The solid state oxidation of methionine containing peptide: a preliminary study using time of flight secondary ion mass spectrometry.

PURPOSE: A surface sensitive mass spectrometric technique: Time of Flight Secondary Ion Mass Spectrometry (ToF-SIMS) was introduced to study the solid state instability of a methionine containing peptide caused by the oxidation of the methionine residue. METHODS: The oxidation of a neuropeptide Methinonine-Enkephalin (ME) in air and under UV acceleration was studied by ToF-SIMS. RESULTS: The apparent oxidation rate is defined by the peak ratio of oxidized molecular ion over unoxidized molecular ion. ME is oxidized at a faster rate to its sulfoxide derivative in the UV accelerated oxidation environment than in lab air. The calibration curve for evaluating the ionization probability ratio of the oxidized deprotonated molecular ion divided by the unoxidized deprotonated molecular ion was obtained. This could be used to extract the real oxidation rate of ME in the solid state. CONCLUSIONS: The preliminary results showed that ToF-SIMS with simple sample handling, fast data acquisition, together with excellent surface sensitivity and detection limit could be an applicable and convenient tool to study peptide reactions in the solid state such as oxidation and deamidation process.

Synthesis and characterization of fluoropolymeric substrata with immobilized minimal peptide sequences for cell adhesion studies. I.

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.

Neuronal cell attachment to fluorinated ethylene propylene films with covalently immobilized laminin oligopeptides YIGSR and IKVAV. II.

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)

Spatial control of neuronal cell attachment and differentiation on covalently patterned laminin oligopeptide substrates.

The spatial control of neuronal cell attachment and differentiation via specific receptor mediated interactions, may provide an effective means for the in vitro reconstruction of neuronal cell architecture. In this study, receptor-specific oligopeptide sequences derived from the extracellular matrix (ECM) molecule laminin, a potent neural cell attachment and differentiation promoter were covalently bound on fluorinated ethylene propylene (FEP) films. The degree of receptor-specific cell attachment and the ability to spatially control neurite outgrowth by covalently patterning the oligopeptide sequences on the FEP film surface were assessed. FEP films were first chemically activated with a Radio Frequency Glow Discharge (RFGD) process that covalently replaces the surface fluorine atoms with reactive hydroxyl groups. Oligopeptides containing the YIGSR sequence from the B1 chain of laminin and the water soluble oligopeptide containing the IKVAV sequence (CSRARKQAASIKVAVSADR) from the A chain were covalently bound to the hydroxylated FEP films. Electron Spectroscopy for Chemical Analysis (ESCA) verified the covalent attachment of the oligopeptides to the material surface. The degree of receptor mediated NG108-15 cell attachment on immobilized CDPGYIGSR films was determined using competitive binding media. A 78% reduction in cell attachment was observed on films containing CDPGYIGSR in the cell plating medium. Only a 23% reduction in cell attachment was noted on films plated in medium containing a mock CDPGYIGSK sequence. FEP films immobilized with the IKVAV oligopeptide sequence were shown to mediate PC12 cell attachment and a competitive binding medium also significantly attenuated cell attachment on the immobilized films. The spatial patterning of these oligopeptide sequences to the FEP surface was shown to localize cell attachment and neurite extension on the patterned pathways. The surrounding unmodified FEP surface was inhibitory in serum containing medium and prevented cellular interactions outside the oligopeptide modifications. The spatial immobilization of laminin oligopeptides on FEP films provides a means to organize the attachment and differentiation of neuronal cells in a receptor-specific manner.

Adhesive electroless metallization of fluoropolymeric substrates.

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.

Selective neuronal cell attachment to a covalently patterned monoamine on fluorinated ethylene propylene films.

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.

Patterned neuronal attachment and outgrowth on surface modified, electrically charged fluoropolymer substrates.

Fluorinated ethylenepropylene copolymer (FEP) and polyvinylidene fluoride (PVDF) can generate static and transient electrical charges, respectively, after bulk molecular rearrangements induced by electrical charging techniques. Neurons cultured on electrically active FEP and PVDF show increased levels of nerve fiber outgrowth compared to electrically neutral material. The purpose of the present study was to determine if the addition of charged surface groups to the surfaces of FEP and PVDF would modify the influence of bulk electrical charges on cultured neurons. Mouse neuroblastoma (Nb2a) cells were cultured on electrically charged and uncharged FEP and PVDF substrates with covalently modified surfaces containing hydroxyl (OH) and amine (NH2) groups. Surface chemical modification was performed on the entire surface or in discrete striped regions. Nb2a cells cultured on electrically active FEP and PVDF showed greater levels of differentiation than cells on electrically neutral substrates. The presence of NH2 groups attenuated these responses in serum-containing media. Cells attached to NH2 rich surfaces generally displayed a flatter morphology and tended to remain attached for longer time periods. Cells cultured on stripe-modified substrates in serum-containing media showed a strong preferential attachment to modified regions, especially on NH2 stripes. In summary, bulk electrical charges are more important than surface charges in stimulating Nb2a cell differentiation. Surface groups serve to modulate neuronal morphology and confer specific attachment promoting properties in serum-containing media. The development of an optimal neuronal regeneration template may require the incorporation of specific bulk and surface properties.

Electrically charged polymeric substrates enhance nerve fibre outgrowth in vitro.

The physical, chemical and electrical properties of synthetic guidance devices are known to influence nerve regeneration in vivo. In the present study, neurons were cultured directly on electrically charged polymer growth substrates to determine if local electrical charges enhance nerve fibre outgrowth in vitro. Piezoelectric polymers such as polyvinylidene fluoride (PVDF) generate transient surface charges under minute mechanical strain. Mouse neuroblastoma (Nb2a) cells were cultured directly on electrically poled (i.e. piezoelectric) and unpoled (i.e. nonpiezoelectric) PVDF substrates in serum-free and serum-containing media. Nerve fibre outgrowth was analysed 24, 48, 72 and 96 h after plating. Piezoelectric PVDF substrates generated 2-3 mV at 1200 Hz when placed on standard incubator shelves and unpoled PVDF substrates showed no output. Nb2a cells grown on piezoelectric substrates exhibited significantly greater levels of process outgrowth and neurite lengths at all time periods for both media conditions. Detailed surface characterization of PVDF substrates using electron spectroscopy for chemical analysis (ESCA) and a comprehensive wettability profile revealed that poled and unpoled PVDF was chemically indistinguishable and showed similar surface wettabilities and adhesive properties. Therefore, we conclude that enhanced process outgrowth was induced by the film's piezoelectric output, making poled PVDF a unique biomaterial for which cell/polymer interactions are mediated predominantly through bulk electrical properties rather than surface properties.

Quantitative static secondary ion mass spectrometry of molecular ions from 1-beta-3,4-dihydroxyphenylalanine (L-dopa) and indolic derivatives.

Traditionally, static secondary ion mass spectrometry (SIMS) is believed to yield qualitative information and very little quantitative information. A method to obtain quantitative molecular ion data from organic static SIMS analysis of L-DOPA and related compounds is presented. Linear calibration curves have been constructed by integrating the protonated molecular ion to silver ion peak area ratios over a known ion dosage and plotting versus the original sample concentration.

Angular dependent ESCA and infrared studies of segmented polyurethanes.

The understanding of surface bonding and composition of complex polymer mixtures used for biomedical implant materials can be accomplished by a combination of techniques. In this study, vibrational spectroscopic probes of bulk and surface bonding and composition are combined with measurements with angular dependent X-Ray Photoelectron Spectroscopy (XPS or ESCA). These data provide a detailed description in the surface composition of Biomer and Avcothane, commercially available biomedical grade polymers and model systems polydimethylsiloxane (DMS) and Avcomat, all of which have been cast as smooth films from solution. Impurities are observed segregated in the near surface region sampled by ESCA which are not observed in the surface infrared results. Both Attenuated Total Reflectance (ATR) and Photoacoustic (PA) sampling are utilized, ATR to provide a depth profile and demonstrate the higher surface sensitivity of PA sampling. The combined results describe the depth of segregation of DMS blocks in Avcothane, the presence of DMS within the topmost 20 A in Biomer, and similar impurities in the model polymers. These results point out the need for multitechnique approach and the control of sample preparation and morphology in understanding complex polymer surfaces.