Litcius/Paper detail

<scp>IMPULSED</scp> model based cytological feature estimation with <scp>U‐Net</scp>: Application to human brain tumor at 3T

Jian Wu, Taishan Kang, Xinli Lan, Xinran Chen, Zhigang Wu, Jiazheng Wang, Liangjie Lin, Congbo Cai, Jianzhong Lin, Xin Ding, Shuhui Cai

2022Magnetic Resonance in Medicine13 citationsDOI

Abstract

PURPOSE: This work introduces and validates a deep-learning-based fitting method, which can rapidly provide accurate and robust estimation of cytological features of brain tumor based on the IMPULSED (imaging microstructural parameters using limited spectrally edited diffusion) model fitting with diffusion-weighted MRI data. METHODS: ) of brain tumor. At the training stage, the image-based training data, synthesized by randomizing quantifiable microstructural parameters within specific ranges, was used to train U-Net. At the test stage, the pre-trained U-Net was applied to estimate the microstructural parameters from simulated data and the in vivo data acquired on patients at 3T. The U-Net was compared with conventional non-linear least-squares (NLLS) fitting in simulations in terms of estimation accuracy and precision. RESULTS: Our results confirm that the proposed method yields better fidelity in simulations and is more robust to noise than the NLLS fitting. For in vivo data, the U-Net yields obvious quality improvement in parameter maps, and the estimations of all parameters are in good agreement with the NLLS fitting. Moreover, our method is several orders of magnitude faster than the NLLS fitting (from about 5 min to <1 s). CONCLUSION: The image-based training scheme proposed herein helps to improve the quality of the estimated parameters. Our deep-learning-based fitting method can estimate the cell microstructural parameters fast and accurately.

Topics & Concepts

Computer scienceElastic net regularizationArtificial intelligenceEstimation theoryNoise (video)Effective diffusion coefficientFeature (linguistics)AlgorithmOverfittingPattern recognition (psychology)Image (mathematics)Feature selectionArtificial neural networkMagnetic resonance imagingMedicineLinguisticsPhilosophyRadiologyGlioma Diagnosis and TreatmentRadiomics and Machine Learning in Medical ImagingAdvanced Neuroimaging Techniques and Applications