人血单个红细胞的共振拉曼光谱研究

给出了人血单个红细胞在不同激发光源下的共振拉曼光谱。从实验谱中得到 ,构象不灵敏的苯丙氨酸的单取代基环的伸缩振动谱线 10 0 2cm-1和吡咯环的CN呼吸振动谱带中 16 2 0cm-1的谱线 ,对 782nm激发光源共振较强 ,呈现出强度大而半高宽小的尖锐谱线 ;而在 5 14nm激发光源下 ,该两条谱线较弱。其他谱线 ,高波数段 (大于 135 0cm-1) ,在 5 14nm激发光源下 ,谱线强度大且清晰 ;低波数段 (小于 135 0cm-1) ,对应 782nm激发光源的拉曼谱线强而明显。同时还给出了同一激光光源下 ,取血后不同时间单个红细胞的拉曼光谱。发现对 782nm激发光源 ,除 16 0 1cm-1谱线强度减小外 ,其他无明显变化 ;而对 5 14nm激发光源 :一是有许多条谱线强度减小 ,二是许多条谱线向低波数移动了 4～ 10cm-1波数左右。这些实验结果 ,可以为研究单个红细胞的结构、功能及进一步研究病变细胞的变异提供有力的实验基础。     

金属纳米电极的制备、表征及其在电化学测量中的应用

本文简要介绍了各种金属纳米电极的制备及表征方法。结合我们自己的工作,重点介绍了纳米电极在电化学反应动力学参数测量及扫描电化学显微镜(SECM)中的应用,并对其发展前景进行了展望。引用文献78篇。     

Ultrasonic treatment of glassy carbon for nanoparticle preparation

Glassy carbon particles (millimetric or micrometric sizes) dispersions in water were treated by ultrasound at 20 kHz, either in a cylindrical reactor, or in a “Rosette” type reactor, for various time lengths ranging from 3 h to 10 h. Further separations sedimentation allowed obtaining few nanoparticles of glassy carbon in the supernatant (diameter <200 nm). Thought the yield of nanoparticle increased together with the sonication time at high power, it tended to be nil after sonication in the cylindrical reactor. The sonication of glassy carbon micrometric particles in water using “Rosette” instead of cylindrical reactor, allowed preparing at highest yield (1–2 wt%), stable suspensions of carbon nanoparticles, easily separated from the sedimented particles. Both sediment and supernatant separated by decantation of the sonicated dispersions were characterized by laser granulometry, scanning electron microscopy, X-ray microanalysis, and Raman and infrared spectroscopies. Their multiscale organization was investigated by transmission electron microscopy as a function of the sonication time. For sonication longer than 10 h, these nanoparticles from supernatant (diameter <50 nm) are aggregated. Their structures are more disordered than the sediment particles showing typical nanometer-sized aromatic layer arrangement of glassy carbon, with closed mesopores (diameter ∼3 nm). Sonication time longer than 5 h has induced not only a strong amorphization (subnanometric and disoriented aromatic layer) but also a loss of the mesoporous network nanostructure. These multi-scale organizational changes took place because of both cavitation and shocks between particles, mainly at the particle surface. The sonication in water has induced also chemical effects, leading to an increase in the oxygen content of the irradiated material together with the sonication time.     

Analytical tools for monitoring changes in physical and chemical properties of chromatography resin upon reuse

Protein A resins are often reused for multiple cycles to improve process economy during mAb purification. Significant reduction in binding capacity and product recovery are typically observed due to the presence of unwanted materials (foulants) deposited on the resin upon reuse. In this paper, we have used a wide spectrum of qualitative and quantitative analytical tools (particle size analysis, HPLC, fluorescence, SEM, MS, and FTIR) to compare the strengths and shortcomings of different analytical tools in terms of their capability to detect the fouling of the resin and relate it to chromatographic cycle performance. While each tool offers an insight into this complex phenomena, fluorescence is the only one that can be used for real‐time monitoring of resin fouling. A correlation could be established between fluorescence intensity and the process performance attributes (like yield or binding capacity) impacted upon resin reuse. This demonstration of the application of fluorescence for real‐time monitoring correlated empirically with process performance attributes and the results support its use as a PAT tool as part of a process control strategy. While the focus of this paper is on fouling of protein A chromatography resin, the approach and strategy are pertinent to other modes of chromatography as well.     

Characterization of copper SERS-active substrates prepared by electrochemical deposition

Surface Enhanced Raman Scattering (SERS) on copper substrates of various morphologies, prepared by electrochemical deposition on platinum targets, was investigated. The substrate preparation procedures differed by the coating bath compositions, applied current densities and the duration of individual steps. The surface morphology of the substrates was visualized by means of Atomic Force Microscopy (AFM) and Scanning Electron Microscopy (SEM). SERS spectra of selected organic thiols were measured and the relation between SERS spectral intensity and the surface structure of SERS-active substrates was studied. It has been shown that good Raman surface enhancement can be achieved on the copper substrates prepared by electrochemical deposition from ammoniac baths. Copper substrates fabricated from acidic baths did not show efficient Raman surface enhancement. The results of microscopic measurements demonstrated that the average surface roughness value does not play a substantial role, whereas the shape of the surface nanostructures is a key parameter.     

Nanoplates controlled synthesis and catalytic activities of silver nanocrystals

The silver nanostructures, from nanoparticles (NPs) to nanorod and nanoplate, can be synthesized quantitatively with DMF (N,N^′$N,N^{\prime }$-dimethyl formamide) and PVA (Polyvinyl alcohol). Due to the anisotropic shape feature, the absorption spectra of the nanoplates prove to be quite different from that of spherical NPs. It may be due to the specific interaction between OH groups and Ag+ ions, which affect selective growth of various planes of silver nanocrystals. In addition, the catalytic activity of the obtained different shaped silver nanocrystals for hydrogen production has also been investigated. The silver nanoplates exhibit higher catalytic activities than silver NPs.     

Geometrical characterization techniques for microlens made by thermal reflow of photoresist cylinder

Microlens characterization is a prerequisite for improving fabrication process, and for satisfying the end user needs. In this paper we explore techniques to characterize geometrical properties of microlens made by thermal reflow: viz. microlens profile; radius of curvature; microlens height; contact angle and focal length. The geometrical characterization is done using techniques such as contact profilometry, scanning electron microscopy (SEM), optical microscopy, white light confocal microscopy and fluorescence confocal microscopy. All the above techniques are studied and compared, keeping in mind the characterization requirements of polymer microlens made by thermal reflow technique.     

Thermal undulations of quasi-spherical vesicles stabilized by gravity

The classical treatment of quasi-spherical vesicle undulations has, in the present work, been reviewed and extended to systems, which are affected by a gravitational field caused by a density difference across the membrane. The effects have been studied by the use of perturbation theory leading to corrections to the mean shape and the fluctuation correlation matrix. These corrections have been included in an analytical expression for the flicker spectrum to probe how the experimentally accessible spectrum changes with gravity. The results are represented in terms of the gravitational parameter, g ₀ = ΔρgR ⁴/κ. The contributions from gravity are in most experimental situations small and thus negligible, but for values of g₀ above a certain limit, the perturbational corrections must be included. Expressions for the relative error on the flicker spectrum have been worked out, so that it is possible to define the regime where gravity is negligible. An upper limit of g₀ has also been identified, where the error in all modes of the flicker spectrum is significant due to distortion of the mean shape. Received 9 July 2002 and Received in final form 15 November 2002 RID="a" ID="a"e-mail: jonas@kemi.dtu.dk RID="b" ID="b"e-mail: ipsen@memphys.sdu.dk     

Design,photophysical properties,and applications of fluorene-based fluorophores in two-photon fluorescence bioimaging: A review

Two-photon fluorescence microscopy (2PFM) emerged as a powerful alternative to conventional one-photon microscopy. 2PFM typically uses two near-infrared (NIR) photons to excite fluorescent dyes, which minimizes light scattering in biological samples. Multiphoton absorption also suppresses background signal and autofluorescence from tissues and allows to achieve higher 3D resolution images with low photodamage and photobleaching. Fluorene dyes possess distinct properties that meet the strict criteria of probes used for 2PFM such as enhanced solubility, photostability, and two-photon absorption cross-section. The fluorene molecule also includes many active positions that allow versatile synthesis, selective functionalization, bioconjugation, and tuning solubility. These properties have led to reporting several fluorene probes including monomers, polymers, and dendrimers with important uses in understanding molecular dynamics and bioimaging. The current review presents a compact summary of fluorene-based fluorophores for 2PFM bioimaging applications, shedding light on structure-photophysical property relationships in fluorenes and polyaromatic probe designs.     

含裂纹试件的声镜实验研究

本文利用声学显微，获得金属材料含裂纹试件细观力学特征图像。通过对比分析，从定性到定量，证明声学显微技术以其自身的独到之处成为一种有效的实验手段，在细观力学的研究中可能具有广泛的应用前景。