Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates

The most prominent structural components in bone are collagen and mineral. However, bone additionally contains a substantial amount of noncollagenous proteins (most notably of the SIBLING protein family), some of which may act as cohesive/adhesive “binders” for the composite hybrid collagen/mineral...

Full description

Bibliographic Details
Published in:Bone
Main Authors: Cavelier, S., Dastjerdi, A. K., McKee, M. D., Barthelat, F.
Format: Article in Journal/Newspaper
Language:unknown
Published: Elsevier Inc. 2018
Subjects:
Bone toughness
Collagen
Mechanical testing
Osteopontin
Transglutaminase
narwhal*
Online Access:https://eprints.qut.edu.au/235110/
id ftqueensland:oai:eprints.qut.edu.au:235110
record_format openpolar
spelling ftqueensland:oai:eprints.qut.edu.au:235110 2024-04-28T08:28:31+00:00 Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates Cavelier, S. Dastjerdi, A. K. McKee, M. D. Barthelat, F. 2018-05 https://eprints.qut.edu.au/235110/ unknown Elsevier Inc. doi:10.1016/j.bone.2018.02.022 Cavelier, S., Dastjerdi, A. K., McKee, M. D., & Barthelat, F. (2018) Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates. Bone, 110, pp. 304-311. https://eprints.qut.edu.au/235110/ 2018 Elsevier Inc. This work is covered by copyright. Unless the document is being made available under a Creative Commons Licence, you must assume that re-use is limited to personal use and that permission from the copyright owner must be obtained for all other uses. If the document is available under a Creative Commons License (or other specified license) then refer to the Licence for details of permitted re-use. It is a condition of access that users recognise and abide by the legal requirements associated with these rights. If you believe that this work infringes copyright please provide details by email to qut.copyright@qut.edu.au Bone Bone toughness Collagen Mechanical testing Osteopontin Transglutaminase Contribution to Journal 2018 ftqueensland https://doi.org/10.1016/j.bone.2018.02.022 2024-04-10T00:20:36Z The most prominent structural components in bone are collagen and mineral. However, bone additionally contains a substantial amount of noncollagenous proteins (most notably of the SIBLING protein family), some of which may act as cohesive/adhesive “binders” for the composite hybrid collagen/mineral scaffolding, whether in the bulk phase of bone, or at its interfaces. One such noncollagenous protein – osteopontin (OPN) – appears to be critical to the deformability and fracture toughness of bone. In the present study, we used a reconstructed synthetic mineral-OPN-mineral interface, and a biogenic (natural tooth dentin) mineral/collagen-OPN-mineral/collagen interface, to measure the fracture toughness of OPN on mineralized substrates. We used this system to test the hypothesis that OPN crosslinking by the enzyme tissue transglutaminase 2 (TG2) that is found in bone enhances interfacial adhesion to increase the fracture toughness of bone. For this, we prepared double-cantilever beam substrates of synthetic pure hydroxyapatite mineral, and of narwhal dentin, and directly apposed them to one another under different intervening OPN/crosslinking conditions, and fracture toughness was tested using a miniaturized loading stage. The work-of-fracture of the OPN interface was measured for different OPN formulations (monomer vs. polymer), crosslinking states, and substrate composition. Noncrosslinked OPN provided negligible adhesion on pure hydroxyapatite, whereas OPN crosslinking (by the chemical crosslinker glutaraldehyde, and TG2 enzyme) provided strong interfacial adhesion for both hydroxyapatite and dentin using monomeric and polymeric OPN. Pre-coating of the substrate beams with monomeric OPN further improved the adhesive performance of the samples, likely by allowing effective binding of this nascent OPN form to mineral/matrix components, with this pre-attachment providing a protein layer for additional crosslinking between the substrates. Article in Journal/Newspaper narwhal* Queensland University of Technology: QUT ePrints Bone 110 304 311
institution Open Polar
collection Queensland University of Technology: QUT ePrints
op_collection_id ftqueensland
language unknown
topic Bone toughness
Collagen
Mechanical testing
Osteopontin
Transglutaminase
spellingShingle Bone toughness
Collagen
Mechanical testing
Osteopontin
Transglutaminase
Cavelier, S.
Dastjerdi, A. K.
McKee, M. D.
Barthelat, F.
Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates
topic_facet Bone toughness
Collagen
Mechanical testing
Osteopontin
Transglutaminase
description The most prominent structural components in bone are collagen and mineral. However, bone additionally contains a substantial amount of noncollagenous proteins (most notably of the SIBLING protein family), some of which may act as cohesive/adhesive “binders” for the composite hybrid collagen/mineral scaffolding, whether in the bulk phase of bone, or at its interfaces. One such noncollagenous protein – osteopontin (OPN) – appears to be critical to the deformability and fracture toughness of bone. In the present study, we used a reconstructed synthetic mineral-OPN-mineral interface, and a biogenic (natural tooth dentin) mineral/collagen-OPN-mineral/collagen interface, to measure the fracture toughness of OPN on mineralized substrates. We used this system to test the hypothesis that OPN crosslinking by the enzyme tissue transglutaminase 2 (TG2) that is found in bone enhances interfacial adhesion to increase the fracture toughness of bone. For this, we prepared double-cantilever beam substrates of synthetic pure hydroxyapatite mineral, and of narwhal dentin, and directly apposed them to one another under different intervening OPN/crosslinking conditions, and fracture toughness was tested using a miniaturized loading stage. The work-of-fracture of the OPN interface was measured for different OPN formulations (monomer vs. polymer), crosslinking states, and substrate composition. Noncrosslinked OPN provided negligible adhesion on pure hydroxyapatite, whereas OPN crosslinking (by the chemical crosslinker glutaraldehyde, and TG2 enzyme) provided strong interfacial adhesion for both hydroxyapatite and dentin using monomeric and polymeric OPN. Pre-coating of the substrate beams with monomeric OPN further improved the adhesive performance of the samples, likely by allowing effective binding of this nascent OPN form to mineral/matrix components, with this pre-attachment providing a protein layer for additional crosslinking between the substrates.
format Article in Journal/Newspaper
author Cavelier, S.
Dastjerdi, A. K.
McKee, M. D.
Barthelat, F.
author_facet Cavelier, S.
Dastjerdi, A. K.
McKee, M. D.
Barthelat, F.
author_sort Cavelier, S.
title Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates
title_short Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates
title_full Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates
title_fullStr Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates
title_full_unstemmed Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates
title_sort bone toughness at the molecular scale: a model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates
publisher Elsevier Inc.
publishDate 2018
url https://eprints.qut.edu.au/235110/
genre narwhal*
genre_facet narwhal*
op_source Bone
op_relation doi:10.1016/j.bone.2018.02.022
Cavelier, S., Dastjerdi, A. K., McKee, M. D., & Barthelat, F. (2018) Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates. Bone, 110, pp. 304-311.
https://eprints.qut.edu.au/235110/
op_rights 2018 Elsevier Inc.
This work is covered by copyright. Unless the document is being made available under a Creative Commons Licence, you must assume that re-use is limited to personal use and that permission from the copyright owner must be obtained for all other uses. If the document is available under a Creative Commons License (or other specified license) then refer to the Licence for details of permitted re-use. It is a condition of access that users recognise and abide by the legal requirements associated with these rights. If you believe that this work infringes copyright please provide details by email to qut.copyright@qut.edu.au
op_doi https://doi.org/10.1016/j.bone.2018.02.022
container_title Bone
container_volume 110
container_start_page 304
op_container_end_page 311
_version_ 1797587018086088704

Similar Items