This paper explores diatom attachment to a range of laser etched polyimide surfaces to directly test 'attachment point theory'. Static bioassays were conducted on microtextured polyimide surfaces using four diatom species, Fallacia carpentariae, Nitzschia cf. paleacea, Amphora sp. and Navicula jeffreyi with cell sizes ranging from 1-14 microm. The microtextured polyimides were modelled from natural fouling resistant bivalve surfaces and had wavelengths above, below and at the same scale as the diatom cell sizes. Diatoms attached in significantly higher numbers to treatments where the numbers of attachment points was highest. The lowest diatom attachment occurred where cells were slightly larger than the microtexture wavelength, resulting in only two theoretical points of attachment. The results support attachment point theory and highlight the need to address larval/cell size in relation to the number of attachment points on a surface. Further studies examining a range of microtexture scales are needed to apply attachment point theory to a suite of fouling organisms and to develop structured surfaces to control the attachment and development of fouling communities.
To improve mixing, obstacles have been placed in the channel to try to disrupt flow and reduce the diffusion path. The disruption to flow velocity field alters the flow direction from one fluid to another. In this way, convection may occur to enhance the mixing. Ideally, properly designed geometric parameters, such as layout and number of obstacles, improve the mixing performance without increasing the pressure drop. In this work, the commercial computational fluid dynamics (CFD) tool for microfluidics is used to study the mixing of two liquids in a "Y" channel. The results indicate that asymmetric layout of the obstacle has more effect on the mixing than the number of obstacles. Placing obstacles in the microchannels is a novel method for mixing in microfluidic devices, and the results can provide useful information in the design of these devices.
Phase singularities are a ubiquitous feature of waves of all forms and represent a fundamental aspect of wave topology. An optical vortex phase singularity occurs when there is a spiral phase ramp about a point phase singularity. We report an experimental observation of an optical vortex in a field consisting of 9-keV x-ray photons. The vortex is created with an x-ray optical structure that imparts a spiral phase distribution to the incident wave field and is observed by use of diffraction about a wire to create a division-of-wave-front interferometer.
We demonstrate here a new method to control the location of cells on surfaces in
two dimensions, which can be applied to a number of biomedical applications
including diagnostic tests and tissue engineered medical devices. Two-dimensional
control over cell attachment is achieved by generation of a spatially controlled
surface chemistry that allows control over protein adsorption, a process
which mediates cell attachment. Here, we describe the deposition of thin
allylamine plasma polymer coatings on silicon wafer and perfluorinated
poly(ethylene-co-propylene) substrates, followed by grafting of a protein resistant
layer of poly(ethylene oxide). Spatially controlled patterning of the surface
chemistry was achieved in a fast, one-step procedure by nanometer thickness
controlled laser ablation using a 248 nm excimer laser. X-ray photoelectron
spectroscopy and atomic force microscopy were used to confirm the production
of surface chemistry patterns with a resolution of approximately 1 µm,
which is significantly below the dimensions of a single mammalian cell.
Subsequent adsorption of the extracellular matrix proteins collagen I and
fibronectin followed by cell culture experiments using bovine corneal epithelial
cells confirmed that cell attachment is controlled by the surface chemistry pattern.
The method is an effective tool for use in a number of in vitro and in vivo
applications.
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