Waveguide effects and implications for cardiac magnetic resonance elastography: A finite element study

Manduca, Armando; Rossman, Timothy; Lake, David S.; Glaser, Kevin J.; Arani, Arvin; Arunachalam, Shivaram P.; Rossman, Phillip J.; Trzasko, Joshua D.; Ehman, Richard L.; Dragomir-Daescu, Dan; Araoz, Philip A.

doi:10.1002/nbm.3996

Cited by 10 publications

(13 citation statements)

References 35 publications

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“…In objects with at least one dimension smaller than about a wavelength (such as in the heart or within tumors), wave behavior depends on geometry as well as the inherent material properties, and such “waveguide effects” can dominate the wave propagation. Consequently, inversion approaches that do not account for this yield biased values 37,71 . This is particularly important in cardiac MRE with typical wall thicknesses around 10 mm.…”

Section: Nomenclature For Mrementioning

confidence: 99%

“…54 Taking the curl of the displacement wave field in a homogeneous medium removes longitudinal contributions in theory, leaving behind a wave field that propagates at the true shear wave speed, corresponding to the intrinsic shear modulus. 37,71 However, there are practical difficulties: This requires full 3D data with good resolution in z, causes noise amplification, and low resolution may mean that spatial gradient operators may cross boundaries and yield incorrect results. Alternatively, some inversion approaches (eg, nonlinear inversion) may yield more accurate results near boundaries or in waveguide situations.…”

Section: Waveguide or Boundary Effectsmentioning

confidence: 99%

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MR elastography: Principles, guidelines, and terminology

Manduca

Bayly

Ehman

et al. 2020

Magnetic Resonance in Med

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128

144

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MANDUCA et Al. per year is increasing rapidly (Figure 1). However, numerous types of acquisitions and processing techniques are in use, and MRE results have been expressed in many different quantities: shear modulus (possibly complex), storage modulus, magnitude of the complex shear modulus, shear stiffness (defined in different ways), wave speed, propagation, loss modulus, attenuation, loss tangent or loss factor, phase angle, damping ratio, attenuation, and penetration rate. This list is not exhaustive and does not include additional quantities related to fitting specific assumed material models or anisotropic materials. This diversity of terminology and absence of standardization can lead to confusion (particularly among clinicians) as to the meaning of certain terms, or how to interpret or compare certain types of MRE results. This paper is written by the MRE Guidelines Committee, a group formalized at the first meeting of the ISMRM MRE Study Group, to attempt to clarify and (to some extent) standardize MRE terminology and practice. Specifically, the purpose of this paper is to (1) explain MRE terminology to those not familiar with it, (2) define "good practices" for practitioners of MRE, and (3) discuss some practices and terms that we believe should be standardized and some that should be discouraged. F I G U R E 2 Schematic stress-strain relationship for soft tissue unloaded and at three different tissue-loading states. Magnetic resonance elastography measures the slope of this curve at a given point, as indicated by the tangent line at ε 3

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Section: Nomenclature For Mrementioning

confidence: 99%

Section: Waveguide or Boundary Effectsmentioning

confidence: 99%

MR elastography: Principles, guidelines, and terminology

Manduca

Bayly

Ehman

et al. 2020

Magnetic Resonance in Med

Self Cite

128

144

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“…The displacement fields are then fed into the MRE reconstruction pipeline, which solves the inverse problem and retrieves the mechanical properties for comparison with groundtruth values. Simulations are generally based on analytical formulations [5,14,17,21] or finite element methods (FEM), either with custom-developed tools [22][23][24] or dedicated commercial softwares [20,[24][25][26][27][28][29][30]. Simulations are very useful to assess the error linked to reconstruction algorithms, however they do not suffice to reflect all potential limitations of an MRE experiment (transducer, B 0 and B 1 inhomogeneities, SNR, motion sensitivity, susceptibility issues, and heterogeneity of the material at very small scales).…”

Section: Introductionmentioning

confidence: 99%

Elastography Validity Criteria Definition Using Numerical Simulations and MR Acquisitions on a Low-Cost Structured Phantom

et al. 2021

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MR Elastography is a novel technique enabling the quantification of mechanical properties in tissue with MRI. It relies on a three-step process that includes the generation of a mechanical vibration, motion capture using dedicated MR sequences, and data processing involving inversion algorithms. If not properly tuned to the targeted application, each of those steps may impact the final outcome, potentially causing diagnostic errors and thus eventually treatment mismanagement. Different approaches exist that account for acquisition or reconstruction errors, but simple tools and metrics for quality control shared by both developers and end-users are still missing. In this context, our goal is to provide an easily deployable workflow that uses generic validity criteria to assess the performance of a given MRE protocol, leveraging numerical simulations with an accessible experimental setup. Numerical simulations are used to help both determining sets of relevant acquisition parameters and assessing the data processing's robustness. Simple validity criteria were defined, and the overall pipeline was tested in a custom-built, structured phantom made of silicone-based material. The latter have the advantage of being inexpensive, easy to handle, facilitate the fabrication of complex structures which geometry resembles the anatomical structures of interest, and are longitudinally stable. In this work, we successfully tested and evaluated the overall performances of our entire MR Elastography pipeline using easy-to-implement and accessible tools that could ultimately translate in MRE standardized and cost-effective procedures.

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“…In the Helmholtz equation, the medium is assumed to be infinite. For most soft tissues in which MRE has been performed (e.g., aorta, heart, and spinal cord), the media are bounded in which the propagating mechanical wave becomes complicated due to the relatively small dimensions and the geometry of the object 55 . Additionally, in bounded media, the equation of motion presented in Equation 2 will no longer hold and thus, new equations of motion that take geometry of the medium into account are needed.…”

Section: Mre Inversionmentioning

confidence: 99%

“…Promising results in different applications were observed. Manduca et al studied the waveguide effects in simulated cardiac MRE data using FEM and reported that inversion without curl processing resulted in biased stiffness values 55 . Moreover, it was observed that 3D inversion on curl-processed MRE data yielded more accurate stiffness estimation when compared to 2D inversion with curl processing, suggesting the importance of 3D MRE inversion.…”

Section: Mre Inversionmentioning

confidence: 99%

Advances and Future Direction of Magnetic Resonance Elastography

Dong

White

Kolipaka

2018

Topics in Magnetic Resonance Imaging

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The mechanical properties of soft tissues are closely associated with a variety of diseases. This motivates the development of elastography techniques in which tissue mechanical properties are quantitatively estimated through imaging. Magnetic resonance elastography (MRE) is a non-invasive phase-contrast MR technique where shear modulus of soft tissue can be spatially and temporally estimated. MRE has recently received significant attention due to its capability in non-invasively estimating tissue mechanical properties, which can offer considerable diagnostic potential. In this work, recent technology advances of MRE, its future clinical applications, and the related limitations will be discussed.

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Waveguide effects and implications for cardiac magnetic resonance elastography: A finite element study

Cited by 10 publications

References 35 publications

MR elastography: Principles, guidelines, and terminology

MR elastography: Principles, guidelines, and terminology

Elastography Validity Criteria Definition Using Numerical Simulations and MR Acquisitions on a Low-Cost Structured Phantom

Advances and Future Direction of Magnetic Resonance Elastography

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