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Human bone tissue-derived ECM hydrogels: controlling physicochemical, biochemical, and biological properties through processing parameters

Human bone tissue-derived ECM hydrogels: controlling physicochemical, biochemical, and biological properties through processing parameters
Human bone tissue-derived ECM hydrogels: controlling physicochemical, biochemical, and biological properties through processing parameters
Decellularized tissues offer significant potential as biological materials for tissue regeneration given their ability to preserve the complex compositions and architecture of the native extracellular matrix (ECM). However, the evaluation and derivation of decellularized matrices from human bone tissue remains largely unexplored. We examined how the physiochemical and biological properties of ECM hydrogels derived from human bone ECM could be controlled by manipulating bone powder size (45-250 μm, 250-1000 μm, and 1000-2000 μm) and ECM composition through modulation of enzyme digestion time (3-5-7 days).
A reduction in material bone powder size and an increase in ECM digestion time produced enhanced protein concentrations in the ECM hydrogels, accompanied by the presence of a diverse array of proteins and improved gelation strength. Human bone marrow-derived stromal cells (HBMSCs) cultured on ECM hydrogels from 45-250 μm bone powder, over 7 days, demonstrated enhanced osteogenic differentiation compared to hydrogels derived from larger bone powders and collagen gels confirming the potential of the hydrogels as biologically active materials for bone regeneration. Digestion time and bone powder size modulation enabled the generation of hydrogels with enhanced release of ECM proteins and appropriate gelation and rheological properties, offering new opportunities for application in bone repair.
2452-199X
Kim, Yanghee
de0d641b-c2cb-4e73-9ae2-e20d33689f5d
Cidonio, Gianluca
558ad583-899a-4d8c-b42b-bc1c354c8757
Kanczler, Janos M.
eb8db9ff-a038-475f-9030-48eef2b0559c
Oreffo, Richard O.C.
ff9fff72-6855-4d0f-bfb2-311d0e8f3778
Dawson, Jonathan I.
982bf202-af02-4a6c-9db0-2d4a72c1ea92
Kim, Yanghee
de0d641b-c2cb-4e73-9ae2-e20d33689f5d
Cidonio, Gianluca
558ad583-899a-4d8c-b42b-bc1c354c8757
Kanczler, Janos M.
eb8db9ff-a038-475f-9030-48eef2b0559c
Oreffo, Richard O.C.
ff9fff72-6855-4d0f-bfb2-311d0e8f3778
Dawson, Jonathan I.
982bf202-af02-4a6c-9db0-2d4a72c1ea92

Kim, Yanghee, Cidonio, Gianluca, Kanczler, Janos M., Oreffo, Richard O.C. and Dawson, Jonathan I. (2024) Human bone tissue-derived ECM hydrogels: controlling physicochemical, biochemical, and biological properties through processing parameters. Bioactive Materials, 43. (doi:10.1016/j.bioactmat.2024.09.007).

Record type: Article

Abstract

Decellularized tissues offer significant potential as biological materials for tissue regeneration given their ability to preserve the complex compositions and architecture of the native extracellular matrix (ECM). However, the evaluation and derivation of decellularized matrices from human bone tissue remains largely unexplored. We examined how the physiochemical and biological properties of ECM hydrogels derived from human bone ECM could be controlled by manipulating bone powder size (45-250 μm, 250-1000 μm, and 1000-2000 μm) and ECM composition through modulation of enzyme digestion time (3-5-7 days).
A reduction in material bone powder size and an increase in ECM digestion time produced enhanced protein concentrations in the ECM hydrogels, accompanied by the presence of a diverse array of proteins and improved gelation strength. Human bone marrow-derived stromal cells (HBMSCs) cultured on ECM hydrogels from 45-250 μm bone powder, over 7 days, demonstrated enhanced osteogenic differentiation compared to hydrogels derived from larger bone powders and collagen gels confirming the potential of the hydrogels as biologically active materials for bone regeneration. Digestion time and bone powder size modulation enabled the generation of hydrogels with enhanced release of ECM proteins and appropriate gelation and rheological properties, offering new opportunities for application in bone repair.

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Accepted/In Press date: 4 September 2024
e-pub ahead of print date: 23 September 2024
Published date: 23 September 2024
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Identifiers

Local EPrints ID: 494567
URI: http://eprints.soton.ac.uk/id/eprint/494567
DOI: doi:10.1016/j.bioactmat.2024.09.007
ISSN: 2452-199X
PURE UUID: 2c7f92ae-6d3a-4b4f-bfa8-033a1cebe5cc
ORCID for Yanghee Kim: ORCID iD orcid.org/0000-0002-5312-3448
ORCID for Janos M. Kanczler: ORCID iD orcid.org/0000-0001-7249-0414
ORCID for Richard O.C. Oreffo: ORCID iD orcid.org/0000-0001-5995-6726

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Date deposited: 10 Oct 2024 16:48
Last modified: 11 Oct 2024 01:48

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Contributors

Author: Yanghee Kim ORCID iD
Author: Gianluca Cidonio
Author: Janos M. Kanczler ORCID iD
Author: Richard O.C. Oreffo ORCID iD
Author: Jonathan I. Dawson

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