Immersed finite element method and its applications to biological systems

Liu, Wing Kam; Liu, Yaling; Farrell, D. A.; Zhang, Lucy; Wang, Sheldon; Fukui, Yoshio; Patankar, Neelesh A.; Zhang, Yongjie; Bajaj, Chandrajit; Lee, Junghoon; Hong, Juhee; Chen, Xinyu; Hsu, Hua-Yi

doi:10.1016/j.cma.2005.05.049

Cited by 254 publications

(191 citation statements)

References 52 publications

(82 reference statements)

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“…The three values { A=1,2,3 } are the so-called principal stretches and I denotes the identity tensor. The strain invariants of Equation (25) can be expressed as functions of 2 A as…”

Section: Large Strain Hyperelasticitymentioning

confidence: 99%

“…Within the biomedical field, for example, the interaction of a viscous incompressible fluid, such as blood with a deformable membrane, as found within heart valves, arteries or veins represents an extraordinary challenge. Research within the biomedical field could influence many aspects of diagnosis and treatment as well as the design and implementation of components such as artificial heart valves, stents and many others [1][2][3][4].…”

Section: Introductionmentioning

confidence: 99%

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A partitioned coupling approach for dynamic fluid–structure interaction with applications to biological membranes

Wood

Gil

Hassan

et al. 2008

Numerical Methods in Fluids

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SUMMARYThis paper presents a fully coupled three-dimensional solver for the analysis of time-dependent fluidstructure interaction. A partitioned time-marching algorithm is employed for the solution to the timedependent coupled discretized problem, thus enabling the use of highly developed, robust and well-tested solvers for each field. Coupling of the fields is achieved through a conservative transfer of information at the fluid-structure interface. An implicit coupling is achieved when the solutions to the fluid and structure subproblems are cycled at each time step until convergence is reached. The three-dimensional unsteady incompressible fluid is solved using a powerful implicit dual time-stepping technique with an explicit multistage Runga-Kutta time stepping in pseudo-time and arbitrary Lagrangian-Eulerian formulation for the moving boundaries. A finite element dynamic analysis of the highly deformable structure is carried out with a numerical strategy combining the implicit Newmark time integration algorithm with a NewtonRaphson second-order optimization method. Various test cases are presented for benchmarking and to demonstrate the potential applications of this method.

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“…The three values { A=1,2,3 } are the so-called principal stretches and I denotes the identity tensor. The strain invariants of Equation (25) can be expressed as functions of 2 A as…”

Section: Large Strain Hyperelasticitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A partitioned coupling approach for dynamic fluid–structure interaction with applications to biological membranes

Wood

Gil

Hassan

et al. 2008

Numerical Methods in Fluids

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“…The IMFEM [78][79][80][81][82][83] is a computational framework to concurrently deal with the relevant physical interactions in biological environments [80,84,85], including fluid-structure interaction (FSI) [82,86,87], cell-cell interaction [81,88,89], thermal fluctuation [78,79,90], electrokinetics [83,91,92], self-assembly behaviour [79,[93][94][95] and other mesoscale and molecular effects [96]. In this work, the IMFEM will be used to simulate the blood flow as well as the microcirculation of NPs.…”

Section: Model and Methodologymentioning

confidence: 99%

Cell and nanoparticle transport in tumour microvasculature: the role of size, shape and surface functionality of nanoparticles

et al. 2016

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Through nanomedicine, game-changing methods are emerging to deliver drug molecules directly to diseased areas. One of the most promising of these is the targeted delivery of drugs and imaging agents via drug carrier-based platforms. Such drug delivery systems can now be synthesized from a wide range of different materials, made in a number of different shapes, and coated with an array of different organic molecules, including ligands. If optimized, these systems can enhance the efficacy and specificity of delivery compared with those of non-targeted systems. Emerging integrated multiscale experiments, models and simulations have opened the door for endless medical applications. Current bottlenecks in design of the drug-carrying particles are the lack of knowledge about the dispersion of these particles in the microvasculature and of their subsequent internalization by diseased cells (Bao et al . 2014 J. R. Soc. Interface 11 , 20140301 ( doi:10.1098/rsif.2014.0301 )). We describe multiscale modelling techniques that study how drug carriers disperse within the microvasculature. The immersed molecular finite-element method is adopted to simulate whole blood including blood plasma, red blood cells and nanoparticles. With a novel dissipative particle dynamics method, the beginning stages of receptor-driven endocytosis of nanoparticles can be understood in detail. Using this multiscale modelling method, we elucidate how the size, shape and surface functionality of nanoparticles will affect their dispersion in the microvasculature and subsequent internalization by targeted cells.

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“…Some examples for this type of approach are the boundary element method [23,26,34], the immersed boundary method [2,7,24,31], the lattice Boltzmann method [6,29] and the moving particle semi-implicit (MPS) method [19,30]). Recent reviews on these numerical methods can be found in Liu et al [18], Yamaguchi et al [33] and Lima et al [14]. Although the multiphase flow approach is a very promising method it requires massive computational power.…”

Section: Limitations and Future Directionsmentioning

confidence: 99%

Microscale Flow Dynamics of Red Blood Cells in Microchannels: An Experimental and Numerical Analysis

Lima

Fernandes

Dias

et al. 2010

Computational Methods in Applied Sciences

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The book collects the state-of-the-art research, methods and new trends on the subject of computational vision and medical image processing contributing to the development of these knowledge areas. PrefaceNowadays, computational methodologies of signal processing and imaging analysis for 2D, 3D and even 4D data are commonly used for various applications in society. For example, Computational Vision systems are progressively used for surveillance tasks, traffic analysis, recognition process, inspection purposes, human-machine interfaces, 3D vision and deformation analysis.One of the main characteristics of the Computational Vision domain is its intermultidisciplinary nature. In fact, in this domain, methodologies of several other fundamental sciences, such as Informatics, Mathematics, Statistics, Psychology, Mechanics and Physics are regularly used. Besides this inter-multidisciplinary characteristic, one of the main rationale that promotes the continuous effort being made in this area of human knowledge is the number of applications in the medical area. For instance, statistical or physical procedures on medical images can be used in order to model the represented structures. This modelling can have different goals, for example: shape reconstruction, segmentation, registration, behavioural interpretation and simulation, motion and deformation analysis, virtual reality, computer-assisted therapy or tissue characterization.The main objective of the ECCOMAS Thematic Conferences on Computational Vision and Medical Image Processing (VIPimage) is to promote a comprehensive forum for discussion on the recent advances in the related fields and try to identify areas of potential collaboration between researchers of different sciences.This book contains the extended versions of nineteen papers selected from works presented at the second ECCOMAS thematic conference on Computational Vision and Medical Image processing (VIPimage 2009), which was held at the Engineering Faculty of the University of Porto, Portugal. It gathers together the state-of-the-art on the subject of Computational Vision and Medical Image processing contributing to the development of these knowledge areas and showing new trends in these fields.The Editors would like to take this opportunity to thank to the European Community on Computational Methods in Applied Sciences, the Abstract The blood flow dynamics in microcirculation depends strongly on the microvascular networks composed with short irregular vessel segments which are linked by numerous bifurcations. This paper presents the application of a confocal micro-PTV system to track RBCs through a rectangular polydimethysiloxane (PDMS) microchannel with a bifurcation. By using a confocal micro-PTV system, we have measured the effect of bifurcation on the flow behaviour of both fluorescent particles diluted in pure water and RBCs in concentrated suspensions. After performing simulations with the commercial finite element software package POLYFLOW R , some experimental results were compared with the nume...

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Immersed finite element method and its applications to biological systems

Cited by 254 publications

References 52 publications

A partitioned coupling approach for dynamic fluid–structure interaction with applications to biological membranes

A partitioned coupling approach for dynamic fluid–structure interaction with applications to biological membranes

Cell and nanoparticle transport in tumour microvasculature: the role of size, shape and surface functionality of nanoparticles

Microscale Flow Dynamics of Red Blood Cells in Microchannels: An Experimental and Numerical Analysis

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