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dc.contributor.author | Arnal Pastor, María Pilar | es_ES |
dc.contributor.author | González-Mora, Debora | es_ES |
dc.contributor.author | García-Torres, Fernando | es_ES |
dc.contributor.author | Monleón Pradas, Manuel | es_ES |
dc.contributor.author | Vallés Lluch, Ana | es_ES |
dc.date.accessioned | 2017-05-12T07:23:04Z | |
dc.date.available | 2017-05-12T07:23:04Z | |
dc.date.issued | 2016-08-02 | |
dc.identifier.issn | 1022-9760 | |
dc.identifier.uri | http://hdl.handle.net/10251/81033 | |
dc.description.abstract | [EN] Self-assembling peptides (SAP) are widely used as scaffolds themselves, and recently as fillers of microporous scaffolds, where the former provides a cell-friendly nanoenvironment and the latter improves its mechanical properties. The characterization of the interaction between these short peptides and the scaffold material is crucial to assess the potential of such a combined system. In this work, the interaction between poly(ethyl acrylate) (PEA) and 90/10 ethyl acrylate-acrylic acid copolymer P(EAcoAAc) with the SAP RAD16-I has been followed using a bidimensional simplified model. By means of the techniques of choice (congo red staining, atomic force microscopy (AFM), and contact angle measurements) the interaction and self-assembly of the peptide has proven to be very sensitive to the wettability and electro-negativity of the polymeric substrate. | es_ES |
dc.description.sponsorship | The authors acknowledge funding through the European Commission FP7 project RECATABI (NMP3-SL-2009-229239), and from the Spanish Ministerio de Ciencia e Innovacion through projects MAT2011-28791-C03-02 and -03. This work was also supported by the Spanish Ministerio de Educacion through M. Arnal-Pastor FPU 2009-1870 grant. The authors acknowledge the assistance and advice of Electron Microscopy Service of the UPV. | en_EN |
dc.language | Inglés | es_ES |
dc.publisher | Springer Verlag | es_ES |
dc.relation.ispartof | Journal of Polymer Research | es_ES |
dc.rights | Reserva de todos los derechos | es_ES |
dc.subject | Self-assembling peptide | es_ES |
dc.subject | Ethyl acrylate | es_ES |
dc.subject | Acrylic acid | es_ES |
dc.subject | Substrate interaction | es_ES |
dc.subject | Wettability | es_ES |
dc.subject | Electron Microscopy Service of the UPV | |
dc.subject.classification | MAQUINAS Y MOTORES TERMICOS | es_ES |
dc.subject.classification | TERMODINAMICA APLICADA (UPV) | es_ES |
dc.title | Interaction between acrylic substrates and RAD16-I peptide in its self-assembling | es_ES |
dc.type | Artículo | es_ES |
dc.identifier.doi | 10.1007/s10965-016-1069-3 | |
dc.relation.projectID | info:eu-repo/grantAgreement/EC/FP7/229239/EU/RECATABI/ | es_ES |
dc.relation.projectID | info:eu-repo/grantAgreement/MICINN//MAT2011-28791-C03-02/ES/MATERIALES DE SOPORTE Y LIBERACION CONTROLADA PARA LA REGENERACION DE ESTRUCTURAS NEURALES AFECTADAS POR ICTUS/ | es_ES |
dc.relation.projectID | info:eu-repo/grantAgreement/ME//FPU2009-1870/ | es_ES |
dc.relation.projectID | info:eu-repo/grantAgreement/MICINN//MAT2011-28791-C03-03/ES/CONSTRUCTOS PARA LA REGENERACION GUIADA DE ESTRUCTURAS DEL SISTEMA NERVIOSO CENTRAL/ | es_ES |
dc.rights.accessRights | Abierto | es_ES |
dc.contributor.affiliation | Universitat Politècnica de València. Escuela Técnica Superior de Ingenieros Industriales - Escola Tècnica Superior d'Enginyers Industrials | es_ES |
dc.contributor.affiliation | Universitat Politècnica de València. Departamento de Termodinámica Aplicada - Departament de Termodinàmica Aplicada | es_ES |
dc.description.bibliographicCitation | Arnal Pastor, MP.; González-Mora, D.; García-Torres, F.; Monleón Pradas, M.; Vallés Lluch, A. (2016). Interaction between acrylic substrates and RAD16-I peptide in its self-assembling. Journal of Polymer Research. 23(9):173-184. https://doi.org/10.1007/s10965-016-1069-3 | es_ES |
dc.description.accrualMethod | S | es_ES |
dc.relation.publisherversion | http://dx.doi. org/10.1007/s10965-016-1069-3 | es_ES |
dc.description.upvformatpinicio | 173 | es_ES |
dc.description.upvformatpfin | 184 | es_ES |
dc.type.version | info:eu-repo/semantics/publishedVersion | es_ES |
dc.description.volume | 23 | es_ES |
dc.description.issue | 9 | es_ES |
dc.relation.senia | 325382 | es_ES |
dc.identifier.eissn | 1572-8935 | |
dc.contributor.funder | Ministerio de Ciencia e Innovación | |
dc.contributor.funder | Ministerio de Educación | |
dc.contributor.funder | European Commission | |
dc.description.references | Davis ME, Motion JP, Narmoneva DA, Takahashi T, Hakuno D, Kamm RD, Zhang S, Lee RT (2005) Injectable self-assembling peptide nanofibers create intramyocardial microenvironments for endothelial cells. Circulation 111(4):442–450 | es_ES |
dc.description.references | Zhang S, Lockshin C, Cook R, Rich A (1994) Unusually stable beta-sheet formation in an ionic self-complementary oligopeptide. Biopolymers 34:663–672 | es_ES |
dc.description.references | Zhang S, Altman M (1999) Peptide self-assembly in functional polymer science and engineering. Reac Func Polym 41:91–102 | es_ES |
dc.description.references | Zhang S, Gelain F, Zhao X (2005) Designer self-assembling peptide nanofiber scaffolds for 3D tissue cell cultures. Semin Cancer Biol 15(5):413–420 | es_ES |
dc.description.references | Zhang S, Zhao X, Spirio L, PuraMatrix (2005) Self-assembling peptide nanofiber scaffolds. In: Ma PX, Elisseeff J (eds) Scaffolding in tissue Engineering. CRC Press, Boca Raton, FL, pp. 217–238 | es_ES |
dc.description.references | Sieminski AL, Semino CE, Gong H, Kamm RD (2008) Primary sequence of ionic self-assembling peptide gels affects endothelial cell adhesion and capillary morphogenesis. J Biomed Mater Res A 87(2):494–504 | es_ES |
dc.description.references | Quintana L, Fernández Muiños T, Genove E, Del Mar Olmos M, Borrós S, Semino CE (2009) Early tissue patterning recreated by mouse embryonic fibroblasts in a three-dimensional environment. Tissue Eng Part A 15(1):45–54 | es_ES |
dc.description.references | Garreta E, Genové E, Borrós S, Semino CE (2006) Osteogenic differentiation of mouse embryonic stem cells and mouse embryonic fibroblasts in a three-dimensional self-assembling peptide scaffold. Tissue Eng 12(8):2215–2227 | es_ES |
dc.description.references | Semino CE, Merok JR, Crane GG, Panagiotakos G, Zhang S (2003) Functional differentiation of hepatocyte-like spheroid structures from putative liver progenitor cells in three-dimensional peptide scaffolds. Differentiation 71:262–270 | es_ES |
dc.description.references | Thonhoff JR, Lou DI, Jordan PM, Zhao X, Compatibility WP (2008) Of human fetal neural stem cells with hydrogel biomaterials in vitro. Brain Res 1187:42–51 | es_ES |
dc.description.references | Tokunaga M, Liu ML, Nagai T, Iwanaga K, Matsuura K, Takahashi T, Kanda M, Kondo N, Wang P, Naito AT, Komuro I (2010) Implantation of cardiac progenitor cells using self-assembling peptide improves cardiac function after myocardial infarction. J Mol Cell Cardiol 49(6):972–983 | es_ES |
dc.description.references | Takei J (2006) 3-Dimensional cell culture scaffold for everyone: drug screening. Tissue engineering and cancer biology. AATEX 11(3):170–176 | es_ES |
dc.description.references | McGrath AM, Novikova LN, Novikov LN, Wiberg MBD (2010) ™ PuraMatrix™ peptide hydrogel seeded with Schwann cells for peripheral nerve regeneration. Brain Res Bull 83(5):207–213 | es_ES |
dc.description.references | Wang W, Itoh S, Matsuda A, Aizawa T, Demura M, Ichinose S, Shinomiya K, Tanaka J (2008) Enhanced nerve regeneration through a bilayered chitosan tube: The effect ofintroduction of glycine spacer into the CYIGSR sequence. J Biomed Mater Res Part A 85:919–928 | es_ES |
dc.description.references | Sargeant TD, Guler MO, Oppenheimer SM, Mata A, Satcher RL, Dunand DC, Stupp SI (2008) Hybrid bone implants: self-assembly of peptide amphiphile nanofibers within porous titanium. Biomaterials 29(2):161–171 | es_ES |
dc.description.references | Vallés-Lluch A, Arnal-Pastor M, Martínez-Ramos C, Vilariño-Feltrer G, Vikingsson L, Castells-Sala C, Semino CE, Monleón Pradas M (2013) Combining self-assembling peptide gels with three-dimensional elastomer scaffolds. Acta Biomater 9(12):9451–9460 | es_ES |
dc.description.references | Valles-Lluch A, Arnal-Pastor M, Martinez-Ramos C, Vilarino-Feltrer G, Vikingsson L, Monleon Pradas M (2013) Grid polymeric scaffolds with polypeptide gel filling as patches for infarcted tissue regeneration. Conf Proc IEEE Eng Med Biol Soc 2013:6961–6964 | es_ES |
dc.description.references | Soler-Botija C, Bagó JR, Llucià-Valldeperas A, Vallés-Lluch A, Castells-Sala C, Martínez-Ramos C, Fernández-Muiños T, Chachques JC, Monleón Pradas M, Semino CE, Bayes-Genis A (2014) Engineered 3D bioimplants using elastomeric scaffold, self-assembling peptide hydrogel, and adipose tissue-derived progenitor cells for cardiac regeneration. Am J Transl Res 6(3):291–301 | es_ES |
dc.description.references | Martínez-Ramos M, Arnal-Pastor M, Vallés-Lluch A, Monleón Pradas M (2015) Peptide gel in a scaffold as a composite matrix for endothelial cells. J Biomed Mater Res Part A 103 A:3293–3302 | es_ES |
dc.description.references | Rico P, Rodríguez Hernández JC, Moratal D, Altankov G, Monleón Pradas M, Salmerón-Sánchez M (2009) Substrate-induced assembly of fibronectin into networks: influence of surface chemistry and effect on osteoblast adhesion. Tissue Eng Part A 15(11):3271–3281 | es_ES |
dc.description.references | Gugutkov D, Altankov G, Rodríguez Hernández JC, Monleón Pradas M, Salmerón Sánchez M (2010) Fibronectin activity on substrates with controlled -OH density. J Biomed Mater Res A 92(1):322–331 | es_ES |
dc.description.references | Rodríguez Hernández JC, Salmerón Sánchez M, Soria JM, Gómez Ribelles JL, Monleón Pradas M (2007) Substrate chemistry-dependent conformations of single laminin molecules on polymer surfaces are revealed by the phase signal of atomic force microscopy. Biophys J 93(1):202–207 | es_ES |
dc.description.references | Cantini M, Rico P, Moratal D, Salmerón-Sánchez M (2012) Controlled wettability, same chemistry: biological activity of plasma-polymerized coatings. Soft Matter 8:5575–5584 | es_ES |
dc.description.references | Anselme K, Ponche A, Bigerelle M (2010) Relative influence of surface topography and surface chemistry on cell response to bone implant materials. Part 2: biological aspects. Proc Inst Mech Eng H J Eng Med 224:1487–1507 | es_ES |
dc.description.references | Hartgerink JD, Beniash E, Stupp SI (2002) Peptide-amphiphile nanofibers: a versatile scaffold for the preparation of self-assembling materials. Proc Natl Acad Sci U S A 99(8):5133–5138 | es_ES |
dc.description.references | Busscher HJ, Vanpelt AWJ, Deboer P, Dejong HP, Arends J (1984) The effect of surface roughening of polymers on measured contact angles of liquids. Colloids Surf 9:319–331 | es_ES |
dc.description.references | Birdi, KS. (1997) Surface tension of polymers. In: Yildrim Erbil H, ed. Handbook of surface and colloid chemistry CRC Press, Boca Raton, p. 292. | es_ES |
dc.description.references | Collier JH (2003) MessersmithPB.Enzymatic modification of self-assembled peptide structures with tissue transglutaminase. Bioconjug Chem 14(4):748–755 | es_ES |
dc.description.references | Kakiuchi Y, Hirohashi N, Murakami-Murofushi K (2013) The macroscopic structure of RADA16 peptide hydrogel stimulates monocyte/macrophage differentiation in HL60 cells via cholesterol synthesis. BiochemBiophys Res Commun 433(3):298–304 | es_ES |
dc.description.references | Pérez-Garnes M, González-García C, Moratal D, Rico P, Salmerón-Sánchez M (2011) Fibronectin distribution on demixednanoscale topographies. Int J Artif Organs 34(1):54–63 | es_ES |
dc.description.references | Salmerón-Sánchez M, Rico P, Moratal D, Lee TT, Schwarzbauer JE, García AJ (2011) Role of material-driven fibronectin fibrillogenesis in cell differentiation. Biomaterials 32(8):2099–2105 | es_ES |
dc.description.references | Ye Z, Zhang H, Luo H, Wang S, Zhou Q, DU X, et al. (2008) Temperature and pH effects on biophysical and morphological properties of self-assembling peptide RADA16-I. J Pept Sci 14:152–162 | es_ES |
dc.description.references | Keselowsky BG, Collard DM, García AJ (2004) Surface chemistry modulates focal adhesion composition and signaling through changes in integrin binding. Biomaterials 25:5947–5954 | es_ES |
dc.description.references | Scotchford CA, Gilmore CP, Cooper E, Leggett GJ, Downes S (2002) Protein adsorption and human osteoblast-like cell attachment and growth on alkylthiol on gold self-assembled monolayers. J Biomed Mater Res 59:84–99 | es_ES |
dc.description.references | Coelho NM, González-García C, Planell JA, Salmerón-Sánchez M, Altankov G (2010) Different assembly of type IV collagen on hydrophilic and hydrophobic substrata alters endothelial cells interaction. Eur Cell Mater 19:262–272 | es_ES |
dc.description.references | Briz N, Antolinos-Turpin CM, Alió J, Garagorri N, Gómez Ribelles JL, Gómez-Tejedor JA (2013) Fibronectin fixation on poly(ethyl acrylate)-based copolymers. J Biomed Mater Res B Appl Biomater 101(6):991–997 | es_ES |
dc.description.references | Owens DK, Wendt RC (1969) Estimation of the surface free energy of polymers. J Appl Polym Sci 13(8):1741–1747 | es_ES |
dc.description.references | Soria JM, Martínez Ramos C, Bahamonde O, García Cruz DM, Salmerón Sánchez M, García Esparza MA, Casas C, Guzmán M, Navarro X, Gómez Ribelles JL, García Verdugo JM, Monleón Pradas M, Barcia JA (2007) Influence of the substrate's hydrophilicity on the in vitro Schwann cells viability. J Biomed Mater Res A 83(2):463–470 | es_ES |
dc.description.references | Van Krevelen, DW. (1997) Properties of polymers. Chapter 13 mechanical properties of solid polymers. Elsevier, pp. 367–437 | es_ES |