Carbon nanotubes as separation carrier in capillary electrophoresis

The utility and versatility of carboxylic single-walled carbon nanotubes (c-SWNT) in capillary electrophoresis (CE) is demonstrated, using as model solutes homologues and structural isomers. In the case of homologues of caffeine and theobromine, distinct changes in the electrophoretic parameters occur at a critical concentration of c-SWNT in the run buffer. It is suggested that the c-SWNT of a definite concentration could form a network in the run buffer as a pseudostationary phase on the basis of the unique tubule structure, providing a different separation from sodium dodecyl sulfate (SDS) micelles. In the case of structural isomers of catechol and hydroquinone, differing from the homologues, it is mainly attributable to the functional groups on the c-SWNT that have an effect on the electrophoretic behaviors by forming intermolecular hydrogen bonding with analytes. Furthermore, aggregated c-SWNT serve as anticonvective media and minimize solute diffusion contributing to zone broadening. The presence of charged c-SWNT suppressed the electrodiffusion and decreased the adsorption between capillary wall and solutes, which led to better peak shapes of isomers.     

Mesoporous silica nanoparticles as nanocarriers

Modern nanomedicine aims at delivering drugs or cells specifically to defective cells; therefore, this calls for developing multifunctional nanocarriers for drug delivery and cell-tracking. Mesoporous silica nanoparticles (MSNs) are well suited for this task. In this feature article, we highlight the strategies in the synthesis and functionalization of small, uniform and colloidal stable MSNs. We then discuss cell uptake of MSNs and tracking cells, as both aspects are closely related to the efficacy of drug delivery and theranostics. Some examples of stimulated drug delivery are described. For application considerations, toxicity and pharmacokinetics are critical issues and in vivo studies are summarized.     

Carbon nanotubes paste electrode

The performance of carbon nanotubes paste electrodes (CNTPE) prepared by dispersion of multi-wall carbon nanotubes (MWNT) within mineral oil is described. The resulting electrode shows an excellent electrocatalytic activity toward ascorbic acid, uric acid, dopamine, 3,4-dihydroxyphenylacetic acid (dopac) and hydrogen peroxide. These properties permit an important decrease in the overvoltage for the oxidation of ascorbic acid (230 mV), uric acid (160 mV) and hydrogen peroxide (300 mV) as well as a dramatic improvement in the reversibility of the redox behavior of dopamine and dopac, in comparison with the classical carbon (graphite) paste electrodes (CPE). The substantial decrease in the overvoltage of the hydrogen peroxide reduction (400 mV) associated with a successful incorporation of glucose oxidase (GOx) into the composite material, allow the development of a highly selective and sensitive glucose biosensor without using any metal, redox mediator or anti-interference membrane. No interference was observed at −0.100 V even for large excess of ascorbic acid, uric acid and acetaminophen. A linear response up to 30 mM (5.40 g l⁻¹) glucose with a detection limit of 0.6 mM (0.11 g l⁻¹) were obtained with the CNTPE modified with 10% w/w GOx. Such an excellent performance of CNTPE toward hydrogen peroxide, represents a very good alternative for developing other enzymatic biosensors.     

Carbon nanotubes as intracellular protein transporters: generality and biological functionality

Various proteins adsorb spontaneously on the sidewalls of acid-oxidized single-walled carbon nanotubes. This simple nonspecific binding scheme can be used to afford noncovalent protein-nanotube conjugates. The proteins are found to be readily transported inside various mammalian cells with nanotubes acting as the transporter via the endocytosis pathway. Once released from the endosomes, the internalized protein-nanotube conjugates can enter into the cytoplasm of cells and perform biological functions, evidenced by apoptosis induction by transported cytochrome c. Carbon nanotubes represent a new class of molecular transporters potentially useful for future in vitro and in vivo protein delivery applications.     

Carbon nanotubes as affinity probes for peptides and proteins in MALDI MS analysis

Recently, carbon nanotubes (CNTs) have been reported to be an effective MALDI matrix for small molecules (Anal. Chem.2003, 75, 6191). In a somewhat related study, we have employed CNTs produced by using NaH-treated anodic aluminum oxide (Na@AAO) as a reactive template as the assisting matrix for MALDI analysis upon the addition of high concentrations of citrate buffer. Our results indicate that the mass range can be extended to ca. 12,000 Da and that alkali metal adducts of analytes are effectively reduced. Furthermore, we have employed citric acid-treated CNTs as affinity probes to selectively concentrate traces of analytes from aqueous solutions. High concentrations of salts and surfactants in the sample solutions are also tolerated. This approach is very suitable for the MALDI analysis of small proteins, peptides, and protein enzymatic digest products.     

Carbon nanotubes: Solid-phase extraction

Since the first report in 1991, carbon nanotubes (CNTs) have shown great possibilities for a wide variety of processes and applications, which include their use as electrodes, sensors (gas, enzymatic, etc.), nanoprobes, electronic materials, field emitters, etc. The combination of structures, dimensions and topologies has provided physical and chemical attractive properties that are unparalleled by most known materials. Their applications have also reached the Analytical Chemistry field in which CNTs are being used as matrices in matrix assisted laser desorption ionization, stationary phases in either gas chromatography, high performance liquid chromatography or capillary electrochromatography, also as pseudostationary phases in capillary electrophoresis, etc. as well as new solid-phase extraction (SPE) materials. Concerning this last application the number of works has considerably increased in the last five years. This review article pretends to focus on the most important features and different applications of SPE using CNTs (including matrix solid-phase dispersion and solid-phase microextraction) covering articles published since their introduction up to now (September 2009).     

Carbon nanotubes for electrochemical biosensing

The aim of this review is to summarize the most relevant contributions in the development of electrochemical (bio)sensors based on carbon nanotubes in the last years.Since the first application of carbon nanotubes in the preparation of an electrochemical sensor, an increasing number of publications involving carbon nanotubes-based sensors have been reported, demonstrating that the particular structure of carbon nanotubes and their unique properties make them a very attractive material for the design of electrochemical biosensors.The advantages of carbon nanotubes to promote different electron transfer reactions, in special those related to biomolecules; the different strategies for constructing carbon nanotubes-based electrochemical sensors, their analytical performance and future prospects are discussed in this article.     

Carbon nanotubes as potential material for drug delivery—experiment and simulation

We discuss the factors influencing the properties of new drug delivery system, composed of carbon nanotubes and analgesic antipyretic drug—paracetamol. Basing on experimental data it is shown, that by a simple manipulation with the heating time at the stage of system preparation, one can easily change the rate of the drug delivery. Moreover, this rate can be changed in a very wide range. Finally, using Molecular Dynamics simulation we also discuss the orientation and properties of drug molecules at different stages of the hot melt deposition process.     

Carbon nanotubes/vanadium oxide composites as cathode materials for lithium-ion batteries

Journal of Sol-Gel Science and Technology - The carbon nanotubes/vanadium oxide composites have been prepared through a facile hydrothermal method. Morphology features of the samples are...     

Carbon nanotubes films: electronic properties and their application as field emitters

Aligned carbon nanotube films have been studied with a wide variety of characterization techniques. Although nanotubes resemble bulk graphite as far as carrier densities, susceptibilities and conductivities are concerned, transport properties and ESR measurments indicate that carrier localization occurs at low temperatures. Nanotube films are good field emitters producing large currents at relatively low electric fields. The performance is superior to the intensely studied CVD diamond films in particular for the threshold field for electron emission. We believe that the observed remarkable electron emission is related to the special electronic structure of the nanotube tips.     

Carbon nanotubes and graphene in analytical sciences

Nanosized carbon materials are offering great opportunities in various areas of nanotechnology. Carbon nanotubes and graphene, due to their unique mechanical, electronic, chemical, optical and electrochemical properties, represent the most interesting building blocks in various applications where analytical chemistry is of special importance. The possibility of conjugating carbon nanomaterials with biomolecules has received particular attention with respect to the design of chemical sensors and biosensors. This review describes the trends in this field as reported in the last 6?years in (bio)analytical chemistry in general, and in biosensing in particular.

Carbon nanotubes for in vivo cancer nanotechnology

The latest progress of using carbon nanotubes (CNTs) for in vivo cancer nanotechnology is reviewed. CNTs can be functionalized by either covalent or non-covalent chemistry to produce functional bioconjugates for many in vivo applications. In vivo behaviors and toxicology studies of CNTs are summarized, suggesting no significant toxicity of well functionalized CNTs to the treated mice. Owing to their unique chemical and physical properties, CNTs, especially single-walled carbon nanotubes (SWNTs), have been widely used for various modalities of in vivo cancer treatment and imaging. Future development of CNT-based nanomedicine may bring novel opportunities to cancer diagnosis and therapy.     

Carbon nanotubes as a support for Pt-and Pt-Ru-catalysts of reactions proceeding in fuel cells

Comparative study of two types of single-wall carbon nanotubes and standard carbon black Vulcan XC-72 as supports for catalysts of reactions proceeding in fuel cells is carried out. The nanotubes were prepared by arc method; they differed in the degree of their purifying from amorphous carbon and metal impurities. The structure and hydrophobic-hydrophilic properties of these carbon supports are studied by etalon porosimetry. The effect of the supports’ specific surface area on the deposited catalyst particles size and specific surface area is studied. The catalysts (Pt-Ru and Pt) were deposited from aqueous solutions of their salts. Platinum was also deposited by thermal decomposition of ethoxy clusters. It is shown that in methanol oxidation reaction at the Pt-Ru catalysts the current values per unit true surface area do not depend on the support nature, provided the catalyst loading is equal and the particle size is similar. When oxygen is reduced at platinum deposited onto purified nanotubes and the carbon black Vulcan XC-72, specific kinetic currents also are close to each other. It is shown that the degree of nanotubes purification and their structure affect the kinetics of this reaction significantly.     

Polypeptide hybrid copolymers as selective micellar nanocarriers in nonaqueous media

The self-assembly of polystyrene-block-poly(l-lysine) (PS-PLLys·HCl) copolymers with different block lengths has been studied in toluene. The obtained spherical micelles exhibit size variations upon addition of acids or bases, as indicated by light and neutron scattering studies. It is shown that pyridine induces a shrinking of the polystyrene chains in the corona region of the micelles, decreasing the aggregate solvent interface. The addition of benzoic acid, on the other hand, leads to a swelling of the copolymer micelles proportional to the molar fraction of polypeptide. This behavior suggests a selective permeability of the PS-PLLys micelles and the possibility to encapsulate organic compounds in toluene depending on their chemical nature.     

Recent advances in liposomal nanohybrid cerasomes as promising drug nanocarriers

Liposomes have been extensively investigated as possible carriers for diagnostic or therapeutic agents due to their unique properties. However, liposomes still have not attained their full potential as drug and gene delivery vehicles because of their insufficient morphological stability. Recently, a super-stable and freestanding hybrid liposomal cerasome (partially ceramic- or silica-coated liposome) has drawn much attention as a novel drug delivery system because its atomic layer of polyorganosiloxane surface imparts higher morphological stability than conventional liposomes and its liposomal bilayer structure reduces the overall rigidity and density greatly compared to silica nanoparticles. Cerasomes are more biocompatible than silica nanoparticles due to the incorporation of the liposomal architecture into cerasomes. Cerasomes combine the advantages of both liposomes and silica nanoparticles but overcome their disadvantages so cerasomes are ideal drug delivery systems. The present review will first highlights some of the key advances of the past decade in the technology of cerasome production and then review current biomedical applications of cerasomes, with a view to stimulating further research in this area of study.     

Carbon nanotubes as efficient catalyst supports for fuel cells with direct ethanol oxidation

Several carbon materials, namely, single-walled nanotubes (CNT1), two-walled nanotubes (CNT2), multiwalled nanotubes (CNT3), and nanofibers (CNF) are synthesized by methane pyrolysis. The resulting nanomaterials are characterized by physical (BET) and electrochemical (charging curves) methods. A catalyst of ethanol electrooxidation PtSn (3: 1, 40 wt % Pt) that involves the mentioned nanomaterials as the supports is synthesized. The catalyst formed on two-walled nanotubes demonstrates the highest activity in ethanol oxidation under model conditions. X-ray diffraction analysis is used in studying the PtSn (3: 1, 40 wt % Pt)/CNT2 catalyst structure. The attained depth of ethanol oxidation is determined by the gas-liquid chromatography. Tests of an ethanol-oxygen fuel cell (FC) with the anodic active layer (AL) based on this catalyst are carried out.     

碳纳米管@碳化硅同轴异质结纳米管非金属光催化剂产氢性能（英文）

近年来,光催化裂解水产氢(H2)引起了广泛的关注.储量丰富,环境友好的非金属无机半导体β-SiC(立方相碳化硅)具有适当的带隙(Eg=2.4 eV,ECB=?0.9 V),是一种潜在的光催化剂.受限于SiC光催化剂内部光生电子-空穴对的快速复合,SiC光催化剂的效率较低.已有的关于SiC光催化剂改性的报道主要包括构建纳米SiC,构建SiC异质结,构建碳/SiC材料杂化材料.进一步的研究表明,SiC与碳材料之间通过紧密的界面接触形成了肖特基结,能将SiC表面的光生电子快速转移,抑制光生电子-空穴对的快速复合,从而提高光催化分解水产氢的活性.另一方面,碳纳米管(CNTs)具有良好的电子导电性,一维有序的管腔所形成的电子快速传导路径.因此,将半导体光催化剂与CNTs复合,是一种制备先进的光催化剂的有效策略.本文利用Si蒸气与CNTs之间的气-固反应,在CNTs表面原位生长SiC纳米包覆层,成功地制备了一维同轴核-壳CNTs@SiC纳米管.高分辨率透射电子显微镜图像表明,SiC与CNTs之间是通过Si-C共价键原子接触,并得到X射线光电子能谱的证实.将一部分CNTs@SiC纳米管在空气中750 oC煅烧2 h以除去CNTs,得到纯SiC纳米颗粒作为对比组.紫外-可见吸收光谱表明,CNTs能够促进SiC对光的吸收.荧光发射光谱(PL),瞬态荧光寿命测试,瞬态光电流测试以及交流阻抗(EIS)测试表明,CNTs能够促进SiC表面光生电子的传输与分离,有利于提升光催化效率.以0.1 mol/L Na2S溶液作为牺牲剂,在模拟太阳光(A.M 1.5)照射下,CNTs@SiC纳米管(不额外负载Pt等贵金属作为助剂)的产氢速率为118.5μmol g^-1 h^-1,是纯SiC纳米颗粒(21.1μmol g^-1 h^-1)的5.62倍.经过20 h的光照测试,CNTs@SiC纳米管的光催化性能无明显衰减;X射线衍射测试与扫描电子显微镜图像表明,CNTs@SiC纳米管的结构与形貌反应前后几乎无变化.莫特-肖特基测试表明,CNTs的费米能级比SiC低,因此SiC表面的光生电子能够快速地转移到CNTs,并且CNTs的良好导电性与一维有序的管腔所形成的长的电子传导路径能够进一步地增加电子寿命,促进光生电子参与光催化反应.另外,通过原子连接的同轴核-壳CNTs@SiC纳米管提供了大量且有效的电子传输路径.因此,与纯SiC纳米晶等同类材料相比,无机非金属CNTs@SiC纳米管具有更强的光催化氢活性.     

Carbon nanotubes as sorbents for the gas phase preconcentration of semivolatile organics in a microtrap

In this paper we present the application of carbon nanotubes as unique sorbents for the fabrication of microtraps for the nanoscale adsorption/desorption of relatively large semivolatile organic molecules. The microtrap application requires high adsorption capacity as well as easy desorbability; the latter being critical for semivolatile compounds. The sorbent characteristics of single and multiwalled carbon nanotubes for gas phase adsorption/desorption of several compounds has been studied. The nonporous nature of carbon nanotubes (CNTs) eliminates the mass transfer resistance related to diffusion into pore structures, thus allowing easy desorbability. At the same time, their high aspects ratios lead to large breakthrough volumes. As compared to a commercial sorbent Carbopack, the breakthrough volume was as much as an order of magnitude higher in the CNTs, while the rate of desorption measured as the peak width at half height of the desorption band was eight times lower. The trapping and desorption characteristics of single and multi walled nanotubes were found to be comparable. We also found that the presence of disordered carbon impurities, which could be removed by controlled oxidative annealing could greatly degrade the performance of CNTs.     

Carbon nanotubes: Potential uses in radionuclide concentration

The review of literature data related to the preparation, properties, and application of carbon nanotubes for sorption recovery of elements is given. Experimental data on the application of Taunit carbon nanofor radionuclide preconcentration from different solutions, as well as of Taunit-based solid-phase extractants for recovery of actinides and rare-earth elements from nitric acid solutions are presented.