Estudo numérico hemodinâmico de um aneurisma na vizinhança de uma bifurcação arterial tridimensional
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Data
2017-03-24
Autores
Carvalho, Jeane Batista de [UNESP]
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Editor
Universidade Estadual Paulista (Unesp)
Resumo
Nas últimas décadas, há uma crescente preocupação em mensurar os parâmetros dinâmicos do sangue, dadas as imensas perdas de vidas por doenças cardiovasculares sendo, muitas delas, por aneurismas. A formação e desenvolvimento de um aneurisma é, predominantemente, degenerativo e provém de uma complexa interação entre os efeitos biológicos da parede arterial, os estímulos de escoamento e tensões provenientes da hemodinâmica. A tensão cisalhante na parede e o cíclico campo de pressão são um dos principais fatores responsáveis pela formação e crescimento de um aneurisma. Logo, há a necessidade de se conhecer os campos de velocidades e pressão além das tensões cisalhantes e efetivas na parede. Uma análise numérica é mais promissora que uma experimental. Uma análise experimental in-vivo possui impasses éticos e morais, sem contar a necessidade de um grande investimento. Outra vantagem de um estudo numérico é a disponibilidade de softwares livres de extração de tomografias que permite a extração da geometria sem a necessidade de um método invasivo que ocorreria em estudo experimental in vivo. Portanto com o auxílio de simulações numéricas (Ansys®), considerando o efeito multi-física de interação fluido estrutura (FSI) pela metodologia de elementos e volumes finitos foi possível verificar o efeito dos fatores que levam a formação e crescimento de aneurisma na aorta abdominal. Os aneurismas estudados foram modelos geométricos e reais sendo um dos reais obtidos através de imagens DICOM.
In recent decades, there is growing concern in measuring the dynamic parameters of the blood, given the immense loss of life from cardiovascular disease in human history, including, aneurysms. The formation and development of an aneurysm is predominantly degenerative and results from a complex interaction between the biological effects of the arterial wall and the flow and stress effects from hemodynamics. The stress in the wall and in the cyclic field of pressure is one of the main factors for the formation and growth of an aneurysm that degenerates until its rupture. Therefore, it is necessary to know the velocity and pressure fields as well as the shear stress and effective stress on the wall. A numerical analysis is more promising than an experimental one since an in-vivo experimental analysis has ethical and moral impasses, not counting the need for a large investment. Another advantage of a numerical study is the availability of free softwares for tomography analysis that allows the extraction of the geometry without the need for an invasive method that would occur in an in vivo experimental study. Therefore, with the aid of numerical simulations (Ansys®), considering the multi-physical effect of fluid structure interaction (FSI) by the methodology of finite elements and finite volumes it was possible to verify the effect of factors that lead to the formation and growth of abdominal aortic aneurysm. The studied aneurysms came from geometric models and from real examples, being one of the real ones obtained through DICOM images.
In recent decades, there is growing concern in measuring the dynamic parameters of the blood, given the immense loss of life from cardiovascular disease in human history, including, aneurysms. The formation and development of an aneurysm is predominantly degenerative and results from a complex interaction between the biological effects of the arterial wall and the flow and stress effects from hemodynamics. The stress in the wall and in the cyclic field of pressure is one of the main factors for the formation and growth of an aneurysm that degenerates until its rupture. Therefore, it is necessary to know the velocity and pressure fields as well as the shear stress and effective stress on the wall. A numerical analysis is more promising than an experimental one since an in-vivo experimental analysis has ethical and moral impasses, not counting the need for a large investment. Another advantage of a numerical study is the availability of free softwares for tomography analysis that allows the extraction of the geometry without the need for an invasive method that would occur in an in vivo experimental study. Therefore, with the aid of numerical simulations (Ansys®), considering the multi-physical effect of fluid structure interaction (FSI) by the methodology of finite elements and finite volumes it was possible to verify the effect of factors that lead to the formation and growth of abdominal aortic aneurysm. The studied aneurysms came from geometric models and from real examples, being one of the real ones obtained through DICOM images.
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Palavras-chave
Aneurisma, Bifurcação na aorta abdominal, Hemodinâmica, Interação Fluido Estrutura (FSI), Bioengenharia, Método de elementos e volumes finitos, Aneurysm, Abdominal aorta bifurcation, Hemodynamics, Fluid Structure Interaction (FSI), Bioengineering, Finite elements and volumes method