Influence of Hydrostatic Pressure on the Corrosion Behavior of Superhydrophobic Surfaces on Bare and Oxidized Aluminum Substrates.

It is generally recognized that superhydrophobic surfaces in water may be used for corrosion resistance due to the entrapped air in the solid/liquid interface and could find potential applications in the protection of ship hull. For a superhydrophobic surface, as its immersion depth into water increases, the resultant hydrostatic pressure is also increased, and the entrapped air can be squeezed out much more easily. It is therefore predicted that high hydrostatic pressure would cause an unexpected decrease in corrosion resistance for the vessels in deep water (e.g., submarines) because of the unstable entrapped air. In this work, in order to clarify the role of hydrostatic pressure in the corrosion behavior of superhydrophobic surfaces, two typical superhydrophobic surfaces (SHSs) were prepared on bare and oxidized aluminum substrates, respectively, and then were immersed into the NaCl aqueous solutions with different depths of ∼0 cm (hydrostatic pressure ∼0 kPa), 10 cm (1 kPa), and 150 cm (15 kPa). It was found out for the SHSs on the oxidized Al, as the hydrostatic pressure increased, the corrosion behavior became severe. However, for the SHSs on the bare Al, their corrosion behavior was complex due to hydrostatic pressure. It was found that the corrosion resistance under 1 kPa was the highest. Further mechanism analysis revealed that this alleviated corrosion behavior under 1 kPa resulted from suppressing the oxygen diffusion through the liquid and reducing the subsequent corrosion rate as compared with 0 kPa, whereas the relatively low hydrostatic pressure (HP) could stabilize the entrapped air and hence enhance the corrosion resistance, compared with 15 kPa. The present study therefore provided a fundamental understanding for the applications of SHSs to prevent the corrosion, especially for various vessels in deep water.

Dynamic corrosion behavior of superhydrophobic surfaces.

For superhydrophobic surfaces immersed in water, a thin layer of air could be entrapped in the solid/liquid interface. This air may hinder the diffusion of dissolved corrosive species (such as Cl- ions in water) to the metallic substrate and, consequently, protect the metal from corrosion. However, in the dynamic water, the relative motion between the solid and the liquid would labilize the entrapped air and, consequently, decrease the corrosion resistance. In this work, to clarify the role of water flow velocity in such corrosion behavior, a superhydrophobic surface on aluminum substrates coded as Al-HCl-H2O-BT-SA was prepared by sequential treatment with HCl, boiling water, bis-(γ-triethoxysilylpropyl)-tetrasulfide (KH-Si69, BT) and stearic acid (SA). The contrast samples coded as Al-HCl-BT-SA, Al-HCl-H2O-SA, and Al-HCl-SA were also prepared similarly by omitting the treatment in boiling-water, the BT passivation, and the treatment in boiling-water/passivation by BT, respectively. These samples were then immersed into an aqueous solution of NaCl with different flow velocity (0, 0.5, 1.0, 1.5, and 2.0 m s-1), and its dynamic corrosion behavior was investigated. The results showed that, as the flow velocity increased, the corrosion resistance of the Al-HCl-H2O-BT-SA sample indeed deteriorated. However, compared with the contrast samples of Al-HCl-BT-SA, Al-HCl-H2O-SA, and Al-HCl-SA, the deterioration in corrosion resistance for the Al-HCl-H2O-BT-SA sample was much lower, implying that the dynamic corrosion resistance of the superhydrophobic surfaces was closely related with the micro-structures and the organic passivated layers. The present study therefore provided a fundamental understanding for the applications of superhydrophobic samples to prevent the corrosion, especially, for various vessels in dynamic water.

[Effect of miR- 155 on immune- factors and its mechanism in mesenchymal stem cells under hypoxic environment].

OBJECTIVE: To investigate the effect of miR-155 on immune-factors and its mechanism in mesenchymal stem cells under hypoxia. METHODS: The microRNA sequences targeting miR-155 mimic and mimic NC gene was designed and transfected into MSC by lipofectamineTM 2000. Lipopolysaccharide was used to stimulate the immunity of MSC under hypoxic environment. Transfection efficiency of miR- 155 and immune-related genes (IL-6, IL-8, iNOS, TGF-ß, HIF-1α) were detected by real-time RT-PCR. The cell surface antigens (CD29, CD73, CD90, CD105, CD31, CD45) and supernatant cytokines (IL- 6, IL- 8, TGF- ß, SDF- 1α) were analyzed by flow cytometry and ELISA, respectively. Western Blot was applied to evaluate related proteins, iNOS and HIF- 1α. RESULT: miR- 155 was transfected into MSC effectively (53.447±8.361 vs 1.070±0.174, P<0.01). In miR-155 high-expressed groups, the expressions of IL-6 and IL-8 were up-regulated [(24.201±1.536) vs (1.802±0.058), P<0.01; (24.406±4.611) vs (7.407± 1.553), P<0.01] and iNOS was markedly suppressed [(0.151 ±0.035) vs (32.925±1.632), P<0.01]. Hypoxia up-regulated expressions of HIF-1α [(45.093±3.371) vs (2.210±0.498), P<0.01] and promoted the regulation of miR-155. MiR-155 and hypoxia had effect on mRNA expression of SDF-1α and TGF-ß [(5.690±1.655) vs (0.841±0.194), P<0.01; (6.982±1.353) vs (0.632±0.184), P<0.01]. However, there was no influence on cytokines of SDF- 1α and TGF- ß [(24.609±2.584) vs (25.359±2.455), P=0.760;(0.568±0.019) vs (0.345±0.037), P=0.002]. CONCLUSION: Hypoxia environment may promote miR-155 to positively modulate immune factors of MSC through up-regulating the expression of HIF-1α, which down-regulated iNOS protein.

Development of a quantitative real-time PCR assay for direct detection of growth of cellulose-degrading bacterium Clostridium thermocellum in lignocellulosic degradation.

AIMS: Currently, there is no direct method for detecting Clostridium thermocellum in the insoluble medium. In this study, a quantitative real-time PCR assay was developed for the direct growth detection of C. thermocellum at the single-cell level in lignocellulosic biomasses. METHODS AND RESULTS: The assay targeted the cipA gene and was able to distinguish C. thermocellum from other species with good reproducibility which quantitative detection limit was 10 cell equivalents (CE) per reaction. OD600-based counting and qPCR quantification of C. thermocellum cultured in soluble medium were compared and an excellent consistency was revealed, indicating the appropriateness of the developed qPCR method. Analysis based on yellow affinity substrate and fermentation products may incorrectly estimate its population. CONCLUSIONS: The developed assay can serve as a specific, sensitive and reproducible method for the detection of C. thermocellum in lignocellulosic biomass at the single-cell level. SIGNIFICANCE AND IMPACT OF THE STUDY: With the ability to rapidly detect C. thermocellum, this method will contribute substantially to the understanding of the lignocellulosic biomass degradation mechanism. Moreover, it can also be applied to detect C. thermocellum growth in certain co-culture system for the understanding of the metabolic interactions.