An overview of recent advances in HPLC instrumentation

This review highlights the fundamentals and the most prominent advances in the field of HPLC instrumentation over the last decades. Fundamental aspects and practical considerations of column switching, conventional (heart-cut) and comprehensive two-dimensional LC are presented. Different aspects of microcolumn- and nanoliquid-chromatography are reviewed. Recent progress in column technology and the demands and developments in instrumentation and accessories for miniaturized LC are also discussed. In the field of miniaturization, particularly in chip-based nano-LC systems, some aspects on micro-fluidic chip fabrication, using particle-packed HPLC microchips or polymer-based monoliths, are addressed. An introduction to ultra performance LC (UPLC) is also presented.     

Strategies for in vivo imaging of enzyme activity: an overview and recent advances

Imaging of enzyme activity in living subjects promises many applications in both basic and translational researches from helping elucidate the enzyme function and mechanism in biology to better disease detection and monitoring, but the complexity and dynamics of enzymatic reactions in living systems present unique challenges for probe design. This critical review examines the approaches in recent literature to in vivo imaging of the activity of a variety of enzyme targets with an emphasis on the chemical perspective of probe design, structure and function. Strategies for designing enzyme-activated probes based on a variety of molecular scaffolds including small molecules, organic and inorganic nanoparticles, and genetically encoded proteins for commonly used molecular imaging modalities--whole body optical (fluorescence, bioluminescence) imaging, magnetic resonance imaging, and radionuclide-based tomographic imaging, are critically evaluated. Recent advances in combining multiple modalities to imaging enzyme activity in living subjects are also highlighted (255 references).     

Recent trends and advances in microbial electrochemical sensing technologies: An overview

Microbial electrochemical systems utilize the electrochemical interaction between microorganisms and electrode surfaces to convert chemical energy into electrical energy, offering a promise as technologies for wastewater treatment, bioremediation, and biofuel production. Recently, growing research attention has been devoted to the development of microbial electrochemical sensrs as biosensing platforms. Microbial electrochemical sensors are a type of microbial electrochemical technology (MET) capable of sensing through the anodic or the cathodic electroactive microorganisms and/or biofilms. Herein, we review and summarize the recent advances in the design of microbial electrochemical sensing approaches with a specific overview and discussion of anodic and cathodic microbial electrochemical sensor devices, highlighting both the advantages and disadvantages. Particular emphasis is given on the current trends and strategies in the design of low-cost, convenient, efficient, and high performing METs with different biosensing applications, including toxicity monitoring, pathogen detection, corrosion monitoring, as well as measurements of biological oxygen demand, chemical oxygen demand, and dissolved oxygen. The conclusion provides perspectives and an outlook to understand the shortcomings in the design, development status, and sensing applications of microbial electrochemical platforms. Namely, we discuss key challenges that limit the practical implementation of METs for sensing purposes and deliberate potential solutions, necessary developments, and improvements in the field.     

Recycling of waste from polymer materials: An overview of the recent works

Polymer recycling is a way to reduce environmental problems caused by polymeric waste accumulation generated from day-to-day applications of polymer materials such packaging and construction. The recycling of polymeric waste helps to conserve natural resource because the most of polymer materials are made from oil and gas. This paper reviews the recent progress on recycling of polymeric waste form some traditional polymers and their systems (blends and composites) such as polyethylene (PE), polypropylene (PP), and polystyrene (PS), and introduces the mechanical and chemical recycling concepts. In addition, the effect of mechanical recycling on properties including the mechanical, thermal, rheological and processing properties of the recycled materials is highlighted in the present paper.     

An overview of recent progress in multiple dual-mode counter-current chromatography

Counter-current chromatography is a chromatographic separation and purification technique being developed. The development of different elution modes has significantly contributed to this field. Multiple dual-mode elution is a method developed based on dual-mode elution, which consists of a series of changing cycles of the phase role and the direction by switching between normal and reverse elution modes of counter-current chromatography. This dual-mode elution method takes full advantage of the liquid nature of stationary and mobile phases of counter-current chromatography and effectively improves the separation efficiency. So, this unique elution mode has gained extensive attention for separating complex samples. This review mainly describes and summarizes in detail its development, applications, and characteristics in recent years. Meanwhile, its advantages, limitations, and future outlook also have been discussed in this paper.     

Electron-capture mass spectrometry: recent advances

Electron-capture (EC) is a sensitive and selective ionization technique for mass spectrometry (MS). In the most familiar form of EC, a susceptible analyte (electrophore) is detected after eluting from a gas chromatography (GC) column, where a low attomole detection limit for standards is routine. High-performance liquid chromatography can facilitate sample cleanup prior to detection by GC-EC-MS, but carryover and shifts in retention time for the "invisible" analyte can be difficulties. Solid-phase extraction avoids these difficulties, but the degree of cleanup and recovery can be problems. Alternative electrophoric derivatizing reagents are available to help deal with interferences, and new reagents such as "AMACE1" are emerging. Releasable forms of electrophores can be used as tags for labeling macromolecules, motivated by the desire to multiplex ligand-type assays. The conventional, gas-phase ion source for EC is not well-understood, especially the role of wall reactions. Using an electron monochromator to tune the electron energy adds to the selectivity and information provided by EC-MS. High-resolution and tandem EC-MS measurements are emerging. Electron-capture dissociation is a new technique to sequence small- to medium-sized peptides, having the advantage of providing more extensive sequence information relative to other MS techniques. Particle-beam EC-MS tends to be less sensitive than GC-EC-MS, but not always. Recently it was demonstrated that EC-MS can be accomplished on an ordinary laser desorption time-of-flight mass spectrometer, and also by using atmospheric pressure chemical ionization. Two applications are discussed here in detail: bile acids and oxidized phenylalanine. EC-MS is well-established as a useful technique for trace analysis in special cases, and the scope of its usefulness is broadening (qualitative analysis and detection of more polar and larger molecules), based on advances in both the chemical and instrumental aspects of this technique.     

Triphenylene-based discotic liquid crystals: recent advances

Since the early work of Chandrasekhar and his co-workers on hexaesters of benzene published in 1977, discotic liquid crystals (DLCs), in particular, triphenylene-based DLC materials have been investigated intensively, especially over the last decade. The first successful commercialisation of triphenylene-based DLCs has been accomplished in Fuji ‘Wide-View’ optical compensation films. DLCs represent a broad well understood class of soft matter which possess the ability to self-organise into highly anisotropic and ordered structures such as columns that function not only as organic anisotropic semiconductors, but also contribute to the development of new smart materials in the field of organic electronics for many device applications such as photovoltaic devices, light-emitting diodes, field-effect transistors, memory elements, and sensors. Over the last 35 years, more than 1000 triphenylene derivatives have been synthesised and investigated starting from structure-properties to structure-device performance relationships. The very first review by Cammidge and Bushby followed by Kumar summarised the chemistry and physical properties of triphenylene-based discotics up to 2003. In this review, progress in the research of triphenylene DLC materials since 2004 is comprehensively outlined.     

Application of NMR to fossil fuels: an assessment of recent advances

Summary Recent applications of high resolution solution- and solid-state NMR techniques to fossil fuels and their derivatives are assessed with emphasis on the quantification of aromatic, aliphatic and heteroatomic groups. ¹³C NMR spectral editing methods that generate C, CH, CH₂ and CH₃ sub-spectra for soluble materials are reasonably quantitative. Two-dimensional methods aid peak assignments in ¹H and ¹³C NMR analysis of distillates. There are few reports on the investigation of heteroatom environments by ¹⁷O, ¹⁴N, ¹⁵N and ³³S NMR, but derivatisation with groups containing a convenient magnetic label (¹H, ¹³C, ¹⁹F and ²⁹Si) has proved successful for estimating acidic OH, NH and SH concentrations in coal-derived liquids and petroleum residues. Solid-state ¹³C NMR analysis of coals and related materials is often only semi-quantitative because not all the carbon is observed using cross-polarisation.

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Anwendung der NMR auf fossile Brennstoffe: Bewertung neuerer Fortschritte

Zusammenfassung Neuere Anwendungen von hochauflösenden Lösungs- und Festkörper-NMR-Techniken auf fossile Brennstoffe und ihre Derivate werden vorgestellt mit der Betonung auf Quantifizierung der aromatischen, aliphatischen und heteroaromatischen Gruppen. Methoden der Editierung von ¹³C-NMR-Spektren, die separate Spektren für C, CH, CH₂ und CH₃-Gruppen liefern, sind bei löslichen Materialien ausreichend quantitativ. Zweidimensionale Methoden helfen bei der Signalzuordnung der ¹H- und ¹³C-NMR-Spektren von Destillaten. Zwar liegen einige Berichte über Untersuchungen von Heteroatomumgebungen mit ¹⁷O-, ¹⁴N-, ¹⁵N- und ³³S-NMR vor, doch hat sich die Derivatisierung mit Gruppen, die einen empfindlicheren Kern als Meßsonde besitzen (¹H, ¹³C, ¹⁰F, ²⁹Si), als erfolgreich zur Abschätzung der Konzentration acider OH-, NH- und SH-Gruppen in aus Kohle entstandenen Flüssigkeiten und in Erdölrückständen erwiesen. Die Analyse von Kohle und ähnlichen Materialien mit Hilfe der Festkörper-¹³C-NMR-Spektroskopie ist oft nur halbquantitativ, da nicht alle Kohlenstoffatome mit der Cross-Polarisations-Technik beobachtet werden.

     

Photocatalysis: an overview of recent developments and technological advancements

Photocatalysis,which is the catalyzation of redox reactions via the use of energy obtained from light sources,is a topic that has garnered a lot of attention in recent years as a means of addressing the environmental and economic issues plaguing society today.Of particular interest are photosynthesis can potentially mimic a variety of vital reactions,many of which hold the key to develop sustainable energy economy.In light of this,many of the technological and procedural advancements that have recently occurred in the field are discussed in this review,namely those linked to:(1)photocatalysts made from metal oxides,nitride,and sulfides;(2)photocatalysis via polymeric carbon nitride(PCN);and(3)general advances and mechanistic insights related to TiO2-based catalysts.The challenges and opportunities that have arisen over the past few years are discussed in detail.Basic concepts and experimental procedures which could be useful for eventually overcoming the problems associated with photocatalysis are presented herein.     

An overview on the recent developments in reactive plasticizers in polymers

This review is about the reactive plasticizer. Plasticizers are small molecules with low molecular weight. These compounds typically have an esteric structure. The plasticizers reduce the glass transition temperature, and the viscosity of the polymer also enhances the flexibility and processability of polymer materials. The main problem of these additives is that, over time, they migrate from the polymeric matrix and exude to the surface of polymeric matrix. As a result, the physical and mechanical properties of the polymer are affected. Various strategies, such as increasing molecular weight of plasticizer, selection of oligomeric structure for plasticizer, and adding nanoparticles of minerals, have been investigated to reduce and eliminate migration. An approach that has recently been of great interest to researchers is the use of reactive plasticizers. In this approach, plasticizers covalently bond to the polymeric chains and prevent migration.     

Aluminum chelation principles and recent advances

Acute Al toxicity is not common. Toxicity from prolonged Al exposure has become much less common, but still occurs occasionally. The potential contribution of Al to Alzheimer's disease and related disorders is not resolved. Diagnosis of Al accumulation and treatment of Al toxicity can be achieved with chelators. The biology and chemistry of Al relevant to its chelation are reviewed. The approaches that have been used to assess potential Al chelators are summarized. The chemistry of desferrioxamine and the hydroxypyridinones in relation to Al chelation and the results of the more recent studies with these agents are reviewed. There is very little clinical experience with the hydroxypyridinones as Al chelators. The results of chemical and animal studies suggest they have potential to replace desferrioxamine, as orally effective Al chelators. However, adverse effects associated with the use of 1,2-dimethyl-3,4-hydroxypyridinone (deferiprone) dampen enthusiasm for the hydroxypyridinones as Al chelators. The uses of Al chelators to enhance Al removal, concentration, detection and speciation are reviewed. The role of Al chelators in the environment and their production by plants to reduce Al toxicity is summarized.     

An overview of some recent developments in ionization methods for mass spectrometry

An overview of some recent advances in ionization sources for mass spectrometry is presented. Limitations were set so that the overview covers ionization techniques relevant to organic and biological analysis that have appeared in the literature since the year 2000. No effort is made to be comprehensive. Rather, a broad sweep overview of author-subjective highlights among a wide variety of sources is presented. These ionization sources include electron ionization, chemical ionization, various atmospheric plasma ionization sources, laser desorption sources, sonic spray and electrospray ionization sources.     

Measurement of endogenous estrogens: analytical challenges and recent advances

Recent developments in the analysis of endogenous estrogens (including both free and conjugated estrogens) are reviewed. Largely due to urging by some cancer researchers, new demands are now being placed on such measurements in terms of sensitivity, throughput, multi-analyte detection and accuracy. Especially high sensitivity is required for detecting estrogens in serum from postmenopausal women, children and men, where concentrations at the low pg/ml level are encountered, and one would prefer to test much less than 1 ml of serum. Aside from throughput, meeting all of these demands may be beyond the reach of immunoassay, the method that has created and continues to dominate this field. Both HPLC and GC versions of mass spectrometry are emerging that have some potential to improve the testing of physiological samples for endogenous estrogens. The following topics are covered in this review: related analyses (e.g. detection of estrogens in environmental samples such as water, where 1-l samples can be collected to provide ng amounts of estrogens); structure and metabolism of estrogens; biological actions (with an emphasis on their role in cancer); immunoassays; HPLC with electrochemical detection; GC-ECD; and various forms of mass spectrometry.     

Theranostic radionuclides: recent advances in production methodologies

Journal of Radioanalytical and Nuclear Chemistry - Various concepts involved in the quantification of radiation dose while following the theranostic approach in nuclear medicine are outlined. The...     

Extraction and stirring integrated techniques: examples and recent advances

Extraction techniques, which focus on selectivity and sensitivity enhancement by isolation and preconcentration of target analytes, are essential in many analytical methods. Because many extraction techniques occur under diffusion-controlled conditions, stirring of the sample solution is required to accelerate the extraction by favoring diffusion of the analytes from the bulk solution to the extractant phase. This stirring may be performed by use of an external device or by integrating extraction and stirring in the same device. This review focuses on the latter techniques, which are promising methods for sample treatment. First, stir-bar-sorptive extraction, the most widely used method, is considered, paying special attention to the development of new coatings. Finally, a general overview of novel integrated techniques in both solid-phase and liquid-phase microextraction is presented; their main characteristics and marked trends are reported.