Deep learning corrects artifacts in RASER MRI profiles

被引：0

作者：

Becker, Moritz ^{[1
]}

Arvidsson, Filip ^{[1
]}

Bertilson, Jonas ^{[1
]}

Aslanikashvili, Elene ^{[1
]}

Korvink, Jan G. ^{[1
]}

Jouda, Mazin ^{[1
]}

Lehmkuhl, Soeren ^{[1
]}

机构：

[1] Karlsruhe Inst Technol, Inst Microstruct Technol, Hermann von Helmholtz Pl 1, D-76344 Eggenstein Leopoldshafen, Germany

来源：

MAGNETIC RESONANCE IMAGING | 2025年 / 115卷

关键词：

MRI; RASER; Hyperpolarization; Deep learning; Artifact removal; PARA-HYDROGEN; NUCLEAR; NMR; RESOLUTION;

D O I：

10.1016/j.mri.2024.110247

中图分类号：

R8 [特种医学]; R445 [影像诊断学];

学科分类号：

1002 ; 100207 ; 1009 ;

摘要：

A newly developed magnetic resonance imaging (MRI) approach is based on "Radiowave amplification by the stimulated emission of radiation" (RASER). RASER MRI potentially allows for higher resolution, is inherently background-free, and does not require radio-frequency excitation. However, RASER MRI can be "nearly unusable" as heavy distortions from nonlinear effects can occur. In this work, we show that deep learning (DL) reduces such artifacts in RASER images. We trained a two-step DL pipeline on purely synthetic data, which was generated based on a previously published, theoretical model for RASER MRI. A convolutional neural network was trained on 630 ' 000 1D RASER projections, and a U-net on 2D random images. The DL pipeline generalizes well when applied from synthetic to experimental RASER MRI data.

引用

页数：8

共 50 条

[21] Deep Learning for Generating Time-of-Flight Camera Artifacts
Mueller, Tobias
Schmaehling, Tobias
Elser, Stefan
Eberhardt, Joerg
JOURNAL OF IMAGING, 2024, 10 (10)
[22] Military software corrects the MRI jitters
Randerson, James
New Scientist, 2003, 180 (2426-2428)
[23] Correcting Susceptibility Artifacts of MRI Sensors in Brain Scanning: A 3D Anatomy-Guided Deep Learning Approach
Soan T M Duong
Son Lam Phung
Bouzerdoum, Abdesselam
Sui Paul Ang
Schira, Mark M.
SENSORS, 2021, 21 (07)
[24] Learning Implicit Brain MRI Manifolds with Deep Learning
Bermudez, Camilo
Plassard, Andrew J.
Davis, Larry T.
Newton, Allen T.
Resnick, Susan M.
Landman, Bennett A.
MEDICAL IMAGING 2018: IMAGE PROCESSING, 2018, 10574
[25] Deep-learning-based motion correction using multichannel MRI data: a study using simulated artifacts in the fastMRI dataset
Hewlett, Miriam
Petrov, Ivailo
Johnson, Patricia M.
Drangova, Maria
NMR IN BIOMEDICINE, 2024, 37 (10)
[26] Retrospective Detection and Suppression of Dark-Rim Artifacts in First-Pass Perfusion Cardiac MRI Enabled by Deep Learning
Unal, Hazar Benan
Beaulieu, Taylor
Rivero, Luis Zamudio
Dharmakumar, Rohan
Sharif, Behzad
2021 43RD ANNUAL INTERNATIONAL CONFERENCE OF THE IEEE ENGINEERING IN MEDICINE & BIOLOGY SOCIETY (EMBC), 2021, : 4079 - 4085
[27] A Deep Learning Model for Classifying Collaterals in Patients with Ischemic Stroke based on Arterial Transit Artifacts on Arterial Spin Labeling MRI
Li, Yi
Tian, Yuchi
Zhang, Wenqing
Liang, Xiaoyun
CEREBROVASCULAR DISEASES, 2023, 52 : 231 - 231
[28] ArtifactID: Identifying artifacts in low-field MRI of the brain using deep learning (vol 89, pg 42, 2022)
Jimeno, Marina Manso
Ravi, Keerthi Sravan
Jin, Zhezhen
Oyekunle, Dotun
Ogbole, Godwin
Geethanath, Sairam
MAGNETIC RESONANCE IMAGING, 2023, 95 : 118 - 118
[29] ABDOMINAL MRI ARTIFACTS
POWERS, T
LUM, A
PATTON, JA
SEMINARS IN ULTRASOUND CT AND MRI, 1989, 10 (01) : 2 - 10
[30] Orbital Artifacts on MRI
Rana, Khizar
Juniat, Valerie
Patel, Sandy
Avey, Greg
Lucarelli, Mark J.
Selva, Dinesh
OPHTHALMIC PLASTIC AND RECONSTRUCTIVE SURGERY, 2023, 39 (04): : 328 - 335

← 1 2 3 4 5 →