L. Buttafoco scite author profile

Porous scaffolds composed of collagen or collagen and elastin were prepared by freeze drying at temperatures between -18 and -196 degrees C. All scaffolds had a porosity of 90-98% and a homogeneous distribution of pores. Freeze drying at -18 degrees C afforded collagen and collagen/elastin matrices with average pore sizes of 340 and 130 mum, respectively. After 20 successive cycles up to 10% of strain, collagen/elastin dense films had a total degree of strain recovery of 70% +/- 5%, which was higher than that of collagen films (42% +/- 6%). Crosslinking of collagen/elastin matrices either in water or ethanol/water (40% v/v) was carried out using a carbodiimide (N-(3-dimethylaminopropyl)-N'-ethylcarbodiimide hydrochloride, EDC) in combination with a succinimide (N-hydroxysuccinimide, NHS) in the presence or absence of a diamine (J230) or by reaction with butanediol diglycidylether (BDGE), followed by EDC/NHS. Crosslinking with EDC/NHS or EDC/NHS/J230 resulted in matrices with increased stiffness as compared to noncrosslinked matrices, whereas sequential crosslinking with the diglycidylether and EDC/NHS yielded very brittle scaffolds. Ethanol/water was the preferred solvent in the crosslinking process because of its ability to preserve the open porous structure during crosslinking. Smooth muscle cells were seeded on the (crosslinked) scaffolds and could be expanded during 14 days of culturing.

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Tissue engineering of blood vessels: characterization of smooth‐muscle cells for culturing on collagen‐and‐elastin‐based scaffolds

Buijtenhuijs

Buttafoco

Poot

et al. 2004

Biotech and App Biochem

108

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Tissue engineering offers the opportunity to develop vascular scaffolds that mimic the morphology of natural arteries. We have developed a porous three-dimensional scaffold consisting of fibres of collagen and elastin interspersed together. Scaffolds were obtained by freeze-drying a suspension of insoluble type I collagen and insoluble elastin. In order to improve the stability of the obtained matrices, they were cross-linked by two different methods. A water-soluble carbodi-imide, alone or in combination with a diamine, was used for this purpose: zero- or non-zero-length cross-links were obtained. The occurrence of cross-linking was verified by monitoring the thermal behaviour and the free-amino-group contents of the scaffolds before and after cross-linking. Smooth-muscle cells (SMCs) were cultured for different periods of time and their ability to grow and proliferate was investigated. SMCs were isolated from human umbilical and saphenous veins, and the purity of the cultures obtained was verified by staining with a specific monoclonal antibody (mAb). Cultured cells were also identified by mAbs against muscle actin and vimentin. After 14 days, a confluent layer of SMCs was obtained on non-cross-linked scaffolds. As for the cross-linked samples, no differences in cell attachment and proliferation were observed between scaffolds cross-linked using the two different methods. Cells cultured on the scaffolds were identified with an anti-(alpha-smooth-muscle actin) mAb. The orientation of SMCs resembled that of the fibres of collagen and elastin. In this way, it may be possible to develop tubular porous scaffolds resembling the morphological characteristics of native blood vessels.

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Biological characterisation of vascular grafts cultured in a bioreactor

et al. 2006

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L. Buttafoco

Electrospinning of collagen and elastin for tissue engineering applications

Preparation and evaluation of molecularly-defined collagen–elastin–glycosaminoglycan scaffolds for tissue engineering

First steps towards tissue engineering of small‐diameter blood vessels: Preparation of flat scaffolds of collagen and elastin by means of freeze drying

Tissue engineering of blood vessels: characterization of smooth‐muscle cells for culturing on collagen‐and‐elastin‐based scaffolds

Biological characterisation of vascular grafts cultured in a bioreactor

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