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Previous studies of the hyphenation of gas chromatographic separation and spectrophotometric detection in the ultraviolet wavelength range between 168 and 330 nm showed a high potential for applications where the analysis of complex samples is required. Within this paper the development of a state-of-the-art detection system for compounds in the vapour phase is described, offering an improved behaviour compared to previous systems: Dependent on the requirements of established detection systems hyphenated with gas chromatography, the main components of the system have to be designed for optimum performance and reliability of the spectrophotometric detector: A deuterium lamp as a broadband light source has been selected for improved stability in the measurements. A new-type absorption cell based on fiber-optics has been developed considering the dynamic necessary to compete with existing techniques. In addition, the influence of the volume of the cell on the chromatogram needs to be analyzed. Tests for determining the performance of the absorption cell in terms of chemical and thermal influences have been carried out. A new spectrophotometer with adequate spectral resolution in the wavelength range, offering improved stability and dynamic for an efficient use in this application was developed. Furthermore, the influence of each component on the performance, reliability and stability of the sensor system will be discussed. An overview and outlook over the potential applications in the environmental, scientific and medical field will be given.
In thin-layer chromatography, fiber-bundle arrays have been introduced for spectral absorption measurements in the UV-region. Using all-silica fiber bundles, the exciting light will be detected after re-emission on the plate with a fiberoptic spectrometer. In addition, fluorescence light can be detected which will be masked by the re-emitted light. Therefore, it is helpful to separate the absorption and fluorescence on the TLC-plate. A modified three-array assembly has been developed: using one array for detection, the two others are used for excitation with broadband band deuterium-light and with UV-LEDs adjusted to the substances under test. As an example, the quantification of glucosamine in nutritional supplements or spinach leaf extract will be described. Using simply heating of the amino-plate for derivation, the reaction product of Glucosamine can be detected sensitively either by light absorption or by fluorescence, using the new fiber-optic assembly. In addition, the properties of the new 3-row fiber-optic array and the commercially available UV-LEDs will be shown, in the interesting wavelength region for excitation of fluorescence, from 260 nm to 360 nm. The squint angle having an influence on coupling efficiency and spatial resolution will be measured with the inverse farfield method. Some properties of UV-LEDs for analytical applications will be described and discussed, too.
The main focus of this chapter is the theoretical and instrumental processes that underpin densitometric methods widely used in thin-layer chromatography (TLC). Densitometric methods include UV–vis, luminescence and fluorescence optical measurements as well as infrared and Raman spectroscopic measurements. The chapter is divided in two general parts: a theoretical part and a practical part. The systems for direct radioactivity measurements and the combination of TLC with mass spectrometry are also discussed. All these systems allow measuring an intensity distribution directly on a TLC plate. We call this “in situ detection” because no analyte is removed from the plate.
The main focus of this chapter is the theoretical and instrumental processes that underpin densitometric methods widely used in thin-layer chromatography (TLC). Densitometric methods include UV–vis, luminescence, and fluorescence optical measurements as well as infrared and Raman spectroscopic measurements. The chapter is divided in two general parts: a theoretical part and a practical part. The systems for direct radioactivity measurements and the combination of TLC with mass spectrometry are also discussed. All these systems allow measuring an intensity distribution directly on a TLC plate. We call this “in situ detection” because no analyte is removed from the plate.
Die quantitative Dünnschichtchromatographie (HPTLC) mit einem Graustufen-Handscanner ist eine preiswerte, schnelle und präzise Methode zur Schwermetallbestimmung. Als Alternative zu teuren Densitometern wird ein Grünlichtscanner mit einer Auflösung von 256 Graustufen benutzt. Die Ortsauflösung beträgt maximal 400 dpi (dots per inch). Die Chromatogramme werden mit 300 dpi aufgenommen. Zur Entwicklung wird eine Camag-Linearkammer verwendet. Zur Probenvorbereitung werden die zu bestimmenden Schwermetallionen bei pH 4,2 mit Dithizon komplexiert. Nur die Metallkationen Zn(2+), Co(2+), Hg(2+), Cd(2+) und Ni(2+) reagieren zu einem farbigen Metallkomplex, wobei sich Zn(2+)- und Co(2+)-Komplexe chromatographisch abtrennen lassen. Nach Komplexierung der Wasserprobe wird mit Essigsäureethylester ausgeschüttelt, Probe- und Standardlösung auf eine Platte aus Kieselgel SI-60 aufgetragen, mit Essigsäureethylester fokussiert und nach der Trocknung der Platte mit Toluol entwickelt. Die HPTLC-Platte wird mit scannereigener Software eingelesen und im PCX-Format (PC PaintBrusch der Fa. ZSoft) auf die Festplatte abgelegt. Zur Auswertung wird eine Leseroutine benutzt. Die ganze Chromatographiebahn ist mit 150 Einzeldioden aufgenommen, die eine Strecke von 48 mm in 564 Einzelmessungen auflösen. Die Summe aller 150 Einzelaufnahmen liefert das Densitogramm aus dem der Schwermetallgehalt bestimmt wird.
Eine einfache Bestimmung von Mineraloel-KWstoffen - Ersatz des FCKW-haltigen Extraktionsmittels
(1996)
Die Messung von KWstoffen in Abwaessern nach DIN ist eine in der Umweltanalytik haeufig geforderte Bestimmung. Die Abwasserprobe wird dabei mit 1,1,2-Trichlortrifluorethan extrahiert. Anschliessend wird der Extrakt mittels IR-Spektroskopie vermessen. Neben einigen Schwaechen ist bei dieser Bestimmungsmethode besonders die Verwendung des ozonschaedigenden FCKW-Loesemittels heute nicht mehr zeitgemaess. - Die Verf. beschreiben ein schnelles robustes Bestimmungsverfahren, das alle Schwaechen der alten Methode vermeidet.
Nativ-organische Abfälle bilden mit ca. 30 Gew. % den Hauptteil des Hausmülls. Daher leistet die Bioabfallkompostierung einen bedeutenden Schritt hin zu einer sinnvollen Abfallverwertung. Bundesweit werden derzeit jährlich etwa 750 000 t Bioabfallkompost erzeugt. Mit Ausnahme von sieben Land- und Stadtkreisen planen die Landkreise Baden-Württembergs die getrennte Sammlung von Bioabfällen: Einwohner von 23 Landkreisen waren 1993, zum Teil versuchsweise, an Biotonnen angeschlossen. Die Notwendigkeit der Bioabfallkompostierung scheint außer Frage zu stehen, intensiv erörtert werden jedoch die Verfahrenskonzepte, die der Bioabfallkompostierung zugrunde liegen. Kern der Diskussion ist, ob einfache Kompostierungsverfahren wie die dezentrale Kompostierung den technisch aufwendigeren Verfahren zentraler Anlagen gleichwertig sind.
Als erster Landkreis in Baden Württemberg hat der Landkreis Sigmaringen bei der Entsorgung des bei 120 000 Einwohnern im Kreis anfallenden organischen Abfalls neue Wege beschritten und die Landwirtschaft in den Stoffkreislauf miteinbezogen, anstatt das anfallende Material zu deponieren. Auf dem Hintergrund der TA-Siedlungsabfall, die vorschreibt, daß nach einer Übergangszeit organische Abfälle nicht mehr deponiert werden dürfen, sondern kompostiert oder thermisch behandelt werden müssen, hat der Landkreis Sigmaringen im Jahr 1992 ein Konzept zur dezentralen Kompostierung verabschiedet.
High performance thin layer chromatography (HPTLC) is a frequently used separation technique which works well for quantification of caffeine and quinine in beverages. Competing separation techniques, e.g. high-performance liquid chromatography (HPLC) or gas chromatography (GC), are not suitable for sugar-containing samples, because these methods need special pretreatment by the analyst. In HPTLC, however, it is possible to separate ‘dirty’ samples without time-consuming pretreatment, because disposable HPTLC plates are used. A convenient method for quantification of caffeine and quinine in beverages, without sample pretreatment, is presented below. The basic theory of in-situ quantification in HPTLC by use of remitted light is introduced and discussed. Several linearization models are discussed.
A home-made diode-array scanner has been used for quantification; this, for the first time, enables simultaneous measurements at different wavelengths. The new scanner also enables fluorescence evaluation without further equipment. Simultaneous recording at different wavelengths improves the accuracy and reliability of HPTLC analysis. These aspects result in substantial improvement of in-situ quantitative densitometric analysis and enable quantification of compounds in beverages.
A new diode-array scanner in combination with a computer-controlled application system meets all the demands of modern HPTLC measurement. Automatic application, simultaneous measurements at different wavelengths, and different linearization models enable appropriate evaluation of all analytical questions. The theory of error propagation recommends quantification at reflectance values smaller than 0.8; this can be verified only by use of diode-array scanning. The same theory also recommends quantification by use of peak height data, because the theory predicts best precision only for peak height evaluation. Diode-array scanning with reflectance monitoring enables appropriate validation in TLC and HPTLC analysis. All these aspects result in substantial improvement of in-situ quantitative densitometric analysis, and simultaneous recording at different wavelengths opens the way for chemometric evaluation, e.g. peak purity monitoring, which improves the accuracy and reliability of HPTLC analysis.
Fluorescence Enhancement of Pyrene Measured by Thin-Layer Chromatography with Diode-Array Detection
(2003)
In-situ densitometry for qualitative or quantitative purposes is a key step in thin-layer chromatography. It offers a simple way of quantifying by measuring the optical density of the separated spots directly on the plate. A new TLC scanner has been developed which is able to measure TLC plates or HPTLC plates, at different wavelengths simultaneously, without destroying the plate surface. The system enables absorbance and fluorescence measurements in one run. Fluorescence measurements are possible without filters or other adjustments.
The measurement of fluorescence from a TLC plate is a versatile means of making TLC analysis more sensitive. Fluorescence measurements with the new scanner are possible without filters or special lamps. Improvement of the signal-to-noise ratio is achieved by wavelength bundling. During plate scanning the scattered light and the fluorescence are both emitted from the surface of the TLC plate and this emitted light provides the desired spectral information from substances on the TLC plate. The measurement of fluorescence spectra and absorbance spectra directly from a TLC plate is based on differential measurement of light emerging from sample-free and sample-containing zones.
The literature recommends dipping TLC plates in viscous liquids to enhance fluorescence. Measurement of the fluorescence and absorbance spectra of pyrene spots reveals the mechanism of enhancement of plate dipping in viscous liquids—blocked contact of the fluorescent molecules with the stationary phase or other sample molecules is responsible for the enhanced fluorescence at lower concentrations.
In conclusion, dipping in TLC analysis is no miracle. It is based on similar mechanisms observable in liquids. The measured TLC spectra are also very similar to liquid spectra and this makes TLC spec-troscopy an important tool in separation analysis.
A new formula is presented for transforming fluorescence measurements in accordance with Kubelka-Munk theory. The fluorescence signals, the absorption signals, and data from a selected reference are combined in one expression. Only diode-array techniques can measure all the required data simultaneously to linearize fluorescence data correctly. To prove the new theory HPTLC quantification of the analgesic flupirtine was performed over the mass range 300 to 5000 ng per spot. The fluorescence calibration curve was linear over the whole range. The transformation of fluorescence measurements into linear mass-dependent data extends the technique of in-situ fluorescence analysis to the high concentration range. It also extends Kubelka-Munk theory from absorption to fluorescence analysis. The results presented also emphasize the importance of Kubelka-Munk theory for in-situ measurements in scattering media, especially in planar chromatography.
We will present the first example of a two-dimensional scanned TLC-plate, measured by use of a diode-array scanner. A spatial resolution of 250 µm was achieved on plate. The system provides real 2D fluorescence and absorption spectra in the wavelength-range from 190 to 1000 nm with a spectral resolution of greater than 1 nm. A mixture of 12 sulphonamides was separated by using a cyanopropyl-coated silica gel plate (Merck, 1.16464) with the solvent mix of methyl tert-butyl ether-methanol-dichloromethane-cyclohexane-NH3 (25%) (48:2:2:1:1, v/v) in the first and with a mixture of water-acetonitrile-dioxane-ethanol (8:2:1:1, v/v) in the second direction. Both developments were carried out over a distance of 70 mm. A separation number (spot capacity) of 259 was calculated. We discussed a new formula for its calculation in 2D-TLC separations. The drawback of this method is that measuring a 2D-TLC plate needs more than 3 h measurement time.
Vorgestellt wird die Dioden-Array-Dünnschichtchromatographie als eine moderne und preiswerte Messmethode zur densitometrischen Erfassung von Substanzen auf einer DC- oder einer HPTLC-Platte. Sicher identifizierbar sind auch Substanzen mit schwachem Chromophor. Die Kubelka-Munk-Gleichung beschreibt einen linearen Zusammenhang zwischen Remissionslicht und lichtabsorbierender Stoffmenge auf der Platte. Die Auswertung im Spektralbereich von 316 bis 334 nm zeigt den Zusammenhang zwischen transformiertem Messsignal und aufgetragener Substanzmasse. Die schnelle Aufnahme von UV/vis-Spektren eröffnet der HPTLC den gesamten Bereich der Methodenvalidierung auf dem Niveau, auf welchem heute die HPLC-Analytik durchgeführt wird.
Editorial
(2022)
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