Microfabrication of nanoporous gold patterns for cell-material interaction studies

P Daggumati, O Kurtulus… - Journal of …, 2013 - pmc.ncbi.nlm.nih.gov
P Daggumati, O Kurtulus, CAR Chapman, D Dimlioglu, E Seker
Journal of Visualized Experiments: Jove, 2013pmc.ncbi.nlm.nih.gov
Nanostructured materials with feature sizes in tens of nanometers have enhanced the
performance of several technologies, including fuel cells, biosensors, biomedical device
coatings, and drug delivery tools. Nanoporous gold (np-Au), produced by a nano-scale self-
assembly process, is a relatively new material that exhibits large effective surface area, high
electrical conductivity, and catalytic activity. These properties have made np-Au an attractive
material to scientific community. Most studies on np-Au employ macro-scale specimens and …
Nanostructured materials with feature sizes in tens of nanometers have enhanced the performance of several technologies, including fuel cells, biosensors, biomedical device coatings, and drug delivery tools. Nanoporous gold (np-Au), produced by a nano-scale self-assembly process, is a relatively new material that exhibits large effective surface area, high electrical conductivity, and catalytic activity. These properties have made np-Au an attractive material to scientific community. Most studies on np-Au employ macro-scale specimens and focus on fundamental science of the material and its catalytic and sensor applications. The macro-scale specimens limit np-Au's potential in miniaturized systems, including biomedical devices. In order to address these issues, we initially describe two different methods to micropattern np-Au thin films on rigid substrates. The first method employs manually-produced stencil masks for creating millimeter-scale np-Au patterns, while the second method uses lift-off photolithography to pattern sub-millimeter-scale patterns. As the np-Au thin films are obtained by sputter-deposition process, they are compatible with conventional microfabrication techniques, thereby amenable to facile integration into microsystems. These systems include electrically-addressable biosensor platforms that benefit from high effective surface area, electrical conductivity, and gold-thiol-based surface bioconjugation. We describe cell culture, immunostaining, and image processing techniques to quantify np-Au's interaction with mammalian cells, which is an important performance parameter for some biosensors. We expect that the techniques illustrated here will assist the integration of np-Au in platforms at various length-scales and in numerous applications, including biosensors, energy storage systems, and catalysts.
pmc.ncbi.nlm.nih.gov
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