Sotirios Kakaletsis scite author profile

Deep vein thrombosis and pulmonary embolism affect 300,000-600,000 patients each year in the US. The progression from deep vein thrombus to pulmonary embolism occurs when blood clots, as a whole or partially, break off from the deep veins and eventually occlude the pulmonary arteries. Venous thromboembolism is the cause of up to 100,000 deaths per year in the US alone. To date, we don't fully understand this mechanical process among other reasons because in-vivo samples are difficult to obtain, highly heterogeneous, and their shapes are inappropriate for most mechanical tests. Toward overcoming these obstacles, we have set out to develop an in-vitro thrombus mimic and to test this mimic under large deformation simple shear. In addition to reporting on the mechanics of our mimics under simple shear, we explore the sensitivity of their mechanics to coagulation conditions and blood storage time, and compare three hyperelastic material models for their ability to fit our data. We found that thrombus mimics made from whole blood demonstrate strain-stiffening, a negative Poynting effect, and hysteresis when tested quasi-statically to 50% strain under simple shear. Additionally, we found that the stiffness of these mimics does not significantly vary with coagulation conditions or blood storage times. Of the three hyperelastic constitutive models that we tested, the Ogden model provided the best fits to both shear stress and normal stress. In conclusion, we developed a robust protocol to generate regularly-shaped, homogeneous thrombus mimics that lend themselves to simple shear testing under large deformation. Future studies will extend our model to include the effect of maturation and explore its fracture properties toward a better understanding of embolization.

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An introduction to the Ogden model in biomechanics: benefits, implementation tools and limitations

Lohr

Sugerman

Kakaletsis

et al. 2022

Phil. Trans. R. Soc. A.

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Constitutive models are important to biomechanics for two key reasons. First, constitutive modelling is an essential component of characterizing tissues’ mechanical properties for informing theoretical and computational models of biomechanical systems. Second, constitutive models can be used as a theoretical framework for extracting and comparing key quantities of interest from material characterization experiments. Over the past five decades, the Ogden model has emerged as a popular constitutive model in soft tissue biomechanics with relevance to both informing theoretical and computational models and to comparing material characterization experiments. The goal of this short review is threefold. First, we will discuss the broad relevance of the Ogden model to soft tissue biomechanics and the general characteristics of soft tissues that are suitable for approximating with the Ogden model. Second, we will highlight exemplary uses of the Ogden model in brain tissue, blood clot and other tissues. Finally, we offer a tutorial on fitting the one-term Ogden model to pure shear experimental data via both an analytical approximation of homogeneous deformation and a finite-element model of the tissue domain. Overall, we anticipate that this short review will serve as a practical introduction to the use of the Ogden model in biomechanics. This article is part of the theme issue ‘The Ogden model of rubber mechanics: Fifty years of impact on nonlinear elasticity’.

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Can machine learning accelerate soft material parameter identification from complex mechanical test data?

Kakaletsis

Lejeune

Rausch

2022

Biomech Model Mechanobiol

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