Innovations in foot and ankle arthrodesis: biological and biomaterial approaches to reducing non-union and the challenge of preclinical models
Innovations in foot and ankle arthrodesis: biological and biomaterial approaches to reducing non-union and the challenge of preclinical models
Foot and ankle arthrodesis remains a critical surgical approach for managing end-stage joint disease, yet its success is frequently hindered by the challenge of non-union. Despite advances in surgical techniques, complex cases – such as tibiotalocalcaneal fusion – still face non-union rates as high as 27 %, largely due to the region’s unique biomechanical demands and compounded by patient comorbidities and surgical variability. In recent years, orthobiologics and advanced biomaterials have demonstrated significant promise in enhancing fusion outcomes, particularly in high-risk patients with bone defects, metabolic disorders, or a history of infection. However, much of the existing clinical evidence stems from other orthopaedic contexts, with limited high-quality data specific to foot and ankle applications. To bridge this gap and support translational innovation, the development of preclinical models that accurately replicate the physiological and pathological characteristics of the human foot and ankle is essential. This review provides a comprehensive overview of the latest advancements in biologics and biomaterials for foot and ankle arthrodesis, with particular emphasis on hydrogels as next-generation platforms for bone regeneration and targeted drug delivery. Additionally, we critically examine the limitations of current preclinical models in terms of biomechanical compatibility and pathological relevance, highlighting opportunities for future refinement.
Xiao, Yueying
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Kanczler, Janos M.
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Dawson, Jonathan I.
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Koc, Togay
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Xiao, Yueying
b26c6317-9b14-4b55-be28-cec316299eeb
Kanczler, Janos M.
eb8db9ff-a038-475f-9030-48eef2b0559c
Dawson, Jonathan I.
b220fe76-498d-47be-9995-92da6c289cf3
Koc, Togay
4ded22a9-295e-471b-8999-7bc9c019b832
Xiao, Yueying, Kanczler, Janos M., Dawson, Jonathan I. and Koc, Togay
(2026)
Innovations in foot and ankle arthrodesis: biological and biomaterial approaches to reducing non-union and the challenge of preclinical models.
Acta Biomaterialia.
(doi:10.1016/j.actbio.2026.01.026).
Abstract
Foot and ankle arthrodesis remains a critical surgical approach for managing end-stage joint disease, yet its success is frequently hindered by the challenge of non-union. Despite advances in surgical techniques, complex cases – such as tibiotalocalcaneal fusion – still face non-union rates as high as 27 %, largely due to the region’s unique biomechanical demands and compounded by patient comorbidities and surgical variability. In recent years, orthobiologics and advanced biomaterials have demonstrated significant promise in enhancing fusion outcomes, particularly in high-risk patients with bone defects, metabolic disorders, or a history of infection. However, much of the existing clinical evidence stems from other orthopaedic contexts, with limited high-quality data specific to foot and ankle applications. To bridge this gap and support translational innovation, the development of preclinical models that accurately replicate the physiological and pathological characteristics of the human foot and ankle is essential. This review provides a comprehensive overview of the latest advancements in biologics and biomaterials for foot and ankle arthrodesis, with particular emphasis on hydrogels as next-generation platforms for bone regeneration and targeted drug delivery. Additionally, we critically examine the limitations of current preclinical models in terms of biomechanical compatibility and pathological relevance, highlighting opportunities for future refinement.
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Accepted/In Press date: 13 January 2026
e-pub ahead of print date: 14 January 2026
Identifiers
Local EPrints ID: 510418
URI: http://eprints.soton.ac.uk/id/eprint/510418
ISSN: 1742-7061
PURE UUID: 7621415c-79d5-4a81-bb62-ec9aa52bc74f
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Date deposited: 30 Mar 2026 16:58
Last modified: 31 Mar 2026 01:42
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Author:
Yueying Xiao
Author:
Janos M. Kanczler
Author:
Togay Koc
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