Ion-mediated progressively stiffening hydrogels for vascularized bone regeneration
Ion-mediated progressively stiffening hydrogels for vascularized bone regeneration
The extracellular matrix (ECM) of tissues progressively changes its mechanical properties in processes such as tissue development, repair, and disease progression. While stiffness has become a key design parameter of biomaterials, most synthetic biomaterials employed in cell culture or tissue regeneration do not display these gradual changes in mechanical properties. Here, we report on a hydrogel platform with the capacity to exhibit progressive stiffening from 0.8 to 7.4 kPa within a ∼48 h time period. The material integrates the tyramine derivative of hyaluronic acid (HAT) and Laponite® (Lap) and harnesses the diffusion of cations from culture media to trigger gradual secondary Lap-HAT cross-linking, resulting in the progressive stiffening of the hydrogel. We assessed the applicability of the hydrogel by first using it as a substrate for in vitro culture to investigate cross-talk between human bone marrow stromal cells (HBMSCs) and human umbilical vein endothelial cells (HUVECs). The progressively stiffening hydrogel led to changes in cell morphology and enhanced differentiation and communication compared to control substrates. In addition, we also tested the potential of the progressively stiffening hydrogels for bone regeneration using a critical-size rat cranial defect model and found that the hydrogel construct promoted vascularized bone regeneration. The current study introduces a hydrogel material that offers a more physiologically relevant environment for in vitro and in vivo applications and provides insight into the mechanical complexity of the ECM and its role in tissue physiology.
189-204
Bu, Wenhuan
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Dawson, Jonathan I.
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Oreffo, Richard O.C.
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D'Este, Matteo
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Eglin, David
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Sun, Hongchen
202fc23d-af98-45f3-a58e-270c9bd4a0eb
Mata, Alvaro
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13 November 2025
Bu, Wenhuan
251ea935-8a77-463e-af64-dc4e2ea1222c
Dawson, Jonathan I.
b220fe76-498d-47be-9995-92da6c289cf3
Oreffo, Richard O.C.
ff9fff72-6855-4d0f-bfb2-311d0e8f3778
D'Este, Matteo
82ed6294-2669-4c99-a24b-a72269c5018a
Eglin, David
6f8d568e-d544-46bb-b164-71e3f3542ab0
Sun, Hongchen
202fc23d-af98-45f3-a58e-270c9bd4a0eb
Mata, Alvaro
cb6c97cc-be81-4ca2-aa75-c9695014771a
Bu, Wenhuan, Dawson, Jonathan I., Oreffo, Richard O.C., D'Este, Matteo, Eglin, David, Sun, Hongchen and Mata, Alvaro
(2025)
Ion-mediated progressively stiffening hydrogels for vascularized bone regeneration.
Acta Biomaterialia, 207, .
(doi:10.1016/j.actbio.2025.10.027).
Abstract
The extracellular matrix (ECM) of tissues progressively changes its mechanical properties in processes such as tissue development, repair, and disease progression. While stiffness has become a key design parameter of biomaterials, most synthetic biomaterials employed in cell culture or tissue regeneration do not display these gradual changes in mechanical properties. Here, we report on a hydrogel platform with the capacity to exhibit progressive stiffening from 0.8 to 7.4 kPa within a ∼48 h time period. The material integrates the tyramine derivative of hyaluronic acid (HAT) and Laponite® (Lap) and harnesses the diffusion of cations from culture media to trigger gradual secondary Lap-HAT cross-linking, resulting in the progressive stiffening of the hydrogel. We assessed the applicability of the hydrogel by first using it as a substrate for in vitro culture to investigate cross-talk between human bone marrow stromal cells (HBMSCs) and human umbilical vein endothelial cells (HUVECs). The progressively stiffening hydrogel led to changes in cell morphology and enhanced differentiation and communication compared to control substrates. In addition, we also tested the potential of the progressively stiffening hydrogels for bone regeneration using a critical-size rat cranial defect model and found that the hydrogel construct promoted vascularized bone regeneration. The current study introduces a hydrogel material that offers a more physiologically relevant environment for in vitro and in vivo applications and provides insight into the mechanical complexity of the ECM and its role in tissue physiology.
Text
Ion-Mediated Progressively Stiffening Hydrogels for Vascularized Bone Regeneration accepted version of Jon's paper
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Accepted/In Press date: 14 October 2025
e-pub ahead of print date: 15 October 2025
Published date: 13 November 2025
Identifiers
Local EPrints ID: 508819
URI: http://eprints.soton.ac.uk/id/eprint/508819
ISSN: 1742-7061
PURE UUID: 323da621-a12c-4a1c-b512-fa6a5c2c512f
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Date deposited: 04 Feb 2026 17:37
Last modified: 07 Feb 2026 02:44
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Author:
Wenhuan Bu
Author:
Matteo D'Este
Author:
David Eglin
Author:
Hongchen Sun
Author:
Alvaro Mata
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