TY - JOUR
T1 - Real-time myocardial landmark tracking for MRI-guided cardiac radio-ablation using Gaussian Processes
AU - Huttinga, Niek R. F.
AU - Akdag, Osman
AU - Fast, Martin F.
AU - Verhoeff, Joost J. C.
AU - Mohamed Hoesein, Firdaus A. A.
AU - van den Berg, Cornelis A. T.
AU - Sbrizzi, Alessandro
AU - Mandija, Stefano
N1 - Funding Information: The authors acknowledge funding by ITEA Eureka cluster on Software innovation through the SIGNET project no. 20052, and by the Dutch Research Council (NWO) through project no. 18078 (VENI) and project no. 19484 (MEGAHERTZ). Publisher Copyright: © 2023 Institute of Physics and Engineering in Medicine.
PY - 2023/7/21
Y1 - 2023/7/21
N2 - Objective. The high speed of cardiorespiratory motion introduces a unique challenge for cardiac stereotactic radio-ablation (STAR) treatments with the MR-linac. Such treatments require tracking myocardial landmarks with a maximum latency of 100 ms, which includes the acquisition of the required data. The aim of this study is to present a new method that allows to track myocardial landmarks from few readouts of MRI data, thereby achieving a latency sufficient for STAR treatments. Approach. We present a tracking framework that requires only few readouts of k-space data as input, which can be acquired at least an order of magnitude faster than MR-images. Combined with the real-time tracking speed of a probabilistic machine learning framework called Gaussian Processes, this allows to track myocardial landmarks with a sufficiently low latency for cardiac STAR guidance, including both the acquisition of required data, and the tracking inference. Main results. The framework is demonstrated in 2D on a motion phantom, and in vivo on volunteers and a ventricular tachycardia (arrhythmia) patient. Moreover, the feasibility of an extension to 3D was demonstrated by in silico 3D experiments with a digital motion phantom. The framework was compared with template matching—a reference, image-based, method—and linear regression methods. Results indicate an order of magnitude lower total latency (<10 ms) for the proposed framework in comparison with alternative methods. The root-mean-square-distances and mean end-point-distance with the reference tracking method was less than 0.8 mm for all experiments, showing excellent (sub-voxel) agreement. Significance. The high accuracy in combination with a total latency of less than 10 ms—including data acquisition and processing—make the proposed method a suitable candidate for tracking during STAR treatments. Additionally, the probabilistic nature of the Gaussian Processes also gives access to real-time prediction uncertainties, which could prove useful for real-time quality assurance during treatments.
AB - Objective. The high speed of cardiorespiratory motion introduces a unique challenge for cardiac stereotactic radio-ablation (STAR) treatments with the MR-linac. Such treatments require tracking myocardial landmarks with a maximum latency of 100 ms, which includes the acquisition of the required data. The aim of this study is to present a new method that allows to track myocardial landmarks from few readouts of MRI data, thereby achieving a latency sufficient for STAR treatments. Approach. We present a tracking framework that requires only few readouts of k-space data as input, which can be acquired at least an order of magnitude faster than MR-images. Combined with the real-time tracking speed of a probabilistic machine learning framework called Gaussian Processes, this allows to track myocardial landmarks with a sufficiently low latency for cardiac STAR guidance, including both the acquisition of required data, and the tracking inference. Main results. The framework is demonstrated in 2D on a motion phantom, and in vivo on volunteers and a ventricular tachycardia (arrhythmia) patient. Moreover, the feasibility of an extension to 3D was demonstrated by in silico 3D experiments with a digital motion phantom. The framework was compared with template matching—a reference, image-based, method—and linear regression methods. Results indicate an order of magnitude lower total latency (<10 ms) for the proposed framework in comparison with alternative methods. The root-mean-square-distances and mean end-point-distance with the reference tracking method was less than 0.8 mm for all experiments, showing excellent (sub-voxel) agreement. Significance. The high accuracy in combination with a total latency of less than 10 ms—including data acquisition and processing—make the proposed method a suitable candidate for tracking during STAR treatments. Additionally, the probabilistic nature of the Gaussian Processes also gives access to real-time prediction uncertainties, which could prove useful for real-time quality assurance during treatments.
KW - MR-linac
KW - STAR
KW - magnetic resonance imaging
KW - motion management
KW - radiotherapy
KW - real-time tracking
KW - stereotactic arrhythmia radio-ablation
UR - http://www.scopus.com/inward/record.url?scp=85164241528&partnerID=8YFLogxK
U2 - https://doi.org/10.1088/1361-6560/ace023
DO - https://doi.org/10.1088/1361-6560/ace023
M3 - Article
C2 - 37339638
SN - 0031-9155
VL - 68
JO - Physics in medicine and biology
JF - Physics in medicine and biology
IS - 14
M1 - 145001
ER -