SiN membranes with submicrometer hole arrays patterned by wafer-scale nanosphere lithography

Klein, Mona Julia Katharina; Montagne, Franck; Blondiaux, Nicolas; Vazquez-Mena, Oscar; Heinzelmann, H.; Pugin, Raphaël; Brugger, Juergen; Savu, Veronica

doi:10.1116/1.3554404

Cited by 22 publications

(18 citation statements)

References 22 publications

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“…This selfassembly based lithographic technique is chosen because it allows for a relatively cheap, fast and reproducible nanopatterning. 42,43 Next, a periodic pattern of nanodomes is etched into the Si 3 N 4 substrate. 1(a) schematically shows the most important fabrication steps, which are described in detail in the ESI.…”

Section: Fabrication Of the Sers Microchipsmentioning

confidence: 99%

Gold nanodome-patterned microchips for intracellular surface-enhanced Raman spectroscopy

Wuytens

Subramanian

Vos

et al. 2015

Analyst

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While top-down substrates for surface-enhanced Raman spectroscopy (SERS) offer outstanding control and reproducibility of the gold nanopatterns and their related localized surface plasmon resonance, intracellular SERS experiments heavily rely on gold nanoparticles. These nanoparticles often result in varying and uncontrollable enhancement factors. Here we demonstrate the use of top-down gold-nanostructured microchips for intracellular sensing. We develop a tunable and reproducible fabrication scheme for these microchips. Furthermore we observe the intracellular uptake of these structures, and find no immediate influence on cell viability. Finally, we perform a proof-of-concept intracellular SERS experiment by the label-free detection of extraneous molecules. By bringing top-down SERS substrates to the intracellular world, we set an important step towards time-dependent and quantitative intracellular SERS.

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Section: Fabrication Of the Sers Microchipsmentioning

confidence: 99%

Gold nanodome-patterned microchips for intracellular surface-enhanced Raman spectroscopy

Wuytens

Subramanian

Vos

et al. 2015

Analyst

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“…Various different approaches have been developed in the past decade to impart such nanoscale patterns to different materials. For instance, self-assembly of nanoparticles as templates 10 , 11 and self-organizing polymers 12 – 14 have been used to generate nanoscale patterns acting as processing masks to eventually generate perforations in thin sheets of material. While the geometries are excellently suited for separation of proteins and other biomolecules, these inorganic materials have the drawback of poor compatibility with biological fluids and the contained proteins.…”

Section: Introductionmentioning

confidence: 99%

Freely suspended perforated polymer nanomembranes for protein separations

Schuster

Rodler

Tscheließnig

et al. 2018

Sci Rep

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Selective removal of nanometer-sized compounds such as proteins from fluids is an often challenging task in many scientific and industrial areas. Addressing such tasks with highly efficient and selective membranes is desirable since commonly used chromatographic approaches are expensive and difficult to scale up. Nanomembranes, molecularly thin separation layers, have been predicted and shown to possess outstanding properties but in spite ultra-fast diffusion times and high-resolution separation, to date they generally lack either of two crucial characteristics: compatibility with biological fluids and low-cost production. Here we report the fast and easy fabrication of highly crosslinked polymer membranes based on a thermoset resin (poly[(o-cresyl glycidyl ether)-co-formaldehyde (PCGF) cured with branched polyethyleneimine (PEI)) with nanoscale perforations of 25 nm diameter. During spin casting, microphase separation of a polylactide-co-glycolide induces the formation of nanometer sized domains that serve as templates for perforations which penetrate the 80 nm thick membranes. Ultrathin perforated nanomembranes can be freely suspended on the cm scale, exhibit high mechanical strength, low surface energies and a sharp permeability cutoff at a hydrodynamic diameter of 10 nm suitable for protein separations.

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“…UV, X-ray, interference and e-beam lithography, when combined with other microfabrication processes such as thin film deposition and etching, have paved the way for the fabrication of nanostructured surfaces and devices [ 18 , 19 ]. Emerging bottom-up approaches such as block copolymer and nanosphere lithography have also appeared with the common goal of fabricating smaller structures [ 20 , 21 ]. These techniques are state of the art with regard to resolution, but they are limited to planar substrates and have mainly been applied to silicon-based materials.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Functional Plastic Parts Using Nanostructured Steel Mold Inserts

et al. 2017

Self Cite

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We report on the fabrication of sub-micro and nanostructured steel mold inserts for the replication of nanostructured immunoassay biochips. Planar and microstructured stainless steel inserts were textured at the sub-micron and nanoscale by combining nanosphere lithography and electrochemical etching. This allowed the fabrication of structures with lateral dimensions of hundreds of nanometers and aspect ratios of up to 1:2. Nanostructured plastic parts were produced by means of hot embossing and injection molding. Surface nanostructuring was used to control wettability and increase the sensitivity of an immunoassay.

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SiN membranes with submicrometer hole arrays patterned by wafer-scale nanosphere lithography

Cited by 22 publications

References 22 publications

Gold nanodome-patterned microchips for intracellular surface-enhanced Raman spectroscopy

Gold nanodome-patterned microchips for intracellular surface-enhanced Raman spectroscopy

Freely suspended perforated polymer nanomembranes for protein separations

Fabrication of Functional Plastic Parts Using Nanostructured Steel Mold Inserts

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