Integrated model of IGF-I mediated biosynthesis in a deformed articular cartilage

L. Zhang; B.S. Gardiner; D.W. Smith; P. Pivonka; A.J. Grodzinsky

doi:10.1061/(ASCE)0733-9399(2009)135:5(439)

Back

Integrated model of IGF-I mediated biosynthesis in a deformed articular cartilage

Journal article

Peer reviewed

Integrated model of IGF-I mediated biosynthesis in a deformed articular cartilage

L. Zhang, B.S. Gardiner, D.W. Smith, P. Pivonka and A.J. Grodzinsky

Journal of Engineering Mechanics, Vol.135(5), pp.439-449

2009

DOI: https://doi.org/10.1061/(ASCE)0733-9399(2009)135:5(439)

Files and links (1)

url

Link to Published Version *Subscription may be requiredView

Abstract

Maintenance of articular cartilage’s functional mechanical properties ultimately depends on the balance between the extracellular matrix component biosynthesis, degradation, and loss. A variety of factors are known to modulate the rate of cartilage matrix synthesis (e.g., growth factors and stress/strain environment). In the present study, we develop an integrated mathematical model that quantifies biological processes within cartilage tissue modulated by insulin-like growth factors (IGFs). Specifically, the model includes IGF transport through a deforming porous media, competitive binding to binding proteins and cell receptors, and matrix macromolecule biosynthesis—particularly glycosaminoglycans (GAGs). These newly synthesized matrix molecules are then able to modify the material properties of cartilage. The model is used to investigate the effect of synovial fluid IGF-I concentration on cartilage homeostasis. The results presented here suggest that GAG production can be rapidly “switched on” when the concentration of IGF-I reaches a certain threshold, while it is predicted that high receptor concentration leads to heterogeneous matrix production. As for the combined effect of IGF-I and mechanical loading on biosynthesis, the current model predicts that a loading regime with high strain magnitude (e.g., 10%) can achieve a synergistic effect on matrix protein production. Furthermore, dynamic loading is seen to promote spatial homogeneous GAG production.

Details

Title: Integrated model of IGF-I mediated biosynthesis in a deformed articular cartilage
Authors/Creators: L. Zhang (Author/Creator) - The University of Melbourne
B.S. Gardiner (Author/Creator) - School of Computer Science and Software Engineering
D.W. Smith (Author/Creator) - Software (Germany)
P. Pivonka (Author/Creator) - School of Computer Science and Software Engineering
A.J. Grodzinsky (Author/Creator) - The University of Melbourne
Publication Details: Journal of Engineering Mechanics, Vol.135(5), pp.439-449
Publisher: ASCE Library
Identifiers: 991005541915607891
Copyright: © 2009 ASCE
Murdoch Affiliation: Murdoch University
Language: English
Resource Type: Journal article

UN Sustainable Development Goals (SDGs)

This output has contributed to the advancement of the following goals:

Source: InCites

Metrics

59 Record Views

43 Times Cited - Web of Science

InCites Highlights

These are selected metrics from InCites Benchmarking & Analytics tool, related to this output

Collaboration types: Domestic collaboration; International collaboration
Citation topics: 1 Clinical & Life Sciences; 1.34 Orthopedics; 1.34.255 Osteoarthritis
Web Of Science research areas: Engineering, Mechanical
ESI research areas: Engineering