Type: Article

An image-based geometric model for numerical simulation of blood perfusion within the liver lobules

Journal: Computer Methods in Biomechanics and Biomedical Engineering (14768259)Year: 2 October 2020Volume: 23Issue: Pages: 987 - 1004

Ahmadi-Badejani R.Mosharaf Dehkordi M.^aAhmadikia H.^a

a :University of Isfahan - IRAN(IR) - Isfahan

DOI:10.1080/10255842.2020.1782389Language: English

Abstract

An image-based numerical algorithm is presented for simulating blood flow through the liver tissue. First, a geometric model is constructed by applying image processing techniques on a real microscopic image of a liver tissue. Then, incompressible blood flow through liver lobules is simulated. Effects of tissue heterogeneity and deformity, presence/absence of the second central vein in a particular lobule, and apparent sinusoids density in the liver cross section on the blood flow are investigated. Numerical results indicate that the existence of thick low permeability vascular septum, high permeability sinusoids, and lobule tissue heterogeneity can considerably affect interlobular and intralobular blood flow. . © 2020 Informa UK Limited, trading as Taylor & Francis Group.

Author Keywords

blood flowgeometric modelimage processingLiver lobulestissue heterogeneityvascular septum

Other Keywords

AnimalsBlood Flow VelocityBlood PressureComputer SimulationHemorheologyImage Processing, Computer-AssistedLiverLiver CirculationModels, AnatomicNumerical Analysis, Computer-AssistedPerfusionPermeabilityReproducibility of ResultsSwineGeometryHemodynamicsImage processingTissueGeometric modelingHigh permeabilityImage processing techniqueMicroscopic imageNumerical algorithmsNumerical resultsPresence/absenceTissue heterogeneityalgorithmArticleblood flowcentral venous pressurehumanhuman tissueimage reconstructionimage segmentationliver lobuleliver sinusoidliver tissuemathematical analysismicroscopyperfusion indexpriority journalshear stresssimulationtissue pressureanatomic modelanimalblood rheologydiagnostic imagingmathematical computingphysiologypigreproducibilityvascularizationBlood