The electrostatic adsorption onto charged surfaces of comb copolymers comprising a polyelectrolyte backbone and pendent PEG side chains, such as poly(l-lysine)-g-poly(ethylene glycol) (PLL-g-PEG), has in previous studies provided protein-repellent thin coatings, particularly on metal oxide surfaces. A drawback of this approach is, however, the instability of such adsorbed layers under extreme pH values or high ionic strength. We have overcome this limitation in the present study by covalently immobilizing PLL-g-PEG copolymers onto aldehyde plasma-modified substrates. Silicon wafers, optical waveguide chips, and perfluorinated ethylene-co-propylene (FEP) polymer substrates were first coated with a thin plasma polymer layer using a propionaldehyde plasma, followed by covalent immobilization of PLL-g-PEG via reductive amination between amine groups of the PLL backbone with aldehyde groups on the plasma-deposited interlayer. The stability in high salt media and the protein resistance of different molecular architectures of immobilized PLL-g-PEG layers were quantitatively investigated by XPS, an optical waveguide technique (OWLS), and ToF-SIMS. The adsorption of bovine serum albumin was found to be below the detection limit (<2 ng/cm(2)), as for electrostatically adsorbed PLL-g-PEG layers. However, after 24 h of exposure of covalently immobilized layers of PLL-g-PEG to high ionic strength buffer (2400 mM NaCl), no significant change in the protein resistance was observed, whereas under the same conditions electrostatically adsorbed PLL-g-PEG coatings lost their protein resistance. Moreover, covalent immobilization via an aldehyde plasma interlayer enabled the application of PLL-g-PEG layers onto substrates such as FEP onto which electrostatic binding is not possible. These findings create a generic platform for the covalent immobilization of PLL-g-PEG onto a wide variety of substrates.
Both curiosity and a desire for efficiency have advanced our ability to manipulate materials with great precision on the micrometer and, more recently, on the nanometer scale. Certainly, the semiconductor and integrated circuit industry has put the pressure on scientist and engineers to develop better and faster nanofabrication techniques. Furthermore, our curiosity as to how life works, and how it can be improved from a medical perspective, stands to gain a great deal from advances in nanotechnology. Novel nanofabrication techniques are opening up the possibilities for mimicking the inherently nano-world of the cell, i.e., the nanotopographies of the extracellular matrix (ECM) and the nanochemistry presented on both the cell membrane and the ECM. In addition, biosensing applications that rely on fabrication of high-density, precision arrays, e.g., DNA or gene chips and protein arrays, will gain significantly in efficiency and, thus, in usefulness once it becomes possible to fabricate heterogeneous nanoarrays. Clearly, continued advances in nanotechnology are desired and required for advances in biotechnology. In this review, we describe the leading techniques for generating nanopatterns with biological function including parallel techniques such as extreme ultraviolet interference lithography (EUV-IL), soft-lithographic techniques (e.g., replica molding (RM) and microcontact printing (muCP)), nanoimprint lithography (NIL), nanosphere lithography (NSL) (e.g., colloid lithography or colloidal block-copolymer micelle lithography) and the nanostencil technique, in addition to direct-writing techniques including e-beam lithography (EBL), focused ion-beam lithography (FIBL) and dip-pen nanolithography (DPN). Details on how the patterns are generated, how biological function is imparted to the nanopatterns, and examples of how these surfaces can and are being used for biological applications will be presented. This review further illustrates the rapid pace by which advances are being made in the field of nanobiotechnology, owing to an increasing number of research endeavors, for an ever increasing number of applications.
Biologically relevant nanopatterns are useful platforms to address fundamental questions, for example, regarding protein-protein and cell-protein interactions. For the creation of nanopatterns, complex and expensive instrumentation is often needed. We present a simple but versatile patterning method using a combination of particle and subsequent molecular self-assembly to produce ordered structures in the micron and sub-micron range. Polystyrene particles were, in a first step, assembled via dip-coating or dried in a drying cell. Silicon wafers and glass slides coated with SiO(2) and a top layer of 11 nm of TiO(2) were used as substrates. Large hexagonally ordered particle monolayers were formed with high reproducibility. These were subsequently shrunk in a controlled manner by exposure to a O(2)/N(2) plasma and subsequently used as etching masks to transfer the particle pattern onto the substrate, creating TiO(2) features in an SiO(2) background. After removing the mask the oxide contrast was translated in three simple dip-and-rinse steps into a biochemical contrast of protein-coated features in an inert background. In short, alkane phosphates were first selectively adsorbed to the TiO(2) features. Then the SiO(2) background was backfilled using poly(L-lysine)-graft-poly(ethylene glycol) and finally streptavidin was adsorbed to the hydrophobic alkane phosphate SAMs, allowing subsequent binding and hybridization of biotinylated DNA.
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