Respiratory Motion Prediction Using Fusion-Based Multi-Rate Kalman Filtering and Real-Time Golden-Angle Radial MRI

Objective: Magnetic resonance imaging (MRI) can provide guidance for interventions in organs affected by respiration (e.g., liver). This study aims to: 1) investigate image-based and surrogate-based motion tracking methods using real-time golden-angle radial MRI; and 2) propose and evaluate a new fu...

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Bibliographic Details
Published in:IEEE transactions on biomedical engineering 2020-06, Vol.67 (6), p.1727-1738, Article 1727
Main Authors: Li, Xinzhou, Lee, Yu-Hsiu, Mikaiel, Samantha, Simonelli, James, Tsao, Tsu-Chin, Wu, Holden H.
Format: Article
Language:English
Subjects:
Data transmission
Error analysis
Feature extraction
Feedback
Golden-angle radial magnetic resonance imaging (MRI)
Image filters
Image reconstruction
In vivo methods and tests
Internet
Kalman filters
Latency
Liver
Magnetic resonance imaging
Methods
motion prediction
motion tracking
Organs
Predictions
Rank tests
Real time
Real-time systems
Respiration
respiratory motion
Root-mean-square errors
system latency
Target tracking
Tracking errors
Waveforms
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Summary:Objective: Magnetic resonance imaging (MRI) can provide guidance for interventions in organs affected by respiration (e.g., liver). This study aims to: 1) investigate image-based and surrogate-based motion tracking methods using real-time golden-angle radial MRI; and 2) propose and evaluate a new fusion-based respiratory motion prediction framework with multi-rate Kalman filtering. Methods: Images with different temporal footprints were reconstructed from the same golden-angle radial MRI data stream to simultaneously enable image-based and surrogate-based tracking at 10 Hz. A custom software pipeline was constructed to perform online tracking and calibrate tracking error and latency using a programmable motion phantom. A fusion-based motion prediction method was developed to combine the lower tracking error of image-based tracking with the lower latency of surrogate-based tracking. The fusion-based method was evaluated in retrospective studies using in vivo real-time free-breathing liver MRI. Results: Phantom experiments confirmed that the median online tracking error of image-based tracking was lower than surrogate-based methods, however, with higher median system latency (350 ms vs. 150 ms). In retrospective in vivo studies, 75 respiratory waveforms of target features from eight subjects were analyzed. The median root-mean-squared prediction error (RMSE) for the fusion-based method (0.97 mm) was reduced (Wilcoxon signed rank test p < 0.05) compared to surrogate-based (1.18 mm) and image-based (1.3 mm) methods. Conclusion: The proposed fusion-based respiratory motion prediction framework using golden-angle radial MRI can achieve low-latency feedback with improved accuracy. Significance: Respiratory motion prediction using the fusion-based method can overcome system latency to provide accurate feedback information for MRI-guided interventions.
ISSN:0018-9294
1558-2531
1558-2531
DOI:10.1109/TBME.2019.2944803