Simulation-Based Joint Estimation of Body Deformation and Elasticity Parameters for Medical Image Analysis

Lee, Huai-Ping; Foskey, Mark; Niethammer, Marc; Krajcevski, Pavel; Lin, Ming C.

doi:10.1109/tmi.2012.2212450

Cited by 53 publications

(20 citation statements)

References 41 publications

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“…Optical methods such as optical coherence tomography 17 and two-photon microtomy 18 can also map the fiber directions at the microscopic level but remain limited to superficial ex vivo tissue and to small regions of interest. In ultrasound imaging, several methods have been proposed to quantify the anisotropy of various physical parameters linked to the fiber orientation, including the ultrasonic attenuation 19, 20 , the integrated backscattered intensity 19–22 and the myocardial stiffness using Elastic Tensor Imaging (ETI) 23 . However, none of these methods has been yet implemented for the time-resolved, 3D mapping of the myocardial fibers orientation.…”

Section: Introductionmentioning

confidence: 99%

Imaging the dynamics of cardiac fiber orientation in vivo using 3D Ultrasound Backscatter Tensor Imaging

Papadacci

Finel

Provost

et al. 2017

Sci Rep

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The assessment of myocardial fiber disarray is of major interest for the study of the progression of myocardial disease. However, time-resolved imaging of the myocardial structure remains unavailable in clinical practice. In this study, we introduce 3D Backscatter Tensor Imaging (3D-BTI), an entirely novel ultrasound-based imaging technique that can map the myocardial fibers orientation and its dynamics with a temporal resolution of 10 ms during a single cardiac cycle, non-invasively and in vivo in entire volumes. 3D-BTI is based on ultrafast volumetric ultrasound acquisitions, which are used to quantify the spatial coherence of backscattered echoes at each point of the volume. The capability of 3D-BTI to map the fibers orientation was evaluated in vitro in 5 myocardial samples. The helicoidal transmural variation of fiber angles was in good agreement with the one obtained by histological analysis. 3D-BTI was then performed to map the fiber orientation dynamics in vivo in the beating heart of an open-chest sheep at a volume rate of 90 volumes/s. Finally, the clinical feasibility of 3D-BTI was shown on a healthy volunteer. These initial results indicate that 3D-BTI could become a fully non-invasive technique to assess myocardial disarray at the bedside of patients.

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Section: Introductionmentioning

confidence: 99%

Imaging the dynamics of cardiac fiber orientation in vivo using 3D Ultrasound Backscatter Tensor Imaging

Papadacci

Finel

Provost

et al. 2017

Sci Rep

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“…In the field of cardiac imaging, the technique has already been successfully implemented to measure quantitatively the temporal variation of stiffness occurring in the myocardium in vivo during the cardiac cycle 34 and the fiber orientation of the different layers of the cardiac muscle. 35 An intracardiac ultrasound approach was proposed by Hollender et al 36 in vivo to assess the stiffness of the interventricular septum using a shear-wave velocimetry technique and ARFI for the characterization of infarcts in porcine heart in vivo. 37 In this study, we have developed a novel, intracardiac, ultrasound-catheter-based SWE technique to image the extent of ablation lesions in vivo.…”

Section: Introductionmentioning

confidence: 99%

Quantitative evaluation of atrial radio frequency ablation using intracardiac shear‐wave elastography

et al. 2014

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“…Following the wide adoption of ultrasound, elastography [2] emerged, which estimates relative elasticity properties by measuring both the deformation of the tissue via ultrasound images and explicitly measuring the external force using special devices. In the last decade or so, numerical methods, such as inverse Finite Element Methods (FEM) [3], [4], were proposed to estimate mechanical properties of deformable body without the measurement of the displacement field. But, these techniques are generally limited to quasi-static deformation process.…”

Section: Introductionmentioning

confidence: 99%

Bayesian estimation of non-rigid mechanical parameters using temporal sequences of deformation samples

Yang

2016

2016 IEEE International Conference on Robotics and Automation (ICRA)

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Material property has great importance in medical robotics. The mechanical properties of the human soft tissue, are important to characterize the tissue deformation of each patient. The (recovered) elasticity parameters can assist surgeons to perform better pre-op surgical planning and enable medical robots to carry out personalized surgical procedures. In this paper, we present a novel algorithm on mechanical-property estimation from a temporal sequence of deformation samples. It does not require an external force-application measurement device or landmark-based displacement tracking. We test our approach on the reconstruction the Young's modulus of a human heart and further validate the results derived from videos using known parameters of tennis and foam balls.

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Simulation-Based Joint Estimation of Body Deformation and Elasticity Parameters for Medical Image Analysis

Cited by 53 publications

References 41 publications

Imaging the dynamics of cardiac fiber orientation in vivo using 3D Ultrasound Backscatter Tensor Imaging

Imaging the dynamics of cardiac fiber orientation in vivo using 3D Ultrasound Backscatter Tensor Imaging

Quantitative evaluation of atrial radio frequency ablation using intracardiac shear‐wave elastography

Bayesian estimation of non-rigid mechanical parameters using temporal sequences of deformation samples

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