in cancer diagnosisAdvanced MRI Techniques and ApplicationsRadiomics and Machine Learning in Medical Imaging