Effects of hydration and fixed charge density on fluid transport in charged hydrated soft tissues

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Gu, Wei Yong¹; Yao, Hai¹

Effects of hydration and fixed charge density on fluid transport in charged hydrated soft tissues

Ann Biomed Eng. November 2003;31(10):1162-1170

©2003 Biomedical Engineering Society

Affiliations

¹Tissue Biomechanics Laboratory, Department of Biomedical Engineering, University of Miami, Coral Gables, FL
Abstract and keywords

The effects of tissue hydration and fixed charge density on hydraulic permeability and creep behavior of cartilaginous tissues have been investigated using the triphasic theory and finite element methods. The empirical model for hydraulic permeability of uncharged gels and Mackie and Meares (1955) model for ion diffusivity were used in the numerical analysis. The hydraulic permeabilities of normal and trypsin-treated porcine annulus fibrosus tissues were measured indirectly. Analysis of the experimental data from this study and in literature indicates that the water content plays a more important role in regulating tissue permeability than fixed charge density for normal tissues. A change in glycosaminoglycan content will change both triphasic closed-circuit (or intrinsic) and biphasic open-circuit permeabilities of cartilaginous tissues. Analysis also shows that both fixed charge density and water content play an important role in tissue creep response. This study adds new knowledge to the permeability and creep behavior of cartilaginous tissues and is important for understanding the nutrition in intervertebral disk.

Keywords: Annulus fibrosus; Intervertebral disk; Fluid transport; Tissue hydration; Fixed charge density; Hydraulic permeability; Triphasic theory; Finite element method
Links

DOI: 10.1114/1.1615576

PubMed: 14649490

WoS: 000186601100003
History

Received: 2003-03-05

Accepted: 2003-07-30

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2007	Likhitpanichkul M. The Cell-Matrix Mechano-Electrochemical Interactions in Articular Cartilage: Experiment and Triphasic Model [PhD thesis]. Columbia University; 2007.
2007	Wan Q. Fundamental Theoretical and Experimental Studies for Applications Toward Functional Tissue Engineering of Articular Cartilage [PhD thesis]. Columbia University; 2007.
2009	Massey CJ. Finite Element Analysis and Materials Characterization of Changes Due to Aging and Degeneration of the Human Intervertebral Disc [PhD thesis]. Drexel University; September 2009.
2004	Yao H. Physical Signals and Solute Transport in Cartilaginous Tissues [PhD thesis]. University of Miami; August 2004.
2007	Flagler DJ. Characterization of Intervertebral Disc Cells by Flow Cytometry [PhD thesis]. University of Miami; May 2007.
2009	Travascio F. Modeling Molecular Transport and Binding Interactions in Intervertebral Disc [PhD thesis]. University of Miami; December 2009.
2010	Jackson AR. Transport and Metabolism of Glucose in Intervertebral Disc [PhD thesis]. University of Miami; December 2010.
2016	Gao X. Modeling the Biomechanics and Mechanobiology of Intervertebral Discs [PhD thesis]. University of Miami; August 2016.
2016	Zhu Q. Numerical Modeling of Intervertebral Disc Degeneration and Repair [PhD thesis]. University of Miami; May 2016.
2017	Kleinhans KL. Transport Properties in Porcine Meniscus Fibrocartilage [PhD thesis]. University of Miami; August 2017.
2017	Wang Y-F. Enhancement of Nutrient Transport and Energy Production of the Intervertebral Disc by the Implantation of Polyurethane Mass [PhD thesis]. University of Miami; August 2017.
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2008	Natoli RM. Impact Loading and Functional Tissue Engineering of Articular Cartilage [PhD thesis]. Houston, TX: Rice University; October 2008.
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