2006
DOI: 10.1002/adma.200600343
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Scanning Probe Nanolithography and Protein Patterning of Low‐Fouling Plasma Polymer Multilayer Films

Abstract: Functional protein patterns with lateral dimensions of less than 300 nm (see figure; scale bar is 20 μm) are obtained from scanning probe nanolithography (SPN) on low‐fouling plasma polymer multilayer thin films. The advantage of this technique over conventional SPN techniques is that the molecule or protein to be coupled to the patterned surface does not have to be present during the lithography process.

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Cited by 52 publications
(52 citation statements)
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References 39 publications
(38 reference statements)
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“…Therefore patterning methods are required that offer functionalization and/or passivation of surfaces on a nanometer scale. Muir and co-workers have shown that protein patterns can be elegantly fabricated by using scanning probe nanolithography [9]. In their study a two-layered system prepared by a plasma deposition process was used.…”
Section: Introductionmentioning
confidence: 99%
“…Therefore patterning methods are required that offer functionalization and/or passivation of surfaces on a nanometer scale. Muir and co-workers have shown that protein patterns can be elegantly fabricated by using scanning probe nanolithography [9]. In their study a two-layered system prepared by a plasma deposition process was used.…”
Section: Introductionmentioning
confidence: 99%
“…One of the most common classes of thin film treatments employed in biomaterial devices is that of 'low-fouling' or 'stealth' coatings [6]. These coatings need to be able to resist or inhibit protein adsorption within the body.…”
Section: Introductionmentioning
confidence: 99%
“…Unlike other SPL methods, DPN bypasses the need to initially alter the intended surface either physically or chemically before deposition of the biomolecules and instead directly deposits the biomolecule “ink” onto the surface (Salaita, Wang, & Mirkin, 2007). Alternative SPL methods have also been described where regions of a non-fouling surface are “dynamically plowed” off through the use of an AFM tip, thus exposing the scratched off zones to protein adsorption (Muir, Fairbrother, Gengenbach, Rovere, Abdo, McLean et al , 2006). Although these protein-compatible technologies allow for resolutions down to tens of nanometers, the techniques suffer from very low throughput and thus present a multitude of challenges when considering the scalability of the process.…”
Section: Introductionmentioning
confidence: 99%