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RGD-mimic polyamidoamine-montmorillonite composites with tunable stiffness as scaffolds for bone tissue-engineering applications

RGD-mimic polyamidoamine-montmorillonite composites with tunable stiffness as scaffolds for bone tissue-engineering applications

Mauro, Nicolò, Chiellini, Federica, Bartoli, Cristina, Gazzarri, Matteo, Laus, Michele, Antonioli, Diego, Griffiths, Peter ORCID: 0000-0002-6686-1271, Manfredi, Amedea, Ranucci, Elisabetta and Ferruti, Paolo (2016) RGD-mimic polyamidoamine-montmorillonite composites with tunable stiffness as scaffolds for bone tissue-engineering applications. Journal of Tissue Engineering and Regenerative Medicine, 11 (7). pp. 2164-2175. ISSN 1932-6254 (Print), 1932-7005 (Online) (doi:https://doi.org/10.1002/term.2115)

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Abstract

This paper reports on the development of montmorillonite (MMT)-reinforced hydrogels, based on a peptidomimetic polyamidoamine carrying guanidine pendants (AGMA1), as substrates for the osteo-induction of osteoblast precursor cells. AGMA1 hydrogels of various degrees of crosslinking responded favourably to MMT reinforcement, giving rise to composite hydrogels with shear storage modulus G′, when fully swollen in water, up to 200 kPa, i.e. 20 times higher than the virgin hydrogels and of the same order or higher than other hydrogel-based composites proposed for orthopaedic applications. This significant improvement was ascribed to the effective interpenetration between the polymer matrix and the inorganic filler. AGMA1–MMT hydrogels, when evaluated as scaffolds for the osteogenic differentiation of mouse calvaria-derived pre-osteoblastic MC3T3-E1 cells, proved able to support cell adhesion and proliferation and clearly induced differentiation towards the osteoblastic phenotype, as indicated by different markers. In addition, AGMA1–MMT hydrogels proved completely degradable in aqueous media at pH 7.4 and did not provide any evidence of cytotoxicity. The experimental evidence suggests that AGMA1–MMT composites definitely warrant potential as scaffolds for osteoblast culture and bone grafts.

Item Type: Article
Uncontrolled Keywords: composites, scaffolds, bone tissue-engineering applications
Subjects: Q Science > QM Human anatomy
R Medicine > RB Pathology
Faculty / School / Research Centre / Research Group: Faculty of Engineering & Science
Faculty of Engineering & Science > School of Science (SCI)
Last Modified: 30 Jul 2018 10:18
URI: http://gala.gre.ac.uk/id/eprint/15711

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