Recent highlights in electro-driven separations- selected applications of alkylthiol gold nanoparticles in capillary electrophoresis and capillary electro-chromatography.

To date, alkylthiol gold nanoparticles (AuNPs) have been widely used in electro-chromatographic separation techniques as a viable alternative to traditional stationary phases. This is mainly due to their stability, chemical inertness, ease of functionality, increased phase ratio, ability to form self-assembled monolayers. They also yield versatile stationary phases with highly specific targeted functionalities. At the nanoscale region, the chemical and physical properties of a molecule display different attributes to that of the parent molecules or material, hence these features can be harnessed in electro-driven chromatographic separations. Application areas illustrating the use of AuNPs in separation science continue to grow and expand to cover many different kinds of analysis. The last decade has witnessed a successful trend in miniaturisation of chemical separation systems toward the micro and nanoscale ranges. Nanoparticle-based stationary phases fit well with performing chemical separations on microfluidic and capillary platforms. In this review the theory of the use of alkylthiol gold nanoparticles in electro-chromatographic driven separation methods will be discussed. This will be followed by details of recent and selected applications showing alkylthiol gold nanoparticles in capillary electrophoretic and open-tubular electro-chromatographic separations. This review will focus solely on alkylthiol based gold nanoparticles, therefore other kinds of chemical moieties bonded to gold nanoparticles are outside the scope of this review. Finally the future outlook of this exciting technology will be outlined in some detail in the final section.

Recent advances in miniaturization-the role of microchip electrophoresis in clinical analysis.

This review is a follow-up from the last review published in 2012 that covers the same topic [22]. Its aim is to cover new innovations and developments since then, involving the role of microchip capillary electrophoresis (MCE) in clinical analysis. MCE has shown great promise in separation science, as it's a state-of-the-art analytical separation technique that offers speed, portability, reduced sample, and reagent requirements, repeatability, can be used online or offline, and can be coupled with many kinds of analytical detectors. It is particularly important in clinical analysis, as it offers online continuous monitoring, can handle small volumes of highly complex biological samples due to its powerful discriminating ability, and it facilitates point-of-care testing. Also microchip separation platforms have been used for sample clean-up, filtration, derivatization, separation and detection, acting as multifunctional platforms ideal for minute sample volumes. In recent times the clinical world has witnessed a need for rapid turnaround times on analysis of very complex samples, and so there has been a shift toward point-of-care testing and other miniaturized analytical techniques as a favorable solution. Research developments in this area have been catalyzed by rapid strides in knowledge in the areas of proteomics, metabolomics, and molecular biology in the quest to understand the physiology of cells, proteins, genes, molecular interactions, and the pathophysiology of disease. Herein, we present selected examples detailing the use of MCE in some of the latest and most exciting clinical applications.

Recent advances in miniaturisation--the role of microchip electrophoresis in clinical analysis.

This review aims to highlight the current role of microchip CE (MCE) in clinical analysis to date, and also its future potential in this important area. One of the most notable advancements in separation science, which has accelerated in the last decade, has been the use of plastic and glass microchips to achieve high-speed electrophoresis separations in seconds, requiring only pico or nanolitre sample volumes. So far, in the clinical laboratory, MCE has lent itself to the resolution of very complex challenging analytes such as DNA, RNA, protein analysis, cellular components and other disease biomarkers. At present, most basic clinical laboratories rely heavily upon various kinds of enzymatic immunoassays as these methods offer speed, specificity, reliability and are well established analytical methods. However, this is not always the case, as with all analytical methods there are limitations, and sometimes enzymatic-based assays can be challenged by low-level concentration of target analytes present in samples resulting in high RSD values and results that cannot be interpreted. In some cases, this difficulty can be exasperated when complex sample matrices are presented for analysis, and interfering components result in highly exaggerated results from unwanted extra enzymatic binding. MCE may have a role in providing alternative highly sophisticated automated clinical analysis using state-of-the-art methodologies.

Histamine determination in human urine using sub-2 µm C18 column with fluorescence and mass spectrometric detection.

A fast, sensitive, and selective method for the determination of histamine in human urine samples by ultrahigh pressure liquid chromatography (LC) with fluorescence and mass spectrometry (MS) detection is investigated. A fluorescent reagent, 4-(1-pyrene) butyric acid N-hydroxysuccinimide ester was conjugated to the primary and secondary amino moieties of histamine. The structure of dipyrene-labeled histamine in human urine was determined by quadrupole time-of-flight MS with electospray ionization interface. The determination of the dipyrene derivative of histamine in urine samples was achieved within 3.9 min on an ultrahigh pressure LC Eclipse Zorbax XDB-C(18) column with 1.8 µm particle diameter. In this work, histamine separation was achieved significantly faster (3.9 min) with improved detection limit (signal-to-noise = 3) of 0.04 nM than 19.5 min with a detection limit of 0.183 nM as reported in a previous method.

Capillary and microchip electrophoresis in microdialysis: recent applications.

The theme of this review is to highlight the importance of microscale electrophoretic-based separation systems in microdialysis (microD). The ability of CE and MCE to yield very rapid and highly efficient separations using just nanolitre volumes of microdialysate samples will also be discussed. Recent advances in this area will be highlighted, by illustration of some exciting new applications while the need for further innovation will be covered. The first section briefly introduces the concept of microD sampling coupled with electrophoresis-based separation and the inherent advantages of this approach. The following section highlights some specific applications of CE separations in the detection of important biomarkers such as low-molecular-weight neurotransmitters, amino acids, and other molecules that are frequently encountered in microD. Various detection modes in CE are outlined and some of the advantages and drawbacks thereof are discussed. The last section introduces the concepts of micro-total analysis systems and the coupling of MCE and microD. Some of the latest innovations will be illustrated. The concluding section reflects on the future of this important chemical alliance between microD and CE/MCE.

Current separation and detection methods in microdialysis the drive towards sensitivity and speed.

This review outlines some of the analytical challenges associated with the analysis of microdialysis (MD) samples, in particular, the minute complex sample volumes that are often encountered. In MD sampling many different low-molecular-weight molecules can be collected, but the research findings are often limited by the sensitivity, specificity, and reliability of the analytical technique that is coupled to the dialysis probe. Therefore it is critical that a lot of consideration is given in selecting the most suitable analytical method including the most appropriate detector. This review aims to highlight the strengths and weaknesses of a range of commonly used analytical methods employed in MD. In Section 1, a brief overview of the MD technique is described, followed by a discussion on some of the advantages and drawbacks of this sampling technique. Sections 2 and 3 examine analytical and other technical considerations regarding analysis, with special emphasis on the factors that specifically influence analytical detection. Section 4 outlines the most commonly employed analytical techniques used in MD, including HPLC coupled with various detectors. Detail is given regarding the LOD and LOQ for many applications using each detector. As MS is of such high importance in MD, a special sub-section has been devoted to it. The importance of CE is also highlighted, with specific applications described. In addition, analytical techniques that do not appear to have found routine use in MD are discussed. Section 5 is concerned with recent innovations in chemical separation techniques, in particular MCE and ultra-performance liquid chromatography. Specific applications of the coupling of these techniques with MD are highlighted, along with technical challenges associated with miniaturization. In the Section 6, the future outlook of MD is discussed. Techniques other than electrophoretic- and chromatographic based separation methods are outside the scope of this review.

High-speed microchip electrophoresis method for the separation of (R,S)-naproxen.

In this research, a capillary electrophoretic method for the fast enantiomeric resolution of (R,S)-naproxen was investigated. Method development involved variation of applied potential, buffer concentration, buffer pH, and cyclodextrin concentration. The optimum electrophoretic separation conditions were 110 mM sodium acetate run buffer (pH 6.0), 30 mM methyl-beta-cyclodextrin, 20% (v/v) acetonitrile, 25 degrees C. The total length of capillary was 48 cm, (50 microm I.D.) with ultra violet (UV) detection at 232 nm. Using these conditions, the number of theoretical plates was close to one million (896,000/m). The possibility of achieving a fast chiral separation of (R,S)-naproxen on a microchip of 2.5 cm in length was investigated. Complete enantiomeric resolution of naproxen was achieved in less than 1 min, on this microchip platform, with linear imaging UV detection. This system had the advantage of real-time separation monitoring, so that enantiomeric resolution could be visually observed, and high-speed chiral analysis was realized. The microchip electrophoresis (MCE) separation was compared with the capillary electrophoresis (CE) separation with regards to speed, efficiency, separation platform, and precision. This work highlights the potential of CE and MCE in future chiral separations.

Rapid separation of antimicrobial metabolites by microchip electrophoresis with UV linear imaging detection.

This research examines microchip electrophoresis with linear imaging UV detection for the analysis of antimicrobial metabolites, monoacetylphloroglucinol (MAPG) and 2,4-diacetylphloroglucinol (2,4-DAPG) from Pseudomonas fluorescens F113. Initial results show the separation of MAPG, 2,4-DAPG and resorcinol in less than 20 s. This was achieved using a quartz microchip with a separation channel length of 25 mm. In order to quantitate the amount of MAPG and 2,4-DAPG in a microbial cultured supernatant sample, on-chip sample introduction in a methanol/buffer matrix was investigated. Sample introduction/injection parameters were optimized to improve sensitivity and thus decrease the limit of detection (LOD). The amount of antimicrobial metabolites present was quantitated with a separation time of 15 s. A previously developed capillary electrophoretic method was compared to the microchip method in relation to speed, efficiency, precision, linear range and limit of detection. This investigation shows the fastest separation so far of these antimicrobial metabolites with high efficiency.

Recent highlights in stationary phase design for open-tubular capillary electrochromatography.

This review examines the most recent innovations made to achieve high performance in open-tubular capillary electrochromatography (OT-CEC) separations, focusing on the ingenious chemical and physical solutions made to increase the surface area and equip the stationary phase with exploitable selectivity. Among the approaches taken are chemically bonded ligands, etching with chemical bonding, sol-gels, molecularly imprinted polymers, porous layers, physically attached or adsorbed phases, and nanoparticle coatings. Particularly noteworthy are modern developments with macrocyclic receptor ligands, nanoparticles and open channel electrochromatography on-chip.

Alkylthiol gold nanoparticles in open-tubular capillary electrochromatography.

Open-tubular columns for capillary electrochromatography (CEC) were formed by immobilising dodecanethiol gold nanoparticles on prederivatised 3-aminopropyl-trimethoxysilane (APTMS) or 3-mercaptopropyl-trimethoxysilane (MPTMS) fused-silica capillaries. The initial stage of this research involved the synthesis and characterisation of dodecanethiol gold nanoparticles, with tunnelling electron microscopy analysis of the dispersed phase of the gold nanoparticles dispersion in CHCl3, revealing spherical particles. The surface features of an Au-MPTMS coated capillary column were determined using scanning electron microscopy. The electroosmotic flow characteristics of Au-APTMS and Au-MPTMS capillary columns were then determined, by varying the pH and the voltage. The electrochromatographic properties of the gold nanoparticles CEC capillaries were investigated using a "reversed-phase" test mixture of thiourea, benzophenone and biphenyl and selected pyrethroid pesticides. Efficient separations of benzophenone and biphenyl solutes on Au-MPTMS and Au-APTMS capillary columns were obtained, as were linear plots of logarithm capacity factor versus % MeOH. A study of the reproducibility of retention for these solutes on Au-APTMS, Au-MPTMS and on a loosely coated capillary demonstrated the necessity of a coupling agent to prevent the gold nanoparticles from washing-off. These dodecanethiol gold capillary columns are easier to produce and operate than packed capillary columns. The research work confirms the use of gold nanoparticles as a novel phase for open-tubular CEC, demonstrating reproducible retention and characteristic reversed-phase behaviour.

Rapid quantification of histamine in human psoriatic plaques using microdialysis and ultra high performance liquid chromatography with fluorescence detection.

Psoriasis is a chronic skin disease resulting from abnormal immune function and is characterized by the presence of scaly psoriatic plaques which are areas of inflammation and excessive skin production. The psoriatic plaques contain mast cells which are increased in number in the uppermost dermis of the psoriatic lesion and which may play a role in the initiation and maintenance of the lesion. These processes are thought to be mediated via the local release of histamine along with other mediators from the mast cells; however their precise role still remains a mystery. Our study involved the development of a rapid and ultra-sensitive liquid chromatographic method for the separation and detection of histamine. To this end a state-of-the-art ultra high pressure liquid chromatography (UHPLC) system incorporating the latest technology in fluorescence detection system was employed which allowed for the rapid and reliable trace level detection of histamine in human derived microdialysate samples. This new reverse phase method utilized a sub-two-micron packed C(18) stationary phase (50 mm × 4.6 mm, 1.8 µm particle size) and a polar mobile phase of ACN:H(2)O:acetic acid (70:30:0.05) (v/v). The column temperature was maintained at (30±2°C), the injection volume was (8 µl), with a flow rate of (1.1 ml/min). Dermal microdialysis was used to collect (20 µl) samples from healthy, peri-lesional and lesional skin regions, in the forearms of a small cohort of subjects (n=6), and the ultra sensitive liquid chromatographic method allowed for nanomolar quantitation of histamine in 6.7 min. To date this represents one of the fastest reported separations of histamine using fluorescence detection with very high chromatographic efficiency (258,000/m) and peak symmetry of (0.88). Prior to sample analysis being performed method linearity, precision and limit of detection (LOD) were investigated. The results showed that intracutaneous histamine measured at 70 min after catheter implantation was (3.44±.52 nmol) (mean±SEM) in non-lesional (control) skin and was not dissimilar to that observed in either lesional (3.10±.76 nmol) or peri-lesional skin (2.24±.20 nmol). A second fraction collected 190 min after implantation also revealed similar levels with no difference in intracutaneous histamine observed between control (2.41±.56 nmol), lesional (2.69±.54 nmol), or peri-lesional skin (2.25±.50 nmol).

Rapid analysis of atorvastatin calcium using capillary electrophoresis and microchip electrophoresis.

In this work, a capillary electrophoretic method for the rapid quantitation of atorvastatin (AT) in a lipitor tablet was investigated and developed. Method development included studies of the effect of applied potential, buffer concentration, buffer pH, and hydrodynamic injection time on the electrophoretic separation. The method was validated with regard to linearity, precision, specificity, LOD, and LOQ. The optimum electrophoretic separation conditions were 25 mM sodium acetate buffer at pH 6, with a separation voltage of 25 kV using a 50 microm capillary of 33 cm total length. Sodium diclofenac was used as an internal standard. Analysis of AT in a commercial lipitor tablet by electrophoresis gave quite high efficiency, coupled with an analysis time of less than 1.2 min in comparison to LC. Once the separation was optimized on capillary, it was further miniaturized to a microchip platform, with linear imaging UV detection using microchip electrophoresis (MCE). Linear imaging UV detection allowed for real-time monitoring of the analyte movement on chip, so that the optimum separation time could be easily determined. This microchip electrophoretic method was compared to the CE method with regard to speed, efficiency, precision, and LOD. This work represents the most rapid and first reported analysis of AT using MCE.

Alkylthiol gold nanoparticles in sol-gel-based open tubular capillary electrochromatography.

A novel open-tubular capillary electrochromatography (OTCEC) column was prepared by immobilizing dodecanethiol gold nanoparticles on prederivatised fused-silica capillary columns with sol-gel technology. 3-Mercaptopropyl-trimethoxysilane (MPTMS) was selected as sol-gel precursor to develop a sol-gel layer on the inner wall of the capillary, prior to assembly of dodecanethiol gold nanoparticles onto the generated sol-gel layer through specific interaction between the gold nanoparticles and surface terminating thiol groups. The electrochromatographic behaviour of the sol-gel gold nanoparticle capillary was compared with a gold nanoparticle capillary prepared via MPTMS surface functionalisation, through variation of the percentage of the organic modifier, pH, and separation voltage. Efficient separation for a "reversed-phase" test mixture of thiourea, naphthalene, and biphenyl and for selected polycyclic aromatic hydrocarbons (PAHs) was obtained on the sol-gel based gold nanoparticle capillaries. OTCEC separations of three selected drug substances (propiophenone, benzoin, and warfarin) were also demonstrated. Scanning electron microscopy was used for the characterization of the sol-gel gold nanoparticle capillary surface. The results confirm that dodecanethiol gold nanoparticles, bound on the sol-gel-based inner layer of fused-silica capillary, can provide sufficient solute-bonded phase interactions for OTCEC with reproducible retention as well as characteristic reversed-phase behaviour.

Gold nanoparticle-modified etched capillaries for open-tubular capillary electrochromatography.

The use of gold nanoparticles in conjunction with etched capillary-based open-tubular capillary electrochromatography (OTCEC) to improve the efficiency of separation and the selectivity between selected solutes is described. The fused-silica capillaries (50-microm i.d.) were etched with ammonium hydrogen difluoride, followed by prederivatization of the new surface with (3-mercaptopropyl)trimethoxysilane (MPTMS) for the immobilization of dodecanethiol gold nanoparticles, for OTCEC. The electrochromatography of a "reversed-phase" test mixture and of selected polycylic aromatic hydrocarbons was investigated, and efficient separations and high theoretical plate numbers per meter were obtained. The electroosmotic flow characteristics of the etched gold nanoparticle capillary, unetched gold nanoparticle capillary, bare capillary, and etched bare capillary were studied by varying the percentage of organic modifier in buffer, buffer pH, and separation voltage. Optical microscopy and scanning electron microscopy were used to examine the process of etching and modification and the surface features of the etched gold nanoparticle capillary. The results confirm that dodecanethiol gold nanoparticles bonded on the etched inner wall of the fused-silica capillary can provide sufficient solute-bonded phase interactions to obtain OTCEC separations with reproducible retention, as well as characteristic reversed-phase behavior, even with the inner diameter of the capillary of 50 microm.

Rapid analysis of antimicrobial metabolites monoacetylphloroglucinol and 2,4-diacetylphloroglucinol using capillary zone electrophoresis.

A rapid capillary electrophoretic (CE) method was developed for the determination of phloroglucinol compounds, monoacetylphloroglucinol (MAPG) and 2,4-diacetylphloroglucinol (DAPG), in microbial supernatants of Pseudomonas fluorescens F113 over a 24-h growth cycle. Prior to electrophoretic separation, solid-phase extraction of supernatant samples on octadecylsilica for the purpose of sample cleanup is recommended. The optimum electrophoretic conditions were found to be 25 mM sodium tetraborate running buffer at pH 9.3, temperature at 25 degrees C with an applied voltage of 25 kV. The capillary was an Agilent fused-silica capillary of total length 33 cm x 50 microm inner diameter, 375 microm outer diameter, with effective length 24.5 cm. While MAPG and DAPG were monitored at selected wavelengths in the range of 214-320 nm, analysis at 214 nm was used and a CE separation time of less than 2 min was achieved. A partial method validation study was performed in accordance with European Agency for Evaluation of Medicinal Products (EMEA) guidelines. The method displayed linearity over the investigated range of 10-200 microg/mL, with limits of detection of 1.2 microg/mL for MAPG and 1.3 microg/mL for DAPG.