Surface-induced self-assembly of dipeptides onto nanotextured surfaces

There is an increasing interest for the utilization of biomolecules for fabricating novel nanostructures due to their ability for specific molecular recognition, biocompatibility, and ease of availability. Among these molecules, diphenylalanine (Phe-Phe) dipeptide is considered as one of the simplest molecules that can generate a family of self-assembly based nanostructures. The properties of the substrate surface, on which the self-assembly process of these peptides occurs, play a critical role. Herein, we demonstrated the influence of surface texture and functionality on the self-assembly of Phe-Phe dipeptides using smooth silicon surfaces, anodized aluminum oxide (AAO) membranes, and poly(chloro-p-xylylene) (PPX) films having columnar and helical morphologies. We found that helical PPX films, AAO, and silicon surfaces induce similar self-assembly processes and the surface hydrophobicity has a direct influence for the final dipeptide structure whether being in an aggregated tubular form or creating a thin film that covers the substrate surface. Moreover, the dye staining data indicates that the surface charge properties and hence the mechanism of the self-assembly process are different for tubular structures as opposed to the peptidic film. We believe that our results may contribute to the control of surface-induced self-assembly of peptide molecules and this control can potentially allow the fabrication of novel peptide based materials with desired morphologies and unique functionalities for different technological applications.     

Enhancement of platinum octaethyl porphyrin phosphorescence near nanotextured silver surfaces

We observe more than a 200-fold increase in the photoexcited phosphorescent emission of PtOEP (2,3,7,8,12,13,17,18-octaethyl-21H,23H-porphyrin platinum II) in a polystyrene film on nanotextured silver surfaces, coincident with a reduction in the triplet state lifetime by a factor of 5. The large enhancement results in films with apparent luminescence quantum yields much greater than unity and can be understood in terms of increased radiative rates due to interactions between the molecules and the electron plasma in nearby silver nanoparticles. We study the photoluminescence efficiency, excitation spectrum, and decay dynamics as a function of film thickness and silver density. We use a model of the photophysics to decompose the phosphorescent enhancement into contributions from increases in absorption, emissive rate, and quenching. Quenching increases in importance for very thin films, and we conclude that approximately 3 nm spacing between metal and chromophore leads to the largest photoluminescence enhancement.     

Interaction of micrometer-scale particles with nanotextured surfaces in shear flow

Dynamic particle adhesion from flow over collecting surfaces with nanoscale heterogeneity occurs in important natural systems and current technologies. Accurate modeling and prediction of the dynamics of particles interacting with such surfaces will facilitate their use in applications for sensing, separating, and sorting colloidal-scale objects. In this paper, the interaction of micrometer-scale particles with electrostatically heterogeneous surfaces is analyzed. The deposited polymeric patches that provide the charge heterogeneity in experiments are modeled as 11-nm disks randomly distributed on a planar surface. A novel technique based on surface discretization is introduced to facilitate computation of the colloidal interactions between a particle and the heterogeneous surface based on expressions for parallel plates. Combining these interactions with hydrodynamic forces and torques on a particle in a low Reynolds number shear flow allows particle dynamics to be computed for varying net surface coverage. Spatial fluctuations in the local surface density of the deposited patches are shown responsible for the dynamic adhesion phenomena observed experimentally, including particle capture on a net-repulsive surface.     

Nanoscale evaluation of lubricity on well-defined polymer brush surfaces using QCM-D and AFM

For preparing a “highly lubricated biointerface”, which has both excellent lubricity and biocompatibility, we investigated the factors responsible for resistance to friction during polymer grafting. We prepared poly(2-methacryloyloxyethyl phosphorylcholine) (PMPC), poly(2-hydroxyethyl methacrylate) (PHEMA), and poly(methyl methacrylate) (PMMA) brush layers with high graft density and well-controlled thickness using atom transfer radical polymerization (ATRP). We measured the water absorptivity in the polymer brush layers and the viscoelasticity of the polymer-hydrated layers using a quartz crystal microbalance with dissipation monitoring (QCM-D) measurements. The PMPC brush layer had the highest water absorptivity, while the PMPC-hydrated layer had the highest fluidity. The friction properties of the polymer brush layers were determined in air, water, and toluene by atomic force microscopy (AFM). The friction on each polymer brush decreased only when a good solvent was chosen for each polymer. In conclusion, the brush layer possessing high water absorptivity and fluidity in water contributes to reduce friction. PMPC grafting is an effective and promising method for obtaining highly lubricated biointerfaces.     

新型双阳离子卟啉的聚集行为及超声诱导的转换

合成了一种新型水溶性双阳离子卟啉PP1,该化合物在结构上同时具有给电子和拉电子基团的分子识别位点.PP1在其自身浓度低于亚微摩尔/升的条件下就可以自发地形成J-聚集体,通过紫外光谱、共振光散射光谱和荧光光谱等手段表征,并测得了其临界聚集浓度.随着自身浓度进一步升高,PP1逐渐转向H-聚集体.另外,一定浓度下PP1的H-聚集能够被超声波诱导而转化为J-聚集.     

The hydrophobic interaction between macroscopic surfaces

The aim of this paper is to review our current level of knowledge of the interaction between hydrophobic surfaces immersed in water. The strong attractive forces observed between such surfaces have generally been referred to as “the hydrophobic interaction”. Although the precise origin of this force has not yet been determined, we will examine recent experimental studies and relate them to other phenomena like cavity formation and repulsive hydration forces.     

Three kinds of heat transfer augmentation in perforated surfaces

Heat exchanger cores, each consisting of a number of single or composite perforated plates separated by wooden spacers to form parallel flow channels, were tested in a subsonic wind tunnel. Three distinct types of augmentation in the heat transfer and friction loss performance have been identified: the transition-turbulent flow enhancement, the “second” laminar flow enhancement and the laminar flow enhancement. The first kind is observed to occur in the transition and turbulent flow regimes on low porosity surfaces [1]. The second type is detected in the “second” laminar flow regime on high porosity surfaces [2]. The present study has revealed the existence of the third pattern which occurs over the entire laminar flow region on low-porosity composite surfaces consisting of a short upstream section for producing vortices and a main section for heat transfer. An attempt is made to explain the enhancement mechanisms.     

Facile preparation of superhydrophobic nanorod surfaces through ion-beam irradiation

Obtaining superhydrophobic surfaces for their application in electronics and flexible wearable devices remains a significant challenge. Most previously reported methods for obtaining superhydrophobic surfaces involve complex and expensive preparation techniques and thus cannot be used for practical applications. Ion-beam irradiation is a simple and promising method for fabricating superhydrophobic nanostructures on large areas at a low cost. Ion-beam irradiation using argon and oxygen gases was used to prepare silica nanorod structures on glass substrates. This study is not just a modification of the surface of nanoparticles, but a change in nanoparticle shape. The nanorods were subsequently treated with perfluorooctyltriethoxysilane to obtain superhydrophobicity. The surface of the silica nanorods exhibited a static water contact angle of 153°, indicating superhydrophobicity. The combination of rough structures of silica nanorods and low surface energy resulted in superhydrophobicity. The surface properties were evaluated in detail using Fourier-transform infrared spectroscopy, field-emission scanning electron microscopy, and X-ray photoelectron spectroscopy. The proposed method is facile, inexpensive, and can be used for the large-scale production of nanorod structures for potential industrial applications.     

Observation of adhesive force and energy of adsorbents on rubber substrates by atomic force microscopy

We observed the surface morphology and adhesive interaction of adsorbents on rubber substrates by atomic force microscopy (AFM). The detachment of adsorbents from rubber substrates is an important issue for various machines like home appliances and laundry machine. Since a clean surface of the functioning parts is required, a frequent cleaning process must be developed. In particular, dust and lint have a tendency to bind to the rubber surface of a laundry machine. Several practical methods have been attempted to remove these particles from the surface. Pure water, detergent, sodium hypochlorite (65 °C), and cold water (18 °C) are treated onto artificial dust and lint mixtures on rubber with water fluid by rapid rpm. The dust‐and‐lint adsorbents are investigated by AFM after the treatment, and topographic images and force–distance (F–D) curves were generated for the samples. The roughness, measured as the root mean square, is a key factor to judge the cleaning quality. From the F–D curves, we are able to obtain adhesive energy in addition to adhesive force which will yield qualitative measures of the interactions between the remaining adsorbents and the rubber surface. Considering the values that were measured, hot water with water fluid by rapid rpm offers the best performance when cleaning the surface. The chemical like sodium hypochlorite is good for thinning the materials, but it solidifies them, which is eventually detrimental to proper functioning. Copyright © 2014 John Wiley & Sons, Ltd.     

Micropatterned designs of thermoresponsive surfaces for modulating cell behaviors

The chemistry and topography of the material surfaces have an important effect on cell behaviors. In this study, we reported the preparation of thermoresponsive micropatterned surfaces (TS) and galactosylated TS for modulating the adhesion/detachment of cells. A thickness of 1 µm of poly(N‐isopropylacrylamide) grafted layer was fabricated on the polystyrene surface with microgrooves using ultraviolet‐induced copolymerization. The thick grafted layer was in favor of the interactions between cells and materials. The following immobilization of galactose ligand with specific affinity to hepatocyte onto TS promoted the adhesion of human hepatocyte line (HL‐7702 cells). The microgrooves structure could facilitate cell adhesion and regulate the oriented growth of cells. Moreover, narrow grooves accelerated the spontaneous detachment of cells only by reducing temperature. Thus, micropatterned biofunctional designs with controlled geometrical features presented in this study have sufficient biofunctional activities in facilitating cell sheet engineering and regenerative medicine. Copyright © 2013 John Wiley & Sons, Ltd.     

3种新型二胺化合物的合成及其晶体结构

以2,6-吡啶二酰氯和(邻、间、对)硝基苯胺反应合成N,N'-(2-硝基苯基)-2,6-二甲酰亚胺吡啶、N,N'-(3-硝基苯基)-2,6-二甲酰亚胺吡啶、N,N'-(4-硝基苯基)-2,6-二甲酰亚胺吡啶等3种二硝基化合物,然后以FeCl3-NH2NH2·H2O活性炭为还原体系,将3种二硝基化合物还原成相应的二胺(Ⅰ...     

超疏水性聚二甲基硅氧烷膜的制备及其表面吸附性研究

采用简单的激光刻蚀方法制备了具有类“菜花”状多级结构的粗糙聚二甲基硅氧烷(PDMS)膜, 并用CCD与高敏感性微电力学天平观察和测量PDMS表面对水的吸附情况. 结果表明, 该膜表面具有超疏水性, 同时对水滴具有超低的吸附力. 还对其表面特殊多级结构产生的机理进行了分析, 并探讨了在化学组成和表面结构对超疏水性以及吸附性产生的影响.     

Chains anisotropy in PDMS networks due to friction on gold surfaces

In this article, we describe an experimental friction study of poly(dimethyl siloxane) (PDMS) networks on metallic substrates such as gold-coated slides, and under different conditions. The friction generates a transfer of a thin layer of PDMS and a preferential orientation of the polymer chains at the interface. However, the characterization of this layer is complicated, given the small amount of matter and the contact with a metallic surface. The polarization-modulation infrared reflexion-absorption spectroscopy (PM-IRRAS), which is an excellent tool for anisotropy and orientation studies, was used to characterize the PDMS transferred layer. Our results showed an induced anisotropy due to the friction, and in which PDMS chains are lying parallel to the gold substrate surface. Our spectroscopic analyzes allowed us to imagine a scheme of PDMS transfer on the gold surface. © 2004 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 42: 2348–2353, 2004     

One-pot synthesis and characterization of three kinds of thiol-organosilica nanoparticles

Using a one-pot synthesis, thiol-organosilica nanoparticles (NPs) made from (3-mercaptopropyl)trimethoxysilane, (3-mercaptopropyl)triethoxysilane, and (3-mercaptopropyl)methyldimethoxysilane have been successfully prepared. We compared the synthesis processes of thiol-organosilica NPs made of these three kinds of organosilicates, as well as particles made from tetraethoxysilicate (TEOS), at concentrations varying between 6.25 and 200 mM. We examined three types of synthetic conditions: the St?ber method, in which particles are prepared in 65% ethanol, and two entirely aqueous solvent syntheses, containing either 2% or 27% ammonium hydroxide. The synthetic mixtures were examined using transmission electron microscopy (TEM) to evaluate the as-prepared NPs. The formation trends and rates for these organosilica NPs vary with differing organosilicate precursors, concentrations, and synthetic conditions. The St?ber method is not suitable for formation of thiol-organosilica NPs as compared with the case of TEOS, but the conditions without ethanol and with 27% ammonium hydroxide are suitable for the formation of thiol-organosilica NPs. The size distributions of the formed NPs were evaluated using TEM and dynamic light scattering. The mean diameters of NPs increase with increasing concentrations of silicate, but the size distributions of NPs prepared under various conditions also differ between silicate sources. Thiol-organosilica NPs internally functionalized with fluorescent dye were also prepared using a one-pot synthesis and were characterized using fluorescence microscopy. The thiol-organosilica NPs retain fluorescent dye maleimide very well. In addition, rhodamine B-doped thiol-organosilica NPs show higher fluorescence than thiol-organosilica NPs prepared with rhodamine red maleimide. The surface of thiol-organosilica NPs contains exposed thiol residues, allowing the covalent attachment of fluorescent dye maleimide and protein maleimide. This is the first report describing the synthesis of thiol-organosilica NPs made of three kinds of thiol-organosilicates, differences in nanoparticle formation due to the kinds and concentrations of thiol-organosilicate and due to synthetic conditions, and the advantages of thiol-organosilica NPs due to the existence of both interior and exterior thiol residues.     

Adsorption behaviors of DPPC/MO aggregates on SiO2 surfaces

The adsorption kinetics of extruded 1,2-dipalmitoyl- sn-glycero-3-phosphatidylcholine (DPPC)/1-(cis-9-octadecenoyl)- rac-glycerol (monoolein, MO) aggregates on SiO 2 surface at 25 degrees C is investigated in real time, using the dissipative quartz crystal microbalance (QCM) technique. Four adsorption pathways have been identified depending on the molar fraction of MO in the DPPC/MO system: (I) intact vesicle adsorption, (II) vesicle reorganization on a SiO 2 surface, (III) supported lipid bilayer (SLB) formation, and (IV) cubosome adsorption. The results can be understood by the fact that DPPC is a lamellar phase-forming lipid, whereas MO prefers the cubic phase. Therefore, the incorporation of MO in DPPC increases the packing parameter. Equally important, MO also increases the mobility of lipid molecules and lateral pressure in the bilayers as a result of the presence of a unique cis- double bond. Before extrusion, the vesicles size increases with the MO content when X MO or= 0.8. The extruded DPPC/MO suspensions consist of reformed vesicles for X MO or= 0.8, all with a uniform diameter of approximately 100 nm. Differential scanning calorimetry (DSC) further indicates that the addition of MO lowers the main phase transition temperature of DPPC and thus makes the hydrophobic interior more fluid.     

RP-HPLC法测定3种中药复方制剂中的黄芩苷

采用反相高效液相色谱法分离测定芩连片、复方鱼腥草片、槐角丸3种中药复方制剂中的黄芩苷。以ODS柱为固定相,甲醇 水(V(甲醇)∶V(水)=60∶40,H3PO4调至pH2 5)作流动相,检测波长275nm,黄芩苷检出限为5.03ng,并在6 03～102.48μg mL范围内呈线性关系,回收率97.0%～99.9%。     

Mineralization mechanism of calcium phosphates under three kinds of Langmuir monolayers

Three kinds of Langmuir monolayers formed by dipalmitoylphosphatidylcholine (DPPC), arachidic acid (AA), and octadecylamine (ODA) were used as templates to study the initial stage of nucleation and crystallization of calcium phosphates. It was demonstrated that the combination of calcium ions (or phosphates) to the monolayer/subphase interface is a prerequisite for subsequent nucleation. It was found that calcium phosphate dihydrate (DPCD) formed at 25.0 degrees C for 12 h has a biphasic structure containing both amorphous and crystalline phases. These results showed that calcium phosphates were formed through a multistage assembly process, during which an initial amorphous phase DPCD was followed by a phase transformation into a crystalline phase and then the most stable hydroxyapatite (HAp). This provided new insights into the template-biomineral interaction and a mechanism for biomineralization.     

水热法生长方式对ZnO纳米棒阵列结构和性能的影响

本文系统地比较了三种方式制备的ZnO纳米棒阵列的结构和性能的异同.根据水热法生长液中碱来源的不同,ZnO纳米棒阵列的生长方式分为三种:N方式(氨水)、H方式(六次甲基四胺)和NH方式(两次N方式和一次H方式).通过扫描电子显微镜,对这三种方式生长的ZnO纳米棒阵列形貌进行了表征.此外,利用X射线衍射仪、透射电子显微镜和激光拉曼光谱对ZnO的结晶性能进行比较.结果表明,ZnO纳米棒阵列的取向性N≈NH>H,ZnO的晶体质量H>NH>N.NH方式综合N方式和H方式的优势,得到了取向性和晶体质量优良的ZnO纳米棒阵列.这将为在进一步应用中有效地选择ZnO纳米棒阵列的制备方式提供重要信息.     

ForceFit: A code to fit classical force fields to quantum mechanical potential energy surfaces

The ForceFit program package has been developed for fitting classical force field parameters based upon a force matching algorithm to quantum mechanical gradients of configurations that span the potential energy surface of the system. The program, which runs under UNIX and is written in C++, is an easy‐to‐use, nonproprietary platform that enables gradient fitting of a wide variety of functional force field forms to quantum mechanical information obtained from an array of common electronic structure codes. All aspects of the fitting process are run from a graphical user interface, from the parsing of quantum mechanical data, assembling of a potential energy surface database, setting the force field, and variables to be optimized, choosing a molecular mechanics code for comparison to the reference data, and finally, the initiation of a least squares minimization algorithm. Furthermore, the code is based on a modular templated code design that enables the facile addition of new functionality to the program. © 2010 Wiley Periodicals, Inc. J Comput Chem, 2010