Determination of bromophos residues by fluorogenic labelling with dansyl chloride and thin-layer. Chromatography

The use of a highly sensitive and inexpensive method for determination of residues of bromophos (an organophosphate pesticide) in peanut crops, by fluorogenic labelling and thin-layer chromatography (TLC) is described. The bromophos is hydrolysed and the product 4-bromo-2,5-dichlorophenol (BDCP) dansylated with dansyl chloride. The fluorescent dansylated BDCP is separated by TLC and detected fluorimetrically. Linear fluorimetric analytical curves are obtained for bromophos weights ranging between 0.5 and 50 ng. The minimum detectable quantity is estimated to be 0.5 ng. The method can be used to recover as little as 400 ng of bromophos residue from 25 g of peanut seeds.     

Use of chromatographic paper as the preadsorption zone

A new type of plates for thin-layer chromatography (TLC) with a paper preadsorption layer is proposed. A method for the preparation of these TLC plates with a concentrating layer is described and their main Chromatographie characteristics are studied with an example of the separation of a test mixture of dyes. Chromatographic paper on glass and polymer plates is proposed as the preadsorption layer. The use of paper for obtaining the sample preadsorption zone drastically increases its volume and simplifies the introduction of a sample into the analytical system (analyzed spots of any shape can be applied) without impairing the efficiency of the process. The application range of TLC plates with flexible support is expanded because plates of this type with a concentrating layer have not been used before.     

TLC Determination of Aliphatic Polyamines on Calcium Sulfate Layers

Biogenic polyamines are sensitive markers for various diseases including cancer. Polyamines are difficult to analyze by chromatography due to their high polarity and water-solubility so that derivatization is an essential step for their chromatographic analysis. Earlier studies have shown the efficacy of calcium sulfate (CaSO₄) as a TLC coating material for the separation of polar compounds. The aim of this study was to explore the potential of CaSO₄ for the analysis of aliphatic polyamines without derivatization. The TLC of six polyamines (ornithine, citrulline, putrescine, cadaverine, spermidine and spermine) was carried out on CaSO₄ and silica gel plates using 11 different mobile phases. The results showed that CaSO₄ is superior to silica for the separation of underivatized polyamines. The development time of the CaSO₄ plates was also about one-third shorter as compared to silica. Methanol was the only solvent to produce differential R _F values for the polyamines studied. Ornithine (R _F , 0–2) and citrulline (R _F , 1–3) were separated from cadaverine (R _F , 0.93), spermine (R _F , 0.85) and spermidine (R _F , 0.85). For quantitative analysis, the polyamines were eluted from the coating material scratched from the plate and the absorbance of the supernatant was measured at 550 nm. The limits of detection (LOD) and quantification (LOQ) were found to be 0.75 and 1.88 μg, respectively. The procedure was applied to the quantitative separation of polyamines in spiked human urine samples (12.5–50 μg). This is probably the first study reporting a TLC method for the separation of underivatized polyamines.     

Application of pharmacia automated FPLC System and PepRPC HR 5/5 bonded phase column for determination of dansylated polyamines

Summary The Pharmacia Automatized FPLC System equipped with a PepRPC HR 5/5 bonded-phase column was tested with dansyl polyamines, toluene, dimethyl- and dibutylphthalate, using either isocratic conditions or linear gradient-elution program of methanol in water as the mobile phase. A simple and reproducible method is described for the quantiation of dansylated natural polyamines, such as putrescine, spermidine and spermine originating from P388/S leukemia cells. Comparing the data from analyses performed in parallel by the Automated FPLC/PepRPC HR 5/5, and a Hewlett-Packard Model 1084B/LiChrosorb RP-8 systems a linear correlation has been found, with a regression coefficient of r=0.974.     

Improved online coupling of planar chromatography with electrospray mass spectrometry: extraction of zones from glass plates

A plunger-based extraction device for HPTLC/MS coupling, which was originally designed for extraction on TLC aluminum foils, was enhanced. The threefold modifications enabled extraction of analytes from glass-backed HPTLC/TLC plates after separation. A buffering of the plunger reduced the occurrence of leakage. The involvement of a torque screwdriver for the fixation resulted in a reproducible contact pressure and avoided breaking the glass plates. The employment of this device was also extended to plates with a layer thickness of 100 μm by reducing the height of the plunger’s cutting edge. Repeatability of the extraction from glass-backed plates, linearity of the signal obtained, and detection capability were shown to be comparable to the original device, which was only usable with aluminum foils. The influence of the elution solvent on the intensity of the MS signal was demonstrated to be a compromise between high elution power of the solvent and good solubility of the analyte in the elution solvent. The extraction device was employed for plates from different lots and for plates with different stationary phases thereby proving its general applicability in planar chromatography.      

Simultaneous separation and quantitation of amino acids and polyamines of forest tree tissues and cell cultures within a single high-performance liquid chromatography run using dansyl derivatization

The objective of the present study was to develop a rapid HPLC method for simultaneous separation and quantitation of dansylated amino acids and common polyamines in the same matrix for analyzing forest tree tissues and cell cultures. The major modifications incorporated into this method as compared to previously published HPLC methods for separation of only dansyl amino acids include: use of a 10 cm column to reduce the total run time by approximately 15 min; modification of the dansyl derivatization process and gradient profile to elute amino acids and common polyamines within the same run; addition of steps for column cleaning within each run; shorter re-equilibration time; and finally, column cleaning and physically reversing the column at the end of a loop of samples. These changes improved peak resolution and increased column longevity by several-fold. Over 1000 foliar samples from mature forest trees could be analyzed with the same column as compared to only 200-250 samples before the incorporation of these changes. This method eluted 22 amino acids within 40 min plus all three common polyamines between 44 and 47 min. The total run time is 53.6 min for amino acids only and 55.6 min for both amino acids and polyamines.     

A simple method for the visualization of the separated zones of sugars on silica-gel TLC plates without spray reagent

A simple procedure of visualization of the separated zones of sugars on silica gel TLC plates without spray reagent is described. The plate is placed into a glass chamber filled with n-hexane. The separated sugars are then seen as opaque zones.     

Ultrathin-Layer Chromatography (UTLC)

Ultrathin-layer chromatography (UTLC) differs from high-performance thin-layer chromatography (HPTLC) and from thin-layer chromatography (TLC) in two basis things: the layer thickness, and the migration distances of the analytes. UTLC has a monolithic or a nanostructured stationary silica gel phase bound directly to the glass plates. Layer thickness in UTLC is 10 μm, instead of 100–250 μm in HPTLC. Migration distances are in the range of 1–3 cm for UTLC, instead of 8–10 cm for HPTLC. Therefore, the major advantages of UTLC over HPTLC and TLC are the shorter development times and higher separation efficiency and sensitivity. Moreover, separations on UTLC plates require smaller reagent and sample volumes. However, the UTLC plates are very difficult to manage with the TLC and HPTLC equipment currently available. Therefore, the next challenge in this area is the development of an inexpensive solution with appropriate instrumentation (sensitive optical scanners and sample application systems). UTLC had been used for separations of many compounds, e.g., pharmaceutically active ingredients, pesticides, plasticisers, natural products, and other chemical substances.     

Thin Layer Chromatography-Laser Mass Spectrometry (TLC-LMS) of Triphenylmethane Dyes: Initial Results

Abstract

Laser mass spectra (LMS) of triphenylmethane dyes were obtained directly from a thin layer chromatographic (TLC) plate using the LAMMA-1000 laser microprobe. Spectra obtained from TLC plates were very similar to those obtained from standard substrates, the only difference being that at threshold power densities spectra from the TLC plates show greater fragmentation. The region below m/z 100 is mostly obscured by peaks due to the chromatographic support; above this range, peaks can be identified corresponding to the molecular cation and simple neutral losses. The inherent lateral rèsolution of the Instrument (～5 μm) was used to resolve multiple components in broad chromatographic spots. The TLC-LMS combination has the advantage that components can be identified even if they are not completely resolved chromatographically.     

Hydroxylation of the silica in microfabricated thin layer chromatography plates as probed by time‐of‐flight secondary ion mass spectrometry and diffuse reflectance infrared Fourier transform spectroscopy

Microfabricated silica thin layer chromatography (TLC) plates have previously been prepared on patterned carbon nanotube forests. The high temperatures used in their fabrication reduce the number of hydroxyl groups on their surfaces. Fortunately, silica can be rehydroxylated. In diffuse reflectance infrared Fourier transform spectroscopy (DRIFT), a silanol peak below 3740 cm^?1 indicates a well‐hydroxylated silica surface that is fit for chromatography. Hydroxylations of our materials with HF are so effective that it is not possible to discern the position of this peak. In contrast, this signal is discernable when the plates are treated with NH₄OH. To find a more convenient method for studying the surfaces of TLC plates, time‐of‐flight secondary ion mass spectroscopy (ToF‐SIMS) was considered. ToF‐SIMS is advantageous because multiple microfabricated TLC plates must be scraped to obtain enough silica for one DRIFT analysis, while static SIMS can be performed on very small regions (500 × 500 µm² or less) of individual plates. Ratios of the SiOH⁺ and Si⁺ ToF‐SIMS signals for microfabricated TLC plates correlated well with ~3740 cm^?1 silanol peaks from DRIFT. Thus, SIMS allows direct analysis of all of our treated and untreated plates, including those hydroxylated with HF. The best hydroxylation condition for HF, which was better than any studied for NH₄OH, was around 150 ppm at room temperature. The best hydroxylation condition for NH₄OH was 50 °C for 72 h. ToF‐SIMS versus DRIFT results of commercial TLC plates were also obtained and evaluated. Copyright © 2014 John Wiley & Sons, Ltd.     

Use of High Pressure Liquid Chromatography and Thin Layer Chromatography for the Separation and Detection of Testosterone and its Metabolites from in vitro Incubation Mixtures

Abstract

Testosterone and its 6β-, 7α-, and 16α-hydroxylated metabolites were resolved by high pressure liquid chromatography and thin layer chromatography. Separation by HPLC was achieved in less than 45 min on a microparticulate silica gel column using isocratic elution with isopro-panol:tetrahydrofuran:hexane (5:15:80) as the mobile phase. TLC systems utilizing silica gel on glass and plastic plates, and polysilicic acid on glass fiber sheets are presented. The monohydroxylated metabolites of testosterone formed during incubation of (¹⁴C)-testosterone with liver postmitochondrial preparations from adult male rats pre-treated with phenobarbital or Aroclor 1254 were separated and quantitated by both HPLC and TLC. The results using both techniques are compared with those obtained by paper chromatography.     

A review of advances in two-dimensional thin-layer chromatography

Although there are many simple thin-layer chromatography (TLC) separations, many more are complex and involve more than a few components, that means having to use special high-performance TLC (HPTLC) plates or microspotting or banding devices to increase its resolving power if developing in only one direction. However, adding a second development to perform two-dimensional TLC (2D TLC) allows even better resolution of complex samples. This is because different modes of chromatography are being invoked by the use of one stationary phase with two mobile phases, bilayer plates, graft TLC, or multidimensional TLC. This paper is a review of recent applications that have benefitted from using 2D TLC in its various forms. They were chosen for their variety of sample types as well as the unique choices of plates and/or mobile phases made by the researchers to yield improved separations.     

New TLC/HPTLC commercially prepared and laboratory prepared plates: A review

Thin-layer chromatography (TLC) had its initial growth in the 1950s when TLC sorbents and devices for making TLC plates in the analytical laboratory became available. A resurgence in TLC use occurred when commercially prepared plates became available around 1965. Their advantage was greater reproducibility because of their uniformity and convenience of use. Having just passed the 50th anniversary of this date, TLC still finds wide application as a useful analytical tool throughout the world. The introduction of high-performance TLC (HPTLC)-prepared plates was also a welcome addition to the chromatography laboratory. Today, advances in TLC instrumentation that aid in sample application, plate development, qualification, and quantification continue to evolve and improve. The TLC/HPTLC plate manufacturers have continued to add new prepared plates to meet the greater demands for higher purity or special applications for these newer devices. More recently, researchers have experimented with new sorbents or preparation techniques that have resulted in special properties for thin-layer-prepared plates, particularly for use in TLC–MS applications. This article will discuss not only some classical TLC plates but also these newer thin layers, their advantages, and some of their applications.     

Thin layer chromatography/mass spectrometry

Thin layer chromatography (TLC)--a simple, cost-effective, and easy-to-operate planar chromatographic technique--has been used in general chemistry laboratories for several decades to routinely separate chemical and biochemical compounds. Traditionally, chemical and optical methods are employed to visualize the analyte spots on the TLC plate. Because direct identification and structural characterization of the analytes on the TLC plate through these methods are not possible, there has been long-held interest in the development of interfaces that allow TLC to be combined with mass spectrometry (MS)--one of the most efficient analytical tools for structural elucidation. So far, many different TLC-MS techniques have been reported in the literature; some are commercially available. According to differences in their operational processes, the existing TLC-MS systems can be classified into two categories: (i) indirect mass spectrometric analyses, performed by scraping, extracting, purifying, and concentrating the analyte from the TLC plate and then directing it into the mass spectrometer's ion source for further analysis; (ii) direct mass spectrometric analyses, where the analyte on the TLC plate is characterized directly through mass spectrometry without the need for scraping, extraction, or concentration processes. Conventionally, direct TLC-MS analysis is performed under vacuum, but the development of ambient mass spectrometry has allowed analytes on TLC plates to be characterized under atmospheric pressure. Thus, TLC-MS techniques can also be classified into two other categories according to the working environment of the ion source: vacuum-based TLC-MS or ambient TLC-MS. This review article describes the state of the art of TLC-MS techniques used for indirect and direct characterization of analytes on the surfaces of TLC plates.     

Polyamine distribution in the rat intestinal mucosa

As the first step in a study of mucosal polyamine metabolism during intestinal adaptation, we have measured mucosal polyamine concentrations at different sites along the normal rat intestine. Putrescine, spermidine, spermine and cadaverine were measured by spectrofluorometric analysis after thin-layer chromatography of their dansylated derivatives. Spermidine was present in the largest amounts at each of the sampling sites. The ratio of the concentration of spermidine to that of spermine paralleled the established pattern of cellular proliferation in the normal intestine as did the putrescine concentration (nmol per 10 cm) which decreased from duodenum to colon. These results provide the essential background to an assessment of the role of polyamines in the intestinal adaptive response.     

Separation behavior of electron-beam curing derived, acrylate-based monoliths

Electron beam (EB) curing-derived monolith materials were prepared from ethyl methacrylate (EMA), trimethylolpropane triacrylate (TMPTA), 2-propanol, 1-dodecanol, and toluene within the confines of 3 mmx100 mm id glass columns, applying a total dose of 22 kGy for curing. Monolithic columns were checked for their separation behavior for selected dansylated (DNS)-amino acids as well as for cyclophilin 18. Their separation performance was compared to that of a C18-modified silica-based rigid rod (Chromoliths). In the separation of dansylated amino acids, retention times were reduced on EB-derived columns, where the peak resolution was significantly better than on a Chromolith. This finding was attributed to a larger fraction of small pores (<2.15 nm) in the EB curing-derived monoliths. Finally, EB curing-derived monoliths have been used to separate cyclophilin 18 from crude cell lysis mixtures.     

Characterization of chemically bonded phases on precoated thin-layer plates by29Si and13C cross-polarization and magig-angle spinning NMR

Summary The paper reports results for commercial precoated plates and home-made bonded phases for TLC examined by²⁹Si and¹³C NMR of solid samples. The NMR spectra readily reveal differences in degree of silylation, details pertaining to the type of reactive silanes used, and differences in the methods of synthesis. They can also be used to explain the cause of the wettability problems encountered with some types of (precoated) TLC plates.     

Thin-layer chromatographic determination of aldehydes encountered in foods as dimethones, octahydroxantheines and barbiturates

Aldehydes in foods can conveniently be characterized and determined by thin-layer chromatography (TLC) after converting them into their dimethones. For further confirmation the dimethones can be cyclized on the TLC plates or in solution to give octahydroxanthenes. Aldehydes also can be determined as their barbiturates. The aldehydes could be determined as dimethones and octahydroxanthenes in amounts up to 5 micrograms and as barbiturates in amounts up to 7.5 micrograms at their UV maxima.     

Sensitive determination of aliphatic amines in water by high-performance liquid chromatography with chemiluminescence detection

A sensitive method has been developed for liquid chromatographic determination of short aliphatic amines in water samples. Analytes are preconcentrated and dansylated on solid sorbents (C18 solid-phase extraction cartridges). The dansyl derivatives are chromatographed and post-column mixed with peroxyoxalate (TCPO) and H2O2 in order to perform chemiluminescence detection. Optimal results have been obtained using a sample volume of 5 ml. The method has been applied to the quantification or screening of several aliphatic amines: methylamine, ethylamine, butylamine, diethylamine, pentylamine and hexylamine. The screening procedure has been developed including also polyamines (putrescine, cadaverine, spermidine and spermine). The results obtained by using chemiluminescence (CL) detection have been compared with other detection systems (fluorescence and UV). The sensitivity can increase from 3 to 75 times respect UV detection and from 2 to 10 times respect fluorescence detection depending on the amine. The detection limits achieved were between 0.15 and 0.9 microg/l.     

Two-Dimensional Planar Chromatography with a Closed Adsorbent Layer

A new two-dimensional chromatography process on closed plates is proposed. A previously described device with ethanol as a mobile phase is used to experimentally study two-dimensional thin-layer chromatography (2D TLC) on plates with 5 × 5 and 10 × 10 cm sizes. This work includes the experimental study and comparison of the following TLC versions: (1) the proposed 2D TLC version with a closed adsorbent layer with 1D separation on closed plates (an ascending mobile phase flow) and (2) conventional 2D TLC with an open adsorbent layer. The ascending version of 2D TLC with a closed adsorbent layer considerably (byR~55%) shortens the chromatographic time, especially with the use of 5 × 5 cm plates in the 2D separation version compared with the 1D version on 10 × 10 cm plates.