Material surfaces that can mediate cellular interactions by the coupling of specific cell membrane receptors may allow for the design of a biomaterial that can control cell attachment, differentiation, and tissue organization. Cell adhesion proteins have been shown to contain minimum oligopeptide sequences that are recognized by cell surface receptors and can be covalently immobilized on material surfaces. In this study, cell attachment to fluorinated ethylene propylene (FEP) films functionalized with the laminin-derived oligopeptides, YIGSR and a 19-mer IKVAV-containing sequence, was assessed using NG108-15 neuroblastoma and PC12 cells. A radiofrequency glow discharge (RFGD) process that replaces the FEP surface fluorine atoms with reactive hydroxyl functionalities was used to activate the film surfaces. The oligopeptides were then covalently coupled to the surface by their C-terminus using a standard nucleophilic substitution reaction. The covalent attachment of the oligopeptides to the FEP surface was verified using electron spectroscopy for chemical analysis (ESCA). Receptor-mediated NG108-15 cell attachment on the YIGSR-modified films was determined using competitive binding assays. Average cell attachment on the oligopeptide immobilized films in medium containing soluble CDPGYIGSR was reduced by approximately a factor of 2, compared to cell attachment in serum-free medium alone. No significant decrease in cell attachment was noted in medium containing the mock oligopeptide sequence CDPGYIGSK. FEP films immobilized with the 19-mer IKVAV sequence demonstrated a higher percentage of receptor mediated cell attachment on the film surfaces.(ABSTRACT TRUNCATED AT 250 WORDS)
A process for producing patterned metal deposits on fluoropolymeric substrates is described. A metal ion—chelating organosilane is chemisorbed by self-assembly onto a fluoropolymer surface after radio-frequency glow discharge plasma surface hydroxylation. Positional modulation of the surface hydrophobicity is illustrated by wetting. The silane covalently binds an aqueous palladium catalyst and subsequent electroless deposition yields homogeneous or patterned metal deposits that exhibit excellent adhesion to the fluoropolymer.
The patterned covalent surface addition of a monoamine to fluorinated ethylene propylene films (FEP) controls both cellular attachment and differentiation in defined media conditions. A radio frequency glow discharge (RFGD) process was used to replace FEP surface fluorine atoms with hydroxyl groups. The primary amine was then covalently attached by polymerizing aminopropyl-triethoxysilane (APTES) via the hydroxyl functionalities. The selective attachment of cells to the APTES regions was determined to be dependent upon the initial adsorption of albumin to the patterned FEP membrane. Albumin was determined to enhance cellular attachment to the APTES regions and prevent attachment to the unmodified FEP areas for both an NB2a neuroblastoma cell line and primary rat endothelial cells. If albumin were not preadsorbed onto the membrane, selective attachment to the modified regions would not occur. Radiolabeling albumin with 125I demonstrated the preference of albumin for adsorption onto the monoamine surface where the cells preferentially attached. Both hydrophobic and ionic forces contributed to the adsorption process. Although selective cellular attachment to the patterned APTES regions could be achieved by albumin preadsorption to the surface, the neuroblastoma cells did not significantly differentiate unless additional serum components were supplemented to the media.
In this work, poly(tetrafluoroethylene-co-hexafluoropropylene) (also known as fluorinated ethylene propylene; FEP) was functionalized at the surface using a radio frequency glow discharge plasma. This particular surface modification produced controlled densities of hydroxyl functionality on the FEP surface. These surface hydroxyl groups provided sites for the covalent attachment of minimal peptide sequences, that are specific for neuronal attachment. FSCA, ATR-FTIR, ToF-SIMS, and fluorescence spectroscopy were used to evaluate peptide reaction efficiencies and to verify that intact peptide sequences were covalently attached to the FEP surfaces. These modified substrata were then used to study the cell attachment and response to covalently bound minimal peptide sequences. Cell attachment and differentiation results using NG108-15 and PC12 neuronal cell lines are presented in the adjoining paper by Ranieri et al.
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