Your search keyword '"Vascular biomechanics"' showing total 48 results

1. Evidence for a protective role of Protein Disulfide Isomerase-A1 against aortic dissection

Author

Porto, Fernando Garcez, Tanaka, Leonardo Yuji, de Bessa, Tiphany Coralie, Oliveira, Percillia Victoria Santos, Souza, Júlia Martins Felipe de, Kajihara, Daniela, Fernandes, Carolina Gonçalves, Santos, Patricia Nolasco, and Laurindo, Francisco Rafael Martins

Published

2023

2. Influence of material parameter variability on the predicted coronary artery biomechanical environment via uncertainty quantification.

Author

Berggren, Caleb C., Jiang, David, Jack Wang, Y. F., Bergquist, Jake A., Rupp, Lindsay C., Liu, Zexin, MacLeod, Rob S., Narayan, Akil, and Timmins, Lucas H.

Subjects

*POLYNOMIAL chaos, *ENERGY function, *STRAIN energy, *DISTRIBUTION (Probability theory), *BIOMECHANICS, *CORONARY arteries

Abstract

Central to the clinical adoption of patient-specific modeling strategies is demonstrating that simulation results are reliable and safe. Indeed, simulation frameworks must be robust to uncertainty in model input(s), and levels of confidence should accompany results. In this study, we applied a coupled uncertainty quantification–finite element (FE) framework to understand the impact of uncertainty in vascular material properties on variability in predicted stresses. Univariate probability distributions were fit to material parameters derived from layer-specific mechanical behavior testing of human coronary tissue. Parameters were assumed to be probabilistically independent, allowing for efficient parameter ensemble sampling. In an idealized coronary artery geometry, a forward FE model for each parameter ensemble was created to predict tissue stresses under physiologic loading. An emulator was constructed within the UncertainSCI software using polynomial chaos techniques, and statistics and sensitivities were directly computed. Results demonstrated that material parameter uncertainty propagates to variability in predicted stresses across the vessel wall, with the largest dispersions in stress within the adventitial layer. Variability in stress was most sensitive to uncertainties in the anisotropic component of the strain energy function. Moreover, unary and binary interactions within the adventitial layer were the main contributors to stress variance, and the leading factor in stress variability was uncertainty in the stress-like material parameter that describes the contribution of the embedded fibers to the overall artery stiffness. Results from a patient-specific coronary model confirmed many of these findings. Collectively, these data highlight the impact of material property variation on uncertainty in predicted artery stresses and present a pipeline to explore and characterize forward model uncertainty in computational biomechanics. [ABSTRACT FROM AUTHOR]

Published

2024

3. PRESENCE OF ATHEROMATOUS PLAQUES AND THEIRS EFFECTS ON THE BLOOD FLOW.

Author

Belhocine, Mostefa, Amrani, Hichem, Fedaoui, Kamel, and Mazouz, Hammoudi

Subjects

ATHEROSCLEROTIC plaque, BLOOD flow, BLOOD transportation, ENDOTHELIUM physiology, ATHEROSCLEROSIS treatment

Abstract

The paper utilizes a finite element method to study both the blood flow and atheromatous plaques. Specifically, the COMSOL finite element package is employed to achieve a fluid model. COMSOL is a powerful finite element tool commonly used in various research and industrial domains to study multiphysics problems. The focus of the investigation is on the geometric aspects of the atheromatous plaques. The study considers different forms and arrangements of stenosis, taking into account the irregularities formed by various shapes of the plaques and the resulting flow patterns. The key findings of the research suggest that the pressure and velocity of blood flow in the artery are dependent on the presence, position, number, and shape of the atheromatous plaques. This information is crucial for understanding the impact of these plaques on blood flow dynamics and may have implications for the diagnosis and treatment of arterial conditions. [ABSTRACT FROM AUTHOR]

Published

2024

4. A new model for evaluating pressure-induced vascular tone in small cerebral arteries.

Author

Coccarelli, Alberto, Pant, Sanjay, Polydoros, Ioannis, and Harraz, Osama F.

Subjects

*DRUG therapy, *SMOOTH muscle, *MUSCLE cells, *CEREBRAL circulation, *MULTISCALE modeling

Abstract

The capacity of small cerebral arteries (SCAs) to adapt to pressure fluctuations has a fundamental physiological role and appears to be relevant in different pathological conditions. Here, we present a new computational model for quantifying the link, and its contributors, between luminal pressure and vascular tone generation in SCAs. This is assembled by combining a chemical sub-model, representing pressure-induced smooth muscle cell (SMC) signalling, with a mechanical sub-model for the tone generation and its transduction at tissue level. The devised model can accurately reproduce the impact of luminal pressure on different cytoplasmic components involved in myogenic signalling, both in the control case and when combined with some specific pharmacological interventions. Furthermore, the model is also able to capture and predict experimentally recorded pressure-outer diameter relationships obtained for vessels under control conditions, both in a Ca 2 + -free bath and under drug inhibition. The modularity of the proposed framework allows the integration of new components for the study of a broad range of processes involved in the vascular function. [ABSTRACT FROM AUTHOR]

Published

2024

5. A mixed-order interpolation solid element for efficient arterial wall simulations.

Author

Mansilla Alvarez, L. A., Ares, G. D., Feijóo, R. A., and Blanco, P. J.

Subjects

*INTERPOLATION, *STATIC equilibrium (Physics), *BENCHMARK problems (Computer science), *MECHANICAL models, *FINITE element method

Abstract

A numerical strategy tailored to model the mechanical equilibrium in vascular vessels is presented. The formulation, based on a specific arrangement of finite elements, exploits the shell-like structure of the vessel wall by proposing a mixed-order approximation of the displacement field. The fields across the thickness are represented by a single element with high order polynomial approximation while the in-plane components are described through low-order 2D polynomials. The formulation is versatile to accommodate any kind of hyperelastic constitutive material model undergoing large strains. A series of numerical examples is presented to validate the effectiveness of the proposed approach. These examples range from benchmark problems reported in the literature to applications in the domain of cardiovascular modeling. The proposed approach proved to be effective and efficient in simulating the mechanics of vascular vessels. [ABSTRACT FROM AUTHOR]

Published

2024

6. Acute Mechanical Consequences of Vessel-Specific Coronary Bypass Combinations.

Author

Kostelnik, Colton J., Gale, Mary K., Crouse, Kiersten J., Shazly, Tarek, and Eberth, John F.

Abstract

Purpose: Premature coronary artery bypass graft (CABG) failure has been linked to geometric, mechanical, and compositional discrepancies between host and graft tissues. Acute hemodynamic disturbances and the introduction of wall stress gradients trigger a myriad of mechanobiological processes at the anastomosis that can be associated with restenosis and graft failure. Although the origins of coronary artery disease dictate the anastomotic target, an opportunity exists for graft-vessel optimization through rationale graft selection. Methods: Here we explored the four distinct regions of the left (L) and right (R) ITA (1 = proximal, 2 = submuscular, 3 = middle, 4 = distal), and four common target vessels in the coronary circulation including the proximal and distal left anterior descending (PLAD & DLAD), right coronary (RCA), and left circumflex (LCX) arteries. Benchtop biaxial mechanical data was used to acquire constitutive model parameters of these tissues and enable vessel-specific computational models to elucidate the mechanical consequences of 32 unique graft-target combinations. Results: Simulations revealed the maximum principal wall stresses for the PLAD, RCA, and LCX occurred when anastomosed with LITA1, and the maximum flow-induced shear stress occurred with LITA4. The DLAD, on the other hand, reached stress maximums when anastomosed to LITA4. Using a normalized objective function of simulation output variables, we found LITA2 to be the best graft choice for both LADs, RITA3 for the RCA, and LITA3 for the LCX. Conclusion: Although mechanical compatibility is just one of many factors determining bypass graft outcomes, our data suggests improvements can be made to the grafting process through vessel-specific regional optimization. [ABSTRACT FROM AUTHOR]

Published

2023

7. A quarter of a century biomechanical rupture risk assessment of abdominal aortic aneurysms. Achievements, clinical relevance, and ongoing developments.

Author

Gasser, T. Christian, Miller, Christopher, Polzer, Stanislav, and Roy, Joy

Subjects

*ABDOMINAL aortic aneurysms, *RISK assessment, *COMPUTATIONAL mechanics

Abstract

Abdominal aortic aneurysm (AAA) disease, the local enlargement of the infrarenal aorta, is a serious condition that causes many deaths, especially in men exceeding 65 years of age. Over the past quarter of a century, computational biomechanical models have been developed towards the assessment of AAA risk of rupture, technology that is now on the verge of being integrated within the clinical decision‐making process. The modeling of AAA requires a holistic understanding of the clinical problem, in order to set appropriate modeling assumptions and to draw sound conclusions from the simulation results. In this article we summarize and critically discuss the proposed modeling approaches and report the outcome of clinical validation studies for a number of biomechanics‐based rupture risk indices. Whilst most of the aspects concerning computational mechanics have already been settled, it is the exploration of the failure properties of the AAA wall and the acquisition of robust input data for simulations that has the greatest potential for the further improvement of this technology. [ABSTRACT FROM AUTHOR]

Published

2023

8. Modeling Fibrous Tissue in Vascular Fluid-Structure Interaction: A Morphology-Based Pipeline and Biomechanical Significance.

Author

Sun Y, Huang J, Lu Q, Yue X, Huang X, He W, Shi Y, and Liu J

Subjects

Humans, Biomechanical Phenomena physiology, Algorithms, Arteries physiology, Arteries anatomy & histology, Computer Simulation, Models, Cardiovascular

Abstract

Modeling fibrous tissue for vascular fluid-structure interaction analysis poses significant challenges due to the lack of effective tools for preparing simulation data from medical images. This limitation hinders the physiologically realistic modeling of vasculature and its use in clinical settings. Leveraging an established lumen modeling strategy, we propose a comprehensive pipeline for generating thick-walled artery models. A specialized mesh generation procedure is developed to ensure mesh continuity across the lumen and wall interface. Exploiting the centerline information, a series of procedures are introduced for generating local basis vectors within the arterial wall. The procedures are tailored to handle thick-walled tissues where basis vectors may exhibit transmural variations. Additionally, we propose methods for accurately identifying the centerline in multi-branched vessels and bifurcating regions. These modeling approaches are algorithmically implementable, rendering them readily integrable into mainstream cardiovascular modeling software. The developed fiber generation method is evaluated against the strategy using linear elastostatics analysis, demonstrating that the proposed approach yields satisfactory fiber definitions in the considered benchmark. Finally, we examine the impact of anisotropic arterial wall models on the vascular fluid-structure interaction analysis through numerical examples, employing the neo-Hookean model for comparative purposes. The first case involves an idealized curved geometry, while the second studies an image-based abdominal aorta model. Our numerical results reveal that the deformation and stress distribution are critically related to the constitutive model of the wall, whereas hemodynamic factors are less sensitive to the wall model. This work paves the way for more accurate image-based vascular modeling and enhances the prediction of arterial behavior under physiologically realistic conditions., (© 2024 John Wiley & Sons Ltd.)

Published

2025

9. Modelling the mechanobiological evolution of aneurysms : an integrative in vivo, in vitro and in silico approach

Author

Mandaltsi, Aikaterini, Watton, Paul N., and Thompson, Mark S.

Subjects

616.1, Biomechanical Engineering, Computational Fluid Dynamics, Vascular biomechanics, Mechanobiology, Aneurysm

Abstract

In silico models of intracranial aneurysm (IA) evolution aim to reliably represent the mechanical blood flow environment, the biology of the arterial wall and, crucially, the complex link between the two, namely the mechanobiology of healthy and diseased arteries. The ultimate goal is to create diagnostic tools for personalized management and treatment of aneurysm disease. Towards that target, the work presented in this thesis aims to establish a directly interactive link between experimental (in vivo and in vitro) and computational work for biologically and clinically relevant research on aneurysm disease. Mechanobiological hypotheses were firstly investigated in a novel 1D mathematical conceptual model of aneurysm evolution: for the first time these included representations of endothelial heterogeneity and smooth muscle cell (SMC) active stress response and apoptosis. The 1D investigations analysed and assessed the role of wall shear stress (WSS) homeostasis in elastin degradation, and the evolving role of the adventitia as a protective sheath in health and primary load-bearer in disease. The 1D framework was applied to a specific patient's aneurysm using both imaging and histological data to parameterise the model, calculating a material parameter for the adventitital collagen. The predicted evolution captured aspects of tissue changes measured with time focusing on the remodelled tissue wall thickness consistent with the experimental measurements, and physiological cyclic deformation in order to propose an approach to modelling adventitia's adaptive role to load bearing. Furthermore, an existing Fluid-Solid-Growth (FSG) computational framework was adapted and calibrated for the same patient-specific case with the help from the experimental data and the analysis from the 1D framework. This FSG model quantifies the arterial mechanical environment and captures the mechanical response of the fibrous arterial constituents. Comparing 1D and 3D investigations to establish consistency for our models, the 3Dmodel tested the hypothesis of WSS homeostasis, additionally introducing the element of spatial heterogeneity in the definition, and a new hypothesis linking cyclic deformation with collagen growth that ensures a physiological mechanical environment in stabilised aneurysms. Moreover, the FSG framework was applied in a specific rabbit aneurysm case and extended to link growth and remodeling to the detailed representation of the pulsatile blood flow mechanical environment. This research illustrates the power of computational modelling when coupled with rich data sets on the physiology, histology and geometry of healthy and diseased vascular tissue. In particular, the integrative modelling framework provides the foundation for establishing mechanobiological links crucial to aneurysm progression, and a basis for further research towards creating reliable aneurysm clinical tools.

Published

2016

10. A Novel In Vivo Approach to Assess Radial and Axial Distensibility of Large and Intermediate Pulmonary Artery Branches

Author

Bellofiore, A, Henningsen, J, Lepak, CG, Tian, L, Roldan-Alzate, A, Kellihan, HB, Consigny, DW, Francois, CJ, and Chesler, NC

Subjects

Engineering, Biomedical Engineering, Lung, Rare Diseases, Biomedical Imaging, Bioengineering, Cardiovascular, Heart Disease, 4.2 Evaluation of markers and technologies, Detection, screening and diagnosis, Animals, Biomechanical Phenomena, Blood Pressure, Dogs, Female, Magnetic Resonance Imaging, Materials Testing, Mechanical Phenomena, Pulmonary Artery, Stress, Mechanical, pulmonary artery stiffness, pulmonary arterial hypertension, vascular biomechanics, magnetic resonance angiography, digital subtraction angiography, Mechanical Engineering, Biomedical engineering

Abstract

Pulmonary arteries (PAs) distend to accommodate increases in cardiac output. PA distensibility protects the right ventricle (RV) from excessive increases in pressure. Loss of PA distensibility plays a critical role in the fatal progression of pulmonary arterial hypertension (PAH) toward RV failure. However, it is unclear how PA distensibility is distributed across the generations of PA branches, mainly because of the lack of appropriate in vivo methods to measure distensibility of vessels other than the large, conduit PAs. In this study, we propose a novel approach to assess the distensibility of individual PA branches. The metric of PA distensibility we used is the slope of the stretch ratio-pressure relationship. To measure distensibility, we combined invasive measurements of mean PA pressure with angiographic imaging of the PA network of six healthy female dogs. Stacks of 2D images of the PAs, obtained from either contrast enhanced magnetic resonance angiography (CE-MRA) or computed tomography digital subtraction angiography (CT-DSA), were used to reconstruct 3D surface models of the PA network, from the first bifurcation down to the sixth generation of branches. For each branch of the PA, we calculated radial and longitudinal stretch between baseline and a pressurized state obtained via acute embolization of the pulmonary vasculature. Our results indicated that large and intermediate PA branches have a radial distensibility consistently close to 2%/mmHg. Our axial distensibility data, albeit affected by larger variability, suggested that the PAs distal to the first generation may not significantly elongate in vivo, presumably due to spatial constraints. Results from both angiographic techniques were comparable to data from established phase-contrast (PC) magnetic resonance imaging (MRI) and ex vivo mechanical tests, which can only be used in the first branch generation. Our novel method can be used to characterize PA distensibility in PAH patients undergoing clinical right heart catheterization (RHC) in combination with MRI.

Published

2015

11. Human genotyping and an experimental model reveal NPR-C as a possible contributor to morbidity in coarctation of the aorta.

Author

LaDisa Jr., John F., Tomita-Mitchell, Aoy, Stamm, Karl, Bazan, Kathleen, Mahnke, Donna K., Goetsch, Mary A., Wegter, Brandon J., Gerringer, Jesse W., Repp, Kathryn, Palygin, Oleg, Zietara, Adrian P., Krolikowski, Mary M., Eddinger, Thomas J., Alli, Abdel A., and Mitchell, Michael E.

Subjects

*AORTIC coarctation, *AORTA, *HYPERTENSION, *THORACIC aorta, *PEPTIDE receptors, *INTRACELLULAR calcium

Abstract

Coarctation of the aorta (CoA) is a common congenital cardiovascular (CV) defect characterized by a stenosis of the descending thoracic aorta. Treatment exists, but many patients develop hypertension (HTN). Identifying the cause of HTN is challenging because of patient variability (e.g., age, follow-up duration, severity) and concurrent CV abnormalities. Our objective was to conduct RNA sequencing of aortic tissue from humans with CoA to identify a candidate gene for mechanistic studies of arterial dysfunction in a rabbit model of CoA devoid of the variability seen with humans. We present the first known evidence of natriuretic peptide receptor C (NPR-C; aka NPR3) downregulation in human aortic sections subjected to high blood pressure (BP) from CoA versus normal BP regions (validated to PCR). These changes in NPR-C, a gene associated with BP and proliferation, were replicated in the rabbit model of CoA. Artery segments from this model were used with human aortic endothelial cells to reveal the functional relevance of altered NPR-C activity. Results showed decreased intracellular calcium ([Ca2+]i) activity to C-type natriuretic peptide (CNP). Normal relaxation induced by CNP and atrial natriuretic peptide was impaired for aortic segments exposed to elevated BP from CoA. Inhibition of NPR-C (M372049) also impaired aortic relaxation and [Ca2+]i activity. Genotyping of NPR-C variants predicted to be damaging revealed that rs146301345 was enriched in our CoA patients, but sample size limited association with HTN. These results may ultimately be used to tailor treatment for CoA based on mechanical stimuli, genotyping, and/or changes in arterial function. [ABSTRACT FROM AUTHOR]

Published

2019

12. Influence of Material Parameter Variability on the Predicted Coronary Artery Biomechanical Environment via Uncertainty Quantification.

Author

Berggren CC, Jiang D, Jack Wang YF, Bergquist JA, Rupp LC, Liu Z, MacLeod RS, Narayan A, and Timmins LH

Abstract

Central to the clinical adoption of patient-specific modeling strategies is demonstrating that simulation results are reliable and safe. Indeed, simulation frameworks must be robust to uncertainty in model input(s), and levels of confidence should accompany results. In this study, we applied a coupled uncertainty quantification-finite element (FE) framework to understand the impact of uncertainty in vascular material properties on variability in predicted stresses. Univariate probability distributions were fit to material parameters derived from layer-specific mechanical behavior testing of human coronary tissue. Parameters were assumed to be probabilistically independent, allowing for efficient parameter ensemble sampling. In an idealized coronary artery geometry, a forward FE model for each parameter ensemble was created to predict tissue stresses under physiologic loading. An emulator was constructed within the UncertainSCI software using polynomial chaos techniques, and statistics and sensitivities were directly computed. Results demonstrated that material parameter uncertainty propagates to variability in predicted stresses across the vessel wall, with the largest dispersions in stress within the adventitial layer. Variability in stress was most sensitive to uncertainties in the anisotropic component of the strain energy function. Moreover, unary and binary interactions within the adventitial layer were the main contributors to stress variance, and the leading factor in stress variability was uncertainty in the stress-like material parameter that describes the contribution of the embedded fibers to the overall artery stiffness. Results from a patient-specific coronary model confirmed many of these findings. Collectively, these data highlight the impact of material property variation on uncertainty in predicted artery stresses and present a pipeline to explore and characterize forward model uncertainty in computational biomechanics., Competing Interests: Statements and Declarations Competing Interests. The authors have no competing financial or non-financial interests to declare that are relevant to the content of this article.

Published

2024

13. A quarter of a century biomechanical rupture risk assessment of abdominal aortic aneurysms. Achievements, clinical relevance, and ongoing developments

Author

Gasser, T. Christian, Miller, Christopher, Polzer, S., Roy, J., Gasser, T. Christian, Miller, Christopher, Polzer, S., and Roy, J.

Abstract

Abdominal aortic aneurysm (AAA) disease, the local enlargement of the infrarenal aorta, is a serious condition that causes many deaths, especially in men exceeding 65 years of age. Over the past quarter of a century, computational biomechanical models have been developed towards the assessment of AAA risk of rupture, technology that is now on the verge of being integrated within the clinical decision-making process. The modeling of AAA requires a holistic understanding of the clinical problem, in order to set appropriate modeling assumptions and to draw sound conclusions from the simulation results. In this article we summarize and critically discuss the proposed modeling approaches and report the outcome of clinical validation studies for a number of biomechanics-based rupture risk indices. Whilst most of the aspects concerning computational mechanics have already been settled, it is the exploration of the failure properties of the AAA wall and the acquisition of robust input data for simulations that has the greatest potential for the further improvement of this technology., QC 20221214

Published

2022

14. A review on the biomechanical behaviour of the aorta.

Author

Wang, Xiaochen, Carpenter, Harry J., Ghayesh, Mergen H., Kotousov, Andrei, Zander, Anthony C., Amabili, Marco, and Psaltis, Peter J.

Subjects

AORTA, TISSUE mechanics, AORTIC dissection, AORTIC aneurysms

Abstract

Large aortic aneurysm and acute and chronic aortic dissection are pathologies of the aorta requiring surgery. Recent advances in medical intervention have improved patient outcomes; however, a clear understanding of the mechanisms leading to aortic failure and, hence, a better understanding of failure risk, is still missing. Biomechanical analysis of the aorta could provide insights into the development and progression of aortic abnormalities, giving clinicians a powerful tool in risk stratification. The complexity of the aortic system presents significant challenges for a biomechanical study and requires various approaches to analyse the aorta. To address this, here we present a holistic review of the biomechanical studies of the aorta by categorising articles into four broad approaches, namely theoretical, in vivo , experimental and combined investigations. Experimental studies that focus on identifying mechanical properties of the aortic tissue are also included. By reviewing the literature and discussing drawbacks, limitations and future challenges in each area, we hope to present a more complete picture of the state-of-the-art of aortic biomechanics to stimulate research on critical topics. Combining experimental modalities and computational approaches could lead to more comprehensive results in risk prediction for the aortic system. [ABSTRACT FROM AUTHOR]

Published

2023

15. Evaluación hidromecánica de venas yugulares bovinas frescas y fijadas en glutaraldehído para uso como bioimplante cardiovascular Hydromechanical evaluation of bovine jugular veins fixed in glutaldehyde for its use as cardiovascular implant

Author

John Bustamante, Claudia E Echeverri, and Javier Valbuena

Subjects

venas yugulares bovinas, bioimplantes valvulares, biomecánica vascular, flujo pulsante, probador biomecánico, bovine jugular veins, valvular bio-implants, vascular biomechanics, pulsatile flow, biomechanical tester, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Muchas de las enfermedades cardiovasculares congénitas pueden intervenirse mediante cirugía, con implantes biológicos o artificiales, lo cuales permitirán restablecer la funcionalidad del sistema cardiovascular. Por sus propiedades, los injertos biológicos procedentes de donantes cadavéricos (homoinjertos) son los más apropiados para cirugías reconstructivas del tracto de salida ventricular, pero infortunadamente son difíciles de adquirir ya que se obtienen de donantes con pocas semanas de nacidos, pretendiendo que se correlacionen con las dimensiones y geometría de la estructura nativa a reparar. Con este proyecto se evaluó el comportamiento hidrodinámico de tramos valvulados de venas yugulares bovinas, obtenidas en la Central Ganadera de Medellín, montando el segmento venoso de estudio en un banco de pruebas que emulaba las condiciones del tracto de salida del ventrículo derecho y tronco de la pulmonar, con el fin de analizar su comportamiento en condiciones similares a las que debe afrontar el vaso como bioimplante en la corrección de alteraciones cardiovasculares congénitas en neonatos y niños.Many congenital heart diseases may be treated surgically with biological or artificial implants that will allow the restoration of cardiovascular system functionality. Due to its properties, the biologic implants obtained from dead donors (homografts) are the most appropriate for ventricular output reconstructive surgeries. Unfortunately, these are difficult to acquire, because they are obtained from newborn donors and may be correlated to the dimensions and geometry of the native structure to be repaired. This project evaluated the hydrodynamic behavior of valvular segments of bovine jugular veins (obtained from the Livestock Central in Medellin), mounting the venous segment on a test bank that simulated the right ventricle output tract and the pulmonary trunk, in order to analyze its behavior in similar conditions to those that the vessel must face as bio-implant in the correction of congenital cardiovascular alterations in newborns and infants.

Published

2007

16. Losartan Attenuates Degradation of Aorta and Lung Tissue Micromechanics in a Mouse Model of Severe Marfan Syndrome.

Author

Lee, Jia-Jye, Galatioto, Josephine, Rao, Satish, Ramirez, Francesco, and Costa, Kevin

Abstract

Marfan syndrome (MFS) is an autosomal dominant disease of the connective tissue due to mutations in the fibrillin-1 gene (FBN1). This study aimed at characterizing microelastic properties of the ascending aortic wall and lung parenchyma tissues from wild type (WT) and age-matched Fbn1 hypomorphic mice (Fbn1 mice) to identify tissue-specific biomechanical effects of aging and disease in MFS. Atomic force microscopy was used to indent lung parenchyma and aortic wall tissues, using Hybrid Eshelby Decomposition analysis to extract layer-specific properties of the intima and media. The intima stiffened with age and was not different between WT and Fbn1 tissues, whereas the media layer of MFS aortas showed progressive structural and mechanical degradation with a modulus that was 50% softer than WT by 3.5 months of age. Similarly, MFS mice displayed progressive structural and mechanical deterioration of lung tissue, which was over 85% softer than WT by 3.5 months of age. Chronic treatment with the angiotensin type I receptor antagonist, losartan, attenuated the aorta and lung tissue degradation, resulting in structural and mechanical properties not significantly different from age-matched WT controls. By revealing micromechanical softening of elastin-rich aorta and lung tissues with disease progression in fibrillin-1 deficient mice, our findings support the use of losartan as a prophylactic treatment that may abrogate the life-threatening symptoms of MFS. [ABSTRACT FROM AUTHOR]

Published

2016

17. FSI Simulations of Pulse Wave Propagation in Human Abdominal Aortic Aneurysm: The Effects of Sac Geometry and Stiffness.

Author

Han Li, Kexin Lin, and Shahmirzadi, Danial

Subjects

*AORTIC aneurysm diagnosis, *THEORY of wave motion, *FLUID velocity measurements, *DIAGNOSTIC imaging, *BIOMECHANICS

Abstract

This study aims to quantify the effects of geometry and stiffness of aneurysms on the pulse wave velocity (PWV) and propagation in fluid-solid interaction (FSI) simulations of arterial pulsatile flow. Spatiotemporal maps of both the wall displacement and fluid velocity were generated in order to obtain the pulse wave propagation through fluid and solid media, and to examine the interactions between the two waves. The results indicate that the presence of abdominal aortic aneurysm (AAA) sac and variations in the sac modulus affect the propagation of the pulse waves both qualitatively (eg, patterns of change of forward and reflective waves) and quantitatively (eg, decreasing of PWV within the sac and its increase beyond the sac as the sac stiffness increases). The sac region is particularly identified on the spatiotemporal maps with a region of disruption in the wave propagation with multiple short-traveling forward/reflected waves, which is caused by the change in boundary conditions within the saccular region. The change in sac stiffness, however, is more pronounced on the wall displacement spatiotemporal maps compared to those of fluid velocity. We conclude that the existence of the sac can be identified based on the solid and fluid pulse waves, while the sac properties can also be estimated. This study demonstrates the initial findings in numerical simulations of FSI dynamics during arterial pulsations that can be used as reference for experimental and in vivo studies. Future studies are needed to demonstrate the feasibility of the method in identifying very mild sacs, which cannot be detected from medical imaging, where the material property degradation exists under early disease initiation. [ABSTRACT FROM AUTHOR]

Published

2016

18. Propuesta de modelo de trauma vascular mediante la caracterización mecánica de prótesis endovasculares (stents) a través del análisis estructural con técnicas FEA.

Author

Bustamante, John, Uribe, Pablo, Sosa, Mauricio, and Valencia, Raúl

Abstract

Objective: The accumulated evidence on angioplasty techniques with stents has raised a controversy about the factors that influence the final vascular response. Indeed, several studies have shown there might be re-stenosis between 30% to 40% about 6 months after placement, relating to the design of the device as one of the main causes. This paper proposes the functional characterization of endovascular stents, analyzing its mechanical influence in the vascular system and predicting implicit traumatic factors in the vessel. Methods: A structural analysis was made for several computational models of endovascular stents using Finite Element Analysis in order to predict the mechanical behavior and the vascular trauma. In this way, the stents were considered as tubular devices composed of multiple links under radial pressure loads, reflecting stress concentration effects. Results: The analysis allowed to visualize how the geometry of stents is adjusted under several load conditions, in order to obtain the response of ''solid-solid'' interaction between the stent and the arterial wall. Thus, an analysis was performed in order to calculate stress, and a conceptual model that explains its mechanical impact on the stent-vessel interaction, was raised, to infer on the functionality from the design of the devices. Conclusions: The proposed conceptual model allows to determine the relationship between the conditions of mechanical interaction of the stents, and warns about the effects in what would be the operation of the device on the vascular environment. [ABSTRACT FROM AUTHOR]

Published

2016

19. The interaction of biochemical, biomechanical, and clinical factors of coronary disease

Author

Gasser, T. Christian, Hedin, Ulf, Roy, Joy, Gasser, T. Christian, Hedin, Ulf, and Roy, Joy

Abstract

Coronary heart disease is a major and global health care challenge, and its biomechanical analysis has been shown to be a useful complement in answering related clinical questions. Compelling evidence has been accumulated showing that two primary biomechanical factors predispose to the disease: low or oscillating wall shear stress and high wall mechanical stress (or strain) of plaque tissue components. While the level of sophistication with which vascular biomechanical analysis can be made has increased dramatically, the utility of biomechanical models in clinical practice remains very limited and their capability is by far not fully exploited. This chapter aims at reviewing the principles of the biomechanical analysis of coronary arteries in relation to the interplay of biomechanical, biochemical, and clinical factors. Techniques, methods, and modeling assumptions are discussed in relation to their clinical relevance, and thus toward the feasibility of translating research results and developing new treatment techniques and diagnostic tools., Part of ISBN 9780128171950 9780128171967QC 20230714

Published

2021

20. Vascular Mechanics in Decellularized Aortas and Coronary Resistance Microvessels in Type 2 Diabetic db/db Mice.

Author

Anghelescu, Mircea, Tonniges, Jeffrey, Calomeni, Ed, Shamhart, Patricia, Agarwal, Gunjan, Gooch, Keith, and Trask, Aaron

Abstract

We previously reported differences in stiffness between macro- and micro-vessels in type 2 diabetes (T2DM). The aim of this study was to define the mechanical properties of the ECM independent of vascular cells in coronary resistance micro-vessels (CRMs) and macro-vessels (aorta) in control Db/db and T2DM db/db mice. Passive vascular remodeling and mechanics were measured in both intact and decellularized CRMs and aortas from 0 to 125 mmHg. We observed no differences in intact control and diabetic aortic diameters, wall thicknesses, or stiffnesses ( p > 0.05). Aortic decellularization caused a significant increase in internal and external diameters and incremental modulus over a range of pressures that occurred to a similar degree in T2DM. Differences in aortic diameters due to decellularization occurred at lower pressures (0-75 mmHg) and converged with intact aortas at higher, physiological pressures (100-125 mmHg). In contrast, CRM decellularization caused increased internal diameter and incremental modulus only in the db/db mice, but unlike the aorta, the intact and decellularized CRM curves were more parallel. These data suggest that (1) micro-vessels may be more sensitive to early adverse consequences of diabetes than macro-vessels and (2) the ECM is a structural limit in aortas, but not CRMs. [ABSTRACT FROM AUTHOR]

Published

2015

21. The influence of intraluminal thrombus on noninvasive abdominal aortic aneurysm wall distensibility measurement.

Author

Metaxa, Eleni, Kontopodis, Nikolaos, Vavourakis, Vasileios, Tzirakis, Konstantinos, Ioannou, Christos, and Papaharilaou, Yannis

Subjects

*ABDOMINAL aortic aneurysms, *AORTIC aneurysms, *ELECTROCARDIOGRAPHY, *COMPUTED tomography, *FINITE element method, *THROMBOSIS, *NONINVASIVE diagnostic tests

Abstract

Abdominal aortic aneurysm wall distensibility can be estimated by measuring pulse pressure and the corresponding sac volume change, which can be obtained by measuring wall displacement. This approach, however, may introduce error if the role of thrombus in assisting the wall in bearing the pulse pressure loading is neglected. Our aim was to introduce a methodology for evaluating and potentially correcting this error in estimating distensibility. Electrocardiogram-gated computed tomography images of eleven patients were obtained, and the volume change between diastole and systole was measured. Using finite element procedures, we determined the equivalent pulse pressure loading that should be applied to the wall of a model where thrombus was digitally removed, to yield the same sac volumetric increase caused by applying the luminal pulse pressure to the model with thrombus. The equivalent instead of the measured pulse pressure was used in the distensibility expression. For a relative volumetric thrombus deposition ( V) of 50 %, a 62 % distensibility underestimation resulted when thrombus role was neglected. A strong linear correlation was observed between distensibility underestimation and V. To assess the potential value of noninvasive wall distensibility measurement in rupture risk stratification, the role of thrombus on wall loading should be further investigated. [ABSTRACT FROM AUTHOR]

Published

2015

22. High Wall Shear Stress can Predict Wall Degradation in Ascending Aortic Aneurysms: An Integrated Biomechanics Study

Author

M. Yousuf Salmasi, Selene Pirola, Sumesh Sasidharan, Serena M. Fisichella, Alberto Redaelli, Omar A. Jarral, Declan P. O’Regan, Aung Ye Oo, James E. Moore, Xiao Yun Xu, Thanos Athanasiou, Imperial College Healthcare NHS Trust- BRC Funding, British Heart Foundation, and British Heart Foundation Centre for Research Excellence

Subjects

medicine.medical_specialty, Histology, 0699 Other Biological Sciences, aortic surgery, Biomedical Engineering, Bioengineering, Dissection (medical), computational fluid dynamics, Aneurysm, 0903 Biomedical Engineering, Internal medicine, medicine, Shear stress, magnetic resonance imaging, Original Research, medicine.diagnostic_test, biology, business.industry, 1004 Medical Biotechnology, Biomechanics, Bioengineering and Biotechnology, Magnetic resonance imaging, Blood flow, medicine.disease, Connective tissue disease, wall shear stress, vascular biomechanics, Cardiology, biology.protein, cardiovascular system, aneurysm, business, CFD, Elastin, TP248.13-248.65, Biotechnology, computational pathology

Abstract

Background: Blood flow patterns can alter material properties of ascending thoracic aortic aneurysms (ATAA) via vascular wall remodeling. This study examines the relationship between wall shear stress (WSS) obtained from image-based computational modelling with tissue-derived mechanical and microstructural properties of the ATAA wall using segmental analysis.Methods: Ten patients undergoing surgery for ATAA were recruited. Exclusions: bicuspid aortopathy, connective tissue disease. All patients had pre-operative 4-dimensional flow magnetic resonance imaging (4D-MRI), allowing for patient-specific computational fluid dynamics (CFD) analysis and anatomically precise WSS mapping of ATAA regions (6–12 segments per patient). ATAA samples were obtained from surgery and subjected to region-specific tensile and peel testing (matched to WSS segments). Computational pathology was used to characterize elastin/collagen abundance and smooth muscle cell (SMC) count.Results: Elevated values of WSS were predictive of: reduced wall thickness [coef −0.0489, 95% CI (−0.0905, −0.00727), p = 0.022] and dissection energy function (longitudinal) [−15,0, 95% CI (−33.00, −2.98), p = 0.048]. High WSS values also predicted higher ultimate tensile strength [coef 0.136, 95% CI (0 0.001, 0.270), p = 0.048]. Additionally, elevated WSS also predicted a reduction in elastin levels [coef −0.276, 95% (CI −0.531, −0.020), p = 0.035] and lower SMC count ([oef −6.19, 95% CI (−11.41, −0.98), p = 0.021]. WSS was found to have no effect on collagen abundance or circumferential mechanical properties.Conclusions: Our study suggests an association between elevated WSS values and aortic wall degradation in ATAA disease. Further studies might help identify threshold values to predict acute aortic events.

Published

2021

23. Mechanical action of the blood onto atheromatous plaques: influence of the stenosis shape and morphology.

Author

Belzacq, Tristan, Avril, Stéphane, Leriche, Emmanuel, and Delache, Alexandre

Subjects

*ATHEROSCLEROTIC plaque, *STENOSIS, *MORPHOLOGY, *FINITE element method, *LAGRANGIAN functions, *EULERIAN graphs

Abstract

The vulnerability of atheromatous plaques in the carotid artery may be related to several factors, the most important being the degree of severity of the endoluminal stenosis and the thickness of the fibrous cap. It has recently been shown that the plaque length can also affect the mechanical response significantly. However, in their study on the effect of the plaque length, the authors did not consider the variations of the plaque morphology and the shape irregularities that may exist independently of the plaque length. These aspects are developed in this paper. The mechanical interactions between the blood flow and an atheromatous plaque are studied through a numerical model considering fluid–structure interaction. The simulation is achieved using the arbitrary Lagrangian–Eulerian scheme in the COMSOL TM commercial finite element package. The stenosis severity and the plaque length are, respectively, set to 45% and 15 mm. Different shapes of the stenosis are modelled, considering irregularities made of several bumps over the plaque. The resulting flow patterns, wall shear stresses, plaque deformations and stresses in the fibrous cap reveal that the effects of the blood flow are amplified if the slope upstream stenosis is steep or if the plaque morphology is irregular with bumps. More specifically, the maximum stress in the fibrous cap is 50% larger for a steep slope than for a gentle slope. These results offer new perspectives for considering the shape of plaques in the evaluation of the vulnerability. [ABSTRACT FROM AUTHOR]

Published

2014

24. Quantifying the Interfibrillar Spacing and Fibrillar Orientation of the Aortic Extracellular Matrix Using Histology Image Processing: Toward Multiscale Modeling.

Author

Shahmirzadi, Danial, Bruck, Hugh A., and Hsieh, Adam H.

Subjects

*EXTRACELLULAR matrix, *MORPHOLOGY, *AORTA, *HISTOLOGY methodology, *EXTRACELLULAR space, *MULTISCALE modeling, *FOURIER transforms, *HOUGH functions

Abstract

An essential part of understanding tissue microstructural mechanics is to establish quantitative measures of the morphological changes. Given the complex, highly localized, and interactive architecture of the extracellular matrix, developing techniques to reproducibly quantify the induced microstructural changes has been found to be challenging. In this paper, a new method for quantifying the changes in the fibrillar organization is developed using histology images. A combinatorial frequency–spatial image processing approach was developed based on the Fourier and Hough transformations of histology images to measure interfibrillar spacing and fibrillar orientation, respectively. The method was separately applied to the inner and outer wall thickness of native- and elastin-isolated aortic tissues under different loading states. Results from both methods were interpreted in a complementary manner to obtain a more complete understanding of morphological changes due to tissue deformations at the microscale. The observations were consistent in quantifying the observed morphological changes during tissue deformations and in explaining such changes in terms of tissue-scale phenomena. The findings of this study could pave the way for more rigorous modeling of structure–property relationships in soft tissues, with implications extendable to cardiovascular constitutive modeling and tissue engineering. [ABSTRACT FROM PUBLISHER]

Published

2013

25. A numerical parametric study of the mechanical action of pulsatile blood flow onto axisymmetric stenosed arteries

Author

Belzacq, Tristan, Avril, Stéphane, Leriche, Emmanuel, and Delache, Alexandre

Subjects

*ARTERIAL stenosis, *BLOOD flow, *NUMERICAL analysis, *ATHEROSCLEROTIC plaque, *FLUID-structure interaction, *AXIAL flow, *ANISOTROPY, *FINITE element method

Abstract

Abstract: In the present paper, a fluid–structure interaction model is developed, questioning how the mechanical action of the blood onto an atheromatous plaque is affected by the length and the severity of the stenosis. An axisymmetric model is considered. The fluid is assumed Newtonian. The plaque is modelled as a heterogeneous hyperelastic anisotropic solid composed of the arterial wall, the lipid core and the fibrous cap. Transient velocity and pressure conditions of actual pulsatile blood flow are prescribed. The simulation is achieved using the Arbitrary Lagrangian Eulerian scheme in the COMSOL commercial Finite Element package. The results reveal different types of behavior in function of the length (denoted L) and severity (denoted S) of the stenosis. Whereas large plaques (L >10mm) are mostly deformed under the action of the blood pressure, it appears that shorter plaques (L <10mm) are significantly affected by the shear stresses. The shear stresses tend to deform the plaque by pinching it. This effect is called: “the pinching effect”. It has an essential influence on the mechanical response of the plaque. For two plaques having the same radius severity S =45%, the maximum stress in the fibrous cap is 50% larger for the short plaque (L =5mm) than for a larger plaque (L =10mm), and the maximum wall shear stress is increased by 100%. Provided that they are confirmed by experimental investigations, these results may offer some new perspectives for understanding the vulnerability of short plaques. [Copyright &y& Elsevier]

Published

2012

26. Caracterización del flujo pulsante vascular mediante observaciones in vitro en modelos biológico y mecánico.

Author

Bustamante, John and Valbuena, Javier

Subjects

*PULSATILE flow, *BLOOD vessels, *IN vitro studies, *BLOOD circulation, *BIOMECHANICS, *HEMODYNAMICS, *BIOCHEMISTRY

Abstract

Objective: The evidence accumulated on the use of pulsatile and non-pulsatile flow-dependent devices raises a controversy concerning the effects of the flow type on the Circulatory system. This paper proposes to characterize the properties of pulsatile flow in elastic conduits in order to determine how the pulse affects the system and to determine the specific details of the flow in the vascular bed. Methods: The biomechanical properties of pulsatile flow were measured on flexible (calf venous vessel), and rigid (plastic pipe) conduits in which the flow was implemented using a pneumatic elastic sack-like pumping device. Results: The experimental data and the biomechanical analysis of the pulsing flow was used to determine the flow pattern in order to develop a mechanical model explaining the effects of the pulse on the vascular system. The resulting model includes the flow's general condition (mechanical component) and its effects on the vascular system (biological/physiological component). Conclusions: The model proposed here allows determining the relationship between the flow conditions and the reaction on the wall; it also allows unifying the interpretation of fluiddynamic factors affecting these phenomena and represents a warning system about the effects of flow changes on the operation of circulatory assistance devices. [ABSTRACT FROM AUTHOR]

Published

2012

27. Biomechanics of Resistance Artery Wall Remodeling in Angiotensin-II Hypertension and Subsequent Recovery.

Author

Nádasy, György L., Várbíró, Szabolcs, Szekeres, Mária, Kocsis, Adrienn, Székács, Béla, Monos, Emil, and Kollai, Márk

Subjects

*HEMODYNAMICS, *BIOMECHANICS, *ANGIOTENSIN II, *HYPERTENSION, *ARTERIOGRAPHY, *NEOVASCULARIZATION

Abstract

Background/Aims: To identify the relationship between systemic and local hemodynamics, as well as segmental biomechanical properties in a musculocutaneous resistance artery during angiotensin-II hypertension and its recovery. Methods: Rats were infused with angiotensin-II using implanted osmotic minipumps (ALZET 2ML4, 150 ng/kg/min) for 4 weeks. Measurements were made either immediately following infusion or after an additional 4-week recovery period. Parallel controls were created. Segmental geometry and blood flow were determined in vivo on microsurgically exposed segments of the saphenous arterial branch (350 μm). Pressure-radius plots of excised cylindrical segments were recorded by pressure arteriography. Results: Eutrophic hypertensive wall remodeling developed, with reduced passive radius, increased wall thickness, elevated low-stress elastic modulus, reduced norepinephrine contraction, and reduced endothelium-mediated dilation. Relaxed wall geometry fully healed in 4 weeks of recovery, but an increased contractility and a reduced in vivo lumen persisted. Regional hemodynamic resistance correlated positively with systemic arterial pressure and wall thickness in vivo, and negatively with in vivo lumen size throughout these studies. Conclusion: A partial recovery of the biomechanical parameters was found. Healing of eutrophic hypertensive remodeling of the resistance artery wall is a complex biomechanical process, not a simple reversal of the original pathological sequel. Copyright © 2010 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2010

28. Mechanopathobiology of Atherogenesis: A Review

Author

VanEpps, J. Scott and Vorp, David A.

Subjects

*CARDIOVASCULAR diseases, *ATHEROSCLEROSIS, *SURGERY, *MEDICAL research

Abstract

Cardiovascular disease is the number one cause of mortality in the United States. Atherosclerosis, the primary etiology of cardiovascular disease is hypothesized to be a time-dependent response to arterial injury. Although risk factors for atherosclerosis are systemic in nature, certain arteries (e.g., coronary arteries) are more susceptible to plaque formation than others. The heterogeneous distribution of atherosclerosis in the vasculature is thought to be related to biomechanical factors. A review of the relevant pathological features of atherogenesis and how physiologically-consistent mechanical stimuli can impact those processes supports this notion. However, specific investigations geared toward finding the mechanistic link between mechanical stimuli and early atherogenic processes are required to differentiate those stimuli that facilitate and those that inhibit atherogenesis. Such knowledge is required for intelligent direction in the search for potential targets for clinical intervention. [Copyright &y& Elsevier]

Published

2007

29. Microfluidic blood vasculature replicas using backside lithography

Author

Marianne Fenech, Viviana Clavería, Manouk Abkarian, Sébastien Méance, Vincent Girod, Benoit Charlot, Institut d’Electronique et des Systèmes (IES), Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS), Matériaux, MicroCapteurs et Acoustique (M2A), Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS), University of Ottawa [Ottawa], Centre de Biochimie Structurale [Montpellier] (CBS), and Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Institut National de la Santé et de la Recherche Médicale (INSERM)

Subjects

Vascular Biomechanics, Materials science, [SDV.BIO]Life Sciences [q-bio]/Biotechnology, Blood Vessel, Microfluidics, Biomedical Engineering, Bioengineering, 02 engineering and technology, 01 natural sciences, Biochemistry, Organ-on-a-chip, law.invention, Diffuser (thermodynamics), Microfluidics device, Cross section (physics), law, medicine, Humans, Particle Size, [SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics, Lithography, ComputingMilieux_MISCELLANEOUS, 010401 analytical chemistry, [SDV.MHEP.HEM]Life Sciences [q-bio]/Human health and pathology/Hematology, General Chemistry, Microfluidic Analytical Techniques, 021001 nanoscience & nanotechnology, 0104 chemical sciences, medicine.anatomical_structure, Blood circulation, Blood Circulation, Photolithography, 0210 nano-technology, Blood Flow Velocity, Blood vessel, Biomedical engineering

Abstract

Blood vessels in living tissues are an organized and hierarchical network of arteries, arterioles, capillaries, veinules and veins. Their sizes, lengths, shapes and connectivity are set up for an optimum perfusion of the tissues in which they deploy. In order to study the hemodynamics and hemophysics of blood flows and also to investigate artificial vasculature for organs on a chip, it is essential to reproduce most of these geometric features. Common microfluidic techniques produce channels with a uniform height and a rectangular cross section that do not capture the size hierarchy observed in vivo. This paper presents a new single-mask photolithography process using an optical diffuser to produce a backside exposure leading to microchannels with both a rounded cross section and a direct proportionality between local height and local width, allowing a one-step design of intrinsically hierarchical networks.

Published

2019

30. A NEW AXISYMMETRICAL MEMBRANE ELEMENT FOR ANISOTROPIC, FINITE STRAIN ANALYSIS OF ARTERIES.

Author

Holzapfel, G. A., Eberlein, R., Wriggers, P., and Weizsacker, H. W.

Subjects

*NUMERICAL analysis, *MATHEMATICAL analysis, *ARTERIES, *BLOOD vessels, *CARDIOVASCULAR system, *BIOLOGICAL membranes

Abstract

To explore the mechanical non-linear behaviour of anisotropic arterial walls on a computational basis, the formulation of a continuum based elastic potential is a major task and challenge to the analyst. The present communication is concerned with the constitutive modelling and numerical analysis of vascular segments covering finite strains. Special attention is paid to a two term potential that constitutes an essential foundation for accurate simulation within the entire strain domain. Axisymmetrical membrane elements are assembled to match the geometry of blood vessels. Numerical results confirm the theoretical approach by referring to experimental data of different rat arteries. [ABSTRACT FROM AUTHOR]

Published

1996

31. Segmental Differences in Geometric, Elastic and Contractile Characteristics of Small Intramural Coronary Arteries of the Rat.

Author

Szekeres, Mária, Nádasy, György L., Dézsi, László, Orosz, Miklós, Tökés, Annamária, and Monos, Emil

Subjects

*CORONARY arteries, *MICROCIRCULATION, *BLOOD circulation, *BLOOD vessels, *CARDIAC contraction

Abstract

The depedence of elastic and contractile properties on the caliber of small intramural coronary arteries was investigated in the rat in vitro. Different segments of the left anterior descending coronary artery branching system were prepared for microarteriography. The segments were cannulated at both ends, immersed in oxygenated normal Krebs Ringer (nKR) solution. Intraluminal pressure was changed at a rate of about 0.5 mm Hg/s between 0 and 150 mm Hg in repeated cycles. The outer diameter was continuously measured with microangiometry. Pressure-diameter curves were recorded after preconditioning pressure cycles in nKR, with PGF[sub 2α] in the bath (7.5 × 10[sup –6] M), and in maximal relaxation with papaverine (2.8 × 10[sup –4] M). Biomechanical parameters were computed for vessels grouped according to their calibers (inner diameters: 50–150, 150–250, 250–350, >350 µm). Distensibility and contractility decreased with increasing caliber of the vessels, while the elastic modulus increased. Spontaneous tone was (at 100 mm Hg in mechanically preconditioned vessels) 18.8 ± 4.5, 8.4 ± 4.4, 9.7 ± 3.7 and 8.3 ± 3.8% in the four groups, respectively. PGF[sub 2α] contraction was maximal around the 300-µm caliber. Our study is the first direct demonstration that intramural small coronary arteries exhibit characteristic variability in their elastic and contractile properties as a function of their caliber. Such differences may be important in segmentally specific control processes of the coronary microcirculation. [ABSTRACT FROM AUTHOR]

Published

1998

32. Développement et optimisation d'endoprothèses vasculaires: architectures optimisées et biomimétiques

Author

Ott, Franck, Boucard, Nadège, Geindreau, Christian, Bailly, Lucie, Orgéas, Laurent, MDB Texinov (MDB Texinov), MDB Texinov, Mécanique et Couplages Multiphysiques des Milieux Hétérogènes (CoMHet ), Laboratoire sols, solides, structures - risques [Grenoble] (3SR ), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), and Bailly, Lucie

Subjects

X-ray microtomography, Vascular biomechanics, [PHYS.MECA.BIOM] Physics [physics]/Mechanics [physics]/Biomechanics [physics.med-ph], [SPI.MECA.MSMECA] Engineering Sciences [physics]/Mechanics [physics.med-ph]/Materials and structures in mechanics [physics.class-ph], Mechanical testing, [SPI.MECA.MSMECA]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Materials and structures in mechanics [physics.class-ph], Endoprothesis, [PHYS.MECA.BIOM]Physics [physics]/Mechanics [physics]/Biomechanics [physics.med-ph], synchrotron ESRF, ComputingMilieux_MISCELLANEOUS, Abdominal Aorta Aneurysm, Permeability

Abstract

International audience

Published

2018

33. High Wall Shear Stress can Predict Wall Degradation in Ascending Aortic Aneurysms: An Integrated Biomechanics Study.

Author

Salmasi MY, Pirola S, Sasidharan S, Fisichella SM, Redaelli A, Jarral OA, O'Regan DP, Oo AY, Moore JE Jr, Xu XY, and Athanasiou T

Abstract

Background: Blood flow patterns can alter material properties of ascending thoracic aortic aneurysms (ATAA) via vascular wall remodeling. This study examines the relationship between wall shear stress (WSS) obtained from image-based computational modelling with tissue-derived mechanical and microstructural properties of the ATAA wall using segmental analysis. Methods: Ten patients undergoing surgery for ATAA were recruited. Exclusions: bicuspid aortopathy, connective tissue disease. All patients had pre-operative 4-dimensional flow magnetic resonance imaging (4D-MRI), allowing for patient-specific computational fluid dynamics (CFD) analysis and anatomically precise WSS mapping of ATAA regions (6-12 segments per patient). ATAA samples were obtained from surgery and subjected to region-specific tensile and peel testing (matched to WSS segments). Computational pathology was used to characterize elastin/collagen abundance and smooth muscle cell (SMC) count. Results: Elevated values of WSS were predictive of: reduced wall thickness [coef -0.0489, 95% CI (-0.0905, -0.00727), p = 0.022] and dissection energy function (longitudinal) [-15,0, 95% CI (-33.00, -2.98), p = 0.048]. High WSS values also predicted higher ultimate tensile strength [coef 0.136, 95% CI (0 0.001, 0.270), p = 0.048]. Additionally, elevated WSS also predicted a reduction in elastin levels [coef -0.276, 95% (CI -0.531, -0.020), p = 0.035] and lower SMC count ([oef -6.19, 95% CI (-11.41, -0.98), p = 0.021]. WSS was found to have no effect on collagen abundance or circumferential mechanical properties. Conclusions: Our study suggests an association between elevated WSS values and aortic wall degradation in ATAA disease. Further studies might help identify threshold values to predict acute aortic events., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Salmasi, Pirola, Sasidharan, Fisichella, Redaelli, Jarral, O’Regan, Oo, Moore, Xu and Athanasiou.)

Published

2021

34. Biaxial biomechanical properties of self-assembly tissue-engineered blood vessels

Author

Zaucha, Michael T., Germain, Lucie, Auger, François A., Gauvin, Robert, Gleason, Rudolph L., Zaucha, Michael T., Germain, Lucie, Auger, François A., Gauvin, Robert, and Gleason, Rudolph L.

Abstract

Along with insights into the potential for graft success, knowledge of biomechanical properties of small diameter tissue-engineered blood vessel (TEBV) will enable designers to tailor the vessels' mechanical response to closer resemble that of native tissue. Composed of two layers that closely mimic the native media and adventitia, a tissue-engineered vascular adventitia (TEVA) is wrapped around a tissue-engineered vascular media (TEVM) to produce a self-assembled tissue-engineered media/adventia (TEVMA). The current study was undertaken to characterize the biaxial biomechanical properties of TEVM, TEVA and TEVMA under physiological pressures as well as characterize the stress-free reference configuration. It was shown that the TEVA had the greatest compliance over the physiological loading range while the TEVM had the lowest compliance. As expected, compliance of the SA-TEBV fell in between with an average compliance of 2.73 MPa−1. Data were used to identify material parameters for a microstructurally motivated constitutive model. Identified material parameters for the TEVA and TEVM provided a good fit to experimental data with an average coefficient of determination of 0.918 and 0.868, respectively. These material parameters were used to develop a two-layer predictive model for the response of a TEVMA which fit well with experimental data.

Published

2018

35. Modelling the mechanobiological evolution of aneurysms: An integrative in vivo, in vitro and in silico approach

Author

Mandaltsi, A, Watton, P, and Thompson, M

Subjects

Vascular biomechanics, Biomechanical Engineering, Computational Fluid Dynamics

Abstract

In silico models of intracranial aneurysm (IA) evolution aim to reliably represent the mechanical blood flow environment, the biology of the arterial wall and, crucially, the complex link between the two, namely the mechanobiology of healthy and diseased arteries. The ultimate goal is to create diagnostic tools for personalized management and treatment of aneurysm disease. Towards that target, the work presented in this thesis aims to establish a directly interactive link between experimental (in vivo and in vitro) and computational work for biologically and clinically relevant research on aneurysm disease. Mechanobiological hypotheses were firstly investigated in a novel 1D mathematical conceptual model of aneurysm evolution: for the first time these included representations of endothelial heterogeneity and smooth muscle cell (SMC) active stress response and apoptosis. The 1D investigations analysed and assessed the role of wall shear stress (WSS) homeostasis in elastin degradation, and the evolving role of the adventitia as a protective sheath in health and primary load-bearer in disease. The 1D framework was applied to a specific patient’s aneurysm using both imaging and histological data to parameterise the model, calculating a material parameter for the adventitital collagen. The predicted evolution captured aspects of tissue changes measured with time focusing on the remodelled tissue wall thickness consistent with the experimental measurements, and physiological cyclic deformation in order to propose an approach to modelling adventitia’s adaptive role to load bearing. Furthermore, an existing Fluid-Solid-Growth (FSG) computational framework was adapted and calibrated for the same patient-specific case with the help from the experimental data and the analysis from the 1D framework. This FSG model quantifies the arterial mechanical environment and captures the mechanical response of the fibrous arterial constituents. Comparing 1D and 3D investigations to establish consistency for our models, the 3Dmodel tested the hypothesis of WSS homeostasis, additionally introducing the element of spatial heterogeneity in the definition, and a new hypothesis linking cyclic deformation with collagen growth that ensures a physiological mechanical environment in stabilised aneurysms. Moreover, the FSG framework was applied in a specific rabbit aneurysm case and extended to link growth and remodeling to the detailed representation of the pulsatile blood flow mechanical environment. This research illustrates the power of computational modelling when coupled with rich data sets on the physiology, histology and geometry of healthy and diseased vascular tissue. In particular, the integrative modelling framework provides the foundation for establishing mechanobiological links crucial to aneurysm progression, and a basis for further research towards creating reliable aneurysm clinical tools.

Published

2017

36. A new deep learning method for displacement tracking from ultrasound RF signals of vascular walls.

Author

Xiao, Chenhui, Li, Zhenzhou, Lu, Jianfeng, Wang, Jinyan, Zheng, Haoteng, Bi, Zuyue, Chen, Mengyang, Mao, Rui, and Lu, Minhua

Subjects

*DEEP learning, *CAROTID artery, *COMPUTER-assisted image analysis (Medicine), *CARDIOVASCULAR system, *OBJECT tracking (Computer vision), *BIOMECHANICS, *CARDIOVASCULAR diseases

Abstract

• A new architecture of motion tracking has been proposed. • Deep learning method for displacement tracking of the vessel wall from the ultrasound RF signals. • It improves the accuracy in vessel wall motion tracking in comparsion with traditional methods. It is necessary to monitor the mechanical properties of arteries which directly related to cardiovascular diseases (CVDs) in the early stages. In this study, we proposed a new method based on deep learning (DL) to track the displacement of the vessel wall from the ultrasound radio-frequency (RF) signals, which is a key technique to achieve quantitative measurement of vascular biomechanics. In comparison with traditional method, both results on simulation and experimental carotid artery data demonstrated that the DL method has higher accuracy for motion tracking of artery walls. Hence, the DL method can be widely applied so that can predict the early pathology of cardiovascular system. [ABSTRACT FROM AUTHOR]

Published

2021

37. A Novel In Vivo Approach to Assess Radial and Axial Distensibility of Large and Intermediate Pulmonary Artery Branches

Author

Christopher J. François, Lian Tian, Alessandro Bellofiore, Heidi B. Kellihan, Naomi C. Chesler, Alejandro Roldán-Alzate, D. Consigny, Joseph Henningsen, and Clayton Guy Lepak

Subjects

medicine.medical_specialty, Cardiac output, medicine.medical_treatment, pulmonary artery stiffness, Biomedical Engineering, Technical Brief, Bioengineering, Blood Pressure, Pulmonary Artery, Stress, Cardiovascular, digital subtraction angiography, Magnetic resonance angiography, Rare Diseases, Dogs, In vivo, Physiology (medical), Internal medicine, medicine.artery, pulmonary arterial hypertension, Materials Testing, medicine, Animals, Embolization, Lung, Mechanical Phenomena, screening and diagnosis, medicine.diagnostic_test, business.industry, magnetic resonance angiography, Mechanical Engineering, Magnetic resonance imaging, Digital subtraction angiography, Mechanical, Magnetic Resonance Imaging, Biomechanical Phenomena, Detection, medicine.anatomical_structure, Heart Disease, Ventricle, Pulmonary artery, vascular biomechanics, Cardiology, Biomedical Imaging, Female, Stress, Mechanical, business, 4.2 Evaluation of markers and technologies

Abstract

Pulmonary arteries (PAs) distend to accommodate increases in cardiac output. PA distensibility protects the right ventricle (RV) from excessive increases in pressure. Loss of PA distensibility plays a critical role in the fatal progression of pulmonary arterial hypertension (PAH) toward RV failure. However, it is unclear how PA distensibility is distributed across the generations of PA branches, mainly because of the lack of appropriate in vivo methods to measure distensibility of vessels other than the large, conduit PAs. In this study, we propose a novel approach to assess the distensibility of individual PA branches. The metric of PA distensibility we used is the slope of the stretch ratio–pressure relationship. To measure distensibility, we combined invasive measurements of mean PA pressure with angiographic imaging of the PA network of six healthy female dogs. Stacks of 2D images of the PAs, obtained from either contrast enhanced magnetic resonance angiography (CE-MRA) or computed tomography digital subtraction angiography (CT-DSA), were used to reconstruct 3D surface models of the PA network, from the first bifurcation down to the sixth generation of branches. For each branch of the PA, we calculated radial and longitudinal stretch between baseline and a pressurized state obtained via acute embolization of the pulmonary vasculature. Our results indicated that large and intermediate PA branches have a radial distensibility consistently close to 2%/mmHg. Our axial distensibility data, albeit affected by larger variability, suggested that the PAs distal to the first generation may not significantly elongate in vivo, presumably due to spatial constraints. Results from both angiographic techniques were comparable to data from established phase-contrast (PC) magnetic resonance imaging (MRI) and ex vivo mechanical tests, which can only be used in the first branch generation. Our novel method can be used to characterize PA distensibility in PAH patients undergoing clinical right heart catheterization (RHC) in combination with MRI.

Published

2015

38. Mechanical characterization of aortas using 2D ultrasound elastography

Author

Mascarenhas, Edgar José Sanches, Loptata, Richard, Peters, Mathijs, and Vieira, Pedro

Subjects

Aortic aneurysm, Vascular biomechanics, Inflation testing, 2D ultrasound elastography

Abstract

Rupture of aortic aneurysms (AA) is a major cause of death in the Western world. Currently, clinical decision upon surgical intervention is based on the diameter of the aneurysm. However, this method is not fully adequate. Noninvasive assessment of the elastic properties of the arterial wall can be a better predictor for AA growth and rupture risk. The purpose of this study is to estimate mechanical properties of the aortic wall using in vitro inflation testing and 2D ultrasound (US) elastography, and investigate the performance of the proposed methodology for physiological conditions. Two different inflation experiments were performed on twelve porcine aortas: 1) a static experiment for a large pressure range (0 – 140 mmHg); 2) a dynamic experiment closely mimicking the in vivo hemodynamics at physiological pressures (70 – 130 mmHg). 2D raw radiofrequency (RF) US datasets were acquired for one longitudinal and two cross-sectional imaging planes, for both experiments. The RF-data were manually segmented and a 2D vessel wall displacement tracking algorithm was applied to obtain the aortic diameter–time behavior. The shear modulus G was estimated assuming a Neo-Hookean material model. In addition, an incremental study based on the static data was performed to: 1) investigate the changes in G for increasing mean arterial pressure (MAP), for a certain pressure difference (30, 40, 50 and 60 mmHg); 2) compare the results with those from the dynamic experiment, for the same pressure range. The resulting shear modulus G was 94 ± 16 kPa for the static experiment, which is in agreement with literature. A linear dependency on MAP was found for G, yet the effect of the pressure difference was negligible. The dynamic data revealed a G of 250 ± 20 kPa. For the same pressure range, the incremental shear modulus (Ginc) was 240 ± 39 kPa, which is in agreement with the former. In general, for all experiments, no significant differences in the values of G were found between different image planes. This study shows that 2D US elastography of aortas during inflation testing is feasible under controlled and physiological circumstances. In future studies, the in vivo, dynamic experiment should be repeated for a range of MAPs and pathological vessels should be examined. Furthermore, the use of more complex material models needs to be considered to describe the non-linear behavior of the vascular tissue.

Published

2014

39. Patient-specific isogeometric analysis for vascular biomechanics

Author

Auricchio, Ferdinando, Conti, Michele, Ferraro, Mauro, Morganti, Simone, Reali, Alessandro, Università degli Studi di Pavia, Center for Advanced Numerical Simulations, Istituto Universitario di Studi Superiori di Pavia (CESNA-IUSS), and Istituto Universitario di Studi Superiori (IUSS)

Subjects

Vascular Biomechanics, [SPI]Engineering Sciences [physics], Mapping, FEAP, Isogeometric Analysis, [PHYS.MECA]Physics [physics]/Mechanics [physics], [MATH.MATH-NA]Mathematics [math]/Numerical Analysis [math.NA]

Abstract

International audience; . Isogeometric Analysis (IGA) has recently emerged as a cost-effective alternative to classic isoparametric Finite Element Analysis. In this work a novel computational framework is proposed in order to get IGA-suitable geometries to simulate different vascular minimally-invasive procedures. The preliminary results show the capability of the framework to import in a straightforward way patient-specific vascular geometries and set an analysis enviroment suitable for the solver FEAP.

Published

2013

40. Numerical and experimental modeling of the fluid structure interaction in stenosed tube : contribution towards the analysis of carotid atheromatous plaque vulnerability

Author

Belzacq, Tristan, UMR 5146 - Laboratoire Claude Goux (LCG-ENSMSE), École des Mines de Saint-Étienne (Mines Saint-Étienne MSE), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT), Centre Ingénierie et Santé (CIS-ENSMSE), Département Biomécanique et Biomatériaux (DB2M-ENSMSE), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT)-CIS, Ecole Nationale Supérieure des Mines de Saint-Etienne, Stéphane Avril, Emmanuel Leriche, and STAR, ABES

Subjects

Stenosis, [SPI.OTHER]Engineering Sciences [physics]/Other, Sténose, Fluid structure interaction, [SPI.OTHER] Engineering Sciences [physics]/Other, Vascular biomechanics, Carotid atheromatous plaque, Blood flow, Ecoulement sanguin, Intéraction fluide structure, Biomécanique vasculaire, Plaque d'athérome carotidienne

Abstract

The rupture of carotid atheromatous plaques is the major cause of cerebrovascular thromboembolic events such as strokes and ischemic attacks. To prevent this issue, carotid endarterectomy is the preferred treatment. The vulnerability of the plaque is related the mechanical action of the blood onto the plaque. This action is different according to the plaque morphology, the plaque constitution and the mechanical properties of the constituents. Several authors developed computational models to perform mechanical analyses for carotid atherosclerotic plaques and to identify critical mechanical descriptors as stresses or strains related to plaque rupture. But the question of which plaque characteristics affect the plaque rupture is not closely elucidated. In this manuscript a fluid structure interaction model is developed, questioning how the mechanical action of the blood onto an atheromatous plaque is affected by the mechanical and geometrical properties of the plaque. Many results are in agreement with the literature: the vulnerability of atheromatous plaques is related to the degree of severity of the endoluminal stenosis and the thickness of the fibrous cap. Moreover the resulting flow patterns, wall shear stresses, plaque deformations and stresses in the fibrous cap reveal that the effects of the blood flow are amplified if the plaque is short, if the slope upstream stenosis is steep or if the plaque morphology is irregular and asymmetric. These results offer new perspectives for understanding the vulnerability of plaques., La rupture de la plaque d'athérome carotidienne est la première cause des infarctus cérébraux. Pour prévenir ces accidents, l'endartérectomie carotidienne est le traitement le plus utilisé. La vulnérabilité de la plaque est en relation avec les efforts que le sang applique sur la plaque. Ces actions sont différentes suivant les propriétés constitutives, mécaniques et géométriques de la plaque. Plusieurs auteurs ont développé des modèles numériques de la plaque d'athérome carotidienne à partir desquels une analyse mécanique a permis de caractériser les déformations et les contraintes en lien avec la rupture de la plaque. Néanmoins, les caractéristiques d'une plaque vulnérable sont encore mal connues. Dans ce manuscrit, un modèle numérique de plaque d'athérome carotidienne est développé en interaction fluide-structure dans le but mieux comprendre comment les actions mécaniques du sang sur la plaque sont affectées par les propriétés mécaniques et géométriques de la plaque. Plusieurs résultats sont en concordance avec la littérature : la vulnérabilité de la plaque est associée à la sévérité de sténose et à l'épaisseur de la chape fibreuse. De plus une analyse de l'écoulement du sang, de la déformation de la plaque et des contraintes dans la plaque révèle que les effets de l'écoulement du sang sont amplifiés si la plaque est courte, si la pente en amont de sténose est raide ou si la morphologie de la plaque est irrégulière et asymétrique. Ces résultats offrent de nouvelles perspectives dans la compréhension de la vulnérabilité de la plaque.

Published

2012

41. A numerical parametric study of the mechanical action of pulsatile blood flow onto axisymmetric stenosed arteries

Author

Tristan Belzacq, Stéphane Avril, Emmanuel Leriche, Alexandre Delache, Centre Ingénierie et Santé (CIS-ENSMSE), École des Mines de Saint-Étienne (Mines Saint-Étienne MSE), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT), Institut Fédératif de Recherche en Sciences et Ingénierie de la Santé (IFRESIS-ENSMSE), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT)-IFR143, Département Biomécanique et Biomatériaux (DB2M-ENSMSE), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT)-CIS, UMR 5146 - Laboratoire Claude Goux (LCG-ENSMSE), Laboratoire de Mathématiques de l'Université de Saint-Etienne (LAMUSE), Université Jean Monnet [Saint-Étienne] (UJM), Laboratoire de Mecanique des Fluides et d'Acoustique (LMFA), École Centrale de Lyon (ECL), Université de Lyon-Université de Lyon-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Institut National des Sciences Appliquées (INSA)-Université de Lyon-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS), PRES de LYON, Université Jean Monnet, LAMUSE (Laboratoire de Mathématiques de l'Université de Saint-Etienne), Ecole Centrale de Lyon, and LMFA (Laboratoire de Mécanique des fluides et d'acoustique)

Subjects

Materials science, 0206 medical engineering, Biomedical Engineering, Biophysics, Pulsatile flow, 02 engineering and technology, Constriction, Pathologic, Numerical simulation, Models, Biological, Stress (mechanics), [PHYS.MECA.MEMA]Physics [physics]/Mechanics [physics]/Mechanics of materials [physics.class-ph], 03 medical and health sciences, 0302 clinical medicine, Fluid–structure interaction, Fluid-structure interaction, [SPI.MECA.MEMA]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Mechanics of materials [physics.class-ph], Shear stress, medicine, Newtonian fluid, Humans, [SPI.GPROC]Engineering Sciences [physics]/Chemical and Process Engineering, Mechanical Phenomena, Stenosis, business.industry, Fibrous cap, Mechanics, Structural engineering, Blood flow, 020601 biomedical engineering, Plaque, Atherosclerotic, Biomechanical Phenomena, Shear (sheet metal), medicine.anatomical_structure, Carotid Arteries, Pulsatile Flow, Vascular biomechanics, business, 030217 neurology & neurosurgery

Abstract

International audience; In the present paper, a fluid-structure interaction model is developed, questioning how the mechanical action of the blood onto an atheromatous plaque is affected by the length and the severity of the stenosis. An axisymmetric model is considered. The fluid is assumed Newtonian. The plaque is modelled as a heterogeneous hyperelastic anisotropic solid composed of the arterial wall, the lipid core and the fibrous cap. Transient velocity and pressure conditions of actual pulsatile blood flow are prescribed. The simulation is achieved using the Arbitrary Lagrangian Eulerian scheme in the COMSOL commercial Finite Element package. The results reveal different types of behavior in function of the length (denoted L) and severity (denoted S) of the stenosis. Whereas large plaques (L > 10 mm) are mostly deformed under the action of the blood pressure, it appears that shorter plaques (L < 10 mm) are significantly affected by the shear stresses. The shear stresses tend to deform the plaque by pinching it. This effect is called: "the pinching effect". It has an essential influence on the mechanical response of the plaque. For two plaques having the same radius severity S = 45%, the maximum stress in the fibrous cap is 50% larger for the short plaque (L = 5 mm) than for a larger plaque (L = 10 mm), and the maximum wall shear stress is increased by 100%. Provided that they are confirmed by experimental investigations, these results may offer some new perspectives for understanding the vulnerability of short plaques.

Published

2012

42. Role of fibrillin-1 in the cardiovascular function during ageing : fibrillin-1 signalling in human endothelial cells and structural and functional exploration in Fbn-1+/mg delta mice

Author

Mariko, Boubacar, Physiopathologie vasculaire : interactions cellulaires, signalisation et vieillissement, Université Joseph Fourier - Grenoble 1 (UJF)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de la Santé et de la Recherche Médicale (INSERM), Université Joseph-Fourier - Grenoble I, Gilles FAURY(Gilles.Faury@ujf-grenoble.fr), and Mariko, Boubacar

Subjects

musculoskeletal diseases, [SDV.MHEP.PHY] Life Sciences [q-bio]/Human health and pathology/Tissues and Organs [q-bio.TO], Fibrillin-1, elastic fibers, microfibrils, signalisation calcique, vieillissement, calcium signaling, endothelial cells, microfibrilles, ageing, cellules endothéliales, biomécanique vasculaire, Marfan syndrome, syndrome de Marfan, vascular biomechanics, [SDV.MHEP.PHY]Life Sciences [q-bio]/Human health and pathology/Tissues and Organs [q-bio.TO], Fibrilline-1, fibres élastiques

Abstract

Fibrillin-1, the main component of microfibrils and second main component of elastic fibers, is a glycoprotein whose gene mutation in human is responsible for Marfan syndrome, characterized at the vascular level by aortic aneurysm and dissections. In this work, we investigated on the one hand, the role of fibrillin-1 in human endothelial cell physiology and, on the other hand, the effect of fibrillin-1 quantitative deficiency on the structure and function of the cardiovascular system during aging in mice. Fibrillin-1 fragment "PF14" induced calcium signaling through α5β1 and αvβ3 integrins, phospholipase C activation and intracellular calcium store mobilization, as well as endothelial cell proliferation and migration. Fibrillin-1 severe or full deficiency leads to premature lethality (within two weeks postnatal) in mice, while partial deficiency, through fibrillin-1 heterozygous hypomorphic deletion of exons 19 to 24 (mgΔ deletion), does not affect mice longevity. Fbn-1+/mgΔ mice were hypotensive with cardiac hypertrophy and presented aortic aneurysm becoming more frequent in aged animals. The aortic wall of Fbn-1+/mgΔ mice presented structural (elastic fibers fragmentations), biomechanical (increased aortic stiffness) and vasomotor alterations. This work suggests that fibrillin- 1 quantitative deficiency may alter the signaling events normally triggered by this protein in endothelial cells during vascular morphogenesis, and subsequently induce aneurysms in the aorta wall during ageing. The opposite effects of fibrillin-1 and elastin deficiencies suggest opposite roles for these two major components of elastic fibers. Moreover, this work validates Fbn-1+/mgΔ mice as a structural and functional model for Marfan syndrome., La fibrilline-1, composant majeur des microfibrilles et second composant majeur des fibres élastiques, est une glycoprotéine dont la mutation du gène chez l'humain est responsable du syndrome de Marfan, caractérisé par des anévrismes et des dissections aortiques. Dans ce travail de thèse, nous avons étudié d'une part le rôle de la fibrilline-1 dans la physiologie des cellules endothéliales vasculaires humaines et d'autre part la conséquence du déficit quantitatif de la fibrilline-1 sur la structure et la fonction du système cardiovasculaire au cours du vieillissement chez la souris. Le fragment de fibrilline-1 "PF14" induit une signalisation calcique via les intégrines α5β1 et αvβ3, l'activation de la phospholipase C et la mobilisation des réserves intracellulaires de calcium, ainsi que la prolifération et la migration des cellules endothéliales humaines. La déficience quantitative sévère ou totale de la fibrilline-1 entraîne une létalité chez la souris dans les deux semaines après la naissance alors que celle, partielle, due à la délétion hétérozygote hypomorphique des exons 19 à 24 du gène de la fibrilline-1 (délétion mgΔ) n'affecte pas la longévité des souris. Les souris Fbn-1+/mgΔ présentent une hypertrophie cardiaque et une hypotension ainsi que des anévrismes aortiques qui deviennent plus fréquents avec l'âge. La paroi aortique de ces souris présente des altérations structurales (fragmentations des lames élastiques), biomécaniques (l'augmentation de la rigidité) et de la vasomotricité, qui s'accentuent avec l'âge. Nos résultats suggèrent que la déficience quantitative de la fibrilline-1 pourrait altérer la signalisation que cette protéine déclenche normalement dans les cellules endothéliales dès la phase de morphogénèse artérielle, et induire en conséquence une pathologie anévrismale de la paroi aortique au cours du vieillissement. Les effets opposés des déficiences quantitatives en fibrilline-1 et en élastine sur la fonction vasculaire suggèrent des rôles opposés pour ces deux composants majeurs des fibres élastiques. Ce travail permet par ailleurs de valider les souris Fbn-1+/mgΔ, tant sur le plan structural que fonctionnel, comme modèle du syndrome de Marfan.

Published

2009

43. Rôle de la fibrilline-1 dans la fonction cardiovasculaire au cours du vieillissement : signalisation de la fibrilline-1 dans les cellules endothéliales humaines et exploration structurale et fonctionnelle chez les souris Fbn-1+/mgΔ

Author

Mariko, Boubacar, Mariko, Boubacar, Physiopathologie vasculaire : interactions cellulaires, signalisation et vieillissement, Université Joseph Fourier - Grenoble 1 (UJF)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de la Santé et de la Recherche Médicale (INSERM), Université Joseph-Fourier - Grenoble I, and Gilles FAURY(Gilles.Faury@ujf-grenoble.fr)

Subjects

musculoskeletal diseases, [SDV.MHEP.PHY] Life Sciences [q-bio]/Human health and pathology/Tissues and Organs [q-bio.TO], Fibrillin-1, elastic fibers, microfibrils, signalisation calcique, vieillissement, calcium signaling, endothelial cells, microfibrilles, ageing, cellules endothéliales, biomécanique vasculaire, Marfan syndrome, syndrome de Marfan, vascular biomechanics, [SDV.MHEP.PHY]Life Sciences [q-bio]/Human health and pathology/Tissues and Organs [q-bio.TO], Fibrilline-1, fibres élastiques

Abstract

Fibrillin-1, the main component of microfibrils and second main component of elastic fibers, is a glycoprotein whose gene mutation in human is responsible for Marfan syndrome, characterized at the vascular level by aortic aneurysm and dissections. In this work, we investigated on the one hand, the role of fibrillin-1 in human endothelial cell physiology and, on the other hand, the effect of fibrillin-1 quantitative deficiency on the structure and function of the cardiovascular system during aging in mice. Fibrillin-1 fragment "PF14" induced calcium signaling through α5β1 and αvβ3 integrins, phospholipase C activation and intracellular calcium store mobilization, as well as endothelial cell proliferation and migration. Fibrillin-1 severe or full deficiency leads to premature lethality (within two weeks postnatal) in mice, while partial deficiency, through fibrillin-1 heterozygous hypomorphic deletion of exons 19 to 24 (mgΔ deletion), does not affect mice longevity. Fbn-1+/mgΔ mice were hypotensive with cardiac hypertrophy and presented aortic aneurysm becoming more frequent in aged animals. The aortic wall of Fbn-1+/mgΔ mice presented structural (elastic fibers fragmentations), biomechanical (increased aortic stiffness) and vasomotor alterations. This work suggests that fibrillin- 1 quantitative deficiency may alter the signaling events normally triggered by this protein in endothelial cells during vascular morphogenesis, and subsequently induce aneurysms in the aorta wall during ageing. The opposite effects of fibrillin-1 and elastin deficiencies suggest opposite roles for these two major components of elastic fibers. Moreover, this work validates Fbn-1+/mgΔ mice as a structural and functional model for Marfan syndrome., La fibrilline-1, composant majeur des microfibrilles et second composant majeur des fibres élastiques, est une glycoprotéine dont la mutation du gène chez l'humain est responsable du syndrome de Marfan, caractérisé par des anévrismes et des dissections aortiques. Dans ce travail de thèse, nous avons étudié d'une part le rôle de la fibrilline-1 dans la physiologie des cellules endothéliales vasculaires humaines et d'autre part la conséquence du déficit quantitatif de la fibrilline-1 sur la structure et la fonction du système cardiovasculaire au cours du vieillissement chez la souris. Le fragment de fibrilline-1 "PF14" induit une signalisation calcique via les intégrines α5β1 et αvβ3, l'activation de la phospholipase C et la mobilisation des réserves intracellulaires de calcium, ainsi que la prolifération et la migration des cellules endothéliales humaines. La déficience quantitative sévère ou totale de la fibrilline-1 entraîne une létalité chez la souris dans les deux semaines après la naissance alors que celle, partielle, due à la délétion hétérozygote hypomorphique des exons 19 à 24 du gène de la fibrilline-1 (délétion mgΔ) n'affecte pas la longévité des souris. Les souris Fbn-1+/mgΔ présentent une hypertrophie cardiaque et une hypotension ainsi que des anévrismes aortiques qui deviennent plus fréquents avec l'âge. La paroi aortique de ces souris présente des altérations structurales (fragmentations des lames élastiques), biomécaniques (l'augmentation de la rigidité) et de la vasomotricité, qui s'accentuent avec l'âge. Nos résultats suggèrent que la déficience quantitative de la fibrilline-1 pourrait altérer la signalisation que cette protéine déclenche normalement dans les cellules endothéliales dès la phase de morphogénèse artérielle, et induire en conséquence une pathologie anévrismale de la paroi aortique au cours du vieillissement. Les effets opposés des déficiences quantitatives en fibrilline-1 et en élastine sur la fonction vasculaire suggèrent des rôles opposés pour ces deux composants majeurs des fibres élastiques. Ce travail permet par ailleurs de valider les souris Fbn-1+/mgΔ, tant sur le plan structural que fonctionnel, comme modèle du syndrome de Marfan.

Published

2009

44. FSI Simulations of Pulse Wave Propagation in Human Abdominal Aortic Aneurysm: The Effects of Sac Geometry and Stiffness

Author

Danial Shahmirzadi, Kexin Lin, and Han Li

Subjects

Quantitative Biology::Tissues and Organs, Strategy and Management, Pulsatile flow, Geometry, 030204 cardiovascular system & hematology, Biology, 01 natural sciences, Industrial and Manufacturing Engineering, 03 medical and health sciences, 0302 clinical medicine, 0103 physical sciences, medicine, Boundary value problem, lcsh:QH301-705.5, 010301 acoustics, Pulse wave velocity, Original Research, Pulse (signal processing), Mechanical Engineering, pulse wave imaging (PWI), Dynamics (mechanics), Metals and Alloys, Stiffness, fluid-solid interaction (FSI), lcsh:Biology (General), Flow velocity, vascular biomechanics, medicine.symptom, abdominal aortic aneurysm (AAA), Displacement (fluid)

Abstract

This study aims to quantify the effects of geometry and stiffness of aneurysms on the pulse wave velocity (PWV) and propagation in fluid-solid interaction (FSI) simulations of arterial pulsatile flow. Spatiotemporal maps of both the wall displacement and fluid velocity were generated in order to obtain the pulse wave propagation through fluid and solid media, and to examine the interactions between the two waves. The results indicate that the presence of abdominal aortic aneurysm (AAA) sac and variations in the sac modulus affect the propagation of the pulse waves both qualitatively (eg, patterns of change of forward and reflective waves) and quantitatively (eg, decreasing of PWV within the sac and its increase beyond the sac as the sac stiffness increases). The sac region is particularly identified on the spatiotemporal maps with a region of disruption in the wave propagation with multiple short-traveling forward/reflected waves, which is caused by the change in boundary conditions within the saccular region. The change in sac stiffness, however, is more pronounced on the wall displacement spatiotemporal maps compared to those of fluid velocity. We conclude that the existence of the sac can be identified based on the solid and fluid pulse waves, while the sac properties can also be estimated. This study demonstrates the initial findings in numerical simulations of FSI dynamics during arterial pulsations that can be used as reference for experimental and in vivo studies. Future studies are needed to demonstrate the feasibility of the method in identifying very mild sacs, which cannot be detected from medical imaging, where the material property degradation exists under early disease initiation.

Published

2016

45. Evaluación hidromecánica de venas yugulares bovinas frescas y fijadas en glutaraldehído para uso como bioimplante cardiovascular

Author

Bustamante, John, Echeverri, Claudia E, and Valbuena, Javier

Subjects

bioimplantes valvulares, valvular bio-implants, biomechanical tester, biomecánica vascular, flujo pulsante, vascular biomechanics, bovine jugular veins, pulsatile flow, venas yugulares bovinas, probador biomecánico

Abstract

Muchas de las enfermedades cardiovasculares congénitas pueden intervenirse mediante cirugía, con implantes biológicos o artificiales, lo cuales permitirán restablecer la funcionalidad del sistema cardiovascular. Por sus propiedades, los injertos biológicos procedentes de donantes cadavéricos (homoinjertos) son los más apropiados para cirugías reconstructivas del tracto de salida ventricular, pero infortunadamente son difíciles de adquirir ya que se obtienen de donantes con pocas semanas de nacidos, pretendiendo que se correlacionen con las dimensiones y geometría de la estructura nativa a reparar. Con este proyecto se evaluó el comportamiento hidrodinámico de tramos valvulados de venas yugulares bovinas, obtenidas en la Central Ganadera de Medellín, montando el segmento venoso de estudio en un banco de pruebas que emulaba las condiciones del tracto de salida del ventrículo derecho y tronco de la pulmonar, con el fin de analizar su comportamiento en condiciones similares a las que debe afrontar el vaso como bioimplante en la corrección de alteraciones cardiovasculares congénitas en neonatos y niños. Many congenital heart diseases may be treated surgically with biological or artificial implants that will allow the restoration of cardiovascular system functionality. Due to its properties, the biologic implants obtained from dead donors (homografts) are the most appropriate for ventricular output reconstructive surgeries. Unfortunately, these are difficult to acquire, because they are obtained from newborn donors and may be correlated to the dimensions and geometry of the native structure to be repaired. This project evaluated the hydrodynamic behavior of valvular segments of bovine jugular veins (obtained from the Livestock Central in Medellin), mounting the venous segment on a test bank that simulated the right ventricle output tract and the pulmonary trunk, in order to analyze its behavior in similar conditions to those that the vessel must face as bio-implant in the correction of congenital cardiovascular alterations in newborns and infants.

Published

2007

46. Biaxial biomechanical properties of self-assembly tissue-engineered blood vessels

Author

Zaucha, Michael T., Gauvin, Robert, Auger, François A., Germain, Lucie, Gleason, Rudolph L., Zaucha, Michael T., Gauvin, Robert, Auger, François A., Germain, Lucie, and Gleason, Rudolph L.

Abstract

Along with insights into the potential for graft success, knowledge of biomechanical properties of small diameter tissue-engineered blood vessel (TEBV) will enable designers to tailor the vessels' mechanical response to closer resemble that of native tissue. Composed of two layers that closely mimic the native media and adventitia, a tissue-engineered vascular adventitia (TEVA) is wrapped around a tissue-engineered vascular media (TEVM) to produce a self-assembled tissue-engineered media/adventia (TEVMA). The current study was undertaken to characterize the biaxial biomechanical properties of TEVM, TEVA and TEVMA under physiological pressures as well as characterize the stress-free reference configuration. It was shown that the TEVA had the greatest compliance over the physiological loading range while the TEVM had the lowest compliance. As expected, compliance of the SA-TEBV fell in between with an average compliance of 2.73 MPa−1. Data were used to identify material parameters for a microstructurally motivated constitutive model. Identified material parameters for the TEVA and TEVM provided a good fit to experimental data with an average coefficient of determination of 0.918 and 0.868, respectively. These material parameters were used to develop a two-layer predictive model for the response of a TEVMA which fit well with experimental data.

Published

2010

47. Patient-specific isogeometric analysis for vascular biomechanics

Author

Auricchio, Ferdinando, Conti, Michele, Ferraro, Mauro, Morganti, Simone, Reali, Alessandro, Auricchio, Ferdinando, Conti, Michele, Ferraro, Mauro, Morganti, Simone, and Reali, Alessandro

Abstract

Isogeometric Analysis (IGA) has recently emerged as a cost-effective alternative to classic isoparametric Finite Element Analysis. In this work a novel computational framework is proposed in order to get IGA-suitable geometries to simulate different vascular minimally-invasive procedures. The preliminary results show the capability of the framework to import in a straightforward way patient-specific vascular geometries and set an analysis enviroment suitable for the solver FEAP.

48. PRESENCE OF ATHEROMATOUS PLAQUES AND THEIRS EFFECTS ON THE BLOOD FLOW

Author

mostefa, belhocine, Bm, hichem, amrani, AH, kamel, fedaoui, dr, Hammoudi, mazouz, Mh, mostefa, belhocine, Bm, hichem, amrani, AH, kamel, fedaoui, dr, and Hammoudi, mazouz, Mh

Abstract

The paper utilizes a finite element method to study both the blood flow and atheromatous plaques. Specifically, the COMSOL finite element package is employed to achieve a fluid model. COMSOL is a powerful finite element tool commonly used in various research and industrial domains to study multiphysics problems. The focus of the investigation is on the geometric aspects of the atheromatous plaques. The study considers different forms and arrangements of stenosis, taking into account the irregularities formed by various shapes of the plaques and the resulting flow patterns. The key findings of the research suggest that the pressure and velocity of blood flow in the artery are dependent on the presence, position, number, and shape of the atheromatous plaques. This information is crucial for understanding the impact of these plaques on blood flow dynamics and may have implications for the diagnosis and treatment of arterial conditions.