Complex mechanical conditioning of cell-seeded agarose constructs can influence chondrocyte biosynthetic activity: biaxial loading influences chondrocytic activity
Complex mechanical conditioning of cell-seeded agarose constructs can influence chondrocyte biosynthetic activity: biaxial loading influences chondrocytic activity
Articular cartilage with its inherently poor capacity for self-regeneration represents a primary target for tissue engineering strategies, with approaches focusing on the in vitro generation of neo-cartilage using chondrocyte-seeded 3D scaffolds subjected to mechanical conditioning. Although uniaxial compression regimens have significantly up-regulated proteoglycan synthesis, their effects on the synthesis of collagen have been modest. Articular cartilage is subjected to shear forces during joint motion. Accordingly, this study utilised an apparatus to apply biaxial loading to chondrocytes seeded within agarose constructs with endplates. The chondrocytes yielded a monotonic increase in proteoglycan synthesis both in free swelling culture up to day 8 and when the constructs were subjected to dynamic compression alone (15% amplitude at a frequency of 1Hz for 48 hours). However, when dynamic shear (10% amplitude at 1 Hz) was superimposed on dynamic compression, total collagen synthesis was also up-regulated, within 3 days of culture, without compromising proteoglycan synthesis. Histological analysis revealed marked collagen deposition around individual chondrocytes. A significant proportion (50%) of collagen was released into the culture medium, suggesting that it had only been partially synthesised in its mature state. The overall biosynthetic activity was enhanced more when the biaxial stimulation was applied in a continuous mode as opposed to intermittent loading. Results of the present study strongly suggest that proteoglycan and collagen synthesis may be triggered by uncoupled mechanosensitive cellular responses. The proposed in vitro model and the prescribed conditioning protocols demonstrated that a short pre-culture period is preferable to long free swelling culture condition as it enables a significantly higher up-regulation of collagen.
1614-1625
Di Federico, E.
7543b95d-31cb-4668-b932-91270a39ac97
Shelton, J.C.
1df8c1c8-2515-417b-a523-17d5677dd1f0
Bader, Daniel
9884d4f6-2607-4d48-bf0c-62bdcc0d1dbf
July 2017
Di Federico, E.
7543b95d-31cb-4668-b932-91270a39ac97
Shelton, J.C.
1df8c1c8-2515-417b-a523-17d5677dd1f0
Bader, Daniel
9884d4f6-2607-4d48-bf0c-62bdcc0d1dbf
Di Federico, E., Shelton, J.C. and Bader, Daniel
(2017)
Complex mechanical conditioning of cell-seeded agarose constructs can influence chondrocyte biosynthetic activity: biaxial loading influences chondrocytic activity.
Biotechnology and Bioengineering, 114 (7), .
(doi:10.1002/bit.26273).
Abstract
Articular cartilage with its inherently poor capacity for self-regeneration represents a primary target for tissue engineering strategies, with approaches focusing on the in vitro generation of neo-cartilage using chondrocyte-seeded 3D scaffolds subjected to mechanical conditioning. Although uniaxial compression regimens have significantly up-regulated proteoglycan synthesis, their effects on the synthesis of collagen have been modest. Articular cartilage is subjected to shear forces during joint motion. Accordingly, this study utilised an apparatus to apply biaxial loading to chondrocytes seeded within agarose constructs with endplates. The chondrocytes yielded a monotonic increase in proteoglycan synthesis both in free swelling culture up to day 8 and when the constructs were subjected to dynamic compression alone (15% amplitude at a frequency of 1Hz for 48 hours). However, when dynamic shear (10% amplitude at 1 Hz) was superimposed on dynamic compression, total collagen synthesis was also up-regulated, within 3 days of culture, without compromising proteoglycan synthesis. Histological analysis revealed marked collagen deposition around individual chondrocytes. A significant proportion (50%) of collagen was released into the culture medium, suggesting that it had only been partially synthesised in its mature state. The overall biosynthetic activity was enhanced more when the biaxial stimulation was applied in a continuous mode as opposed to intermittent loading. Results of the present study strongly suggest that proteoglycan and collagen synthesis may be triggered by uncoupled mechanosensitive cellular responses. The proposed in vitro model and the prescribed conditioning protocols demonstrated that a short pre-culture period is preferable to long free swelling culture condition as it enables a significantly higher up-regulation of collagen.
Text
Complex mechanical conditioning of cell-seeded agarose constructs can influence chondrocyte biosynthetic activity - Di Federico
- Accepted Manuscript
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Accepted/In Press date: 7 February 2017
e-pub ahead of print date: 23 March 2017
Published date: July 2017
Organisations:
Researcher Development
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Local EPrints ID: 406562
URI: http://eprints.soton.ac.uk/id/eprint/406562
ISSN: 0006-3592
PURE UUID: 2b4262dc-e206-44e1-87bc-773c4c099db9
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Date deposited: 18 Mar 2017 02:22
Last modified: 16 Mar 2024 05:07
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Author:
E. Di Federico
Author:
J.C. Shelton
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