Triggered, navigated, multi‐baseline method for proton resonance frequency temperature mapping with respiratory motion

Vigen, Karl K.; Daniel, Bruce L.; Pauly, John M.; Butts, Kim

doi:10.1002/mrm.10608

Cited by 156 publications

(146 citation statements)

References 21 publications

(32 reference statements)

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“…However, the use of navigator echoes is restricted to rigid body motion and may not be optimal for complex organ displacements or deformations. A triggered, navigated, multi-baseline method was demonstrated in the liver in vivo with variable respiratory motion (95). This technique uses respiratory triggering, diaphragm position determination with a navigator echo, and the collection of multiple baseline images to generate the temperature maps.…”

Section: Prf Thermometry and Motionmentioning

confidence: 99%

MR thermometry

Rieke

Pauly

2008

Magnetic Resonance Imaging

1,006

952

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Minimally invasive thermal therapy as local treatment of benign and malignant diseases has received increasing interest in recent years. Safety and efficacy of the treatment require accurate temperature measurement throughout the thermal procedure. Noninvasive temperature monitoring is feasible with magnetic resonance (MR) imaging based on temperature-sensitive MR parameters such as the proton resonance frequency (PRF), the diffusion coefficient (D), T 1 and T 2 relaxation times, magnetization transfer, the proton density, as well as temperature-sensitive contrast agents. In this article the principles of temperature measurements with these methods are reviewed and their usefulness for monitoring in vivo procedures is discussed. Whereas most measurements give a temperature change relative to a baseline condition, temperature-sensitive contrast agents and spectroscopic imaging can provide absolute temperature measurements. The excellent linearity and temperature dependence of the PRF and its near independence of tissue type have made PRF-based phase mapping methods the preferred choice for many in vivo applications. Accelerated MRI imaging techniques for real-time monitoring with the PRF method are discussed. Special attention is paid to acquisition and reconstruction methods for reducing temperature measurement artifacts introduced by tissue motion, which is often unavoidable during in vivo applications.

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Section: Prf Thermometry and Motionmentioning

confidence: 99%

MR thermometry

Rieke

Pauly

2008

Magnetic Resonance Imaging

1,006

952

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“…Several approaches for the removal of thermometry artifacts have been proposed in the past, such as multibaseline corrections to sample periodic changes (11,12) and referenceless phase corrections (13). A recent approach combined multibaseline corrections with rapid two dimensional (2D) image registration to provide both a removal of thermometry artifacts and a correction of in-plane displacement in real-time (14).…”

mentioning

confidence: 99%

Spectrally selective pencil‐beam navigator for motion compensation of MR‐guided high‐intensity focused ultrasound therapy of abdominal organs

Köhler

Senneville

Quesson

et al. 2011

Magnetic Resonance in Med

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MR-guided high-intensity focused ultrasound (MR-HIFU) is a noninvasive technique for depositing thermal energy in a controlled manner deep within the body. However, the MR-HIFU treatment of mobile abdominal organs is problematic as motion-related thermometry artifacts need to be corrected and the focal point position must be updated in order to follow the moving organ to avoid damaging healthy tissue. In this article, a fat-selective pencil-beam navigator is proposed for real-time monitoring and compensation of through-plane motion. As opposed to the conventional spectrally nonselective navigator, the fat-selective navigator does not perturb the water-proton magnetization used for proton resonance frequency shift thermometry. This allows the proposed navigator to be placed directly on the target organ for improved motion estimation accuracy. The spectral and spatial selectivity of the proposed navigator pulse is evaluated through simulations and experiments, and the improved slice tracking performance is demonstrated in vivo by tracking experiments on a human kidney and on a human liver. The direct motion estimation provided by the fat-selective navigator is also shown to enable accurate motion compensated MR-HIFU therapy of in vivo porcine kidney, including motion compensation of thermometry and beam steering based on the observed threedimensional kidney motion. Magn Reson Med 66:102-111,

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“…Ultimately, it would be desirable to be able to treat free-breathing awake patients. This may be possible using real-time motion tracking, perhaps using the ultrasound probe itself to track the motion (30), a phased array with a large steering range, and motioninsensitive MR thermometry schemes (31)(32)(33).…”

Section: Livermentioning

confidence: 99%

“…Such phased array devices will develop further to their full potential through the implementation of treatment plans that include beam aberration correction (80) and the optimization of thermal dose delivery (81). Fully automatic closed-loop feedback to control heating (40,57,81,82) combined with robust motion detection and correction schemes for the MR thermometry (31)(32)(33)83) will also likely reach the clinic for MRgFUS.…”

Section: Future Development Of Technologymentioning

confidence: 99%

Current status and future potential of MRI‐guided focused ultrasound surgery

Jólesz

McDannold

2008

Magnetic Resonance Imaging

112

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The combination of the imaging abilities of magnetic resonance imaging (MRI) with the ability to delivery energy to targets deep in the body noninvasively with focused ultrasound presents a disruptive technology with the potential to significantly affect healthcare. MRI offers precise targeting, visualization, and quantification of temperature changes and the ability to immediately evaluate the treatment. By exploiting different mechanisms, focused ultrasound offers a range of therapies, ranging from thermal ablation to targeted drug delivery. This article reviews recent preclinical and tests clinical of this technology. WHILE ITS POTENTIAL has been recognized for decades (1-4), focused ultrasound (FUS) therapy has been in the incubation phase for a long time. Although it has been tested in numerous animal experiments, its widespread clinical realization has lagged, primarily due to the lack of intraprocedural accurate temperature monitoring. When the idea of MRI-guidance was introduced in connection with FUS and MRI thermometry during sonication was demonstrated (5,6), it was anticipated that MR-guided FUS surgery (MRgFUS) would be widely accepted clinically within a few years. Despite these early expectations, there has been relatively slow progress in the clinical implementation of MRgFUS.Early development concentrated primarily on breast tumors (benign fibroadenoma (7,8) and malignant breast cancer (9,10)). These early implementations of the MRgFUS technology motivated the improvement of transducer technology from single-element transducers to MRI-compatible multielement phase arrays (11). There was also significant progress in MRI thermometry and its use to monitor and control sonications. Importantly, too, methods were developed to robustly quantify temperature changes (12). At first, only 2D temperature maps were obtained by MRI to allow for accurate targeting of the beam (13). Later these thermal images were used to generate maps of the thermal dose (14) that could then be used to tailor the energy deposition using closed-loop feedback control (15). This preclinical work led to the development of the first commercial system by InSightec (Haifa, Israel), the Exablate 2000, the first implementation of a fully integrated MRgFUS system that combined a phased array transducer, a computer-controlled robotic positioner, and a workstation that integrated control based on MR thermometry.The early limited clinical trials of breast tumor treatment (8 -10,16,17) were followed by the first major clinical application: the noninvasive therapy of benign uterine fibroids (18,19). The successful Phase I trial was followed by a multicenter . These clinical trials led to the approval of this technology for the treatment of uterine fibroids in several countries, including the United States. Examples of MR thermometry and postablation imaging of a uterine fibroid ablation are shown in Figure 1.The success of uterine fibroid ablation has invigorated the entire field. Technology has rapidly improved and clinical applications ke...

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Triggered, navigated, multi‐baseline method for proton resonance frequency temperature mapping with respiratory motion

Cited by 156 publications

References 21 publications

MR thermometry

MR thermometry

Spectrally selective pencil‐beam navigator for motion compensation of MR‐guided high‐intensity focused ultrasound therapy of abdominal organs

Current status and future potential of MRI‐guided focused ultrasound surgery

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