Speed and efficiency: evaluating pulmonary nodule detection with AI-enhanced 3D gradient echo imaging

Sebastian Ziegelmayer, Alexander W. Marka, Maximilian Strenzke, Tristan Lemke, Hannah Rosenkranz, Bernadette Scherer, Thomas Huber, Kilian Weiss, Marcus R. Makowski, Dimitrios C. Karampinos, Markus Graf, Joshua Gawlitza

Research output: Contribution to journalArticlepeer-review

1 Scopus citations

Abstract

Objectives: Evaluating the diagnostic feasibility of accelerated pulmonary MR imaging for detection and characterisation of pulmonary nodules with artificial intelligence-aided compressed sensing. Materials and methods: In this prospective trial, patients with benign and malignant lung nodules admitted between December 2021 and December 2022 underwent chest CT and pulmonary MRI. Pulmonary MRI used a respiratory-gated 3D gradient echo sequence, accelerated with a combination of parallel imaging, compressed sensing, and deep learning image reconstruction with three different acceleration factors (CS-AI-7, CS-AI-10, and CS-AI-15). Two readers evaluated image quality (5-point Likert scale), nodule detection and characterisation (size and morphology) of all sequences compared to CT in a blinded setting. Reader agreement was determined using the intraclass correlation coefficient (ICC). Results: Thirty-seven patients with 64 pulmonary nodules (solid n = 57 [3–107 mm] part-solid n = 6 [ground glass/solid 8 mm/4–28 mm/16 mm] ground glass nodule n = 1 [20 mm]) were analysed. Nominal scan times were CS-AI-7 3:53 min; CS-AI-10 2:34 min; CS-AI-15 1:50 min. CS-AI-7 showed higher image quality, while quality remained diagnostic even for CS-AI-15. Detection rates of pulmonary nodules were 100%, 98.4%, and 96.8% for CS-AI factors 7, 10, and 15, respectively. Nodule morphology was best at the lowest acceleration and was inferior to CT in only 5% of cases, compared to 10% for CS-AI-10 and 23% for CS-AI-15. The nodule size was comparable for all sequences and deviated on average < 1 mm from the CT size. Conclusion: The combination of compressed sensing and AI enables a substantial reduction in the scan time of lung MRI while maintaining a high detection rate of pulmonary nodules. Clinical relevance statement: Incorporating compressed sensing and AI in pulmonary MRI achieves significant time savings without compromising nodule detection or characteristics. This advancement holds clinical promise, enhancing efficiency in lung cancer screening without sacrificing diagnostic quality. Key Points: Lung cancer screening by MRI may be possible but would benefit from scan time optimisation. Significant scan time reduction, high detection rates, and preserved nodule characteristics were achieved across different acceleration factors. Integrating compressed sensing and AI in pulmonary MRI offers efficient lung cancer screening without compromising diagnostic quality.

Original languageEnglish
JournalEuropean Radiology
DOIs
StateAccepted/In press - 2024
Externally publishedYes

Keywords

  • Computed tomography
  • Lung
  • Magnetic resonance images
  • Multiple pulmonary nodules

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