Application of a Deep Learning Algorithm for Combined Super-Resolution and Partial Fourier Reconstruction Including Time Reduction in T1-Weighted Precontrast and Postcontrast Gradient Echo Imaging of Abdominopelvic MR Imaging

Purpose: The purpose of this study was to test the technical feasibility and the impact on the image quality of a deep learning-based super-resolution reconstruction algorithm in 1.5 T abdominopelvic MR imaging. Methods: 44 patients who underwent abdominopelvic MRI were retrospectively included, of which 4 had to be subsequently excluded. After the acquisition of the conventional volume interpolated breath-hold examination (VIBEStd), images underwent postprocessing, using a deep learning-based iterative denoising super-resolution reconstruction algorithm for partial Fourier acquisitions (VIBESR). Image analysis of 40 patients with a mean age of 56 years (range 18–84 years) was performed qualitatively by two radiologists independently using a Likert scale ranging from 1 to 5, where 5 was considered the best rating. Results: Image analysis showed an improvement of image quality, noise, sharpness of the organs and lymph nodes, and sharpness of the intestine for pre- and postcontrast images in VIBESR compared to VIBEStd (each p < 0.001). Lesion detectability was better for VIBESR (p < 0.001), while there were no differences concerning the number of lesions. Average acquisition time was 16 s (±1) for the upper abdomen and 15 s (±1) for the pelvis for VIBEStd, and 15 s (±1) for the upper abdomen and 14 s (±1) for the pelvis for VIBESR. Conclusion: This study demonstrated the technical feasibility of a deep learning-based super-resolution algorithm including partial Fourier technique in abdominopelvic MR images and illustrated a significant improvement of image quality, noise, and sharpness while reducing TA.

[1]  E. Fishman,et al.  Does artificial intelligence surpass the radiologist? , 2022, Diagnostic and interventional imaging.

[2]  Bernd Kuehn,et al.  Quantitative assessment of iteratively denoised 3D SPACE with inner-volume excitation and simultaneous multi-slice BLADE for optimizing female pelvis magnetic resonance imaging at 1.5 T. , 2022, Academic Radiology.

[3]  Daniel Wessling,et al.  Deep learning-based super-resolution gradient echo imaging of the pancreas: Improvement of image quality and reduction of acquisition time. , 2022, Diagnostic and interventional imaging.

[4]  A. Luciani,et al.  Fast T2-weighted liver MRI: Image quality and solid focal lesions conspicuity using a deep learning accelerated single breath-hold HASTE fat-suppressed sequence. , 2022, Diagnostic and interventional imaging.

[5]  E. Fishman,et al.  The future of radiology: What if artificial intelligence is really as good as predicted? , 2022, Diagnostic and interventional imaging.

[6]  Daniel Wessling,et al.  Comprehensive clinical evaluation of a deep learning-accelerated, single-breath-hold abdominal HASTE at 1.5 T and 3 T. , 2022, Academic radiology.

[7]  C. Adamsbaum,et al.  External validation of a commercially available deep learning algorithm for fracture detection in children: Fracture detection with a deep learning algorithm. , 2021, Diagnostic and interventional imaging.

[8]  Daniel Wessling,et al.  Analysis of a Deep Learning-Based Superresolution Algorithm Tailored to Partial Fourier Gradient Echo Sequences of the Abdomen at 1.5 T: Reduction of Breath-Hold Time and Improvement of Image Quality. , 2021, Investigative radiology.

[9]  D. Nickel,et al.  Deep learning-accelerated T2-weighted imaging of the prostate: Reduction of acquisition time and improvement of image quality. , 2021, European journal of radiology.

[10]  S. Kannengiesser,et al.  Image Quality Improvement of Dynamic Contrast-Enhanced Gradient Echo Magnetic Resonance Imaging by Iterative Denoising and Edge Enhancement , 2021, Investigative radiology.

[11]  S. Kannengiesser,et al.  Application of a Novel Iterative Denoising and Image Enhancement Technique in T1-Weighted Precontrast and Postcontrast Gradient Echo Imaging of the Abdomen: Improvement of Image Quality and Diagnostic Confidence. , 2020, Investigative radiology.

[12]  M. Prior,et al.  MR enterography – Impact on image quality between single‐ versus split‐dose Buscopan , 2020, Journal of medical imaging and radiation oncology.

[13]  Zhongshuai Zhang,et al.  Feasibility of free-breathing T1-weighted 3D radial VIBE for fetal MRI in various anomalies. , 2020, Magnetic resonance imaging.

[14]  C. Dietrich,et al.  Indications for abdominal imaging: When and what to choose? , 2020, Journal of ultrasonography.

[15]  John M Pauly,et al.  Data‐driven self‐calibration and reconstruction for non‐cartesian wave‐encoded single‐shot fast spin echo using deep learning , 2020, Journal of magnetic resonance imaging : JMRI.

[16]  A. Boss,et al.  Accelerated diffusion-weighted imaging for lymph node assessment in the pelvis applying simultaneous multislice acquisition , 2018, Medicine.

[17]  Jonathan I. Tamir,et al.  Variable-Density Single-Shot Fast Spin-Echo MRI with Deep Learning Reconstruction by Using Variational Networks. , 2018, Radiology.

[18]  Hsiao-Wen Chung,et al.  Free‐breathing abdominal MRI improved by repeated k‐t‐subsampling and artifact‐minimization (ReKAM) , 2018, Medical physics.

[19]  Terry K Koo,et al.  A Guideline of Selecting and Reporting Intraclass Correlation Coefficients for Reliability Research. , 2016, Journal Chiropractic Medicine.

[20]  Patricia T. Chang,et al.  Pediatric Emergency Magnetic Resonance Imaging: Current Indications, Techniques, and Clinical Applications. , 2016, Magnetic resonance imaging clinics of North America.

[21]  M. Gee,et al.  Inflammatory bowel disease imaging: Current practice and future directions. , 2016, World journal of gastroenterology.

[22]  J. Soto,et al.  Emergency abdominal MRI: current uses and trends. , 2016, The British journal of radiology.

[23]  M. Zaitsev,et al.  Motion artifacts in MRI: A complex problem with many partial solutions , 2015, Journal of magnetic resonance imaging : JMRI.

[24]  Y. Nakaya,et al.  Signal-to-noise ratio and parallel imaging performance of commercially available phased array coils in 3.0 T brain magnetic resonance imaging , 2015, Radiological Physics and Technology.

[25]  I. Pedrosa,et al.  Magnetic Resonance Imaging of Acute Abdominal and Pelvic Pain in Pregnancy , 2014, Topics in magnetic resonance imaging : TMRI.

[26]  Tian-wu Chen,et al.  GRE T2∗-Weighted MRI: Principles and Clinical Applications , 2014, BioMed research international.

[27]  E. Merkle,et al.  Contrast-enhanced free-breathing 3D T1-weighted gradient-echo sequence for hepatobiliary MRI in patients with breath-holding difficulties , 2013, European Radiology.

[28]  Simon Bauer,et al.  Free-breathing dynamic contrast-enhanced MRI of the abdomen and chest using a radial gradient echo sequence with K-space weighted image contrast (KWIC) , 2013, European Radiology.

[29]  Brian Hargreaves,et al.  Rapid gradient‐echo imaging , 2012, Journal of magnetic resonance imaging : JMRI.

[30]  M. McHugh Interrater reliability: the kappa statistic , 2012, Biochemia medica.

[31]  Michael Markl,et al.  Gradient echo imaging , 2012, Journal of magnetic resonance imaging : JMRI.

[32]  Christopher G. Roth,et al.  Optimizing abdominal MR imaging: approaches to common problems. , 2010, Radiographics : a review publication of the Radiological Society of North America, Inc.

[33]  N. Rofsky,et al.  Abdominal MR imaging with a volumetric interpolated breath-hold examination. , 1999, Radiology.

[34]  S. Mirowitz Diagnostic pitfalls and artifacts in abdominal MR imaging: a review. , 1998, Radiology.

[35]  L. Martí-Bonmatí,et al.  Reduction of peristaltic artifacts on magnetic resonance imaging of the abdomen: a comparative evaluation of three drugs , 1996, Abdominal Imaging.

[36]  M. Pui,et al.  MR imaging of the brain: comparison of gradient-echo and spin-echo pulse sequences. , 1995, AJR. American journal of roentgenology.