Interpenetrating polymer networks (IPNs) were designed to resist materials fouling caused by non-specific protein adsorption, and indiscriminate cell or bacterial adhesion. These IPNs were thin adherent films ( ~ 20 nm) comprised of acrylamide (AAm), ethylene glycol (EG), and acrylic acid (AA) grafted to either silicon waters or quartz substrates via photoinitiated free radical polymerization. These networks were further modified to promote specific cell adhesion by tethering bioactive groups such as peptides that mimic cell-binding domains found on extracellular matrix molecules. As a specific example of biomolecular surface engineering, peptides from the cell-binding domain of bone sialoprotein were tethered to a p(AAm-co-EG/AA) IPN to control cell behavior at the surface. The networks were characterized by contact angle measurements, spectroscopic ellipsometry, and X-ray photoelectron spectroscopy to convey information on IPN wettability, thickness, and chemistry. The surface characterization data supported the theory that the PEG/AA layer formed an IPN with the underlying p(AAm) network, and after graft modification of this IPN with diamino PEG (PEG(NH2)2), the PEG(NH2)2 chains were enriched at the surface. Rat calvarial osteoblasts attached to Arg-Gly-Asp (RGD) modified IPNs at levels significantly greater than on clean quartz, Arg-Gly-Glu (RGE) modified, or the PEG(NH2)2 modified IPN, with or without serum in the media. Cells maintained in media containing 15% fetal bovine serum (FBS) proliferated, exhibited nodule formation, and generated sheets of mineralized extracellular matrix (ECM) with the addition on β-glycerophosphate to the media. Cell adhesion and mineralized ECM formation were specifically dependent on the peptide sequence present at the surface. 相似文献
Densely pegylated particles that can serve as a model system for artificial cells were prepared by covalently grafting amino polyethylene glycol (PEG, molecular weight 3400 or 5000) onto carboxyl polystyrene particles (PS-COOH) using carbodiimide chemistry. PEG-modified particles (PS-PEG) were characterized by determination of the PEG surface concentration, zeta-potential, size, and morphology. Under optimized grafting conditions, a dense "brush-like" PEG layer was formed. A PEG surface concentration of approximately 60 pmol/cm2, corresponding with an average distance between grafted PEG chains of approximately 17 A can be realized. It was shown that grafting of PEG onto PS-COOH reduced the adsorption of proteins from human plasma (85 vol %) in phosphate-buffered saline up to 90%. 相似文献
The layer‐by‐layer (LbL) assembly technique was applied for the surface modification of biodegradable poly(lactide‐co‐glycolide) nanoparticles (NPs), employing poly(acrylic acid) (PAA), and polyethylenimine (PEI) as building blocks. Amino terminated poly(ethylene glycol) (PEG) and folate decorated PEG (PEG‐FA) were grafted onto the multilayers via condensation between carboxylic groups and amine groups from PEG or PEG‐FA. The LbL assembly and the covalent functionalization were monitored by means of ζ‐potential measurements and the quartz crystal microbalance with dissipation technique (QCM‐D). Protein adsorption after incubation of the NPs in culture medium containing optionally the serum proteins was investigated and related to cellular uptake. Experiments on cellular uptake showed that after PEGylation the uptake ratio of the NPs decreased significantly, but became three times larger when PEG‐FA was grafted on the NPs instead of the PEG.
Abstract In previous work using gold as a model substrate, we showed that modification of surfaces with poly(ethylene glycol) (PEG) and corn trypsin inhibitor (CTI) rendered them protein resistant and inhibitory against activated factor XII. Sequential attachment of PEG followed by CTI gave superior performance compared to direct attachment of a preformed PEG-CTI conjugate. In the present work, a sequential method was used to attach PEG and CTI to a polyurethane (PU) substrate to develop a material with applicability for blood-contacting medical devices. Controls included surfaces modified only with PEG and only with CTI. Surfaces were characterized by water contact angle and X-ray photoelectron spectroscopy. The surface density of CTI was in the range of a monolayer and was higher on the PU substrate than on gold reported previously. Biointeractions were investigated by measuring fibrinogen adsorption from buffer and plasma, factor XIIa inhibition and plasma clotting time. Both the PU–PEG surfaces and the PU–PEG–CTI surfaces showed low fibrinogen adsorption from buffer and plasma, indicating that PEG retained its protein resistance when conjugated to CTI. Although the CTI density was lower on PU–PEG–CTI than on PU modified only with CTI, PU–PEG–CTI exhibited greater factor XIIa inhibition and a longer plasma clotting time, suggesting that PEG facilitates the interaction of CTI with factor XIIa. Thus sequential attachment of PEG and CTI may be a useful approach to improve the thromboresistance of PU surfaces. 相似文献
The objective of this study was to investigate the bioactivity and protein-resistant properties of dual functioning surfaces modified with PEG for protein resistance and corn trypsin inhibitor (CTI) for anticoagulant effect. Surfaces on gold substrate were prepared with varying ratios of free PEG to CTI-conjugated PEG. Two methods designated, respectively, "sequential" and "direct" were used. For sequential surfaces, PEG was first immobilized on gold and the surfaces were incubated with CTI at varying concentration. For direct surfaces, a PEG-CTI conjugate was synthesized and gold surfaces were modified using solutions of the conjugate of varying concentration. The CTI density on these surfaces was measured using radiolabeled CTI. Water contact angles were measured and the thickness of PEG-CTI layers was determined by ellipsometry. Fibrinogen adsorption from buffer and human plasma, and adsorption from binary solutions of fibrinogen and α-lactalbumin were investigated using radiolabeling methods. Bioactivity of the surfaces was evaluated via their effects on FXIIa inhibition and plasma clotting time. It was found that as the ratio of CTI-conjugated PEG to free PEG increased, bioactivity increased but protein resistance was relatively constant. It is concluded that on these surfaces conjugation of PEG to CTI does not greatly compromise the protein resistance of the PEG but results in improved interactions between the CTI and the "target" protein FXIIa. At the same CTI density, sequential surfaces were more effective in terms of inhibiting FXIIa and prolonging clotting time. 相似文献
In order to develop a versatile model for blood-compatible materials, we studied morphology and platelet adhesion of a dipalmitoyl-phosphatidylcholine (DPPC)/dipalmitoyl-phosphatidylethanolamine-polyethylene glycol (PEG lipid) mixed monolayer. This monolayer, which mimics the cell membrane structure, consists of two heterogeneous layers, that is, a PEG layer lying on top of a phospholipid monolayer. The DPPC/PEG lipid mixed monolayer was prepared using the Langmuir-Blodgett (LB) Technique. The monolayer was transferred onto a silanized glass substrate by the down-stroke mode, at a surface pressure of 25 mN/m. The transfer efficiency achieved unity at all times. The morphologies of PEG chains on the phospholipid monolayer in water, in a dried state, and in a hydrated state were evaluated using Pi-A isotherm, ellipsometry, and atomic force microscopy (AFM), respectively. When the concentration of PEG lipid was below 1 mol %, the PEG chains could cover the DPPC surface completely in water, but not in the dried state. On the other hand, the PEG chains could cover the phospholipid surface completely in a dried state, as well as in water, when the PEG lipid concentration was above 3 mol %. These PEG chains, showing a brush-type conformation in water, were highly packed and had a bulky structure at the surface in the dried state as well as in the hydrated state. A bulky and extended PEG layer, above 3 mol % concentration, was greatly effective in the prevention of platelet adhesion. 相似文献
Fabrication of functional tissue constructs from designed three-dimensional structures of cells using the layered method of cultured cell sheets could prove to be an attractive approach to tissue engineering. Rapid recovery of cell sheets is considered to be important as a basic technology for practical assembly of tissue-mimicking structures. To accelerate required culture substrate hydrophilic/hydrophobic functional changes according to the hydrated/dehydrated structural changes in response to culture temperature alteration, poly(N-isopropylacrylamide) (PIPAAm) was grafted with poly(ethylene glycol) (PEG) onto porous culture membranes by electron beam irradiation. Analyses by attenuated total reflection-Fourier transform infrared and electron spectroscopy for chemical analysis revealed that PIPAAm and PEG were successfully grafted to surfaces of porous membranes. PIPAAm-grafted porous membranes (PIPAAm-PM) were compared with porous membranes co-grafted with various amounts of PEG and PIPAAm (PIPAAm(PEG)-PM) for cell sheet detachment experiments. Approximately 35min incubation at 20 degrees C was required to completely detach cell sheets from PIPAAm-PM in a static condition, while only 19min to detach cell sheets from PIPAAm(PEG0.5%)-PM, which is co-grafted with PIPAAm and 0.5wt% of PEG. With porous membranes, water molecules were accessed by the PIPAAm molecules grafted on the surfaces from both underneath and peripheral to the attached cell sheet, resulting in more rapid hydration of grafted PIPAAm molecules and detachment of cell sheet than that for nonporous tissue culture polystyrene (TCPS) dish. With PIPAAm(PEG)-PMs, grafted PEG chains should accelerate the diffusion of water molecules to PIPAAm grafts, showing more rapid detachment of cell sheet compare to PIPAAm-PMs. 相似文献
Transcellular transport is essential for transmucosal and plasma-to-tissue drug delivery by nanoparticles, whereas its fundamental pathways have not been fully clarified. In this study, an in-depth investigation was conducted into the intracellular itinerary and the transcytosis pathway of wheat germ agglutinin-functionalized nanoparticles (WGA-NP) with various polymer architectures in the Caco-2 cell model. GFP-Rabs, Rab4, Rab5, Rab7, Rab11, GTPases served as key regulators of vesicular transport, and their mutants were transfected to Caco-2 cells respectively to determine the cellular itinerary of WGA-NP and the role of Rabs therein. Transcytosis inhibition experiments indicated that transcellular transport of WGA-NP (PEG(3000)-PLA(40000) formulation) happened in a cytoskeleton-dependent manner and majorly by means of clathrin-mediated mechanism. Intracellular transport, especially the endolysosome pathway was found largely contribute to the transcytosis of WGA-NP. WGA-NP with shorter surface PEG length (2000) resulted in higher cellular association and more colocalization with the clathrin-mediated transport pathway, while that with longer surface PEG length (5000) avoided the clathrin-mediated transport pathway but achieved higher transcytosis after 4?h incubation. WGA-NP with PLGA as the core materials obtained elevated lysosome escape and enhanced transcytosis after 2?h incubation. These findings provided important evidence for the role of polymer architectures in modulating cellular transport of functionalized nanocarriers, and would be helpful in improving carrier design to enhance drug delivery. 相似文献
While silicone elastomers generally have excellent biomaterials properties, their hydrophobicity can elicit undesired local biological responses through adsorption and denaturation of proteins. Surface-bound poly(ethylene glycol) (PEG) can ameliorate the situation by preventing contact between the external biology and the silicone elastomer. It is further possible to manipulate the biocompatibility of the surface by linking peptides, proteins or other biological entities to the PEG. Previous synthetic approaches to PEG-protected surfaces are compromised by issues of reproducibility. We describe two rapid and efficient approaches to silicone surface modification by PEG-linked adhesion peptides that overcome this problem: SiH groups are introduced throughout a silicone elastomer during elastomer synthesis or only at the surface after cure; then, in either case, protein-repellent PEG brushes at the surface are introduced by hydrosilylation to give surfaces that can be stored for extensive periods of time without degradation. Activation of the free alcohol with an NSC group followed by immediate conjugation to relevant biological molecules occurs in high yields, as shown for RGDS and GYRGDS. High surface grafting density of the peptides was demonstrated using radiolabeling techniques. Biological activity was demonstrated by a 5-fold increase in cell adhesion on the peptide-modified surfaces when compared to unmodified PDMS control surfaces. 相似文献