No Cover Image

Journal article 1461 views 357 downloads

Data-driven modelling of the FRC network for studying the fluid flow in the conduit system

Rostislav Savinkov, Alexey Kislitsyn, Daniel J. Watson, Raoul van Loon Orcid Logo, Igor Sazonov Orcid Logo, Mario Novkovic, Lucas Onder, Gennady Bocharov

Engineering Applications of Artificial Intelligence, Volume: 62, Pages: 341 - 349

Swansea University Authors: Raoul van Loon Orcid Logo, Igor Sazonov Orcid Logo

  • savinkov2016.pdf

    PDF | Accepted Manuscript

    Released under the terms of a Creative Commons Attribution Non-Commercial No Derivatives License (CC-BY-NC-ND).

    Download (2.99MB)

Check full text

DOI (Published version): 10.1016/j.engappai.2016.10.007

Abstract

The human immune system is characterized by enormous cellular and anatomical complexity. Lymph nodes are key centers of immune reactivity, organized into distinct structural and functional modules including the T-cell zone, fibroblastic reticular cell (FRC) network and the conduit system. A thorough...

Full description

Published in: Engineering Applications of Artificial Intelligence
ISSN: 0952-1976
Published: 2017
Online Access: Check full text

URI: https://cronfa.swan.ac.uk/Record/cronfa30588
Abstract: The human immune system is characterized by enormous cellular and anatomical complexity. Lymph nodes are key centers of immune reactivity, organized into distinct structural and functional modules including the T-cell zone, fibroblastic reticular cell (FRC) network and the conduit system. A thorough understanding of the modular organization is a prerequisite for lymphoid organ tissue-engineering. Due to the biological complexity of lymphoid organs, the development of mathematical models capable of elaborating the lymph node architecture and functional organization, has remained a major challenge in computational biology. Here, we present a computational method to model the geometry of the FRC network and fluid flow in the conduit system. It differs from the blood vascular network image-based reconstruction approaches as it develops the parameterized geometric model using the real statistics of the node degree and the edge length distributions. The FRC network model is then used to analyze the fluid flow through the underlying conduit system. A first observation is that the pressure gradient is approximately linear, which suggests homogeneity of the network. Furthermore, calculated permeability values View the MathML source show the generated network is isotropic, while investigating random variations of pipe radii (with a given mean and standard deviation) shows a significant effect on the permeability. This framework can now be further explored to systematically correlate fundamental characteristics of the FRC conduit system to more global material properties such as permeability.
Keywords: Lymph node engineering; Fibroblastic reticular cell; Conduit system; Complex vascular network; Artificial networks; Fluid flow
College: Faculty of Science and Engineering
Start Page: 341
End Page: 349

Similar Items