3D gadolinium-enhanced high-resolution near-isotropic pancreatic imaging at 3.0-T MR using deep-learning reconstruction

Sylvie Guan; Julie Poujol; Elodie Gouhier; Caroline Touloupas; Alexandre Delpla; Isabelle Boulay-Coletta; Marc Zins

doi:10.1186/s13244-025-02066-7

3D gadolinium-enhanced high-resolution near-isotropic pancreatic imaging at 3.0-T MR using deep-learning reconstruction

Insights Imaging. 2025 Sep 24;16(1):204. doi: 10.1186/s13244-025-02066-7.

Authors

Sylvie Guan^#^{1

2}, Julie Poujol^#³, Elodie Gouhier^{4

5}, Caroline Touloupas⁴, Alexandre Delpla⁴, Isabelle Boulay-Coletta⁴, Marc Zins⁴

Affiliations

¹ Department of Medical Imaging, Saint Joseph Hospital, Paris, France. sguan@for.paris.
² Department of Medical Imaging, Rothschild Foundation Hospital, Paris, France. sguan@for.paris.
³ MR Clinical Research, GE HealthCare, Buc, France.
⁴ Department of Medical Imaging, Saint Joseph Hospital, Paris, France.
⁵ Department of Medical Imaging, Pitié-Salpêtrière Hospital, Paris, France.

^# Contributed equally.

Abstract

Objectives: To compare overall image quality, lesion conspicuity and detectability on 3D-T1w-GRE arterial phase high-resolution MR images with deep learning reconstruction (3D-DLR) against standard-of-care reconstruction (SOC-Recon) in patients with suspected pancreatic disease.

Materials and methods: Patients who underwent a pancreatic MR exam with a high-resolution 3D-T1w-GRE arterial phase acquisition on a 3.0-T MR system between December 2021 and June 2022 in our center were retrospectively included. A new deep learning-based reconstruction algorithm (3D-DLR) was used to additionally reconstruct arterial phase images. Two radiologists blinded to the reconstruction type assessed images for image quality, artifacts and lesion conspicuity using a Likert scale and counted the lesions. Signal-to-noise ratio and lesion contrast-to-noise ratio were calculated for each reconstruction. Quantitative data were evaluated using paired t-tests. Ordinal data such as image quality, artifacts and lesions conspicuity were analyzed using paired-Wilcoxon tests. Interobserver agreement for image quality and artifact assessment was evaluated using Cohen's kappa.

Results: Thirty-two patients (mean age 62 years ± 12, 16 female) were included. 3D-DLR significantly improved SNR for each pancreatic segment and lesion CNR compared to SOC-Recon (p < 0.01), and demonstrated significantly higher average image quality score (3.34 vs 2.68, p < 0.01). 3D DLR also significantly reduced artifacts compared to SOC-Recon (p < 0.01) for one radiologist. 3D-DLR exhibited significantly higher average lesion conspicuity (2.30 vs 1.85, p < 0.01). The sensitivity was increased with 3D-DLR compared to SOC-Recon for both reader 1 and reader 2 (1 vs 0.88 and 0.88 vs 0.83, p = 0.62 for both results).

Conclusion: 3D-DLR images demonstrated higher overall image quality, leading to better lesion conspicuity.

Critical relevance statement: 3D deep learning reconstruction can be applied to gadolinium-enhanced pancreatic 3D-T1w arterial phase high-resolution images without additional acquisition time to further improve image quality and lesion conspicuity.

Key points: 3D DLR has not yet been applied to pancreatic MRI high-resolution sequences. This method improves SNR, CNR, and overall 3D T1w arterial pancreatic image quality. Enhanced lesion conspicuity may improve pancreatic lesion detectability.

Keywords: Deep learning; High-resolution; Image reconstruction; Magnetic resonance imaging; Pancreas.