Characterization of Surface Modifications by White Light Interferometry: Applications in Ion Sputtering,Laser Ablation,and Tribology Experiments

In materials science and engineering it is often necessary to obtain quantitative measurements of surface topography with micrometer lateral resolution. From the measured surface, 3D topographic maps can be subsequently analyzed using a variety of software packages to extract the information that is needed.In this article we describe how white light interferometry, and optical profilometry (OP) in general, combined with generic surface analysis software, can be used for materials science and engineering tasks. In this article, a number of applications of white light interferometry for investigation of surface modifications in mass spectrometry, and wear phenomena in tribology and lubrication are demonstrated. We characterize the products of the interaction of semiconductors and metals with energetic ions (sputtering), and laser irradiation (ablation), as well as ex situ measurements of wear of tribological test specimens.Specifically, we will discuss:

1. Aspects of traditional ion sputtering-based mass spectrometry such as sputtering rates/yields measurements on Si and Cu and subsequent time-to-depth conversion.
2. Results of quantitative characterization of the interaction of femtosecond laser irradiation with a semiconductor surface. These results are important for applications such as ablation mass spectrometry, where the quantities of evaporated material can be studied and controlled via pulse duration and energy per pulse. Thus, by determining the crater geometry one can define depth and lateral resolution versus experimental setup conditions.
3. Measurements of surface roughness parameters in two dimensions, and quantitative measurements of the surface wear that occur as a result of friction and wear tests.

Some inherent drawbacks, possible artifacts, and uncertainty assessments of the white light interferometry approach will be discussed and explained.     

Insertion of Flexible Neural Probes Using Rigid Stiffeners Attached with Biodissolvable Adhesive

Microelectrode arrays for neural interface devices that are made of biocompatible thin-film polymer are expected to have extended functional lifetime because the flexible material may minimize adverse tissue response caused by micromotion. However, their flexibility prevents them from being accurately inserted into neural tissue. This article demonstrates a method to temporarily attach a flexible microelectrode probe to a rigid stiffener using biodissolvable polyethylene glycol (PEG) to facilitate precise, surgical insertion of the probe. A unique stiffener design allows for uniform distribution of the PEG adhesive along the length of the probe. Flip-chip bonding, a common tool used in microelectronics packaging, enables accurate and repeatable alignment and attachment of the probe to the stiffener. The probe and stiffener are surgically implanted together, then the PEG is allowed to dissolve so that the stiffener can be extracted leaving the probe in place. Finally, an in vitro test method is used to evaluate stiffener extraction in an agarose gel model of brain tissue. This approach to implantation has proven particularly advantageous for longer flexible probes (>3 mm). It also provides a feasible method to implant dual-sided flexible probes. To date, the technique has been used to obtain various in vivo recording data from the rat cortex.     

Fundamental Technical Elements of Freeze-fracture/Freeze-etch in Biological Electron Microscopy

Freeze-fracture/freeze-etch describes a process whereby specimens, typically biological or nanomaterial in nature, are frozen, fractured, and replicated to generate a carbon/platinum “cast” intended for examination by transmission electron microscopy. Specimens are subjected to ultrarapid freezing rates, often in the presence of cryoprotective agents to limit ice crystal formation, with subsequent fracturing of the specimen at liquid nitrogen cooled temperatures under high vacuum. The resultant fractured surface is replicated and stabilized by evaporation of carbon and platinum from an angle that confers surface three-dimensional detail to the cast. This technique has proved particularly enlightening for the investigation of cell membranes and their specializations and has contributed considerably to the understanding of cellular form to related cell function. In this report, we survey the instrument requirements and technical protocol for performing freeze-fracture, the associated nomenclature and characteristics of fracture planes, variations on the conventional procedure, and criteria for interpretation of freeze-fracture images. This technique has been widely used for ultrastructural investigation in many areas of cell biology and holds promise as an emerging imaging technique for molecular, nanotechnology, and materials science studies.     

Neutron activation analysis of biological samples with a preirradiation chemical separation

A preirradiation separation procedure has been developed to separate Al, Cu, Mn, and V from biological materials. Chelex-100 resin is used as the separation medium, and the resin is irradiated directly. Three NIST biological Standard Reference Materials and five samples of human blood serum, obtained under carefully controlled conditions, have been analyzed by NAA following this separation.     

生物航煤生产技术的发展现状

由于温室气体的大量排放和对化石燃料的高度依赖,航空业的可持续发展得到了全世界的关注。生物航煤被认为是一种有前景的传统航空燃料替代品。本文概述了制备生物航煤的代表性工艺技术路线、发展现状以及生物航煤产业发展所面临的机遇和挑战。迄今为止,已经有多种生物航煤制备工艺得到美国材料实验协会(American Society for Testing and Materials, ASTM)认证。其中,酯和脂肪酸加氢是目前最为成熟、可以实现完全商业化的路径。考虑到技术经济性和成熟度,短期内,费托合成是比较有发展前景的工艺。     

T-cell regulation of B-lymphoblastoid cell line function

Seventeen B-lymphoblastoid cell lines (B-LCLs) have been studied for their ability to intereact with normal T cells and produce IgG and IgM in culture. All B-LCLs were HLA homozygous, having been derived from consanguineous donors by in vitro transformation with Epstein-Barr virus, 1 × 10⁴ B-LCLs were cultured with 0, 5, 10, or 20 times as many normal peripheral blood T cells in a 0.2-ml culture. Culture supernatants were removed after 3 and 6 days and assayed for IgG and IgM by a radioimmunoassay. Thirteen of the cell lines were able to secrete immunoglobulin (50–6000 ng/ml), primarily IgG, when cultured without T cells. Addition of T cells (sheep erythrocyte rosette-forming cells) modulated immunoglobulin production, causing either marked enhancement or suppression depending upon the B-cell line. T cells cultured without the B-LCLs did not secrete immunoglobulin above the background level of the immunoassays (6.25 ng/ml). Cell lines which did not secrete IgM when cultured alone could frequently be induced to do so when T cells from select donors were added. Under these conditions, IgM was generally found only in the supernatant fluid removed after 6 days. Taken together, these results suggest that B-LCLs contain cells of at least two stages, those that secrete IgG and resting cells capable of secreting IgM. Furthermore, cells at both stages can be regulated by normal T cells.     

Process of Making Three-dimensional Microstructures using Vaporization of a Sacrificial Component

Vascular structures in natural systems are able to provide high mass transport through high surface areas and optimized structure. Few synthetic material fabrication techniques are able to mimic the complexity of these structures while maintaining scalability. The Vaporization of a Sacrificial Component (VaSC) process is able to do so. This process uses sacrificial fibers as a template to form hollow, cylindrical microchannels embedded within a matrix. Tin (II) oxalate (SnOx) is embedded within poly(lactic) acid (PLA) fibers which facilitates the use of this process. The SnOx catalyzes the depolymerization of the PLA fibers at lower temperatures. The lactic acid monomers are gaseous at these temperatures and can be removed from the embedded matrix at temperatures that do not damage the matrix. Here we show a method for aligning these fibers using micromachined plates and a tensioning device to create complex patterns of three-dimensionally arrayed microchannels. The process allows the exploration of virtually any arrangement of fiber topologies and structures.     

Precision materials: Computational design methods of accurate protein materials

Nature has evolved a vast repertoire of structures and functions based on an ordered, orchestrated, protein building-blocks assembly. For decades these sophisticated materials have been studied, mimicked, and repurposed, yet recently, computational protein engineering methods provided an alternative route: creating protein materials de-novo, surpassing evolutionary constraints and optimized for specific tasks. We highlight two areas of research that fundamentally accelerate design of structurally well-defined programmable protein materials. First, implementations of hierarchical assembly and geometric sampling (docking) strategies to create designable backbones under pre-specified symmetry constraints. Second, progress in protein–protein interfaces and sequence design methods, using Rosetta, that drive programmable supramolecular assemblies. These approaches have proven effective in generating diverse protein assemblies in 0-, 1-, 2-, and 3-dimensional architectures (constituting single or multiple components), and as part of a synthetic or a biological system. We expect these methods shall transform the toolbox of protein designers developing next generation synthetic and biological materials.     

Molecular cloning of Bacillus polymyxa (1→4)-β-d-xylanase gene in Escherichia coli

Escherichia coli has been transformed with recombinant plasmids carrying DNA from Bacillus polymyxa. A sensitive and simple immunoassay was used to screen for E. coli transformed with the chimeric plasmid carrying a (1→4)-β-d-xylanase (1,4-β-d-xylan xylanohydrolase, EC 3.2.1.8) gene. One such clone was isolated. The enzyme present in extracts of these E. coli cells was active in catalysing the hydrolysis of (1→4)-β-d-xylo-oligosaccharides of identified structure from the mucilage of Plantago ovata Forsk, as indicated by the production of reducing sugars. This work holds promise for the large-scale production of xylanases as a new route to the economic and usable degradation of xylans and is a model for the large-scale production of enzymes.     

The IGF-1/cortisol ratio as a useful marker for monitoring training in young boxers

Training effects on plasma insulin-like growth factor-1 (IGF-1)/cortisol ratio were investigated in boxers. Thirty subjects were assigned to either the training or the control group (n = 15 in both). They were tested before the beginning of training (T0), after 5 weeks of intensive training (T1), and after 1 week of tapering (T2). Physical performances (Yo-Yo intermittent recovery test level-1), training loads, and blood sampling were obtained at T0, T1, and T2. Controls were only tested for biochemical and anthropometric parameters at T0 and T2. A significantly higher physical performance was observed at T2 compared to T1. At T1, cortisol levels were significantly increased whereas IGF-1 and insulin-like growth factor binding protein-3 (IGFBP-3) levels remained unchanged compared to baseline. At T2, cortisol levels decreased while IGF-1 and IGFBP-3 levels increased. The IGF-1/cortisol ratio decreased significantly at T1 and increased at T2, and its variations were significantly correlated with changes in training loads and Yo-Yo intermittent recovery test level 1 (IRT1) performance over the training period. Cortisol variations correlated with changes in training load (r = 0.64; p < 0.01) and Yo-Yo IRT1 performance (r = 0.78; p < 0.001) at T1 whereas IGF-1 variations correlated only with changes in Yo-Yo IRT1 performance at T2 (r = 0.71; p < 0.001). It is concluded that IGF-1/cortisol ratio could be a useful tool for monitoring training loads in young trained boxers.