Model validation for a noninvasive arterial stenosis detection problem

Banks, Harvey Thomas; Hu, Shuhua; Kenz, Z.R.; Kruse, Carola; Shaw, Sylvie; Whiteman, J. R.; Brewin, M.P.; Greenwald, Stephen E.; Birch, Malcolm

doi:10.3934/mbe.2014.11.427

Cited by 8 publications

(2 citation statements)

References 52 publications

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“…We refer to for a much more detailed treatment of the background to both the biomedical science and the proposed methodology and algorithm; to and for full details of the inverse problem and to for the experimental protocol and findings.…”

Section: Application: Shear Waves In Biotissue‐mimicking Gelmentioning

confidence: 99%

“…The material data are taken as ϱ = 1010 kg∕m 3 , E 0 = 167 kPa and ν = 0.44 (the Voigt term was set to zero:

\underset{bold-italicC}{falsemml-underline} MathClass-rel= \underset{bold-italic 0}{falsemml-underline}

). High quality estimates for the viscoelastic parameters have now appeared in but, for the sake of illustration here, we simply took ϕ 0 = 0.2, ϕ 1 = 0.8 and τ 1 = 2 with N ϕ = 1 in . The spatial discretization used in the succeeding text is a SEM on, mostly, a 13 (radial) by 25 (axial) uniform mesh of bicubics supported on tensor products of the Gauss–Lobatto nodes.…”

Section: Application: Shear Waves In Biotissue‐mimicking Gelmentioning

confidence: 99%

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High‐order space‐time finite element schemes for acoustic and viscodynamic wave equations with temporal decoupling

Banks

Birch

Brewin

et al. 2014

Numerical Meth Engineering

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We revisit a method originally introduced by Werder et al. (in Comput. Methods Appl. Mech. Engrg., 190:6685–6708, 2001) for temporally discontinuous Galerkin FEMs applied to a parabolic partial differential equation. In that approach, block systems arise because of the coupling of the spatial systems through inner products of the temporal basis functions. If the spatial finite element space is of dimension D and polynomials of degree r are used in time, the block system has dimension (r + 1)D and is usually regarded as being too large when r > 1. Werder et al. found that the space-time coupling matrices are diagonalizable over for r ⩽100, and this means that the time-coupled computations within a time step can actually be decoupled. By using either continuous Galerkin or spectral element methods in space, we apply this DG-in-time methodology, for the first time, to second-order wave equations including elastodynamics with and without Kelvin–Voigt and Maxwell–Zener viscoelasticity. An example set of numerical results is given to demonstrate the favourable effect on error and computational work of the moderately high-order (up to degree 7) temporal and spatio-temporal approximations, and we also touch on an application of this method to an ambitious problem related to the diagnosis of coronary artery disease. Copyright © 2014 The Authors. International Journal for Numerical Methods in Engineering published by John Wiley & Sons Ltd.

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Section: Application: Shear Waves In Biotissue‐mimicking Gelmentioning

confidence: 99%

“…The material data are taken as ϱ = 1010 kg∕m 3 , E 0 = 167 kPa and ν = 0.44 (the Voigt term was set to zero:

\underset{bold-italicC}{falsemml-underline} MathClass-rel= \underset{bold-italic 0}{falsemml-underline}

Section: Application: Shear Waves In Biotissue‐mimicking Gelmentioning

confidence: 99%

High‐order space‐time finite element schemes for acoustic and viscodynamic wave equations with temporal decoupling

Banks

Birch

Brewin

et al. 2014

Numerical Meth Engineering

Self Cite

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Estimating intratumoral heterogeneity from spatiotemporal data

2018

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Glioblastoma multiforme (GBM) is a malignant brain cancer with a tendency to both migrate and proliferate. We propose modeling GBM with heterogeneity in cell phenotypes using a random differential equation version of the reaction-diffusion equation, where the parameters describing diffusion (D) and proliferation ([Formula: see text]) are random variables. We investigate the ability to perform the inverse problem to recover the probability distributions of D and [Formula: see text] using the Prohorov metric, for a variety of probability distribution functions. We test the ability to perform the inverse problem for noisy synthetic data. We then examine the predicted effect of treatment, specifically, chemotherapy, when assuming such a heterogeneous population and compare with predictions from a homogeneous cell population model.

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Experimental and numerical investigation on soft tissue dynamic response due to turbulence-induced arterial vibration

Salman

Yazıcıoğlu

2019

Med Biol Eng Comput

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Model validation for a noninvasive arterial stenosis detection problem

Cited by 8 publications

References 52 publications

High‐order space‐time finite element schemes for acoustic and viscodynamic wave equations with temporal decoupling

High‐order space‐time finite element schemes for acoustic and viscodynamic wave equations with temporal decoupling

Estimating intratumoral heterogeneity from spatiotemporal data

Experimental and numerical investigation on soft tissue dynamic response due to turbulence-induced arterial vibration

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