Linear and Nonlinear Viscoelastic Modeling of Aorta and Carotid Pressure–Area Dynamics Under In Vivo and Ex Vivo Conditions

Valdez‐Jasso, Daniela; Bia, Daniel; Armentano, Ricardo L.; Haider, Mansoor A.; Olufsen, Mette S.

doi:10.1007/s10439-010-0236-7

Cited by 89 publications

(86 citation statements)

References 43 publications

(74 reference statements)

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“…The flow at the aortic root can be measured using Doppler ultrasound [44, p. 38] and magnetic resonance (MR) [45]. Blood pressure can be recorded noninvasively in superficial arteries, such as carotid, brachial, radial and femoral, using applanation tonometry [16,25,26,46]. Invasive measurements can be obtained in the aorta and other extracranial arteries using pressuresensing catheters [14].…”

Section: Discussionmentioning

confidence: 99%

“…The internal luminal area can be measured in superficial arteries using ultrasound-based echo-tracking [16,26,47] and MR [45]. Invasive measurements using piezoelectric crystal transducers have been carried out in animal experiments [26].…”

Section: Discussionmentioning

confidence: 99%

“…This is, therefore, a limitation of our study, and a full verification of our results using in vivo data remains to be done in future work. Future work could also carry out a similar analysis using more complex visco-elastic models of the arterial wall that account for stress relaxation [10,23,24] and the nonlinear behaviour of the arterial wall [25,26].…”

Section: Discussionmentioning

confidence: 99%

“…There are, however, more complex models that also account for stress relaxation [10,23,24] and the nonlinear behaviour of the wall [25,26]. Here we use a Voigt-type visco-elastic model since it is the simplest model to reproduce, to first approximation, the main features of visco-elastic effects on blood flow in large arteries [9,16,[20][21][22].…”

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confidence: 99%

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Physical determining factors of the arterial pulse waveform: theoretical analysis and calculation using the 1-D formulation

et al. 2012

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The shape of the arterial pulse waveform is intimately related to the physical properties of the cardiovascular system. It is clinically relevant to measure those properties that are related to cardiovascular function, such as the local elasticity and viscosity of the arterial wall, total compliance and net peripheral resistance of the systemic arterial tree. Most of these properties cannot be directly measured in vivo, but they can be calculated from pressure, flow and wall displacement measurements that can be obtained in vivo. We carry out a linear analysis of the one-dimensional (1-D) equations of blood flow in Voigt-type visco-elastic vessels to study the effects on pulse wave propagation of blood viscosity, flow inertia, wall visco-elasticity, total arterial compliance, net resistance, peripheral outflow pressure, and flow rate at the aortic root. Based on our analysis, we derive methods to calculate the local elastic and viscous moduli of the arterial wall, and the total arterial compliance, net resistance, time constant and peripheral outflow pressure of the systemic arterial tree from pressure, flow and wall displacement data that can be measured in vivo. Analysis of in vivo data is beyond the scope of this study, and therefore, we verify the results of our linear analysis and assess the accuracy of our estimation methods using pulse waveforms simulated in a nonlinear visco-elastic 1-D model of the larger conduit arteries of the upper body, which includes the circle of Willis in the cerebral circulation.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Physical determining factors of the arterial pulse waveform: theoretical analysis and calculation using the 1-D formulation

et al. 2012

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“…28 While obtaining large amounts of data on the stress-strain behavior of such biomaterials is straightforward, analyzing it in a uniform, comparable, and user-independent manner is more challenging. 29 Despite significant advancements in highly correlative mechanistic models [30][31][32][33][34][35][36][37][38] for stress-strain analysis, most of the reported literature still relies on stiffness, as measured by the Young's modulus, as the primary mechanical measure for biological tissues. However, as tissues are subjected to many nonelastic deformation modes and their responses may differ significantly from ideal spring behavior, measuring only this characteristic can be misleading, at best.…”

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confidence: 99%

A Mathematical Model for Analyzing the Elasticity, Viscosity, and Failure of Soft Tissue: Comparison of Native and Decellularized Porcine Cardiac Extracellular Matrix for Tissue Engineering

Bronshtein

Au-Yeung

Sarig

et al. 2013

Tissue Engineering Part C: Methods

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The clinical success of tissue-engineered constructs commonly requires mechanical properties that closely mimic those of the human tissue. Determining the viscoelastic properties of such biomaterials and the factors governing their failure profiles, however, has proven challenging, although collecting extensive data regarding their tensile behavior is straightforward. The easily calculated Young's modulus remains the most reported mechanical measure, regardless of its limitations, even though single-relaxation-time (SRT) models can provide much more information, which remain scarce due to a lack of manageable tools for implementing these models. We developed an easy-to-use algorithm for applying the Zener SRT model and determining the elastic moduli, viscosity, and failure profiles of materials under different mechanical tests in a user-independent manner. The algorithm was validated on the data resulting from tensile tests on native and decellularized porcine cardiac tissue, previously suggested as a promising scaffold material for cardiac tissue engineering. This analysis yields new and more accurate measurements such as the elastic moduli and viscosity, the model's relaxation time, and information on the factors governing the materials' failure profiles. These measurements indicate that the viscoelasticity and strength of the decellularized acellular extracellular matrix (ECM) are similar to those of native tissue, although its elasticity and apparent viscosity are higher. Nonetheless, reseeding and culturing the ECM with mesenchymal stem cells was shown to partially restore the mechanical properties lost after decellularization. We propose this algorithm as a platform for soft-tissue analysis that can provide comparable and unbiased measures for characterizing viscoelastic biomaterials commonly used in tissue engineering.

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Exploitation of Mechanobiology for Cardiovascular Therapy

2016

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Linear and Nonlinear Viscoelastic Modeling of Aorta and Carotid Pressure–Area Dynamics Under In Vivo and Ex Vivo Conditions

Cited by 89 publications

References 43 publications

Physical determining factors of the arterial pulse waveform: theoretical analysis and calculation using the 1-D formulation

Physical determining factors of the arterial pulse waveform: theoretical analysis and calculation using the 1-D formulation

A Mathematical Model for Analyzing the Elasticity, Viscosity, and Failure of Soft Tissue: Comparison of Native and Decellularized Porcine Cardiac Extracellular Matrix for Tissue Engineering

Exploitation of Mechanobiology for Cardiovascular Therapy

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