A computational algorithm for optimal design of a bioartificial organ scaffold architecture

We develop a computational algorithm based on a diffuse interface approach to study the design of bioartificial organ scaffold architectures. These scaffolds, composed of poroelastic hydrogels housing transplanted cells, are linked to the patient’s blood circulation via an anastomosis graft. Before...

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Vydáno v:PLoS computational biology Ročník 20; číslo 11; s. e1012079
Hlavní autoři: Bukač, Martina, Čanić, Sunčica, Muha, Boris, Wang, Yifan
Médium: Journal Article
Jazyk:angličtina
Vydáno: United States Public Library of Science 01.11.2024
Public Library of Science (PLoS)
Témata:
Advection
Algorithms
Analysis
Anastomosis
Artificial organs
Bioartificial Organs
Biology and Life Sciences
Blood circulation
Blood flow
Blood plasma
Cell viability
Computational Biology - methods
Computer applications
Computer Simulation
Design
Design and construction
Design optimization
Fabrication
Geometry
Humans
Hydrogels
Hydrogels - chemistry
Hypoxia
Insulin
Kinematics
Medicine and Health Sciences
Nutrients
Oxygen
Oxygen - metabolism
Pancreas
Physical Sciences
Plasma
Plasma physics
Poroelasticity
Reaction-diffusion equations
Research and Analysis Methods
Rheological properties
Rheology
Scaffolds
Science education
Simulation
Stem cells
Time dependence
Tissue Engineering - methods
Tissue Scaffolds - chemistry
Velocity
United States
Croatia
ISSN:1553-7358, 1553-734X, 1553-7358
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Shrnutí:We develop a computational algorithm based on a diffuse interface approach to study the design of bioartificial organ scaffold architectures. These scaffolds, composed of poroelastic hydrogels housing transplanted cells, are linked to the patient’s blood circulation via an anastomosis graft. Before entering the scaffold, the blood flow passes through a filter, and the resulting filtered blood plasma transports oxygen and nutrients to sustain the viability of transplanted cells over the long term. A key issue in maintaining cell viability is the design of ultrafiltrate channels within the hydrogel scaffold to facilitate advection-enhanced oxygen supply ensuring oxygen levels remain above a critical threshold to prevent hypoxia. In this manuscript, we develop a computational algorithm to analyze the plasma flow and oxygen concentration within hydrogels featuring various channel geometries. Our objective is to identify the optimal hydrogel channel architecture that sustains oxygen concentration throughout the scaffold above the critical hypoxic threshold. The computational algorithm we introduce here employs a diffuse interface approach to solve a multi-physics problem. The corresponding model couples the time-dependent Stokes equations, governing blood plasma flow through the channel network, with the time-dependent Biot equations, characterizing Darcy velocity, pressure, and displacement within the poroelastic hydrogel containing the transplanted cells. Subsequently, the calculated plasma velocity is utilized to determine oxygen concentration within the scaffold using a diffuse interface advection-reaction-diffusion model. Our investigation yields a scaffold architecture featuring a hexagonal network geometry that meets the desired oxygen concentration criteria. Unlike classical sharp interface approaches, the diffuse interface approach we employ is particularly adept at addressing problems with intricate interface geometries, such as those encountered in bioartificial organ scaffold design. This study is significant because recent developments in hydrogel fabrication make it now possible to control hydrogel rheology and utilize computational results to generate optimized scaffold architectures.
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The authors have declared that no competing interests exist.
ISSN:1553-7358
1553-734X
1553-7358
DOI:10.1371/journal.pcbi.1012079