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ABSTRACT: A buffer-mediated gelation route for collagen hydrogels that allows the formation of homogeneous
composite and hybrid materials with various silica sources (i.e., colloidal silica and soluble silicates) at
high concentration (up to 25�10�3
M) is described. Most significant improvement in rheological
properties and proliferation of primary adult human dermal fibroblasts was obtained for the silicate-
based hybrid materials. A similar trend was observed in composite materials incorporating 14nm
SiO2 nanoparticles, although to a much lesser extent, whereas larger colloids (80 and 390 nm) did not
significantly impact mechanical stability and cell behavior. Modification of 80nm particles surface
with amine groups weakens the collagen-mineral interface, resulting in the decrease of material
stability and leading to particle aggregation during the course of cell proliferation experiments.
Advanced Engineering Materials 01/2012; 14(3-3):B51-B55. · 1.18 Impact Factor
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Martín F Desimone,
Christophe Hélary,
Sandrine Quignard,
Ivo B Rietveld, Isabelle Bataille,
Guillermo J Copello,
Gervaise Mosser,
Marie-Madeleine Giraud-Guille,
Jacques Livage,
Anne Meddahi-Pellé,
Thibaud Coradin
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ABSTRACT: Hybrid and nanocomposite silica-collagen materials derived from concentrated collagen hydrogels were evaluated in vitro and in vivo to establish their potentialities for biological dressings. Silicification significantly improved the mechanical and thermal stability of the collagen network within the hybrid systems. Nanocomposites were found to favor the metabolic activity of immobilized human dermal fibroblasts while decreasing the hydrogel contraction. Cell adhesion experiments suggested that in vitro cell behavior was dictated by mechanical properties and surface structure of the scaffold. First-to-date in vivo implantation of bulk hydrogels in subcutaneous sites of rats was performed over the vascular inflammatory period. These materials were colonized and vascularized without inducing strong inflammatory response. These data raise reasonable hope for the future application of silica-collagen biomaterials as biological dressings.
ACS Applied Materials & Interfaces 09/2011; 3(10):3831-8. · 4.53 Impact Factor
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ABSTRACT: The implantation of a biomaterial for tissue engineering requires the presence of a suitable scaffold on which the tissue repair and regeneration will take place. Polymers have been frequently used for that purpose because they show similar properties to that of the natural extracellular matrix. Scaffold properties and biocompatibility are modulated by the composition of the polymers used. In this work four polysaccharide-based hydrogels (PSH) made of dextran and pullulan were synthesized. Their in vitro properties were determined and then tested in vivo in a rat model. As pullulan concentration increased in dextran hydrogels, the glass transition temperature and the maximum modulus decreased. In vitro degradation studies for 30 days demonstrated no significant degradation of PSH except for 100% pullulan hydrogel. In vivo tissue response evaluated 30 days after PSH subcutaneous implantation in rats indicated that all PSH were surrounded by a fibrous capsule. Adding pullulan to dextran induced an increased inflammatory reaction compared to PSH-D(100% dextran) or PSH-D(75)P(25)(75% dextran). This in vitro and in vivo data can be used in the design of hydrogels appropriate for tissue engineering applications.
Journal of Biomedical Materials Research Part A 03/2011; 96(3):535-42. · 2.63 Impact Factor
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ABSTRACT: Silica-collagen bionanocomposite hydrogels were obtained by addition of silica nanoparticles to a protein suspension followed by neutralization. Electron microscopy studies indicated that larger silica nanoparticles (80 nm) do not interact strongly with collagen, whereas smaller ones (12 nm) form rosaries along the protein fibers. However, the composite network structurally evolved with time due to the contraction of the cells and the dissolution of the silica nanoparticles. When compared to classical collagen hydrogels, these bionanocomposite materials showed lower surface contraction in the short term (1 week) and higher viability of entrapped cells in the long term (3 weeks). A low level of gelatinase MMP2 enzyme expression was also found after this period. Several proteins involved in the catabolic and anabolic activity of the cells could also be observed by immunodetection techniques. All these data suggest that the bionanocomposite matrices constitute a suitable environment for fibroblast adhesion, proliferation and biological activity and therefore constitute an original three-dimensional environment for in vitro cell culture and in vivo applications, in particular as biological dressings.
Acta biomaterialia 10/2010; 6(10):3998-4004. · 3.98 Impact Factor
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ABSTRACT: Collagen hydrogels first appeared promising for skin repair. Unfortunately, their extensive contraction and their poor mechanical properties constituted major disadvantages toward their utilization as permanent graft. The present study has investigated a way to correct these drawbacks by increasing the collagen concentration in controlled conditions. Concentrated collagen hydrogels (CCH) at 1.5, 3 and 5mg/ml were obtained. The effect of raised collagen concentration on contraction, cell growth and remodeling activities was evaluated for 21 days in culture. Subsequently, in vivo integration of CCH and normal collagen hydrogels (NCH) was assessed. Compared to NCH, CCH contraction was delayed and smaller. At day 21, surface area of CCH at 3mg/ml was 18 times more important than that of NCH. Whatever the initial fibroblast density, CCH favored cell growth that reached about 10 times the initial cell number at day 21; cell proliferation was inhibited in NCH. Gelatinase A activities appeared lower in CCH than within NCH. In vivo studies in rats revealed a complete hydrolysis of NCH 15 days after implantation. In contrast, CCH at 3mg/ml was still present after 30 days. Moreover, CCH showed cell colonization, neovascularization and no severe inflammatory response. Our results demonstrate that concentrated collagen hydrogels can be considered as new candidates for dermal substitution because they are is easy to handle, do not contract drastically, favor cell growth, and can be quickly integrated in vivo.
Biomaterials 10/2009; 31(3):481-90. · 7.40 Impact Factor
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ABSTRACT: Percutaneous coronary interventions play a major role in the management of patients affected by coronary artery diseases. However, their efficiency is impaired by restenosis, defined as a reduction of the vessel lumen, occurring a few months after the procedure. A low-molecular-weight fraction of fucoidan, a vegetal heparin-like sulphated polysaccharide, was recently shown to greatly reduce in-stent restenosis after angioplasty in rabbits. To better understand the in vivo anti-restenotic effects of this polymer, we used fractions of fucoidan and compared to heparin and dextran of different sizes. We carried out in vitro growth inhibition experiments on vascular smooth muscle cells, performed an in vivo pharmacokinetic study, and locally delivered fluorescently-labeled polysaccharides in rabbit iliac arteries after angioplasty with a non-occlusive catheter. The results indicated that (i) preparation of well-characterized fractions from natural fucoidan is compulsory for in vitro and in vivo studies, (ii) antiproliferative activity of sulphated polysaccharides on cultured smooth muscle cells is not a major predictive factor for the reduction of restenosis in vivo and (iii) pharmacokinetic parameters and binding of low-molecular-weight fucoidan on angioplasty-induced injured vascular walls are important local and general factors controlling its mechanisms of action.
Journal of Biomaterials Science Polymer Edition 02/2009; 20(5-6):689-702. · 1.69 Impact Factor
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ABSTRACT: Prosthetic materials are largely used in surgery and tissue engineering. However, many postoperative complications are due to poor integration of the materials, which delays the healing process. The objective of our study was to develop a synthetic scaffold that, according to histopathological and biomechanical criteria, would achieve both tolerance and efficiency. In this study, we evaluated the effect of intramuscular and subcutaneous implantation of a new hybrid mesh (HM) in rats. This HM was composed of clinical grade polypropylene mesh embedded in a polysaccharide hydrogel. Histological and biomechanical studies on the polysaccharide gel alone and on HM were performed 15 and 30 days after implantation, and then compared with two clinically used materials, porcine decellularized small intestinal submucosa and a polypropylene mesh. Results showed that the incorporation of a polypropylene mesh within the polysaccharide hydrogel led to the absence of adverse effects and better tissue organization. Thus, this new synthetic biocompatible HM with suitable properties for tissue repair appears to be a promising material for clinical applications.
Tissue Engineering Part A 05/2008; 14(4):519-27. · 4.64 Impact Factor
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ABSTRACT: In the present study, we measured the ability of various cationized pullulan tubular hydrogels to retain plasmid DNA, and tested the ability of retained plasmid DNA to transfect vascular smooth muscle cells (VSMCs). Cationized pullulans were obtained by grafting at different charge densities ethylamine (EA) or diethylaminoethylamine (DEAE) on the pullulan backbone. Polymers were characterized by elemental analysis, acid-base titration, size exclusion chromatography, Fourier-transform infrared spectroscopy, and proton nuclear magnetic resonance. The complexation of cationized pullulans in solution with plasmid DNA was evidenced by fluorescence quenching with PicoGreen. Cationized pullulans were then chemically crosslinked with phosphorus oxychloride to obtain tubular cationized pullulan hydrogels. Native pullulan tubes did not retain loaded plasmid DNA. In contrast, the ability of cationized pullulan tubes to retain plasmid DNA was dependent on both the amine content and the type of amine. The functional integrity of plasmid DNA in cationized pullulan tubes was demonstrated by in vitro transfection of VSMCs. Hence, cationized pullulan hydrogels can be designed as tubular structures with high affinity for plasmid DNA, which may provide new biomaterials to enhance the efficiency of local arterial gene transfer strategies.
Journal of Biomedical Materials Research Part A 01/2008; 83(3):819-27. · 2.63 Impact Factor
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ABSTRACT: Biomaterials are already widely used in medical sciences. The field of biomaterials began to shift to produce materials able to stimulate specific cellular responses at the molecular level. The combined efforts of cell biologists, engineers, materials scientists, mathematicians, geneticists, and clinicians are now used in tissue engineering to restore, maintain, or improve tissue functions or organs. This rapidly expanding approach combines the fields of material sciences and cell biology for the molecular design of polymeric scaffolds with appropriate 3D configuration and biological responses. Future developments for new blood vessels will require improvements in technology of materials and biotechnology together with the increased knowledge of the interactions between materials, blood, and living tissues. Biomaterials represent a crucial mainstay for all these studies.
Medecine sciences: M/S 20(6-7):679-84. · 0.64 Impact Factor
