<i>In vivo</i> viscoelastic properties of the brain in normal pressure hydrocephalus

Streitberger, Kaspar Josche; Wiener, Edzard; Hoffmann, Jan; Freimann, Florian Baptist; Klatt, Dieter; Braun, Jürgen; Lin, Kui; McLaughlin, Joyce R.; Sprung, Christian; Klingebiel, Randolf; Sack, Ingolf

doi:10.1002/nbm.1602

Cited by 162 publications

(146 citation statements)

References 32 publications

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“…A moderate reduction in estimated mechanical property resolution will reduce the visibility of small scale mechanical property variations; however, many of the clinical MRE results reported to date have used a spatial average of mechanical properties taken over large regions. 2,5,17,31 A moderate reduction in the property resolution will not have a large effect on these types of measurements.…”

Section: Discussionmentioning

confidence: 99%

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Multiresolution MR elastography using nonlinear inversion

et al. 2012

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Purpose: Nonlinear inversion (NLI) in MR elastography requires discretization of the displacement field for a finite element (FE) solution of the "forward problem", and discretization of the unknown mechanical property field for the iterative solution of the "inverse problem". The resolution requirements for these two discretizations are different: the forward problem requires sufficient resolution of the displacement FE mesh to ensure convergence, whereas lowering the mechanical property resolution in the inverse problem stabilizes the mechanical property estimates in the presence of measurement noise. Previous NLI implementations use the same FE mesh to support the displacement and property fields, requiring a trade-off between the competing resolution requirements. Methods: This work implements and evaluates multiresolution FE meshes for NLI elastography, allowing independent discretizations of the displacements and each mechanical property parameter to be estimated. The displacement resolution can then be selected to ensure mesh convergence, and the resolution of the property meshes can be independently manipulated to control the stability of the inversion. Results: Phantom experiments indicate that eight nodes per wavelength (NPW) are sufficient for accurate mechanical property recovery, whereas mechanical property estimation from 50 Hz in vivo brain data stabilizes once the displacement resolution reaches 1.7 mm (approximately 19 NPW). Viscoelastic mechanical property estimates of in vivo brain tissue show that subsampling the loss modulus while holding the storage modulus resolution constant does not substantially alter the storage modulus images. Controlling the ratio of the number of measurements to unknown mechanical properties by subsampling the mechanical property distributions (relative to the data resolution) improves the repeatability of the property estimates, at a cost of modestly decreased spatial resolution. Conclusions: Multiresolution NLI elastography provides a more flexible framework for mechanical property estimation compared to previous single mesh implementations.

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Section: Discussionmentioning

confidence: 99%

“…Tissue shear modulus is relevant to diagnosing diseases including cancer, 1 liver fibrosis, 2 and multiple sclerosis. 3 Other mechanical properties such as the viscoelastic loss modulus [3][4][5] have also shown promise as diagnostic criteria.…”

Section: Introductionmentioning

confidence: 99%

Multiresolution MR elastography using nonlinear inversion

et al. 2012

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“…10,11,14,24 The recent development of a 3D multislab, multishot acquisition for whole-brain MRE could achieve high signal-to-noise efficacy. [25][26][27][28][29] 3D analysis could improve the results if the wave propagation is complicated, especially if there is throughplane oblique wave propagation that a 2D analysis would not visualize correctly.…”

Section: Discussionmentioning

confidence: 99%

“…7 Although MRE is not common in a neurologic setting, a series of attempts have been made to measure the stiffness of the brain affected by Alzheimer disease, 8,9 multiple sclerosis, 10 and normal-pressure hydrocephalus. 11,12 As for intracranial tumors, only a few studies involving meningiomas and glioblastomas have been published. 13,14 In these studies, a correlation between histopathologic characteristics and MRE has not been described in detail.…”

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confidence: 99%

Shear Stiffness of 4 Common Intracranial Tumors Measured Using MR Elastography: Comparison with Intraoperative Consistency Grading

Sakai¹,

Takehara²,

Yamashita

et al. 2016

AJNR Am J Neuroradiol

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“…In the literature, Green et al (2008), Sack et al (2009), Streitberger et al (2011), have measured the viscoelastic modulus of brains in vivo using MRE with clinical MRI, considering both magnitude and phase of the displacement in the tissue. Asbach et al (2008) Viscoelastic modulus of agarose gels by magnetic resonance elastography using Micro-MRI…”

Section: Introductionmentioning

confidence: 99%

Viscoelastic modulus of agarose gels by magnetic resonance elastography using Micro-MRI

Suzuki

Tadano

Goto

et al. 2015

Mechanical Engineering Journal

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This study aimed to apply magnetic resonance elastography (MRE) using micro-magnetic resonance imaging (micro-MRI) system for the measurements of viscoelastic modulus in soft matters. The rectangular specimens of 90 × 70 × 50 mm were made of agarose gel with five kinds of stiffness by changing concentrations. The specimens were oscillated with longitudinal waves transmitted by an elastic-bar from a vibration generator in a micro-MRI system. Since the viscoelastic properties depend on the excitation frequency and amplitude, the experimental conditions were selected in the range of 50-250 Hz and 0.1-0.5 mm. The viscoelastic modulus was expressed as storage shear modulus G′ and loss shear modulus G″. As a result, G′ increased with the frequency and amplitude, and the difference of G′ between hard and soft gels was obtained. The viscoelastic modulus of agarose gels was measured using the MRE system under the excitation conditions. Furthermore, double-layer specimens composed of 0.6 and 2.0 wt% gels were examined as an application of the MRE system. The difference of wave pattern between the hard and soft parts was observed. The values of G′ in the soft parts of the double-layer specimens corresponded to the value of the single-layer specimen, but the values of G′ in the hard parts were varied. and Klatt et al. (2010) have also measured the viscoelastic modulus of livers in vivo.The authors developed an MRE system consisting of a micro-magnetic resonance imaging (micro-MRI) with 0.3 T, a bar-type transmitter, and a vibration generator, which allowed the excitation frequency of 50-250 Hz and the amplitude of 0.1-0.5 mm (Tadano, et al., 2012). The bar-type transmitter and the vibration generator were used to generate strong excitation. In that study, it was confirmed that the distribution of displacement was obtained within the agarose gel of 1.2 wt% concentration under the excitation conditions. Furthermore, to decrease the error of viscoelastic modulus, the authors proposed a calculation method for the MRE measurements under the low magnetic field based on the integration of the displacement (Jiang and Nakamura, 2011). It is necessary to apply the MRE instrument and the calculation method to the measurements of viscoelastic modulus of soft matters and to discuss the availability of the system. Therefore, the present study aimed to investigate the effect of the excitation frequency of 50-250 Hz and the amplitude of 0.1-0.5 mm on the viscoelastic modulus of agarose gels with five kinds of stiffness by using the MRE system. Furthermore, the distributions of the displacement and viscoelastic modulus in the specimens consisting of hard and soft gel parts were investigated as an application of the MRE system. Three kinds of the double-layer specimen were examined in the study. MethodsWhen a specimen was excited with a sine wave in the MRI, local displacements in the specimen under a gradient magnetic field were calculated from the phase shift of MR signal (Muthupillai, et al., 1996;Manduca, et al., 2001). A complex...

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In vivo viscoelastic properties of the brain in normal pressure hydrocephalus

Cited by 162 publications

References 32 publications

Multiresolution MR elastography using nonlinear inversion

Multiresolution MR elastography using nonlinear inversion

Shear Stiffness of 4 Common Intracranial Tumors Measured Using MR Elastography: Comparison with Intraoperative Consistency Grading

Viscoelastic modulus of agarose gels by magnetic resonance elastography using Micro-MRI

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