Parallel generation of extensive vascular networks with application to an archetypal human kidney model.

L F M Cury,G D Maso Talou,P J Blanco,M Younes-Ibrahim

doi:10.1098/rsos.210973

Abstract

Given the relevance of the inextricable coupling between microcirculation and physiology, and the relation to organ function and disease progression, the construction of synthetic vascular networks for mathematical modelling and computer simulation is becoming an increasingly broad field of research. Building vascular networks that mimic in vivo morphometry is feasible through algorithms such as constrained constructive optimization (CCO) and variations. Nevertheless, these methods are limited by the maximum number of vessels to be generated due to the whole network update required at each vessel addition. In this work, we propose a CCO-based approach endowed with a domain decomposition strategy to concurrently create vascular networks. The performance of this approach is evaluated by analysing the agreement with the sequentially generated networks and studying the scalability when building vascular networks up to 200 000 vascular segments. Finally, we apply our method to vascularize a highly complex geometry corresponding to the cortex of a prototypical human kidney. The technique presented in this work enables the automatic generation of extensive vascular networks, removing the limitation from previous works. Thus, we can extend vascular networks (e.g. obtained from medical images) to pre-arteriolar level, yielding patient-specific whole-organ vascular models with an unprecedented level of detail.

Highlights

Given the relevance of the inextricable coupling between microcirculation and physiology, and the relation to organ function and disease progression, the construction of synthetic vascular networks for mathematical modelling and computer simulation is becoming an increasingly broad field of research
We first evaluate the performance of the parallel approach (PDCCO) compared with the sequential approach (DCCO) in three idealized experiments, and later we analyse the performance of PDCCO to generate complex trees with a large number of vessels
constructive optimization (CCO) strategies emerged as a promising approach to address this problem [24], leading to variants, such as the DCCO approach [30] to enhance the capabilities of the methodology to deal with the construction of intricate vascular networks

Summary

Introduction

Given the relevance of the inextricable coupling between microcirculation and physiology, and the relation to organ function and disease progression, the construction of synthetic vascular networks for mathematical modelling and computer simulation is becoming an increasingly broad field of research. Most modelling approaches available in the literature employ simplified mathematical representations for the peripheral vascular beds [11,12,13] In this sense, the oversimplification of the micro-circulation does not allow the study of sophisticated physiology at the level of smaller vascular structures, such as the size-dependent arterioles vasodilatory/remodelling responses. Hemodynamics at the scale of arterioles and capillaries was investigated through mathematical models operating on top of vascular models constructed through high-resolution micro-tomographic images obtained from animal models [18,19] In this context, automatic vascularization algorithms emerged more than two decades ago as a systematic approach to generate networks of interconnected vessels in regions of interest. These algorithms follow the hypothesis that network topology and geometry achieve an energetically efficient (or semi-efficient) perfusion of the vascularized tissues

Methods

Results

Conclusion