蜂毒素在功能化金纳米粒子表面的吸附及构象变化

利用硼氢化钠还原法制备了金纳米粒子, 通过在其表面修饰链长不同的巯基羧酸, 得到了功能化纳米粒子. 利用荧光发射、紫外吸收和圆二色谱等手段研究了功能化金纳米粒子与蜂毒素分子之间的相互作用及其所诱导的蛋白质分子的构象变化. 研究结果表明, 功能化修饰的金纳米粒子可通过静电相互作用吸附蜂毒素(Melittin)并诱导其α-螺旋结构的形成, 且这种效应与巯基羧酸分子的链长直接相关.     

NaYF_4:Yb~(3+),Er~(3+)上转换发光纳米晶在三元混合溶剂体系中的配体交换修饰及发光性质

选用2-胺乙基膦酸双官能团小分子作为配体交换剂,采用氯仿/乙醇/水三元混合溶剂体系下的配体交换修饰方法,解决了疏水纳米晶与亲水配体的有效接触反应问题,实现了上转换纳米晶的水溶性以及表面胺基功能化修饰.通过傅里叶变转换红外光谱和热重分析证实了表面配体分子的替换.透射电子显微镜和激光粒度分析结果显示,所得水溶性纳米晶具有粒径均一,水力直径小和分散稳定的特点.样品的发射光谱结果表明,配体交换过程对纳米晶的发光无明显影响,保持了良好的发光性能.通过荧光共聚焦成像技术实现了胺基修饰上转换发光纳米晶对HeLa细胞的光学成像,证实所得纳米晶适合于潜在的生物学应用.     

尺寸可控的金纳米粒子在功能化的MWNTs表面的自组装

提出了一个有效的、以晶种媒介的光化学法可控生长不同尺寸的胶体金纳米粒子在多壁碳纳米管(MWNTs)表面的自组装.方法基于羧基化的MWNTs以双官能团巯基乙酸分子化学修饰而连接上巯基,随后,不同尺寸的胶体金纳米粒子以共价结合的方式分别被直接锚定在其表面,从而获得良好的Au/MWNTs杂化材料.通过UV-Vis光谱、TEM和XRS等技术对胶体金纳米粒子、Au/MWNTs复合物及其自组装过程的表征,详细研究了金纳米粒子尺寸对功能化MWNTs表面自组装的影响,结果表明,直径为2.5～5.2nm范围很好分散的金纳米粒子能够很好自组装在平均直径约20nm的功能化MWNTs表面上.同时探讨了双官能团分子的化学修饰和金纳米粒子对MWNTs表面自组装的驱动力。     

铜纳米材料的制备

纳米铜由于其独特的物理化学性质以及在光学、电子、催化、抗菌、润滑、聚合物填充改性等领域的广泛应用得到了人们越来越多的关注。近年来研究者已经利用多种合成方法制备了不同尺寸和形貌的铜纳米材料。本文综述了目前铜纳米材料的几种常用的制备方法,包括化学还原法、微乳液法、多元醇法、有机前驱体热分解法、电化学法等,评述了这些方法的优缺点。在化学还原法中配体对无机纳米材料的表面修饰起着至关重要的作用,因而我们详细介绍了不同分子配体在铜纳米材料尺寸和形貌控制以及表面功能化等方面的特点和作用。最后结合本课题组在纳米材料制备方面的工作,对铜纳米材料的发展进行了展望。     

金纳米星的制备、表面修饰及其在生物医学领域的应用研究

随着纳米技术的飞速发展,复杂三维结构的金纳米星已成为一种新型纳米材料。金纳米星具有独特的物理化学性质,如可调制的LSPR光学特性、SERS效应、光热特性、较大的比表面积等,这些性质使其在纳米材料和生物医学领域具有极高的潜在应用价值。本文首先介绍了金纳米星独特的光学性质,并对这些光学特性的理论基础进行解释;接着对近年来国内外制备金纳米星的主要方法进行阐述,主要包括种子介导生长法和一步合成法,这两种制备方法均存在各自的优缺点。在功能化的探针构筑方面,金纳米星的表面修饰主要包括两种方法：二氧化硅包裹金纳米星和高分子聚合物或生物分子修饰金纳米星。在应用方面,本文对金纳米星在生物分子检测、医学成像、肿瘤的诊断与光热治疗、药物传输和控制释放方面的最新研究进展进行了总结。最后,对目前金纳米星探针在制备和应用中存在的一些问题进行了探讨,并展望了该领域未来的研究内容和方向。     

金纳米团簇功能化及其在生物医学中的应用

对单分子层保护的金纳米团簇(Au-MPCs)进行化学修饰,可制成多元单层修饰的金纳米团簇（Au-MMPCs）。常用的修饰方法为配体交换法,这种方法用带有生物活性基团的巯基化合物或二硫化合物取代Au-MPCs表面的配体分子,形成多元单层修饰的金纳米团簇。巯基化合物或二硫化合物中的生物活性基团可使所制备Au-MMPCs与蛋白质、核酸或细胞膜等作用,使Au-MMPCs具有相应的生物活性,从而能广泛应用于细胞转染、药物传输、酶活性调控等生物医学领域。本文介绍了用Brust-Schiffrin法制备Au-MMPCs的机理及影响因素,基于Au-MMPCs的方法及相关机理,综述了Au-MMPCs在生物医学中的应用。     

氧化铁磁性纳米粒子的表面配体交换及相转移

以苯甲醇为单一溶剂, 通过常压、高温热解乙酰丙酮铁, 制备了尺寸单分散的四氧化三铁磁性纳米粒子. 采用透射电镜(TEM), X射线衍射(XRD), 动态光散射(DLS)等方法对粒子形貌和结构进行了表征. 利用傅里叶变换红外(FT-IR)光谱和热重分析(TGA)研究了所制备纳米粒子的表面化学, 结果表明稳定四氧化三铁粒子的是苯甲酸分子, 且表面覆盖度小于20%. 所制备的磁性纳米粒子可以在室温下方便地进行表面配体交换, 从而为氧化铁磁性纳米粒子的功能化提供新的途径.     

Fe3O4/葡聚糖/抗体磁性纳米生物探针的制备和层析检测

在免疫检测中 ,经常利用一些具有特殊物理化学性质的标记物对抗体 (或抗原 )进行偶联标记 ,在抗体与抗原识别后 ,通过对标记物的定性和定量检测而达到对抗原 (或抗体 )检测的目的 .传统的免疫标记物包括放射性同位素 [1] 、酶 [2 ] 、胶体金 [3] 和有机荧光染料分子 [4 ] 等 .近年来 ,随着纳米技术的发展 ,半导体荧光纳米晶 [5,6 ] 和磁性纳米晶 [7] 在免疫检测方面受到了广泛关注 .磁性纳米晶性能稳定 ,较易制备 ,可与多种分子复合使粒子表面功能化 ,并且由于磁纳米晶具有超顺磁性 ,为样品的分离、富集和提纯提供了很大方便 .这些优点使它…     

LaF_3∶Yb~(3+),Er~(3+)纳米晶:溶剂热法合成及上转换发光性质

利用溶剂热合成方法,分别以油酸和油胺为表面有机配体,合成了具有六角结构,颗粒尺寸分别为19和23nm单分散的LaF3:Yb3+,Er3+纳米晶。在980nm红外激光照射下,LaF3:Yb3+,Er3+纳米晶发射出肉眼可观察的绿色和红色上转换荧光,而且其发光过程均符合双光子过程。结合红外光谱与上转换光谱分析了表面有机配体对LaF3:Yb3+,Er3+纳米晶上转换发光的影响,结果显示,以油酸分子为表面配体的纳米晶具有较高的上转换发射强度,但以油胺为表面配体的纳米晶的红光发射相对增强。     

功能化纳米金增强的DNA电化学检测和序列分析

用冠以大量二茂铁的纳米金微粒 /抗生蛋白链菌素结合物为标记物 ,将其标记于生物素修饰的寡聚核苷酸片段上 ,制成了具有电化学活性和纳米金放大作用的DNA电化学生物传感器 .首先采用巯基DNA和巯基烷烃混合自组装膜制备了金修饰电极 ,将探针DNA分子固定在了电极表面 ,运用杂交原则结合靶点分子在电极表面形成了双螺旋的DNA链 ,然后借助抗生蛋白链菌素和生物素之间的强亲和作用 ,引入了功能化的纳米金 .通过伏安法测定了修饰在纳米金上的二茂铁的氧化还原电流 ,可以识别和测定溶液中互补的靶点DNA ,17 mer靶点DNA的浓度在 0 .0 0 1～ 10nmol/L范围内有线性关系 ,检测限可达 0 .75× 10 -12 mol/L .     

Freezing the self-assembly process of gold nanocrystals

The ability to stop the self-assembly of gold nanocrystals at a desired stage of the process provides new leverage to understand and control the dynamics of self-assembly. Herein, competitive ligands are used to unfavor the interaction of the cross-linker with the gold surface and terminate the growth reaction of gold nanoparticles and nanorod chains.     

Photochemical instability of CdSe nanocrystals coated by hydrophilic thiols

The photochemical instability of CdSe nanocrystals coated by hydrophilic thiols was studied nondestructively and systematically in water. The results revealed that the photochemical instability of the nanocrystals actually included three distinguishable processes, namely the photocatalytic oxidation of the thiol ligands on the surface of nanocrystals, the photooxidation of the nanocrystals, and the precipitation of the nanocrystals. At first, the thiol ligands on the surface of a nanocrystal were gradually photocatalytically oxidized using the CdSe nanocrystal core as the photocatalyst. This photocatalytic oxidation process was observed as a zero-order reaction in terms of the concentration of the free thiols in the solution. The photogenerated holes in a nanocrystal were trapped onto the thiol ligands bound on the surface of the nanocrystal, which initiated the photooxidation of the ligands and protected the nanocrystal from any photooxidation. After nearly all of the thiol ligands on the surface of the nanocrystals were converted into disulfides, the system underwent several different pathways. If the disulfides were soluble in water, then all of the disulfides fell into the solution at the end of this initial process, and the nanocrystals precipitated out of the solution without much variation over their size and size distribution. When the disulfides were insoluble in water, they likely formed a micelle-like structure around the nanocrystal core and kept it soluble in the solution. In this case, the nanocrystals only precipitated after severe oxidation, which took a long period of time. If the system contained excess free thiol ligands, they replaced the photochemically generated disulfides and maintained the stability and solubility of the nanocrystals. The initiation stage of the photooxidation of CdSe nanocrystals themselves increased as the thickness and packing density of the ligand shell increased. This was explained by considering the ligand shell on the surface of a nanocrystal as the diffusion barrier of the oxygen species from the bulk solution into the interface between the nanocrystal and the surface ligands. Experimental results clearly indicated that the initiation stage of the photooxidation was not caused by the chemical oxidation of the system kept in air under dark conditions or the hydrolysis of the cadmium-thiol bonds on the surface of the nanocrystals, both of which were magnitudes slower than the photocatalytic oxidation of the surface ligands if they occurred at all. The results described in this contribution have already been applied for designing new types of thiol ligands which dramatically improved the photochemical stability of CdSe nanocrystals with a ligand shell that is as thin as approximately 1 nm.     

Stabilization of inorganic nanocrystals by organic dendrons

A series of hydrophilic organic dendron ligands was designed and synthesized for stabilizing high-quality semiconductor and noble metal nanocrystals. The focal point of the dendron ligands is chosen to be a thiol group which is a universal coordinating site for compound semiconductor and noble metal nanocrystals. The methods for binding these dendron ligands onto the surface of the nanocrystals are simple and straightforward. The thin, about 1-2 nm, but closely packed and tangled ligand shell provides sufficient stability for the "dendron-protected nanocrystals" to withstand the rigors of the coupling chemistry and the standard separation/purification techniques. The chemistry presented can be immediately applied for the development of a new generation of biomedical labeling reagents based on high-quality semiconductor nanocrystals. It also provides an alternative path to apply noble metal nanocrystals for developing sensitive detection schemes for chemical and biochemical purposes. The concept may further provide an optimal solution for many other problems encountered in nanocrystal-related research and development, for which the stability of the nanocrystals is a critical issue. Furthermore, the experimental results confirmed that the photochemical stability of colloidal semiconductor and noble metal nanocrystals is the key for developing reliable and reproducible processing chemistry for these nanocrystals.     

Synthesis and properties of nanosilicon stabilized by butyl and perfluorobutyl ligands

Nanocrystalline silicon stabilized by butyl and perfluorobutyl ligands that form improper surface states of silicon nanocrystals were synthesized. The presence of perfluorobutyl ligands on the surface of silicon nanocrystals was proved by IR spectroscopy. Nanocrystals with perfluorobutyl ligands form aggregates, which decreases the efficiency of photoluminescence. The nanocrystals with butyl ligands have smaller size but their photoluminescence can be clearly recorded.     

Regioselective placement of alkanethiolate domains on tetrahedral and octahedral gold nanocrystals

Electrostatically stabilized monolayer shells of metal-oxide cluster anions (polyoxometalates, or POMs) on the surfaces of ca. 8 nm tetrahedral and octahedral gold nanocrystals regioselectively direct water-soluble alkanethiolate ligands to the corners and edges of the gold polyhedra.     

Multidentate-protected colloidal gold nanocrystals: pH control of cooperative precipitation and surface layer shedding

Colloidal gold nanocrystals (AuNCs) with broad size tunability and unusual pH-sensitive properties have been synthesized using multidentate polymer ligands. Because they contain both carboxylic functional groups and sterically hindered aliphatic chains, the multidentate ligands can not only reduce gold precursors but also stabilize gold nanoclusters during nucleation and growth. The "as-synthesized" AuNCs are protected by an inner coordinating layer and an outer polymer layer and are soluble in water and polar solvents. When the solution pH is lowered by just 0.6 units (from 4.85 to 4.25), the particles undergo a dramatic cooperative transition from being soluble to insoluble, allowing rapid isolation, purification, and redispersion of the multidentate-protected AuNCs. A surprising finding is that when a portion of the surface carboxylate groups are neutralized by protonation, the particles irreversibly shed their outer polymer layer and become soluble in nonpolar organic solvents. Furthermore, the multidentate polymer coatings are permeable to small organic molecules, in contrast to the tightly packed self-assembled monolayers of alkanethiols on gold. These insights are important in regard to the design of "smart" imaging and therapeutic nanoparticles that are activated by small pH changes in the tumor interstitial space or endocytic organelles.     

Size-dependent dissociation pH of thiolate ligands from cadmium chalcogenide nanocrystals

A method, pseudo steady-state titration, is introduced for determining the precipitation pH of nanocrystals coated by electron-donating ligands. CdSe nanocrystals coated with hydrophilic deprotonated thiol (thiolate) ligands were studied systematically. For comparison, CdTe and CdS nanocrystals coated with the same types of ligands were also examined. The results show that the precipitation of the nanocrystals is caused by the dissociation of the nanocrystal-ligand coordinating bonds from the nanocrystal surface. The ligands are removed from the surface due to protonation in a relatively low pH range, between 2 and 7 depending on the size, approximately within the quantum confinement size regime, and chemical composition (band gap) of the nanocrystals. In contrast, the redispersion of the nanocrystals was found to be solely determined by the deprotonation of the ligands. The size-dependent dissociation pH of the ligands was tentatively used as a means for determining the size-dependent free energy associated with the formation of a nanocrystal-ligand coordinating bond.     

A distinct platinum growth mode on shaped gold nanocrystals

An ultralow amount of platinum can be deposited on the gold surface using copper underpotential deposition and galvanic exchange. The platinum tended to deposit as layers on the octahedral gold nanocrystals with an Au(111) surface, while it aggregated and formed small particles on the cubic gold nanocrystals with an Au(100) surface.     

On the size-dependent behavior of nanocrystal-ligand bonds

Recent experiments have indicated that 3-mercapto-1-propanol ligands display a size-dependent binding energy of attachment to the surface of II-VI semiconductor nanocrystals. Using semiempirical calculations, we exhaustively calculate the energy of this bond at each surface site, for CdSe and CdSe/CdS core/shell nanocrystals ranging from 1.8 to 4.1 nm in diameter. Our results suggest that the experimentally observed changes in binding energy are due to the distribution of surface facets on the nanocrystals, and not related to the band gap, as proposed in the experimental paper.     

Photoelectron spectroscopic investigations of chemical bonding in organically stabilized PbS nanocrystals

The surface structure of organically capped PbS nanocrystals using synchrotron radiation excited core-level photoelectron spectroscopy has been studied. The nanocrystallites prepared by methods of colloidal chemistry have average diameters of 3.1, 3.9, 4.6, and 7.6 nm with narrow size distributions and are stabilized either with oleic acid only or with a combination of trioctylphosphine and oleic acid as ligands. High resolution photoelectron spectroscopy measurements allowed the surface structure to be studied and in particular how the organic ligands bind to the surface of the PbS nanocrystals to be elucidated. The results indicate that the trioctylphosphine ligands passivate only the surface S sites while oleic acid ligands appear to bind mainly to Pb sites.