Litcius/Paper detail

Robust <scp>EMI</scp> elimination for <scp>RF</scp> shielding‐free <scp>MRI</scp> through deep learning direct <scp>MR</scp> signal prediction

Yujiao Zhao, Linfang Xiao, Jiahao Hu, EX Wu

2024Magnetic Resonance in Medicine23 citationsDOIOpen Access PDF

Abstract

PURPOSE: To develop a new electromagnetic interference (EMI) elimination strategy for RF shielding-free MRI via active EMI sensing and deep learning direct MR signal prediction (Deep-DSP). METHODS: Deep-DSP is proposed to directly predict EMI-free MR signals. During scanning, MRI receive coil and EMI sensing coils simultaneously sample data within two windows (i.e., for MR data and EMI characterization data acquisition, respectively). Afterward, a residual U-Net model is trained using synthetic MRI receive coil data and EMI sensing coil data acquired during EMI signal characterization window, to predict EMI-free MR signals from signals acquired by MRI receive and EMI sensing coils. The trained model is then used to directly predict EMI-free MR signals from data acquired by MRI receive and sensing coils during the MR signal-acquisition window. This strategy was evaluated on an ultralow-field 0.055T brain MRI scanner without any RF shielding and a 1.5T whole-body scanner with incomplete RF shielding. RESULTS: Deep-DSP accurately predicted EMI-free MR signals in presence of strong EMI. It outperformed recently developed EDITER and convolutional neural network methods, yielding better EMI elimination and enabling use of few EMI sensing coils. Furthermore, it could work well without dedicated EMI characterization data. CONCLUSION: Deep-DSP presents an effective EMI elimination strategy that outperforms existing methods, advancing toward truly portable and patient-friendly MRI. It exploits electromagnetic coupling between MRI receive and EMI sensing coils as well as typical MR signal characteristics. Despite its deep learning nature, Deep-DSP framework is computationally simple and efficient.

Topics & Concepts

EMIElectromagnetic interferenceElectromagnetic shieldingElectromagnetic coilDeep learningSIGNAL (programming language)ScannerComputer scienceElectronic engineeringEngineeringArtificial intelligenceElectrical engineeringProgramming languageAdvanced MRI Techniques and ApplicationsElectromagnetic Fields and Biological EffectsFunctional Brain Connectivity Studies
Robust <scp>EMI</scp> elimination for <scp>RF</scp> shielding‐free <scp>MRI</scp> through deep learning direct <scp>MR</scp> signal prediction | Litcius