Abstract
Purpose: In local hyperthermia, precise temperature control throughout the entire target region is key for swift, safe, and effective treatment. In this article, we present a model predictive control (MPC) algorithm providing voxel-level temperature control in magnetic resonance-guided high intensity focused ultrasound (MR-HIFU) and assess the improvement in performance it provides over the current state of the art.Materials and methods: The influence of model detail on the prediction quality and runtime of the controller is evaluated and a tissue mimicking phantom is characterized using the resulting model. Next, potential problems arising from modeling errors are evaluated in silico and in the characterized phantom. Finally, the controller’s performance is compared to the current state-of-the-art hyperthermia controller in side-by-side experiments.Results: Modeling diffusion by heat exchange between four neighboring voxels achieves high predictive performance and results in runtimes suited for real-time control. Erroneous model parameters deteriorate the MPC’s performance. Using models derived from thermometry data acquired during low powered test sonications, however, high control performance is achieved. In a direct comparison with the state-of-the-art hyperthermia controller, the MPC produces smaller tracking errors and tighter temperature distributions, both in a homogeneous target and near a localized heat sink.Conclusion: Using thermal models deduced from low-powered test sonications, the proposed MPC algorithm provides good performance in phantoms. In direct comparison to the current state-of-the-art hyperthermia controller, MPC performs better due to the more finely tuned heating patterns and therefore constitutes an important step toward stable, uniform hyperthermia.
Highlights
Mild local heating of tumor tissue to hyperthermic temperature in the range of 41–43 C has been shown to have strong synergistic effects on radio- and chemotherapy, acting on cellular and tissue level [1,2,3,4,5,6]
We present a model predictive control (MPC) algorithm providing voxel-level temperature control in magnetic resonance-guided high intensity focused ultrasound (MR-HIFU) and assess the improvement in performance it provides over the current state of the art
Radiofrequency-based hyperthermia devices integrated into a magnetic resonance imaging (MRI) scanner could address some of above shortcomings and are currently evaluated for use in clinical settings [20,21]
Summary
Mild local heating of tumor tissue to hyperthermic temperature in the range of 41–43 C has been shown to have strong synergistic effects on radio- and chemotherapy, acting on cellular and tissue level [1,2,3,4,5,6]. In combination with MR thermometry and a simple binary feedback loop, electronic beam steering has been used to achieve MRHIFU mediated, regional hyperthermia The feasibility of this technique has been demonstrated in several preclinical studies [36,37,38,39,40,41,42] and recently in a first clinical trial using the MR-HIFU system SonalleveVR (Profound Medical Inc., Toronto, Canada) [43]. We explore a novel control algorithm for MR-HIFU mediated mild hyperthermia applications, following the MPC paradigm It aims to improve upon the existing binary control option by Tillander et al [44], which we consider to be the state of the art, by optimizing the heat delivered to each individual voxel inside the target ROI based on a mathematical model of the tissue. Since the controller was implemented on a clinical MR-HIFU system, a direct performance comparison between the MPC and the existing binary control algorithm of Tillander et al [44] was performed and is presented last
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