Marine-derived biomaterials represent a sustainable alternative to mammalian sources for biomedical applications, aligning with circular economy principles. In this study, native fibrillar collagen extracted from food waste of the sea urchin was successfully methacrylated for the first time to produce structurally stable, photo-cross-linkable hydrogels. A dedicated methacrylation protocol was developed to overcome the intrinsic limitations imposed by the supramolecular organization of intact collagen fibrils, enabling effective functionalization while preserving their native architecture. Methacrylated collagen hydrogels were obtained via UV-induced photo-cross-linking and further functionalized with sea urchin-derived polyhydroxynaphthoquinones to generate antioxidant composite hydrogels. The resulting biomaterials were comprehensively characterized in terms of ultrastructure, macroporosity, swelling behavior, mechanical properties, water uptake, degradation kinetics under physiological and enzymatic conditions, antioxidant activity, and in vitro cytocompatibility using human dermal fibroblasts. Compared with non-methacrylated collagen scaffolds, methacrylated hydrogels exhibited enhanced structural stability, reduced swelling-induced deformation, and significantly increased resistance to degradation. Incorporation of sea urchin-derived antioxidants further improved hydrogel stability and conferred marked antioxidant activity, which was largely preserved after incorporation. In vitro assays demonstrated that the hydrogels supported cell viability and metabolic activity. Overall, these findings demonstrate that methacrylated sea urchin collagen hydrogels, with or without antioxidant loading, constitute a promising class of sustainable biomaterials for tissue engineering applications.

Methacrylation of Fibrillar Sea Urchin Collagen: Production of Sustainable, Stable, and Functional Hydrogels / M. Roncoroni, G.M.. - In: ACS OMEGA. - ISSN 2470-1343. - (2026), pp. 1-18. [Epub ahead of print] [10.1021/acsomega.6c01928]

Methacrylation of Fibrillar Sea Urchin Collagen: Production of Sustainable, Stable, and Functional Hydrogels

M. Roncoroni
Primo
;
G. Martinelli
Secondo
;
T. Chwojnik;C. Scapuzzi;D. Maggioni;S. Farris;S. Marzorati
Penultimo
;
M. Sugni
Ultimo
2026

Abstract

Marine-derived biomaterials represent a sustainable alternative to mammalian sources for biomedical applications, aligning with circular economy principles. In this study, native fibrillar collagen extracted from food waste of the sea urchin was successfully methacrylated for the first time to produce structurally stable, photo-cross-linkable hydrogels. A dedicated methacrylation protocol was developed to overcome the intrinsic limitations imposed by the supramolecular organization of intact collagen fibrils, enabling effective functionalization while preserving their native architecture. Methacrylated collagen hydrogels were obtained via UV-induced photo-cross-linking and further functionalized with sea urchin-derived polyhydroxynaphthoquinones to generate antioxidant composite hydrogels. The resulting biomaterials were comprehensively characterized in terms of ultrastructure, macroporosity, swelling behavior, mechanical properties, water uptake, degradation kinetics under physiological and enzymatic conditions, antioxidant activity, and in vitro cytocompatibility using human dermal fibroblasts. Compared with non-methacrylated collagen scaffolds, methacrylated hydrogels exhibited enhanced structural stability, reduced swelling-induced deformation, and significantly increased resistance to degradation. Incorporation of sea urchin-derived antioxidants further improved hydrogel stability and conferred marked antioxidant activity, which was largely preserved after incorporation. In vitro assays demonstrated that the hydrogels supported cell viability and metabolic activity. Overall, these findings demonstrate that methacrylated sea urchin collagen hydrogels, with or without antioxidant loading, constitute a promising class of sustainable biomaterials for tissue engineering applications.
Settore CHEM-06/A - Fondamenti chimici delle tecnologie
Settore BIOS-03/A - Zoologia
   Byproduct Recycling: Innovative TEchnology from the Sea (BRITEs)
   BRITEs
   MINISTERO DELL'ISTRUZIONE E DEL MERITO
   2017FNZPNN_002

   Chain for Innovative ReCycling: sea Urchin food by-products for zero waste-based muLtiple Applications (CIRCULAr)
   CIRCULAr
   FONDAZIONE CARIPLO
   2019-2169

   Progetto PSR (2025) Linea 8- Sottomisura A - Dott.ssa Stefania MARZORATI - EcoBioMat: sviluppo di biomateriali da scarti per applicazioni biomediche e green packaging
   EcoBioMat
   UNIVERSITA' DEGLI STUDI DI MILANO
   Domanda 15566809 / Progressivo #14
2026
7-lug-2026
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