Simone Di Gregorio scite author profile

We present a two phase model for microcirculation that describes the interaction of plasma with red blood cells. The model takes into account of typical effects characterizing the microcirculation, such as the Fahraeus-Lindqvist effect and plasma skimming. Besides these features, the model describes the interaction of capillaries with the surrounding tissue. More precisely, the model accounts for the interaction of capillary transmural flow with the surrounding interstitial pressure. Furthermore, the capillaries are represented as one-dimensional channels with arbitrary, possibly curved configuration. The latter two features rely on the unique ability of the model to account for variations of flow rate and pressure along the axis of the capillary, according to a local differential formulation of mass and momentum conservation. Indeed, the model stands on a solid mathematical foundation, which is also addressed in this work. In particular, we present the model derivation, the variational formulation and its approximation using the finite element method. Finally, we conclude the work with a comparative computational study of the importance of the Fahraeus-Lindqvist, plasma skimming and capillary leakage effects on the distribution of flow in a microvascular network.

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A computational model applied to myocardial perfusion in the human heart: From large coronaries to microvasculature

Gregorio

Fedele

Corno

et al. 2021

Journal of Computational Physics

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Numerical simulations of the microvascular fluid balance with a non-linear model of the lymphatic system

Possenti

Casagrande

Gregorio

et al. 2019

Microvascular Research

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Fluid homeostasis is required for life. Processes involved in fluid balance are strongly related to exchanges at the microvascular level. Computational models have been presented in the literature to analyze the microvascular-interstitial interactions. As far as we know, none of those models consider a physiological description for the lymphatic drainage-interstitial pressure relation. We develop a computational model that consists of a network of straight cylindrical vessels and an isotropic porous media with a uniformly distributed sink term acting as the lymphatic system. In order to describe the lymphatic flow rate, a nonlinear function of the interstitial pressure is defined, based on literature data on the lymphatic system. The proposed model of lymphatic drainage is compared to a linear one, as is typically used in computational models. To evaluate the response of the model, the two are compared with reference to both physiological and pathological conditions. Di↵erences in the local fluid dynamic description have been observed using the non-linear model. In particular, the distribution of interstitial pressure is heterogeneous in all the cases analyzed. The resulting averaged values of the interstitial pressure are also di↵erent, and they agree with literature data when using the non-linear model.

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A global sensitivity analysis approach applied to a multiscale model of microvascular flow

Possenti

Gregorio

Casagrande

et al. 2020

Computer Methods in Biomechanics and Biomedical Engineering

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Prediction of myocardial blood flow under stress conditions by means of a computational model

Gregorio

Vergara

Pelagi

et al. 2022

Eur J Nucl Med Mol Imaging

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