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| Grohsjean, Alexander |
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| Falmagne, G. |
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| Erice, C. |
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| Hernandez, A. M. Vargas |
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| Leiton, A. G. Stahl |
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| Lipka, K. |
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| Pantaleo, F. |
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| Torterotot, L. |
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| Savina, M. |
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| Cerri, O. |
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| Jung, A. W. |
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| Chiarito, B. |
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| Sahin, M. O. |
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| Strong, G. |
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| Saradhy, R. |
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| Joshi, B. M. |
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| Kaynak, B. |
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| Barrera, C. Baldenegro |
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| Longo, Egidio |
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| Kolberg, Ted |
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| Ferguson, Thomas |
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| Leverington, Blake |
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| Haase, Fabian |
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| Heath, Helen F. |
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| Kokkas, Panagiotis |
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Piozzi, Antonella
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (23/23 displayed)
- 2023Rice husk ash as a green feedstock for the extraction of nano-silica and its application in the synthesis of an efficient solid biocatalyst
- 2020Enhanced performance of Candida rugosa lipase immobilized onto alkyl chain modified-magnetic nanocompositescitations
- 2017Taurine grafting and collagen adsorption on PLLA films improve human primary chondrocyte adhesion and growthcitations
- 2016Flexible aliphatic poly(isocyanurate-oxazolidone) resins based on poly(ethylene glycol) diglycidyl ether and 4,4′-methylene dicyclohexyl diisocyanatecitations
- 2015Self-Assembly of catecholic moiety-containing cationic random acrylic copolymerscitations
- 2015Antimicrobial and antioxidant amphiphilic random copolymers to address medical device-centered infectionscitations
- 2014Biomimetic Polyurethanescitations
- 2014Partially sulfonated ethylene-vinyl alcohol copolymer as new substrate for 3,4-ethylenedioxythiophene vapor phase polymerizationcitations
- 2013Editorial of the special issue antimicrobial polymerscitations
- 2012A new approach for the preparation of hydrophilic poly(L-lactide) porous scaffold for tissue engineering by using lamellar single crystalscitations
- 2012Lipase Immobilization on Differently Functionalized Vinyl-Based Amphiphilic Polymers: Influence of Phase Segregation on the Enzyme Hydrolytic Activitycitations
- 2012Synthesis of biomimetic segmented polyurethanes as antifouling biomaterialscitations
- 2010Novel intrinsically antimicrobial polymers to control biofilm formation on medical devices
- 2010Synthesis and properties of block poly(ether-ester)s based on poly(ethylene oxide) and various hydrophobic segmentscitations
- 2010Polyurethane anionomers containing metal ions with antimicrobial properties: Thermal, mechanical and biological characterizationcitations
- 2009Antibiofilm properties of functionalized polyurethanes adsorbed with metal ions (Ag+, Cu2+, Zn2+, Al3+ and Fe3+)
- 2007Synthesis, characterization, and in vitro activity of antibiotic releasing polyurethanes to prevent bacterial resistancecitations
- 2007Staphylococcus epidermidis biofilm growth on polyurethanes is inhibited by the synergistic action of Dispersin B and cefamandole nafate.
- 2005Inhibition of Candida growth and biofilm formation on polyurethanes by fluconazole adsorption.citations
- 2004Inhibition of bacterial biofilm formation on polymer surfaces by a natural antimicrobial agent
- 2004Inhibition of biofilm formation in Gram-positive bacteria by a natural antimicrobial agent
- 2001CATALITIC ACTIVITY OF IMMOBILIZED FUMARASEcitations
- 2000Sulfation and preliminary biological evaluation of ethylene-vinyl alcohol copolymerscitations
Places of action
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booksection
Biomimetic Polyurethanes
Abstract
The wide use of polyurethanes in the biomedical field is essentially related to their unique molecular structure from which both their elastomeric features and excellent biocompatibility stem. Properties like flexural endurance, fatigue resistance, compliance and biodegradability can be easily tuned in polyurethanes by properly varying their constituents. For more than 50 years, biostable polyurethanes have played a major role in the manufacturing of medical devices, particularly the intravascular ones. Since the early 1990s, the availability of biodegradable polyurethanes has extended their use also in tissue engineering and in drug delivery. In all these applications, the control of phenomena occurring at the biomaterial/biological tissue interface is of crucial importance to fulfill the required tasks. In the last two decades, by using inspiration from nature, a range of biomimetic materials with remarkable functional properties have been developed. These materials have the potential to elicit a desired cellular response by mimicking a specific biological environment. This chapter is focused on the recent achievements obtained in the development of biomimetic polyurethanes. First, the polyurethane chemistry will be illustrated to highlight how the selection of monomers and polymerization conditions allow synthesis of materials with a specific set of properties to enhance performance for a given application. Then, the role of biomimetic polyurethanes in preventing medical device-related infections or as scaffolding materials in tissue engineering will be presented and discussed.