<scp>CEST</scp> and nuclear Overhauser enhancement imaging with deep learning–extrapolated semisolid magnetization transfer reference: Scan‐rescan reproducibility and reliability studies

Heo, Hye‐Young; Singh, Munendra; Yedavalli, Vivek; Jiang, Shanshan; Zhou, Jinyuan

doi:10.1002/mrm.29937

Magnetic Resonance in Med

2023

DOI: 10.1002/mrm.29937

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CEST and nuclear Overhauser enhancement imaging with deep learning–extrapolated semisolid magnetization transfer reference: Scan‐rescan reproducibility and reliability studies

Hye‐Young Heo,

Munendra Singh,

Vivek Yedavalli

et al.

Abstract: PurposeTo develop a novel MR physics‐driven, deep‐learning, extrapolated semisolid magnetization transfer reference (DeepEMR) framework to provide fast, reliable magnetization transfer contrast (MTC) and CEST signal estimations, and to determine the reproducibility and reliability of the estimates from the DeepEMR.MethodsA neural network was designed to predict a direct water saturation and MTC‐dominated signal at a certain CEST frequency offset using a few high‐frequency offset features in the Z‐spectrum. The… Show more

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2024

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Cited by 2 publications

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Fast and motion‐robust saturation transfer MRI with inherent B₀ correction using rosette trajectories and compressed sensing

Mahmud,

Singh,

van Zijl

et al. 2024

Magnetic Resonance in Med

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PurposeTo implement rosette readout trajectories with compressed sensing reconstruction for fast and motion‐robust CEST and magnetization transfer contrast imaging with inherent correction of B0 inhomogeneity.MethodsA pulse sequence was developed for fast saturation transfer imaging using a stack of rosette trajectories with a higher sampling density near the k‐space center. Each rosette lobe was segmented into two halves to generate dual‐echo images. B0 inhomogeneities were estimated using the phase difference between the images and corrected subsequently. The rosette‐based imaging was evaluated in comparison to a fully sampled Cartesian trajectory and demonstrated on CEST phantoms (creatine solutions and egg white) and healthy volunteers at 3 T.ResultsCompared with the conventional Cartesian acquisition, compressed sensing reconstructed rosette images provided image quality with overall higher contrast‐to‐noise ratio and significantly faster readout time. Accurate B0 map estimation was achieved from the rosette acquisition with a negligible bias of 0.01 Hz between the rosette and dual‐echo Cartesian gradient echo B0 maps, using the latter as ground truth. The water‐saturation spectra (Z‐spectra) and amide proton transfer weighted signals obtained from the rosette‐based sequence were well preserved compared with the fully sampled data, both in the phantom and human studies.ConclusionsFast, motion‐robust, and inherent B0‐corrected CEST and magnetization transfer contrast imaging using rosette trajectories could improve subject comfort and compliance, contrast‐to‐noise ratio, and provide inherent B0 homogeneity information. This work is expected to significantly accelerate the translation of CEST‐MRI into a robust, clinically viable approach.

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Fast and motion‐robust saturation transfer MRI with inherent B₀ correction using rosette trajectories and compressed sensing

Mahmud,

Singh,

van Zijl

et al. 2024

Magnetic Resonance in Med

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Enhancing amide proton transfer imaging in ischemic stroke using a machine learning approach with partially synthetic data

Viswanathan,

Yin,

Kurmi

et al. 2024

NMR in Biomedicine

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Amide proton transfer (APT) imaging, a technique sensitive to tissue pH, holds promise in the diagnosis of ischemic stroke. Achieving accurate and rapid APT imaging is crucial for this application. However, conventional APT quantification methods either lack accuracy or are time‐consuming. Machine learning (ML) has recently been recognized as a potential solution to improve APT quantification. In this paper, we applied an ML model trained on a new type of partially synthetic data, along with an optimization approach utilizing recursive feature elimination, to predict APT imaging in an animal stroke model. This partially synthetic datum is not a simple blend of measured and simulated chemical exchange saturation transfer (CEST) signals. Rather, it integrates the underlying components including all CEST, direct water saturation, and magnetization transfer effects partly derived from measurements and simulations to reconstruct the CEST signals using an inverse summation relationship. Training with partially synthetic data requires less in vivo data compared to training entirely with fully synthetic or in vivo data, making it a more practical approach. Since this type of data closely resembles real tissue, it leads to more accurate predictions than ML models trained on fully synthetic data. Results indicate that an ML model trained on this partially synthetic data can successfully predict the APT effect with enhanced accuracy, providing significant contrast between stroke lesions and normal tissues, thus clearly delineating lesions. In contrast, conventional quantification methods such as the asymmetric analysis method, three‐point method, and multiple‐pool model Lorentzian fit showed inadequate accuracy in quantifying the APT effect. Moreover, ML methods trained using in vivo data and fully synthetic data exhibited poor predictive performance due to insufficient training data and inaccurate simulation pool settings or parameter ranges, respectively. Following optimization, only 13 frequency offsets were selected from the initial 69, resulting in significantly reduced scan time.

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CEST and nuclear Overhauser enhancement imaging with deep learning–extrapolated semisolid magnetization transfer reference: Scan‐rescan reproducibility and reliability studies

Cited by 2 publications

References 60 publications

Fast and motion‐robust saturation transfer MRI with inherent B₀ correction using rosette trajectories and compressed sensing

Fast and motion‐robust saturation transfer MRI with inherent B₀ correction using rosette trajectories and compressed sensing

Enhancing amide proton transfer imaging in ischemic stroke using a machine learning approach with partially synthetic data

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CEST and nuclear Overhauser enhancement imaging with deep learning–extrapolated semisolid magnetization transfer reference: Scan‐rescan reproducibility and reliability studies

Cited by 2 publications

References 60 publications

Fast and motion‐robust saturation transfer MRI with inherent B0 correction using rosette trajectories and compressed sensing

Fast and motion‐robust saturation transfer MRI with inherent B0 correction using rosette trajectories and compressed sensing

Enhancing amide proton transfer imaging in ischemic stroke using a machine learning approach with partially synthetic data

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Product

Resources

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Fast and motion‐robust saturation transfer MRI with inherent B₀ correction using rosette trajectories and compressed sensing

Fast and motion‐robust saturation transfer MRI with inherent B₀ correction using rosette trajectories and compressed sensing