Real-time MR-thermometry and dosimetry for interventional guidance on abdominal organs

Roujol, Sébastien; Ries, Mario; Quesson, Bruno; Moonen, Chrit; Senneville, Baudouin Denis de

doi:10.1002/mrm.22309

Cited by 130 publications

(139 citation statements)

References 29 publications

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“…These errors might be caused by respiratory, cardiac, peristaltic or bulk motion with standard deviations of >±10°C even without any application of heat (25,73). Structural changes of the treatment area due to tissue coagulation during an ablation procedure (40) This library is used to link the phase measured during thermal therapy to the correct reference image by means of an acquired navigator echo (22), non-similarity coefficients (77) or intercorrelation coefficients (78,79). While robust to periodic motion, reference or baseline methods are prone to irregular physiological motion such as arrhythmia.…”

Section: Motionmentioning

confidence: 99%

Magnetic resonance thermometry: Methodology, pitfalls and practical solutions

Winter

Oberacker

Paul

et al. 2015

International Journal of Hyperthermia

174

156

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Clinically established thermal therapies like thermo ablative approaches or adjuvant hyperthermia treatment rely on accurate thermal dose information for the evaluation and adaptation of the thermal therapy. Intratumoral temperature measurements have been correlated successfully with clinical endpoints. Magnetic resonance imaging is the most suitable technique for non-invasive thermometry avoiding complications related to invasive temperature measurements. Since the advent of MR thermometry two decades ago, numerous MR thermometry techniques have been developed continuously increasing accuracy and robustness for in vivo applications. While this progress was primarily focused on relative temperature mapping, current and future efforts will likely close the gap towards quantitative temperature readings. These efforts are essential to benchmark thermal therapy efficiency, understand temperature related biophysical and physiological processes and to use these insights to set new landmarks for diagnostic and therapeutic applications. With that in mind, this review summarizes and discusses advances in MR thermometry providing practical considerations, pitfalls and technical obstacles constraining temperature measurement accuracy, spatial and temporal resolution in vivo. Established approaches and current trends in thermal therapy hardware are surveyed with respect to potential benefits for MR thermometry.3

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Section: Motionmentioning

confidence: 99%

Magnetic resonance thermometry: Methodology, pitfalls and practical solutions

Winter

Oberacker

Paul

et al. 2015

International Journal of Hyperthermia

174

156

View full text Add to dashboard Cite

show abstract

“…Motion throughout the imaging session was estimated with an implementation (Roujol et al 2010) of non-rigid registration based on optical flow. As derived by Horn & Schunck (1981), the optical flow's objective function is formulated as…”

Section: Motion Estimationmentioning

confidence: 99%

On-line 3Dmotion estimation using low resolution MRI

et al. 2015

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Abstract.Image processing such as deformable image registration finds its way into radiotherapy as a means to track non-rigid anatomy. With the advent of magnetic resonance imaging (MRI) guided radiotherapy, intrafraction anatomy snapshots become technically feasible. magnetic resonance (MR) imaging provides the needed tissue signal for high-fidelity image registration. However, acquisitions, especially in 3D, take a considerable amount of time. Pushing towards real-time adaptive radiotherapy, MR imaging needs to be accelerated without degrading the quality of information.In this paper, we investigate the impact of image resolution on the quality of motion estimations. Potentially, spatially undersampled images yield comparable motion estimations. At the same time, their acquisition times would reduce greatly due to the sparser sampling. In order to substantiate this hypothesis, an exemplary 4D dataset of the abdomen is downsampled gradually. Subsequently, spatiotemporal deformations are extracted consistently using the same motion estimation for each downsampled dataset. Errors between the original and the respectively downsampled version are then evaluated.Compared to ground-truth, results show high similarity of deformations estimated from downsampled image data. Using a dataset with (2.5mm) 3 voxel size, deformation fields could be recovered well up to a downsampling factor of 2, i.e. (5mm) 3 . In a therapy guidance scenario MRI, imaging speed would accordingly increase approximately fourfold, with acceptable loss of estimated motion quality.

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“…Selecting the corresponding baseline image can be performed by determining the organ's position with a navigator echo, 11 or based on a similarity criterion, such as nonsimilarity coefficients 12 or intercorrelation coefficients. 13,14 The multibaseline methods require cyclic organ motion in order to acquire a full set of all possible baseline images and require additional setup time to assemble the baseline library. They are generally much more robust to motion than conventional baseline subtraction, but remain sensitive to susceptibility changes during therapy.…”

Section: Introductionmentioning

confidence: 99%

Hybrid referenceless and multibaseline subtraction MR thermometry for monitoring thermal therapies in moving organs

et al. 2010

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Purpose: Magnetic resonance thermometry using the proton resonance frequency ͑PRF͒ shift is a promising technique for guiding thermal ablation. For temperature monitoring in moving organs, such as the liver and the heart, problems with motion must be addressed. Multi-baseline subtraction techniques have been proposed, which use a library of baseline images covering the respiratory and cardiac cycle. However, main field shifts due to lung and diaphragm motion can cause large inaccuracies in multi-baseline subtraction. Referenceless thermometry methods based on polynomial phase regression are immune to motion and susceptibility shifts. While referenceless methods can accurately estimate temperature within the organ, in general, the background phase at organ/ tissue interfaces requires large polynomial orders to fit, leading to increased danger that the heated region itself will be fitted by the polynomial and thermal dose will be underestimated. In this paper, a hybrid method for PRF thermometry in moving organs is presented that combines the strengths of referenceless and multi-baseline thermometry. Methods: The hybrid image model assumes that three sources contribute to image phase during thermal treatment: Background anatomical phase, spatially smooth phase deviations, and focal, heat-induced phase shifts. The new model and temperature estimation algorithm were tested in the heart and liver of normal volunteers, in a moving phantom HIFU heating experiment, and in numerical simulations of thermal ablation. The results were compared to multi-baseline and referenceless methods alone. Results: The hybrid method allows for in vivo temperature estimation in the liver and the heart with lower temperature uncertainty compared to multi-baseline and referenceless methods. The moving phantom HIFU experiment showed that the method accurately estimates temperature during motion in the presence of smooth main field shifts. Numerical simulations illustrated the method's sensitivity to algorithm parameters and hot spot features. Conclusions: This new hybrid method for MR thermometry in moving organs combines the strengths of both multi-baseline subtraction and referenceless thermometry and overcomes their fundamental weaknesses.

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Real-time MR-thermometry and dosimetry for interventional guidance on abdominal organs

Cited by 130 publications

References 29 publications

Magnetic resonance thermometry: Methodology, pitfalls and practical solutions

Magnetic resonance thermometry: Methodology, pitfalls and practical solutions

On-line 3Dmotion estimation using low resolution MRI

Hybrid referenceless and multibaseline subtraction MR thermometry for monitoring thermal therapies in moving organs

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