Epithelialization of hydrogels achieved by amine functionalization and co-culture with stromal cells

Rimmer, Stephen; Johnson, Claire; Zhao, Bojun; Collier, Joyleen; Gilmore, Louisa; Sabnis, S. D.; Wyman, Paul; Sammon, Chris; Fullwood, Nigel J.; MacNeil, Sheila

doi:10.1016/j.biomaterials.2007.08.028

Cited by 52 publications

(39 citation statements)

References 32 publications

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“…However, it is the denuded matrix of the wound surface that carries the memory of what epithelial type should reside on it, and in wound healing, the matrix determines whether normal epithelial cells would or would not be prone to populate the wound area. Therefore, considerable effort is made in engineering instructive signals into substrates that would enhance epithelialization, using the methods ranging from soaking matrices with growth factors, through chemical matrix surface activation, up to the use of whole organisms to make changes in wounded tissues, such as medicinal maggot application (119,120). Cell memory and sensitivity to mechanical stimuli has been recently used in promising studies of acute and chronic wound epithelialization with the use of ultrasound and shock waves, and are now entering phase III clinical evaluation (121).…”

Section: Organ Level: Integration Of All Memory Mechanismsmentioning

confidence: 99%

Memory Encoded Throughout Our Bodies: Molecular and Cellular Basis of Tissue Regeneration

et al. 2008

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When a sheep loses its tail, it cannot regenerate it in the manner of lizards. On the other hand, it is possible to clone mammals from somatic cells, showing that a complete developmental program is intact in a wounded sheep's tail the same way it is in a lizard. Thus, there is a requirement for more than only the presence of the entire genetic code in somatic cells for regenerative abilities. Thoughts like this have motivated us to assemble more than just a factographic synopsis on tissue regeneration. As a model, we review skin wound healing in chronological order, and when possible, we use that overview as a framework to point out possible mechanisms of how damaged tissues can restore their original structure. This article postulates the existence of tissue structural memory as a complex distributed homeostatic mechanism. We support such an idea by referring to an extremely fragmented literature base, trying to synthesize a broad picture of important principles of how tissues and organs may store information about their own structure for the purposes of regeneration. Selected developmental, surgical, and tissue engineering aspects are presented and discussed in the light of recent findings in the field. (Pediatr Res 63: 502-512, 2008)

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Section: Organ Level: Integration Of All Memory Mechanismsmentioning

confidence: 99%

Memory Encoded Throughout Our Bodies: Molecular and Cellular Basis of Tissue Regeneration

et al. 2008

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“…(12) However, it was also shown, (12,14) as well as by Lin et al, (15) Our previous work showed that low molar mass (Mn < 2700 g mol -1 ) PBMA with carboxylic acid end groups (PBMA-COOH) was cytotoxic. (16) However, here we have shown that it is possible to produce PBMA-COOH with a low number average molar mass (Mn = 1400 g mol -1 ) that is not toxic to either human dermal fibroblasts or human renal epithelial cells provided the low molar mass material is diluted with higher molar mass material: i.e.…”

Section: Human Renal Epithelial Cells (Hrepc)mentioning

confidence: 84%

“…It was shown that coatings formed from PBMA-COOH were good substrates for supporting the culture of HDF and HREpCs. Following on from other previous work involving hydrogel membranes with primary amine functionality (12,14) the work reported here shows that primary amine-functional materials can be used to support epithelial cells but not fibroblasts. Our early work had provided some indication that coculture with stromal cells was advantages to supporting human corneal epithelial cells (HCECs) on amine-functional hydrogels but latter work by use (14) showed that this was not the case and that epithelialisation with HCECs was achieved with monoculture.…”

Section: Human Renal Epithelial Cells (Hrepc)mentioning

confidence: 99%

“…Following on from other previous work involving hydrogel membranes with primary amine functionality (12,14) the work reported here shows that primary amine-functional materials can be used to support epithelial cells but not fibroblasts. Our early work had provided some indication that coculture with stromal cells was advantages to supporting human corneal epithelial cells (HCECs) on amine-functional hydrogels but latter work by use (14) showed that this was not the case and that epithelialisation with HCECs was achieved with monoculture. (12) The data here support those observations and although more work is required to establish the mechanism of action of these systems these aminated oligomers provide a useful coating system to promote epithelialisation on medical devices.…”

Section: Human Renal Epithelial Cells (Hrepc)mentioning

confidence: 99%

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Poly(n-butyl methacrylate) with primary amine end groups for supporting cell adhesion and proliferation of renal epithelial cells

Cox-Nowak

Al-Yamani

Grant

et al. 2017

International Journal of Polymeric Materials and Polymeric Biom

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Polymer coatings that support epithelial cell culture have been developed. Ozonolysis and subsequent work up of poly(butyl methacrylate-co-butadiene) copolymers is used to form oligomers with carboxylic acid end groups, which are then further reacted with diamines to provide poly(butyl methacrylate)s with primary amine end groups. The polymers are cast as films and used as cell culture substrates for human dermal fibroblasts and human renal epithelial cells. Fibroblast and epithelial cells adhere and proliferate on acid functional materials but on amine functional films epithelial cells show greater viability than fibroblasts. Graphical Abstract 2

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“…Emerging technologies to enhance the tissue response have involved the development of modified surfaces. This has involved the production of biomimetic surfaces either using synthetic analogues [9] or covalent binding of biological molecules, for example, collagen I to synthetic polymers such as polyethylene glycol/polyacrylic acid copolymers and N-isopropylacrylamide [10]. The cosmetic results from this approach are poor and thus there would be significant advantages in the development of a synthetic tissue equivalent.…”

Section: Cornea and Conjunctivamentioning

confidence: 98%

Biomaterials for ocular reconstruction

2014

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Synthetic materials have played a significant role in ophthalmic applications to improve vision for many years. This has been in four main areas in ophthalmology: ocular surface reconstruction, lens replacement, vitreous replacement and structural support and cell transplantation in the retina. Corneal replacement therapies have been developed using both synthetic acrylic-based materials and more recently naturally derived materials such as amniotic membrane.

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Epithelialization of hydrogels achieved by amine functionalization and co-culture with stromal cells

Cited by 52 publications

References 32 publications

Memory Encoded Throughout Our Bodies: Molecular and Cellular Basis of Tissue Regeneration

Memory Encoded Throughout Our Bodies: Molecular and Cellular Basis of Tissue Regeneration

Poly(n-butyl methacrylate) with primary amine end groups for supporting cell adhesion and proliferation of renal epithelial cells

Biomaterials for ocular reconstruction

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