Regulation of immature cartilage growth by IGF-I, TGF-β1, BMP-7, and PDGF-AB: role of metabolic balance between fixed charge and collagen network

Asanbaeva, Anna; Masuda, Koichi; Thonar, Eugene J-M.A.; Klisch, Stephen M.; Sah, Robert L.

doi:10.1007/s10237-007-0096-8

Cited by 33 publications

(52 citation statements)

References 97 publications

(116 reference statements)

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“…It has been hypothesized that changes in cartilage size and in maturation (as quantified by the tensile properties) could result by altering the balance of proteoglycan and collagen metabolism (27,41,42). Culturing immature cartilage explants with fetal bovine serum (FBS), insulin-like growth factors-1, or bone morphogenetic protein-7 (BMP-7) resulted in an expansive growth phenotype characterized by large increases in size, stimulation of proteoglycan in excess of collagen, and decreases in tensile stiffness and strength (42). Alternatively, culture with TGF-␤1 promoted cartilage homeostasis with little change in size, composition, or mechanical properties (42).…”

Section: Growth and Maturationmentioning

confidence: 99%

“…Culturing immature cartilage explants with fetal bovine serum (FBS), insulin-like growth factors-1, or bone morphogenetic protein-7 (BMP-7) resulted in an expansive growth phenotype characterized by large increases in size, stimulation of proteoglycan in excess of collagen, and decreases in tensile stiffness and strength (42). Alternatively, culture with TGF-␤1 promoted cartilage homeostasis with little change in size, composition, or mechanical properties (42). The identification of biochemical stimuli which promote maturation in immature cartilage explants has been elusive, though depletion of proteoglycans by chondroitinase-ABC treatment before culture resulted in increased tensile stiffness (27).…”

Section: Growth and Maturationmentioning

confidence: 99%

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Bioengineering Cartilage Growth, Maturation, and Form

2008

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Cartilage of articular joints grows and matures to achieve characteristic sizes, forms, and functional properties. Through these processes, the tissue not only serves as a template for bone growth but also yields mature articular cartilage providing joints with a low-friction, wear-resistant bearing material. The study of cartilage growth and maturation is a focus of both cartilage biologists and bioengineers with one goal of trying to create biologic tissue substitutes for the repair of damaged joints. Experimental approaches both in vivo and in vitro are being used to better understand the mechanisms and regulation of growth and maturation processes. This knowledge may facilitate the controlled manipulation of cartilage size, shape, and maturity to meet the criteria needed for successful clinical applications. Mathematical models are also useful tools for quantitatively describing the dynamically changing composition, structure and function of cartilage during growth and maturation and may aid the development of tissue engineering solutions. Recent advances in methods of cartilage formation and culture which control the size, shape, and maturity of these tissues are numerous and provide contrast to the physiologic development of cartilage.

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Section: Growth and Maturationmentioning

confidence: 99%

Section: Growth and Maturationmentioning

confidence: 99%

Bioengineering Cartilage Growth, Maturation, and Form

2008

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“…There is also a steady increase in the amount of collagenase and other enzymes that are responsible for collagen degradation. Specifically designed compositions of the ECM are critical in the bioengineering of multiple tissues and organs, including bone and cartilage (71)(72)(73)(74), cleft palate repair (4,75), brain injury repair (76), heart valves (77,78), and the skin, which is the most advanced living artificial organ at the present time (42). The elastic component of the ECM, characterized by molecules of elastin that crosslink with one another, confers a resilience to recoil after stretching.…”

Section: Wrecked Tissue Remnants and Building New Scaffoldsmentioning

confidence: 99%

Memory Encoded Throughout Our Bodies: Molecular and Cellular Basis of Tissue Regeneration

et al. 2008

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When a sheep loses its tail, it cannot regenerate it in the manner of lizards. On the other hand, it is possible to clone mammals from somatic cells, showing that a complete developmental program is intact in a wounded sheep's tail the same way it is in a lizard. Thus, there is a requirement for more than only the presence of the entire genetic code in somatic cells for regenerative abilities. Thoughts like this have motivated us to assemble more than just a factographic synopsis on tissue regeneration. As a model, we review skin wound healing in chronological order, and when possible, we use that overview as a framework to point out possible mechanisms of how damaged tissues can restore their original structure. This article postulates the existence of tissue structural memory as a complex distributed homeostatic mechanism. We support such an idea by referring to an extremely fragmented literature base, trying to synthesize a broad picture of important principles of how tissues and organs may store information about their own structure for the purposes of regeneration. Selected developmental, surgical, and tissue engineering aspects are presented and discussed in the light of recent findings in the field. (Pediatr Res 63: 502-512, 2008)

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“…AC from the patellofemoral groove has demonstrated consistent GAG and COL densities in previous stud-ies [13,14,17,18]. Biochemical data from [14] was used as it is the most recent and most closely matches the sites harvested from for this study.…”

Section: Untreated Control Group Biochemical Datamentioning

confidence: 99%

“…Growth factors such as insulin-like growth factor 1 (IGF-1) and transforming growth factor beta 1 (TGF-β1) have been used to promote geometric growth or alter the constituent balance [13,14,[17][18][19]. Mechanical stimuli such as relative interstitial fluid velocity and mechanical cues such as maximum principle strain direction have been correlated with AC remodeling [20][21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Prediction of Articular Cartilage Remodeling During Dynamic Compression with a Finite Element Model

Yamauchi¹

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Prediction of Articular Cartilage Remodeling During Dynamic Compression with a Finite Element Model Kevin YamauchiFirst, an in vitro growth experiment was performed to test the hypothesis that applying dynamic unconfined compression during culture produces heterogeneous remodeling in newborn bovine articular cartilage explants. Heterogeneous measures of cartilage microstructure were obtained by biochemical assays and quantified polarized light microscopy. Significant differences were measured between the GAG content in the inner and outer portions of the samples stimulated with dynamic unconfined compression. The COL fiber network was found to be more highly aligned in the inner portion of the sample than in the peripheral region.Next, a poroelastic finite element model with a remodeling subroutine was developed to test the hypothesis that the magnitude of relative interstitial fluid velocity and maximum principle strain stimulate GAG and COL fiber network remodeling, respectively, in articular cartilage during culture with dynamic unconfined compression. The GAG remodeling law was successful in predicting the heterogeneous changes in GAG content. The collagen remodeling law was not successful in predicting the changes in the COL network microstructural orientation, suggesting another mechanical cue is responsible for stimulating the remodeling of the COL fiber network.iv

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Regulation of immature cartilage growth by IGF-I, TGF-β1, BMP-7, and PDGF-AB: role of metabolic balance between fixed charge and collagen network

Cited by 33 publications

References 97 publications

Bioengineering Cartilage Growth, Maturation, and Form

Bioengineering Cartilage Growth, Maturation, and Form

Memory Encoded Throughout Our Bodies: Molecular and Cellular Basis of Tissue Regeneration

Prediction of Articular Cartilage Remodeling During Dynamic Compression with a Finite Element Model

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