Thin–layer Chromatography (TLC) Analytical Toxicology - Thin–layer Chromatography (TLC) | 1 Thin–layer chromatography (TLC) is a widely used technique for the separation and identification of drugs. It is equally applicable to drugs in their pure state, to those extracted from pharmaceutical formulations, to illicitly manufactured materials and to biological samples. TLC as we know it today (see Fig 1) was established in the 1950s with the introduction of standardised procedures that lead to improved separation performance and reproducibility, and paved the way for its commercialisation and an increase in the number of published applications. The 1970s saw the introduction of fine–particle layers and associated instrumentation required for their correct use. In this form, TLC became known as high–performance TLC, instrumental TLC or modern TLC to distinguish it from its parent, now generally referred to as conventional TLC. High–performance TLC has not displaced conventional TLC from laboratory studies and the two approaches coexist today because of their complementary features (Table 1). Conventional TLC provides a quick, inexpensive and portable method for qualitative analysis. It requires minimal and readily available instrumentation and uses easily learned experimental techniques. High–performance TLC is characterised by the use of kinetically optimised layers for faster and more efficient separations, takes advantage of a wider range of sorbent chemistries to optimise selectivity and requires the use of instrumentation for convenient (automated) sample application, development and detection. High–performance TLC provides accurate and precise quantitative results based on in situ measurements and a record of the separation in the form of a chromatogram, such as the example in Fig 2. While all modern laboratories are capable of drug analysis by conventional TLC, only those laboratories equipped with the necessary instrumentation for high–performance TLC have this option.
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Thin–layer chromatography (TLC) is a widely used technique for the separation andidentification of drugs. It is equally applicable to drugs in their pure state, to thoseextracted from pharmaceutical formulations, to illicitly manufactured materials and tobiological samples. TLC as we know it today (see Fig 1) was established in the 1950s withthe introduction of standardised procedures that lead to improved separation performanceand reproducibility, and paved the way for its commercialisation and an increase in thenumber of published applications. The 1970s saw the introduction of fine–particle layers andassociated instrumentation required for their correct use. In this form, TLC became knownas high–performance TLC, instrumental TLC or modern TLC to distinguish it from its parent,now generally referred to as conventional TLC. High–performance TLC has not displacedconventional TLC from laboratory studies and the two approaches coexist today because oftheir complementary features (Table 1). Conventional TLC provides a quick, inexpensive andportable method for qualitative analysis. It requires minimal and readily availableinstrumentation and uses easily learned experimental techniques. High–performance TLC ischaracterised by the use of kinetically optimised layers for faster and more efficientseparations, takes advantage of a wider range of sorbent chemistries to optimise selectivityand requires the use of instrumentation for convenient (automated) sample application,development and detection. High–performance TLC provides accurate and precisequantitative results based on in situ measurements and a record of the separation in theform of a chromatogram, such as the example in Fig 2. While all modern laboratories arecapable of drug analysis by conventional TLC, only those laboratories equipped with thenecessary instrumentation for high–performance TLC have this option.
Time for development (capillary flow) (min) 3–20 20–200
Detection limitsa Absorption (ng) 0.1–0.5 1–5
Detection limits Fluorescence (pg) 5–10 50–100
Nominal particle size range (μm) 3–7 5–20
Apparent particle size (μm)b 5–7 8–10
Minimum plate height (μm) 22–25 35–45
Optimum velocity (mm/s) 0.3–0.5 0.2–0.5
Porosity Total 0.65–0.70 0.65–0.75
Porosity Interparticle 0.35–0.45 0.35–0.45
Porosity Intraparticle 0.28 0.28
Table 1. Characteristic properties of silica gel precoated TLC layers
a For drugs with favourable detection properties. b Determined by chromatographicmeasurements. Precoated TLC layers are prepared from silica gel with a narrower particlesize range than typical bulk materials available for self–made layers.
Figure 2. Separation of ethynyl steroids (birth–control pillcomponents) by high–performance TLC. Two 15 mindevelopments with the mobile phase hexane–chloroform–carbontetrachloride–ethanol (7:18:22:1) on a silica gel 60high–performance TLC plate. Chromatogram was recorded byscanning densitometry at 220 nm.In the basic TLC experiment, the sample is applied to the layer as a spot or band near to thebottom edge of the layer. The separation is carried out in a closed chamber by eithercontacting the bottom edge of the layer with the mobile phase, which advances through thelayer by capillary forces, or the mobile phase is forced to move through the layer at acontrolled velocity by an external pressure source or centrifugal force. A separation of thesample results from the different rates of migration of the sample components in thedirection travelled by the mobile phase. After development and evaporation of the mobilephase, the sample components are separated in space, their position and quantity beingdetermined by visual evaluation or in situ scanning densitometry aided by the formation ofeasily detected derivatives by post–chromatographic chemical reactions, as required.
Separations by column liquid chromatography (HPLC) and TLC occur by essentially thesame physical process. The two techniques are frequently considered as competitors, whenit would be more realistic to consider them as complementary. The attributes of TLC thatprovide for its co–existence as a complementary technique to HPLC are summarised inTable 2. Based on these attributes, TLC methods are most effective for the low–cost analysisof a large number of samples (e.g. drug screening in biological fluids and tissues,determination of the botanical origin and potency of traditional herbal medicines, stabilitytesting and content uniformity testing), for the rapid analysis of samples that requireminimum sample clean up or where TLC allows a reduction in the number of samplepreparation steps (e.g. analysis of samples containing components that remain sorbed to thestationary phase or contain suspended microparticles). TLC is also preferred for the analysisof substances with poor detection characteristics that require post–chromatographicchemical treatment for detection. In other cases, HPLC methods are generally preferred,particularly if a large number of theoretical plates are necessary for a separation, forseparations by size–exclusion and ion–exchange chromatography, and for trace analysisusing selective detectors unavailable for TLC.
Attribute Application
Separation of samples in parallelLow–cost analysis and high–throughputscreening of samples requiring minimalsample preparation
Disposable stationary phase Analysis of crude samples (minimisingsample preparation requirements)
Analysis of a single or small number ofsamples when their composition and/or matrixproperties are unknown
Analysis of samples containing componentsthat remain sorbed to the separation mediumor contain suspended microparticles
Static detectionSamples that requirepost–chromatographic treatment fordetection
Samples that require sequential detectiontechniques (free of time constraints) foridentification or confirmation
10.25 Diuretics10.26 Drugs of abuse10.27 Ergot alkaloids10.28 Ergot alkaloids10.29 Narcotic analgesics and narcotic antagonists10.30 Oral hypoglycemics and antidiabetics10.31 Pesticides10.32 Phenothiazines and other tranquilisers10.33 Psychomimetics and sympathomimetics10.34 Quaternary ammonium compounds10.35 Steroids10.36 Sulfonamides10.37 Vitamins10.38 Xanthine stimulants
Stationary phases
Conventional TLC plates can be prepared in the laboratory by standardised methods, butreproducible layer preparation is easier to achieve in a manufacturing setting and fewlaboratories prepare their own plates today. Precoated plates for high performance,conventional and preparative TLC are available in a range of sizes and different layerthickness, supported on glass, aluminium or plastic backing sheets. To impart the desiredmechanical stability and abrasion resistance to the layer a binder, such as poly(vinylalcohol), poly(vinyl pyrrolidone), gypsum or starch in amounts from 0.1 to 10% (w/w) isincorporated into the layer. An ultraviolet (UV)-indicator, such as manganese–activated zincsilicate of a similar particle size to the sorbent, may be added to the layer to visualiseseparated samples by fluorescence quenching. TLC plates with a narrow preadsorbent zonelocated along one edge of the layer are available to aid manual sample application.
Silica gel is the most important stationary phase for TLC, with other inorganic oxideadsorbents, such as alumina, kieselguhr (a silica gel of low surface area) and Florisil (asynthetic magnesium silicate), of minor importance. Most silica gel sorbents have an
average pore size of 6 nm and are designed for the separation of small molecules (relativemolecular mass < 700). The chromatographic properties of the inorganic oxide adsorbentsdepend on their surface chemistry and specific surface area. For silica gel, silanol groupsare the dominant adsorption sites. The complementary sample properties that governretention are the number and type of functional groups and their spatial location (Fig 3).The influence of functional group properties on selectivity is illustrated in Fig 2 for theseparation of ethynyl steroids. The steroids with phenolic groups are the most stronglyretained, followed by hydroxyl groups, and then ketone and ester groups. Subtle separationdifferences through steric hindrance at a functional group and differences in ringconformations are also seen, which allow the separation of steroids with very similarchemical properties.
Figure 3. General adsorption scale forseparations by silica gel TLC.
Chemically bonded layers are prepared from silica gel by reaction with various organosilanereagents to form siloxane bonds, with some of the silanol groups present on the silicasurface (Table 3). Reversed–phase alkylsiloxane–bonded layers with a high level of surfacebonding cannot be used with mobile phases that contain a significant amount of water(>30% v/v) because of the inadequate mobile–phase velocity generated by capillary forces.Water compatibility for alkylsiloxane–bonded layers is achieved by increasing the particlesize, using a reproducible although lower degree of silanisation, and by using modifiedbinders. These layers are referred to as water wettable and are used for all types ofreversed–phase separations, while layers with a high degree of silanisation are usedpredominantly with non–aqueous mobile phases. Alkylsiloxane bonded phases are usedprimarily (but not exclusively) for the separation of water–soluble polar drugs and weakacids and bases after ion suppression (buffered mobile phase) or ion–pair formation. Watercompatibility is not a problem for polar chemically bonded phases, which can be used for
both normal- and reversed–phase separations. For separations that cannot be achieved onsilica gel, the polar chemically bonded phases are the most widely used stationary phases.The 3–aminopropylsiloxane–bonded layers can function as a weak anion exchanger for theseparation of polyanions with a buffered mobile phase. Cellulose layers provide only weakretention of common drug substances and are used primarily to separate very polarcompounds in biochemistry.
Table 27.3.: Clarke’s Analysis of Drugs and Poisons
Type of modification Functional group Applicationa
Alkylsiloxane Si–CH3For reversed phase separations generally,but not exclusively
Si–C2H5Separation of water–soluble polar organiccompounds (RPC)
Si–C8H17Weak acids and bases after ion suppression(RPC)
Si–C18H37Strong acids and bases by ion–pairmechanism (RPC)
Phenylsiloxane Si–C6H5 Of limited use for drug analysis
Cyanopropylsiloxane Si–(CH2)3CN Useful for both RPC and NPC
In NPC it exhibits properties similar to alow–capacity silica gel.
In RPC it exhibits properties similar toshort–chain alkylsiloxane–bonded layers (ithas no selectivity for dipole–typeinteractions)
Aminopropylsiloxane Si–(CH2)3NH2Used mainly in NPC and IEC; limitedretention in RPC
Type of modification Functional group Applicationa
Selectively retains compounds byhydrogen–bond interactions in NPC;separation order generally different to thatin silica gel
Functions as a weak anion exchanger inacidic mobile phases (IEC)
Spacer bondedpropanediol
Si–(CH2)3OCH2 Si-CH(OH)CH2OH
Used in NPC and RPC, but more useful forNPC because of low retention in RPC
Polar drugs selectively retained byhydrogen bond and dipole–typeinteractions in NPC; more hydrogen–bondacidic and less hydrogen–bond basic thanaminopropylsiloxane–bonded layers inNPC; more retentive thanaminopropylsiloxane–bonded layers in RPC
Similar retention to short–chainalkylsiloxane–bonded layers, but differentselectivity for hydrogen–bonding drugs
Table 3. Retention properties of silica based chemically bonded layers
TLC has found limited use for the separation of enantiomers. The most widely usedapproach employs ligand–exchange chromatography on reversed–phase layers impregnatedwith a solution of copper acetate and (2S,4R,2RS)-N-(2–hydroxydodecyl)-4–hydroxyproline.Separations result from stability differences in diastereomeric complexes formed betweenthe drug, copper and the proline selector. Suitable drugs for this application require anamino acid or α-hydroxycarboxylic acid group for complex formation. A more versatileapproach to the separation of enantiomeric drug substances by reversed–phase TLC is theuse of chiral selectors, such as cyclodextrins or bovine serum albumin, as mobile–phaseadditives.
The technique of TLC involves a number of separate steps, namely preparing the layer,applying the sample, developing the plate and detecting the separated zones. These stepsare described below.
Layer pretreatments
Prior to chromatography it is common practice to prepare the layers for use by any or all ofthe following steps: washing, conditioning and equilibration. Layers may also be cut topreferred sizes using scissors for plastic- or aluminium–backed plates and diamond orcarbide glass–cutting tools for glass–backed plates. Newly consigned precoated layers areinvariably contaminated, or quickly become so, because of residual contaminants from themanufacturing process, contact with packaging materials and adsorption of materials fromthe atmosphere. To remove contaminants, single or double immersion in a polar solvent,such as methanol or propan–2–ol, for about 5 min is generally superior to predevelopmentwith the mobile phase. For trace analysis, sequential immersion and predevelopment maybe required to obtain the best results.
For inorganic oxide adsorbents the absolute RF (see later) value and the reproducibility of RF
values depend on the layer activity. The latter is controlled by the adsorption of reagents,most notably water, through the gas phase. Physically adsorbed water can be removed fromsilica gel layers by heating at about 120° for 30 min. Afterwards, the plates are stored in agrease–free desiccator over blue silica gel. Heat activation is not normally required forchemically bonded layers. Equilibration of activated layers by exposure to the atmosphere isextremely rapid and layer activation is at times an unnecessary step. In modernair–conditioned laboratories, layers achieve a consistent level of activity that should providesufficient reproducibility for most separations. Inorganic oxide layers can be adjusted to adefined activity by exposure to a defined gas phase in an enclosed chamber. Sincemanipulation in the atmosphere almost certainly readjusts this activity, it is best performedafter application of the sample zones in a developing chamber that allows both layerconditioning and development in the same chamber (e.g. a twin–trough chamber), or in aseparate conditioning chamber immediately before development. Atmospheres of differentconstant relative humidity can be obtained by using solutions of concentrated sulfuric acidor saturated solutions of various salts. Acid or base deactivation can be carried out in asimilar manner by exposure to, for example, ammonia or hydrochloric acid fumes.
Drugs are applied to TLC plates as spots or bands of minimum size with a homogeneousdistribution of material within the starting zone. For high–performance layers, withdesirable starting spot diameters of about 1.0 to 2.0 mm, this corresponds to a samplevolume of 100 to 200 nL if applied by a dosimeter (micropipette). For conventional TLCplates, sample volumes five- to ten–fold greater are acceptable. Desirable properties of thesample solution are summarised in Table 4. If scanning densitometry is used for detection,manual sample application with hand–held devices is inadequate. For densitometry, thestarting position of each spot must be known accurately, which is achieved easily withmechanical devices that operate to a precise grid mechanism. Also, the sample must beapplied to the layer without disturbing the surface, something that is nearly impossible toachieve using manual application.
Sample application devices for TLC encompass a wide range of sophistication andautomation. The most popular devices for quantitative TLC use the spray–on technique. Acontrolled nitrogen–atomiser sprays the sample from a syringe or capillary, to form narrow,homogeneous bands on the plate surface. The plate is moved back and forth under theatomiser on a translational stage to apply bands of any length between zero (spots) and themaximum transit length of the spray head. Bands are typically 0.5 or 1.0 cm in length, withthe longer bands used primarily for preparative–scale separations. The rate of sampledeposition is also adjustable to accommodate sample solutions of different volatility andviscosity. An advantage of spray–on devices is that different volumes of a single standardsolution can be applied for calibration purposes and the standard addition method ofquantification is carried out easily by overspraying the sample already applied to the layerwith a solution of the standard. Fully automated sample applicators can be programmed toselect samples from a rack of vials and deposit fixed volumes of the sample, at a controlledrate, to selected positions on the plate. The applicator automatically rinses itself betweensample applications and can spot or band a whole plate with different samples andstandards without operator intervention.
Glass microcapillaries for conventional TLC and fixed–volume dosimeters (which consist of a100 or 200 nL platinum–iridium capillary sealed into a glass–support capillary) forhigh–performance TLC are also commonly used for sample application and require lesssophisticated instrumentation. The capillary tip is brought into contact with the platesurface using a mechanical device to discharge its volume. A click–stop grid mechanism isused to provide an even spacing of the samples on the layer and a frame of reference forsample location during scanning densitometry.
Layers with a preadsorbent zone (a narrow zone prepared from a silica gel of low surfacearea with weak retention) simplify some aspects of sample application. This allows relativelylarge sample volumes or dirty samples to be applied to the preadsorption zone and theirreconcentration to a narrow band at the interface between the preadsorbent and separationzones by a short development prior to chromatography. However, since the distribution ofthe sample may not be even within the band, the quantitative accuracy of densitometricmeasurements may be lowered using this approach.
Development
The principal development techniques in TLC are linear, circular and anticircular, with thevelocity of the mobile phase controlled by capillary forces or forced–flow conditions. In anyof these modes continuous or multiple development can be used to extend the applicationrange. Radial development is used rarely for drug analysis and is not considered further.Forced–flow development requires sophisticated equipment not commonly found inanalytical laboratories, and is not described here.
For linear (or normal) development, samples are applied along one edge of the plate and theseparation developed for a fixed distance in the direction of the opposite edge. Viewed inthe direction of development, the chromatogram consists of a series of compact symmetricalspots of increasing diameter or, if samples are applied as bands, in rectangular zones ofincreasing width.
In continuous development the mobile phase is allowed to traverse the layer under theinfluence of capillary forces until it reaches some predetermined position on the plate, atwhich point it is evaporated continuously. Evaporation of the mobile phase usually occurs atthe plate atmospheric boundary using either natural or forced evaporation. Continuousdevelopment is used primarily to separate simple mixtures with a short development lengthand a weaker (more selective solvent) than employed for normal development.
In unidimensional multiple development, the TLC plate is developed for some selecteddistance, then either the layer or the mobile phase is withdrawn from the developingchamber, and adsorbed solvent evaporated from the layer before repeating the developmentprocess. The principal methods of unidimensional multiple development are summarised inTable 5. Multiple development provides a very versatile strategy for separating complexmixtures, since the primary experimental variables of development distance andcomposition of the mobile phase can be changed at any development step, and the number
of steps varied to obtain the desired separation. Multiple development provides a higherresolution of complex mixtures than does normal or continuous development, can easilyhandle samples of a wide polarity range (stepwise gradient development) and, because theseparated zones are usually more compact, leads to lower detection limits. Equipment forautomated multiple development is commercially available.
For drug mixtures that span a wide retention range, some form of gradient development isrequired to separate all the components in either a single chromatogram or in separatechromatograms for successive developments. Continuous solvent–composition gradients, ascommonly employed in HPLC, are used rarely in TLC. These require experimentalconditions that are less convenient than those for step mobile–phase gradients. In addition,step gradients can be constructed easily to mimic a continuous linear gradient, with theadded advantage that the zone refocusing effect can be employed to minimise zonebroadening. Gradients of increasing solvent strength are used to fractionate complexmixtures by separating just a few components in each step. Individual drugs are usuallyidentified and quantified at the intermediate steps at which the drugs of interest areseparated. In this way, the zone capacity can be made much larger than predicted for acomplete separation recorded as a single chromatogram. However, this approach is tediouswhen many components are of interest and it is difficult to automate. Alternatively, ifincremental multiple development is used, the sample can be separated for the shortestdistance in the strongest mobile phase, with each subsequent, longer development usingmobile phases of decreasing solvent strength. This strategy is most useful when the finalseparation is to be recorded as a single chromatogram, but it is limited in zone capacitybecause all the components must be located between the sample origin and the final solventfront. The two approaches for exploiting solvent–strength gradients are thus complementaryand selection is made based on the properties of the sample. The decreasingsolvent–strength gradient approach is the operating basis of automatedmultiple–development chambers.
In two–dimensional TLC the sample is spotted at the corner of the layer and developedalong one edge of the plate. The solvent is then evaporated, the plate rotated through 90°and redeveloped in the orthogonal direction. If the same solvent is used for bothdevelopments, the sample is redistributed along a line from the corner at which the platewas spotted to the corner diagonally opposite. In this case, only a small increase inresolution can be anticipated. The realisation of a more efficient separation system impliesthat the resolved sample should be distributed over the entire plate surface. This can beachieved only if the selectivity of the separation mechanism is complementary in theorthogonal directions. Using two solvent systems with complementary selectivity is the
simplest approach to implement in practice, but it is often only partially successful. In manycases the two solvent systems differ only in their intensity for a given set of properties andare not truly orthogonal. Chemically bonded layers can be used in the reversed–phase andnormal–phase modes, and they enable the use of additives and buffers as a further way toadjust selectivity. The acceptance of two–dimensional TLC for quantitative analysis, though,will depend on providing a convenient method for in situ detection and data analysis. Itseems unlikely that two–dimensional development will be more widely used in TLC, exceptfor qualitative analysis, until the problems of detection are solved.
Development chambers
The development process in TLC can be carried out in a variety of vessels that differsignificantly in design and sophistication. For convenience these are often categorisedunder the headings of normal (N-chamber) and sandwich (S-chamber), and furthersubdivided according to whether the internal atmosphere is saturated (NS or SS) orunsaturated (NU or SU). Sandwich chambers have a depth of gas phase in front of the layerof less than 3 mm, with other chamber designs indicated as normal chambers. Saturation ofthe vapour phase is achieved by using solvent–saturated pads or filter papers as a chamberlining.
The twin–trough chamber is the most popular of the simplest TLC developing chambers. Itconsists of a standard rectangular developing tank with a raised, wedge–shaped bottom. Thewedged bottom divides the tank into two compartments, so that it is possible to eitherdevelop two plates simultaneously or to use one compartment to condition the layer prior todevelopment. The horizontal developing chamber (Fig 4) can be used in either the normal orsandwich configuration for either conventional edge–to–edge or simultaneousedge–to–centre development. Starting the development simultaneously from opposite edgesallows the number of samples separated to be doubled in the same time. The sandwichconfiguration of the horizontal developing chamber is not suitable for mobile phases thatcontain volatile acids, bases or large amounts of volatile polar solvents, such as methanol oracetonitrile, because of the restricted access of the saturated vapour phase to the dryportion of the separation layer.
The automated developing chamber increases laboratory productivity and improves thereproducibility of separations by providing precise control of layer conditioning,mobile–phase composition, solvent–front migration distance and drying conditions. Thischamber can be used in the normal or sandwich configuration with all the operational
features preselected on a microprocessor–based control unit and monitored by sensortechnology.
The automated multiple–development chamber (Fig 5) provides the necessary conditionsand control for automated separations by incremental multiple development with adecreasing solvent–strength gradient. The operating parameters of layer conditioning,solvent–front migration distance, mobile–phase composition and drying time for eachdevelopment, and the total number of developments for the separation, are entered into thecomputer–based control unit. The complete separation sequence is carried out withoutfurther intervention. Each development is typically 3 to 5 mm longer than the previous oneand, depending on the complexity of the desired mobile phase gradient, a total of 10 to 30developments are used, which requires 1.5 to 4.5 h for completion.
Detection
About 1 to 10 μg of coloured substances with a quantitative reproducibility rarely betterthan 10–30% can be detected by visual inspection of a TLC plate. This may be adequate forqualitative methods, but for reliable quantification in situ spectrophotometric methods arepreferred, as they are more accurate and far less tedious and time consuming than excisingzones from the layer for determination by conventional solution spectrophotometry. Thefluorescence–quenching technique enables visualisation of UV-absorbing drugs on TLCplates that incorporate a fluorescent indicator. The zones of UV-absorbing substance appeardark against the brightly fluorescing background of a lighter colour when the plate isexposed to UV light of short wavelength. The method is not universal, since it requiresoverlap between the absorption bands of the indicator (γmax ≈ 280 nm with virtually noabsorption below 240 nm) and the drug, but in favourable cases it is a valuable andnon–destructive method for zone location.
All optical methods for the quantitative in situ evaluation of TLC chromatograms are basedupon measuring the difference in optical response between a sample–free region of thelayer and regions of the layer in which separated substances are present. Reflectancemeasurements can be made at any wavelength from the UV to the near infrared (185 to2500 nm). The relationship between signal and sample amount in the absorption mode isnon–linear, and does not conform to any simple equation. The principal method ofquantification in TLC is by calibration using a series of standards that span theconcentration range of the drug to be determined. The calibration curve is usually based ona second–order polynomial fit for the calibration standards, with individual samples
The determination of drugs that fluoresce on TLC plates is fundamentally different toabsorption measurements. At low sample concentrations the fluorescence signal F isdescribed adequately by F = φI0εbC, where φ is the quantum yield, I0 the intensity of theexcitation source, ε the molar absorption coefficient, b the thickness of the TLC layer and Cthe sample amount. With the exception of the sample amount all terms in this expressionare constant, or fixed by the experiment, and therefore the fluorescence emission is linearlydependent on the sample amount over two or three orders of magnitude.
Derivatisation reactions
There is a long history of the use of derivatisation reactions in TLC to visualise colourlesscompounds. Many of these reactions are of a qualitative nature, which was not a problemwhen TLC was used rarely for quantification. Some of these reactions have been adapted tothe demands of quantitative scanning densitometry, as either pre- or post–chromatographictreatments, and new reagents and methods have been added specifically for quantitativemeasurements in TLC.
In post–chromatographic reactions the reagents can be applied to the layer through the gasphase or by evenly coating the layer with a solution of the reagents. Gas–phase methods arefast and convenient, but restricted by the number of useful reagents. Examples includeiodine, ammonia and hydrogen chloride, which are applied by inserting the layer into a tankthat contains a saturated atmosphere of the reactive vapour. Spraying or dipping are usedto apply reagents in solution to the layer. Spray techniques that use simple atomisers havelong been used in TLC, but reagent application by this method is quite difficult to performwell. The homogeneity of the reagent distribution over the layer depends on many factors,such as the droplet size, distance between the spray device and layer, direction of sprayingand discharge rate of the reagent. If ventilation of the workspace is inadequate, spraytechniques can be a potential health hazard. For quantitative analysis, immersion of thelayer into a solution of the reagents in a controlled manner, referred to as dipping, is thepreferred technique, since it does not rely on manual dexterity and produces superiorresults in scanning densitometry. Some spray reagents do not make good dipping solutionsbecause they contain solvents that are too aggressive or viscous for convenient application(aqueous concentrated acids and bases, for example). Dipping solutions are usually lessconcentrated than spray reagents and water is often replaced by an alcohol for adequatepermeation of reversed–phase layers. In general, it is necessary to reformulate dippingsolutions from earlier recipes for spray solutions and, possibly, to change the reaction
conditions. Automated low–volume dipping chambers provide a uniform speed and dwelltime for the immersion process, which typically requires only a few seconds, and is longenough to impregnate the layer with solution, but not long enough to wash samplecomponents off the layer.
Post–chromatographic derivatisation reactions can be classified as reversible or destructive,depending on the type of interaction between the reagents and separated drugs, and asselective or universal, based on the specificity of the reaction. The most common reversiblemethods employ iodine vapour, water, fluorescein, or pH indicators as visualising reagents.In the iodine vapour method, the dried plate is enclosed in a chamber that contains a fewcrystals of iodine; components on the chromatogram are stained more rapidly than thebackground and appear as yellow–brown spots on a light yellow background. Simplyremoval of the plate from the visualisation chamber to allow the iodine to evaporate canreverse the reaction. Spraying a TLC plate with water reveals hydrophobic compounds aswhite spots on a translucent background when the water–moistened plate is held againstthe light. Solutions of pH indicators (e.g. bromocresol green, bromophenol blue) are widelyused to detect acidic and basic drugs.
Irreversible methods are more common for quantification and comprise hundreds ofreagents based on selective chemistries reduced to standard operations over severaldecades of use. Some typical examples used in drug identification are summarised in Table6. Reagents that are specific to functional groups or selective for compound classes can beapplied to determine low levels of substances in complex matrices such as biological fluidsand plant extracts.
The fluorescence response for drugs and their derivatives on TLC layers is sometimes lessthan that expected from solution measurements, is observed at different excitation andemission wavelengths than in solution, and may decrease with time. Adsorption onto thesorbent layer provides additional nonradiative pathways for the dissipation of the excitationenergy, which is most probably lost as heat to the surroundings and reduces the observedfluorescence signal. The extent of fluorescence quenching often depends on the sorbentused for the separation and is generally more severe for silica gel than for chemicallybonded sorbents. In most cases, impregnating the layer with a viscous liquid, such as liquidparaffin or Triton X-100, before evaluating the separation enhances the emission signal (infavourable cases ten- to 200–fold). The general mechanism of fluorescence enhancement isassumed to be dissolution of the sorbed solute with enhancement in response due to thefraction of solute that is transferred to the liquid phase, where fluorescence quenching isless severe. Viscous solvents are employed to minimise zone broadening from diffusion inthe liquid phase during the measurement process.
Commercial instruments for scanning densitometry usually allow measurements in thereflectance mode by absorbance or fluorescence. Most instruments employ gratingmonochromators for wavelength selection and spectrum recording in the absorption mode.For fluorescence measurements a filter, which transmits the emission wavelength envelopebut attenuates the excitation wavelength, is placed between the detector and the plate. Theseparations are scanned at selectable speeds up to about 10 cm/s by mounting the plate ona movable stage controlled by stepping motors. A fixed sample beam is shaped into arectangular area on the plate surface, through which the plate is transported in thedirection of development. Each scan, therefore, represents a lane of length defined by thesolvent–front migration distance and width by the slit dimensions of the source. Distortedchromatograms can be corrected by track optimisation, in which the sample zones areintegrated as if the slit had moved along an optimum track from peak maximum to peakmaximum. In modern TLC the relative standard deviation from all errors, instrumental andchromatographic, can be maintained below 2 to 3%, which makes it a very reliablequantitative tool.
Image analysers
For image analysers, scanning takes place electronically using a combination of a computerwith video digitiser, light source, monochromators and appropriate optics to illuminate theplate and focus the image onto a charged–coupled device video camera. The capturedimages are initialised, stored and transformed by the computer into chromatographic data.Background subtraction and thresholding are common data–transformation processes.Image analysers provide fast data acquisition, simple instrument design and convenientsoftware tools that search and compare sample images. Technological limitations currentlyprevent image analysers from competing with mechanical scanners in terms of sensitivity,resolution and available wavelength–measuring range. They have proved popular forless–demanding tasks, for the development of field–portable instruments and as areplacement for photographic documentation of TLC separations.
Other instrumental detection methods
Radioisotope–labelled drugs and their metabolites can be detected selectively with goodsensitivity by imaging detectors that use windowless gas–flow proportional counters asdetectors. The proportional counter is filled with a mixture of argon and methane gas, which
is ionised locally by collision with beta or gamma rays produced by radioactive decay in thesample zones that contain radioisotopes. The local bursts of ionised gas molecules aresensed by a position–sensitive detector and stored in computer memory. These signals areaccumulated for quantitative measurements.
Flame ionisation has been used to detect samples of low volatility that lack a chromophorefor optical detection. The separation is performed on specially prepared, thin, quartz rodswith a surface coating of sorbent attached by sintering. The rods are developed in thenormal way, usually held in a support frame that also serves as the scan stage after the rodshave been removed from the developing chamber and dried. The rods are moved at acontrolled speed through a hydrogen flame and the signal processed in a similar manner tothe flame ionisation detector used in gas chromatography. The linear working range of thedetector is about 3 to 30 μg for most substances. There are few reported applications indrug analysis.
General interfaces are available for the in situ measurement of mass, infrared and Ramanspectra of separated zones on TLC plates. Individual results in terms of sensitivity andspectral quality are impressive, but none of these methods are used routinely in druganalysis laboratories. This is a possible area for development.
Method development
The development technique is selected based on the number of detectable components inthe mixture and their polarity range (Table 7). A single development withcapillary–controlled flow may be too difficult or impossible for mixtures that contain morethan eight to ten components of interest. In addition, if the range of polarities is too wide,multiple development techniques using mobile phase gradients are necessary. It is onlynecessary to separate the components of major interest from each other and from the lessimportant components, which need not be separated individually. Method development iseasier if standards for the relevant compounds are available. Standards simplify zonetracking and enable detection characteristics and the possibility of spectroscopic resolutionof incompletely separated zones to be established. Standards are also required forcalibration, if quantification is required, and to construct spectral libraries for identificationpurposes. The expected concentration range of relevant compounds may indicate the needfor derivatisation to obtain the required detection limits and to increase zone separation ofneighbouring compounds if one compound is a minor component with similar migrationproperties to a major component.
Forced flow 1 <80 (up to 150 depending onpressure limit)
Capillary–controlled flow 2 <400
Forced flow 2 Several thousand
Based on experimental observations
Capillary–controlled flow 1 12–14
Forced flow 1 30–40
Capillary–controlled flow (AMD) 1 30–40
Capillary–controlled flow 2 About 100
Table 7. Zone capacity calculated or predicted for different conditions in TLC
A general guide to the selection of stationary phases for TLC separations is summarised inFig 6. Silica gel is generally the first choice to separate drugs of low molecular weight thatare soluble in moderately polar organic solvents. Reversed–phase chromatography onchemically bonded layers is generally used to separate drugs that are difficult to separateon silica gel because of inadequate retention, inadequate selectivity or zone asymmetry.Ionic compounds and easily ionised compounds are separated frequently by reversed–phasechromatography using buffered mobile phases (weak acids and bases) or ion–pair reagents(strong acids and bases). Only a limited number of stationary phases are available forion–exchange chromatography, which is not a widely used separation mechanism in TLC.
Figure 6. Mode selection guide for TLC (LSC, liquid–solidchromatography on an inorganic oxide layer; BPC, liquid–solidchromatography on a chemically bonded layer; RPC,reversed–phase chromatography with a chemically bonded layerand an aqueous organic mobile phase; IPC, ion–pairchromatography with reversed–phase separation conditions; PC,precipitation chromatography used to separate polymers basedon solubility differences in a mobile–phase solvent gradient.
Since the solvent used for the separation is evaporated prior to detection, a wider range ofUV-absorbing solvents are commonly used in TLC than is the case for HPLC. Solvents mustbe of high purity, since involatile impurities and stabilisers remain sorbed to the layer thatcauses problems in the detection step. Multicomponent mobile phases can produce amobile–phase gradient in the direction of development through demixing. If demixing iscomplete, zones with sharp boundaries are formed, which separate the chromatogram intosections of different solvent composition and, therefore, selectivity. Demixing effects areless apparent when saturated developing chambers are used. These considerations hinderoptimisation strategies based on the composition of the mobile phases as popularised inHPLC.
The selection of a mobile phase to separate simple mixtures need not be difficult and can bearrived at quickly by guided trial and error methods. A solvent of the correct strength for aunidimensional development migrates the sample components into the RF range 0.2 to 0.8,
or thereabouts and, if of the correct selectivity, distributes the sample components evenlythroughout this range. Solvent systems can be screened in parallel using severaldevelopment chambers, as prescribed in the PRISMA model. To select suitable mobilephases, the first experiments are carried out on TLC plates in unsaturated chambers withten solvents, chosen from the different selectivity groups, indicated by bold type in Table 8.After these screening experiments with single solvents, the solvent strength is eitherreduced or increased so that the substance zones are distributed in the RF range 0.2 to 0.8.If the substances migrate into the upper third of the plate, the solvent strength is reducedby dilution with hexane (the strength–adjusting solvent). If the substances remain in thelower third of the plate with the single solvents, the solvent strength is increased by theaddition of a strong solvent, such as water or acetic acid. A similar procedure is followed inthe reversed–phase mode, except that solvent selection is limited to water–miscible solventsand water is used as the strength–adjusting solvent. From these trial experiments, thosesolvents that show the best separation are selected for further optimisation in the secondpart of the model.
Selectivity group Solvent
I n-Butyl ether, diisopropyl ether, methyl t-butyl ether, diethyl ether
II n-Butanol, propan–2–ol, propanol, ethanol, methanol
III Tetrahydrofuran, pyridine, methoxyethanol, dimethylformamide
IV Acetic acid, formamide
V Dichloromethane, 1,1–dichloroethane
VI Ethyl acetate, methyl ethyl ketone, dioxane, acetone, acetonitrile
VII Toluene, benzene, nitrobenzene
VIII Chloroform, dodecafluoroheptanol, water
Table 8. Solvent–strength parameters and selectivity groups for solvents used forseparations on silica gel
Between two and five solvents can be selected to construct the PRISMA model for solventoptimisation. Modifiers required to maintain an acceptable zone shape, such as acids andion–pair reagents, can be added in a low and constant concentration, so that their influence
on solvent strength can be neglected. The PRISMA model (Fig 7) is a three–dimensionalgeometrical design that correlates solvent strength with selectivity of the mobile phase. Themodel consists of three parts: the base or platform (represents the modifier), the regularpart of the prism with congruent base and top surfaces, and the irregular truncated topprism (frustum). The lengths of the edges of the prism (SA, SB, SC) correspond to the solventstrengths of the neat solvents (A, B, C). Since the selected solvents usually have differentsolvent strengths, the lengths of the edges of the prism are generally unequal and the topplane of the prism is not parallel and congruous with its base. If the prism is cut parallel toits base at the height of the lowest edge (determined by the solvent strength of the weakestsolvent, solvent C in Fig 7), the lower part gives a regular prism, and the top and anyplanes, which represent weaker solvents diluted with a strength–adjusting solvent, areparallel equilateral triangles. The upper frustum of the model is used for mobile–phaseoptimisation of polar drugs in normal phase TLC, while the regular part is used to separatemoderately polar drugs in normal–phase TLC and all separations by reversed–phase TLC.
Figure 7. The PRISMA mobile–phase optimisation model,showing the construction of the prism and the arrangement ofselectivity points on the top face or horizontal plane cut throughthe prism.
For polar compounds, optimisation is always started on the top irregular triangle of themodel, either within the triangle, when three solvents are selected, or along one side, forbinary mobile phases. Any solvent composition on the face of the triangle can berepresented by a three–co–ordinate selectivity point (PS), each co–ordinate corresponding tothe volume fraction of the solvent at that position on the triangle (Fig 7). Optimisation iscommenced by selecting solvent combinations that correspond to the centre point PS = 333and three other points close to the apexes of the triangle PS = 811, 181 and 118. If theseparation obtained is insufficient, other selectivity points are tested around the solventcombination that gave the best separation. On changing the selectivity points on the toptriangle the solvent strength changes as well, especially when the solvent strengths of thesolvents used to construct the prism are significantly different. The solvent strength shouldbe adjusted with the strength–adjusting solvent as required to maintain the separation inthe optimum RF range. Failure to obtain the beginning of a separation requires that a newprism be constructed, using a different solvent for at least one of the edges.
For reversed–phase TLC, the solvation–parameter model provides a convenientcomputer–aided approach to method development. Suitable water–miscible solvents with arange of selectivity include methanol, propan–2–ol, 2,2,2–trifluoroethanol, acetonitrile (ordioxane), acetone (or tetrahydrofuran) and dimethylformamide (or pyridine). Foroptimisation of systems (stationary phases and binary mobile phases), preliminary results inthe form of system maps (a continuous plot of the system constants against mobile–phasecomposition) are required. System maps are a permanent record of the system propertiesused in all calculations and are available for most common layers and indicated solvents forselectivity optimisation. For each computer–simulated separation a retention map iscalculated from the system map and displays the computed RF values as a continuousfunction of the binary mobile–phase composition. A typical retention map for thecomputer–predicted separation of analgesics on an octadecylsiloxane–bonded layer with2,2,2–trifluoroethanol–water mixtures as the mobile phase is shown in Fig 8. Solventcompositions that result in an acceptable zone separation are identified easily by visualinspection. Computer simulation of retention maps allows those systems (defined as acombination of stationary and mobile phase) likely to provide an acceptable separation to beidentified before experimental work commences. The agreement between model predictedand experimental RF values is generally good, typically better than 0.05 RF units. Amixture–design approach is used to extend this method to ternary solvent mixtures.
Figure 8. Retention map for the simulation of the separation of analgesics byreversed–phase TLC on an octadecylsiloxane–bonded layer with 2,2,2–trifluoroethanol–wateras the mobile phase [1, chlorphenamine (chlorpheniramine); 2, ibuprofen; 3, naproxen; 4,phenacetin; 5, aspirin; 6, caffeine; 7, acetaminophen].
For drug mixtures of a wide polarity range, stepwise changes in solvent composition arerequired to achieve a satisfactory TLC separation. Models to calculate migration distancesusing incremental multiple development with increasing and decreasing solvent–strengthgradients have been described, but are complicated and not widely used. Optimisedgradients for automated multiple development are usually arrived at by more pragmaticmeans. Methods based on a universal gradient commence with methanol, end with hexaneand use either dichloromethane or methyl t-butyl ether as the intermediate solvent forseparations on silica gel. By scaling and superimposing the chromatogram of the separationabove the theoretical gradient profile, those regions of the chromatogram that affect theseparation are identified easily. The solvent composition for the initial and finaldevelopment steps is adjusted to eliminate those portions of the gradient that do notcontribute to the separation. The gradient shape is modified to enhance resolution in thoseregions of the chromatogram that are separated poorly or to minimise regions devoid ofsample zones. For moderately complex mixtures this approach is often satisfactory. If, afterthe above adjustments, the separation is inadequate it is necessary to identify a more
selective solvent for problem regions in the gradient. The PRISMA model can be used at thispoint to identify more selective solvents to incorporate into the gradient as a replacementfor the initial, terminal or base solvent.
Preparative thin–layer chromatography
Preparative TLC is used mainly to purify drugs or to isolate drug metabolites and impuritiesin amounts of about 1 to 100 mg for subsequent use as reference materials, structuralelucidation, biological activity evaluation and other purposes. Scale up from analytical TLCis achieved by increasing the thickness of the layer (loading capacity increases with thesquare root of the layer thickness) and by increasing the plate length used for sampleapplication. Precoated TLC plates for preparative chromatography vary in size from 20 cm ×20 cm to 20 cm × 40 cm and are coated with 0.5 to 10 mm thick layers, with the mostpopular thickness being 1.0 to 2.0 mm. As the average particle size (≈ 25 μm) and sizedistribution (5 to 40 μm) are larger for preparative layers, and as sample overloadconditions are used commonly in preparative chromatography, invariably inferiorseparations in a longer time (≈ 1 to 2 h) are obtained compared with analytical separations.Resolution can be increased significantly by using wedge–shaped, gradient–thickness layers.These layers have a uniform increase in thickness from 0.3 mm at the bottom to 1.7 mm atthe top. Sample bands are focused during migration by the negative mobile–phase velocitygradient created by the layer geometry.
Sample application is a critical step in preparative TLC, and if performed improperly candestroy all or part of the separation. The sample, usually as a 5 to 10 % (w/v) solution in avolatile solvent, is applied as a band along one edge of the layer to give a maximum sampleload of about 5 mg/cm for each millimetre of layer thickness. Sample loads are usually lowerfor difficult separations and for cellulose and chemically bonded layers. Any of theautomated band applicators for analytical TLC are suitable for sample application inpreparative TLC. Manual sample application by syringe or glass pipette must be performedcarefully to avoid damaging the layer and producing irregularly shaped migrating zones. Ashort predevelopment, of about 1 cm with a strong solvent, is often useful to refocusmanually applied bands. Preparative layers with a preadsorbent zone are useful for manualsample application, since the focusing mechanism can be used to correct for poorsample–application technique. In all cases, it is important that the sample solvent isevaporated fully from the layer prior to the start of the separation to avoid the formation ofdistorted separation zones. It is usual to leave a blank margin of 2 to 3 cm at each vertical
Most of the changes in preparative TLC over the past decade have occurred in the methodof development. Conventionally, ascending development in large–volume tanks that hold anumber of preparative layers in a rack is used commonly. In laboratories that performpreparative TLC on a regular basis, higher resolution and shorter development times areachieved by using forced–flow development or rotation planar chromatography (accelerateddevelopment using centrifugal force). These methods allow conventional development andelution with on–line detection and automated fraction collection to be used.
After development, physical methods of zone detection are used to identify the samplebands of interest. Layers that contain a UV indicator for fluorescence quenching or theadsorption of iodine vapours are useful for this purpose. If a reactive spray reagent is usedfor visualisation, it should be sprayed on a small strip of the chromatogram only, so as not tocontaminate the remainder of the material. Once the bands of interest are located, thezones are scraped off the plate carefully with a spatula or similar tool. A number of devicesbased on the vacuum–suction principle for removing the marked zones from the plate areavailable also. Soxhlet extraction, liquid extraction or solvent elution with a polar solvent isused to recover drugs from the sorbent. For solvent extraction, water is often added todampen the silica gel prior to extraction with a water–immiscible organic solvent.Chloroform and ethanol (methanol is less suitable because of its higher silica solubility) arewidely used for solvent elution. Colloidal silica can be removed by membrane filtration priorto vacuum stripping of the solvent.
Retardation factor
The retardation factor, or RF value, is the fundamental parameter used to characterise theposition of a sample zone in a TLC chromatogram. For linear development it represents theratio of the distance migrated by the sample compared to the distance travelled by thesolvent front:
R F = ZX/(Zf − Z0)
where ZX is the distance travelled by the sample from its origin, (Zf − Z0) the distancetravelled by the mobile phase from the sample origin, Zf the distance travelled by the mobilephase measured from the mobile phase level at the start of the separation, and Z0 thedistance from the sample origin to the mobile phase level at the start of the separation. The
boundary conditions for RF values are 1 ≥ RF ≥ 0. The RF value is generally calculated to twodecimal places. Some authors prefer to tabulate values as whole numbers, as hRF valuesequivalent to 100RF.
Drug identification
The RF value is affected too adversely by measurement difficulties and by variations inexperimental and environmental conditions to be a useful identification parameter on itsown. When standard substances are available, it is common practice to run standards andsamples in the same system for improved confidence in identification based on RF values. Ifscanning densitometry is used, an acceptable agreement in RF values is generally supportedby the automated matching of specific absorbance ratios or full spectra for the samples andstandards.
In drug–screening programmes, in which simultaneous separation of standards and samplesis impractical, the certainty of drug identification is improved by simultaneous separation ofa series of related standard substances that allow the experimental RF values to becorrected to standardised RF values from automated library searches:
hR F(X)c = hRF(A)c + [Δc/Δ][hRF(X) − hRF(A)]
Δc = hRF(B)c − hRF(A)c
Δ = hRF(B) − hRF(A)
where hRF(X) is the RF value for substance X, hRF(A) and hRF(B) are the RF values for thestandard substances that bracket hRF(X), and the superscript c indicates the corrected valuefor X and the accepted values for A and B. Alternatively, a calibration curve of experimentalRF values against the accepted RF values for the standards can be prepared and used totranspose experimental RF values to corrected RF values. Typically, four evenly spacedstandard substances with the sample origin (hRF = 0) and solvent front (hRF = 100) areincluded as additional reference points.
Database searches
Database searches are used in systematic toxicological analysis to identify suspect
substances in biological fluids and post–mortem tissue samples. Extracted samples areseparated in one or more standard TLC systems. The corrected RF values, often combinedwith the results of sequential post–chromatographic colour reactions, are then entered intothe search program. The input data are automatically compared against a database ofreference drugs, common metabolites, natural contaminants, etc., for identification. Anumber of chemometric procedures can be used for data analysis, but the most commonapproach is based on the mean list method.
It is assumed that the errors in individual measurements are random and can be describedby a standard deviation. The precision of the separation system can then be described as themean of the standard deviation of all substances separated in the system, called the systemmean standard deviation. This allows a confidence interval or window to be assigned to thesystem as some multiple (typically three) of the system mean standard deviation. Each RF
value in the system database that appears in the window could be confused with the originalsubstance. The number of substances identified as above is called the list length. Repeatingthe process for all RF values in that system and averaging the individual list lengths providesthe mean list length for that system. The mean list length indicates, on average, the numberof substances in the database that qualify as candidates for the identification of a singledrug. The shorter the mean list length, the greater the information potential of the system.Combining the results from additional retention parameters in complementary standardseparation systems, colour reactions, spectroscopic data, etc., minimises the mean listlength to the point that only a small number of candidate compounds for the unknown areindicated. More specific tests can then be used to identify the unknown from among thesmall number of indicated possibilities. For systematic drug identification in forensictoxicology, commonly two or more complementary TLC systems combined with the resultsfrom several in situ sequential colour reactions are used. For drugs of toxicological interest,a mean list length from two to ten is possible.
Systematic drug identification
Systematic toxicological analysis takes advantage of the separation of an unknownsubstance in standard TLC systems (or other chromatographic systems) to establish theprobable identity of the substance by reference to a database of candidate compounds usinga statistical comparison approach, such as the mean list method. Suitable chromatographictechniques for systematic toxicological analysis must meet the following criteria:
the drugs must exhibit acceptable chromatographic properties in the separation1.systemthe RF values for the drugs must be distributed evenly over the full RF range2.the RF values are standardised in such a way that good interlaboratory reproducibility3.is obtainedwhen more than one separation system is used, there must be a low correlation of RF4.values in the selected systems.
TLC systems that meet these requirements are described below.
Since pH-dependent extractions are customarily used in drug extraction and work–upprocedures, generally different TLC systems are used to separate acidic and basic drugs,with neutral drugs likely to occur in both fractions. The Committee for SystematicToxicological Analysis of the International Association of Forensic Toxicologists (TIAFT)recommended 11 separation systems for drug identification (Table 9). Four systems (1 to4a) are to separate neutral and acidic drugs and seven systems (4b to 10) are to separateneutral and basic drugs. Reference data are presented for about 1600 toxicologicallyrelevant substances. For general drug screens, the use of two separation systems with a lowcorrelation is recommended: systems 2 and 4(a) for neutral and acidic drugs and systems 5and 8 for neutral and basic drugs (systems 7 and 8 are nearly as good). Combining colourreactions with the TLC data improves the certainty of identification significantly. Fourcolour reactions are carried out on the same plate in sequence. After each step the colour isnoted and encoded by means of a colour chart (1, yellow; 2, orange; 3, brown; 4, red; 5,purple; 6, black; 7, blue; 8, green; 0, no spot observed). The sequence consists offormaldehyde vapour and Mandelin’s reagent, water, fluorescence under 366 nm irradiationand modified Dragendorff’s reagent. Other sequential colour reactions can be encoded andutilised in the same way. The Merck Tox Screening System (MTSS) contains the TIAFTTLCdatabase and several other useful tools for searches using other chromatographic andspectroscopic databases and user–created databases.
TLC system
No Mobile phase Chambertype
Stationaryphase
Referencecompounds* hRc
FError
window†
(1) Chloroform–acetone(4:1) Saturated Silica gel Paracetamol 15 7
Table 10. The separation systems recommended by Romano et al. (1994) for systematictoxicological analysis by TLC (drug database: Romano et al. 1994)
*Error window estimated as 7–9% RcF.
These systems use slight modifications of the mobile–phase compositions recommended byTIAFT. The UniTox system uses three TLC systems (Table 11). System 1 is designed toseparate neutral and acidic drugs and systems 2 and 3 to separate basic, amphoteric andquaternary drugs. Two of the separation systems are based on reversed–phase separationsdesigned to complement the more familiar silica gel separations. The database contains over375 drugs of general toxicological interest, including a large number of amphetamines.
Table 11. The UniTox system for systematic toxicological analysis by TLC [drug database,Ojanpera 1995; additional compounds (amfetamines) in Ojanpera et al. 1991]
The Toxi-Lab system is a TLC kit for toxicological drug screening; it contains equipment forextraction, development, detection and identification. Separations are performed onunsupported, particle–embedded glass–fibre sheets with holes punched in them to receivesamples and standards as extraction or reference disks. A combination of silica gel andreversed–phase separations together with sequential colour reactions is used foridentification and confirmation purposes. The database is designed for computer searcheswith results entered in a standard format.
Pesticides are a further class of toxic substances of interest to systematic toxicologicalanalysis because of their general availability, toxicity and potential confusion with drugs.Erdmann et al. (1990) developed a database for 170 commonly used pesticides separated inthree standardised TLC systems (Table 27.12). The systems in Table 27.12 supplementthose in Table 27.9, in which many common pesticides migrate with the solvent front.Systems 1 and 2 are recommended for general screening and system 3 for the identificationof special compounds not distinguished in the first two systems.
(1) Hexane–acetone(4:1) Saturated Silica gel Triazophos 21
Parathion–methyl 30
Pirimiphos–methyl 49
Quintozene 84
(2) Toluene–acetone(19:1) Saturated Silica gel Carbofuran 20
Azinophos–methyl 42
Methidathion 56
Parathion–ethyl 85
(3) Chloroform–acetone(1:1) Saturated Silica gel Nicotine 11
Ioxynil 39
PCP 60
Methabenzthiazuron 85
Table 12. Standardised TLC systems for the screening of pesticides (pesticide database,Erdmann et al. 1990)
General applications
Thousands of general and validated methods are available for the determination of drugs aspharmaceutical products and in biological fluids. Since the zone capacity of TLC systems issmall, there are no general methods for drugs as a class, but there are a large number ofmethods for individual drugs defined by therapeutic or chemical categories. These still
represent substantial diversity driven by the need to optimise selectivity for each group ofsubstances taken for analysis. This information can provide a useful starting point forsystem selection, but is no general substitute for systematic method development. For thesereasons universal methods for general drug analysis do not exist and earlier attempts atsystematised approaches for different drug categories have failed to keep pace with thegrowth in number of drugs in those categories. In addition, systems recommended for theseparation of individual drug categories rarely prove optimal for the separation of individualdrugs and their impurities or metabolites.
Systems for thin-layer chromatography
The TLC systems given below are general screening methods for nitrogenous bases(Systems TA, TB, TC, TL, TAE and TAF), for acids and neutral compounds (Systems TD, TE,TF and TAD) with a further three general screening methods (Systems TAJ, TAK and TAL).Furthermore, seven systems specific for pesticides (Systems TW, TX, TY, TZ, TAA, TAB andTAC) and another 19 systems covering specific groups of drugs are also listed. The drugsare divided into chemical or pharmacological groups, but some other drugs are includedwith certain groups if they are chemically similar and would be extracted with that group.
There may not be one best system for a particular separation and a number of systems canbe applied from those suggested. However, each of the systems described has been selectedbecause it gives a good spread of Rf values, has high reproducibility, and has lowcorrelation with the other systems selected for that group of drugs. These systems haveproved useful for a large number of groups of drugs over the years and are robust anddependable. At least three systems are given for each group, where possible. The Rf valuesof the reference compounds suggested for the general screening systems have been derivedusing solutions of approximately 2 mg/mL of each substance.
Fluorescent plates should always be used and the absorption or fluorescence of the drugunder ultraviolet light (both 254 and 350 nm) should be used as a location procedure. Thesuggested locating agents include general ones to visualise any drug that might be presentas well as more specific ones to pick out individual classes of drugs.
Note
In the tables of Rf values, a dash indicates that no value is available for the compound.
Systems described in Table 27.9 have been assigned the following codes:
Code Number in Table 27.9
TA 7
TB 8
TC 9
TD 1
TE 4
TF 2
TL 10
TAD 3
TAE 5
TAF 6
Screening systems
Basic nitrogenous drugs
A. H. Stead et al., Analyst, 1982, 107, 1106–1168 and R. A. de Zeeuw et al., Thin-layerChromatographic Rf Values of Toxicologically Relevant Substances on StandardizedSystems: Report XVII of the DFG Commission for Clinical-Toxicological Analysis, 2nd Edn,VCH, Weinheim, 1992.
System TA
Plates: Silica gel G, 250 μm thick, dipped in, or sprayed with, 0.1 M potassiumhydroxide in methanol, and dried.Mobile phase: Methanol:strong ammonia solution (100:1.5).Reference compounds: Atropine Rf 18, Codeine Rf 33, Chlorprothixene Rf 56,Diazepam Rf 75.
Mobile phase: Methanol:n-butanol (60:40) and 0.1 mol/L NaBr.Reference compounds: Codeine Rf 22, Diphenhydramine Rf 48, Quinine Rf 65,Diazepam Rf 85.
Location reagents for systems TA, TB and TC
Ninhydrin spraySpray the plate with the reagent and then heat in an oven at 100° for 5 min. Violet or pinkspots are given by primary amines and yellow colours by secondary amines.FPN reagentRed or brown-red spots are given by phenothiazines and blue spots by dibenzazepines. Thisreagent may be used to overspray a plate which has been previously sprayed with ninhydrinspray.Dragendorff sprayYellow, orange, red-orange, or brown-orange spots are given by tertiary alkaloids. Thisreagent may be used to overspray a plate which has been previously sprayed with ninhydrinspray and FPN spray.Acidified iodoplatinate solutionViolet, blue-violet, grey-violet, or brown-violet spots on a pink background are given bytertiary amines and quaternary ammonium compounds. Primary and secondary amines givedirtier colours. This solution may be used to overspray a plate which has previously beensprayed with ninhydrin spray, FPN reagent and Dragendorff spray.Mandelin’s reagentThis reagent is preferably poured onto the plate because of the danger of sprayingconcentrated acid. Many different colours are given with a variety of drugs (see Chapter 19and the Index of Colour Tests).Marquis reagentThis reagent is preferably poured onto the plate because of the danger of sprayingconcentrated acid. Black or violet spots are given by alkaloids related to morphine. Manydifferent colours are given with a variety of drugs (see Chapter 19).Acidified potassium permanganate solutionYellow-brown spots on a violet background are given by drugs with unsaturated aliphaticbonds.Rf valuesRf values for drugs in these systems will be found in drug monographs and in the Indexes ofAnalytical Data in Volume 2; they are also included in the systems for specific groups ofdrugs which follow.
A. H. Stead et al., Analyst, 1982, 107, 1106–1168 and R. A. de Zeeuw et al., Thin-layerChromatographic Rf Values of Toxicologically Relevant Substances on StandardizedSystems: Report XVII of the DFG Commission for Clinical-Toxicological Analysis, 2nd Edn,VCH, Weinheim, 1992.
Van Urk reagentSpray the plate with the reagent and then heat in an oven at 100° for 5 min. Yellow spotsare given by sulfonamides and by meprobamate, blue spots are given by ergot alkaloids, andpink or violet spots are given by some other compounds, e.g. phenazone.Ferric chloride solutionBlue or violet spots are given by phenols. This solution may be used to overspray a platewhich has been previously sprayed with Van Urk reagent.Mercurous nitrate sprayBarbiturates give dark spots which fade slowly; with some dilute solutions the spots faderapidly.Acidified potassium permanganate solutionYellow-brown spots on a violet background are given by drugs with unsaturated aliphaticbonds, e.g. secobarbital. This solution may be used to overspray a plate which has beenpreviously sprayed with mercurous nitrate spray.
Neutral drugs
Furfuraldehyde reagentViolet to blue-black spots are given by some neutral compounds, e.g. carbamates.Acidified iodoplatinate solutionThis solution may be used to overspray a plate which has been previously sprayed withfurfuraldehyde reagent.Rf valuesRf values for drugs in these systems will be found in drug monographs and in the Indexes ofAnalytical Data in Volume 2; they are also included in the systems for specific groups ofdrugs which follow.NoteIt is worth noting that system TE can be used for acidic, neutral and basic drugs.Furthermore, systems TC and TAD use the same mobile phase so that acidic, neutral andbasic drugs can be run in the same tank, although on separate plates. It should also benoted that the above systems for basic nitrogenous drugs are also able to separate neutraldrugs if the latter are present in the sample or in the basic extract thereof.Finally, the Indexof Colour Tests lists colour reactions with TLC spray reagents for approximately 250compounds and may therefore serve as an indication of colour reactions specific to certain
The TLC systems listed below (Systems TAJ, TAK and TAL) were developed primarily byProfessor George Maylin, New York State Racing Wagering Board, Drug TestingProgramme, as well as System TAM listed under steroids.
System TAJ
Plates: Silica gel G, 250 μm thick.Mobile phase: Chloroform:ethanol (90:10).
Location reagentsThe reagents for systems TD, TE and TF can be used as well as those given below.Chromic acid solutionA variety of colours are given by certain substances, e.g. diclofenac, red; diflunisal, blue-grey; feprazone, yellow; flufenamic acid, blue; indometacin, grey-brown; meclofenamic acid,violet; mefenamic acid, green; oxyphenbutazone, yellow; phenylbutazone, brown; salsalate,brown; sulindac, white.Ludy Tenger reagentOrange or orange-brown spots are given by certain substances.
Analgesics, NSAIDs
Molecule TA TB TC TD TE TF TG TL TAD TAE TAJ TAK TAL
The tabulated systems, previously described, together with the associated location reagentsmay be used or System TH, below, which gives good separations.
Mercuric chloride-diphenylcarbazone reagentWhite spots on a violet background are given in neutral systems, and violet spots on a pinkbackground are given if the plate is alkaline.Acidified potassium permanganate solutionYellow-brown spots on a violet background are given by drugs with unsaturated aliphaticbonds.Zwikker’s reagentPink spots are given by 5,5-disubstituted barbiturates, green spots are given bythiobarbiturates, and faint pink spots are given by bromobarbiturates and by 1,5,5-trisubstituted barbiturates. The test is not very sensitive.Fluorescein solutionSpray the plates with a 10% solution of sodium hydroxide and heat at 100° in an oven for 5min before applying the reagent. Pink spots are given by bromobarbiturates.Mercurous nitrate sprayBarbiturates give dark spots which fade slowly; with some dilute solutions the spots faderapidly.
Molecule TA TB TC TD TE TF TL TAD TAE TAF TAJ TAK TAL
Temazepam 53 8 59 51 62 47 53 65 1563 82 65 54 92
Triazolam 60 1 40 5 44 2 16 41 1647 65 – – –
Zopiclone – 4 – – 47 – – – 1732 – – – –
Bronchodilators
The tabulated systems, previously described, may be used together with the associatedlocation reagents.
Molecule TA TB TC TE TL TAE TAF
Bambuterol – 2 – 37 – 18 –
Bambuterol monocarbamate – – – 21 – 19 –
Bamifylline 65 – 54 – 34 71 –
Butetamate 69 59 57 81 47 48 56
Protokylol 65 1 3 – 6 – –
Rimiterol – – – 6 – 7 –
Salbutamol 46 1 1 20 4 16 74
Cannabinoids
The tabulated systems, previously described, may be used together with the associatedlocation reagents or Systems TI and TJ, below. These systems may be used for extracts ofboth cannabis and cannabis resin.
System TI
Plates: Silica gel G, 250 μm thick, dipped in, or sprayed with, a 10% solution of silvernitrate, and dried.Mobile phase: Toluene, using unsaturated (open tank) conditions.
Plates: Silica gel G, 250 μm thick, sprayed with diethylamine immediately before use.Mobile phase: Xylene:hexane:diethylamine (25:10:1).
Location reagents for systems TI and TJ
Fast blue B solutionCannabidiol gives an orange colour, cannabinol gives a violet colour, and Δ9-tetrahydrocannabinol gives a red colour. The colours may be intensified by oversprayingwith 1 M sodium hydroxide or by exposing the plate to ammonia fumes.Duquenois reagentAfter spraying with the reagent, overspray the plate with hydrochloric acid. Blue to violetcolours are given by cannabinoids.Molecule TA TE TI TJ TAH TAJ TAK TAL
Δ9-THC 11 31 30 29 50 00 1 31
CBN 94 95 52 20 45 90 77 97
CBD 94 95 5 36 60 88 76 97
Cardioactive drugs
The tabulated systems, previously described, may be used together with the associatedlocation reagents.
The tabulated systems, previously described, may be used together with the associatedlocation reagents.
Location reagentsThe reagents given for systems TD, TE and TF can be used as well as that given below.N-(1-Naphthyl)ethylenediamine solutionSpray the plate with dilute sulfuric acid, expose it to nitrogen dioxide vapour for 15 min andthen spray with the reagent.
The tabulated systems, previously described, may be used together with the associatedlocation reagents. A further three systems (TAH, TAI and TAN), described below may beused for drugs of abuse. Please refer to Chapter 2 for Rf values.
The tabulated systems, previously described, may be used together with the associatedlocation reagents.
System TL, previously described, may be used or system TM below. Note that these systemscan be run in a single tank as they use the same mobile phase and have low correlation of Rfvalues.
Naphthoquinone sulfonate solutionSpray the plate with the reagent, then spray with a 10% v/v solution of hydrochloric acidand heat at 110° for 20 min. Red-violet spots on a light pink background are given by ergotalkaloids.Nitroso-naphthol solutionSpray the plate with the reagent, then spray with a 10% v/v solution of hydrochloric acidand heat at 110° for 20 min. Blue-black spots on a yellow background are given by ergotalkaloids.Van Urk reagentAfter spraying the plate, heat in an oven at 100° for 5 min. Blue spots are given by ergotalkaloids.
Location reagentAllow the plate to dry in air, heat at 110° for 2 h, allow to cool, spray withmolybdate–antimony reagent, and then lightly overspray with ascorbic acid reagent.
Plates: Silica gel (without gypsum), 250 μm thick.Mobile phase: Methanol:0.2 M hydrochloric acid (80:20).
Location reagents for systems TN and TO
Acidified iodoplatinate solutionViolet, blue-violet, grey-violet, or brown-violet spots on a pink background are given byquaternary ammonium compounds.Cobalt thiocyanate solutionBlue spots are given by quaternary ammonium compounds.
The tabulated systems, previously described, may be used or Systems TP, TQ, TR, TS andTAM.Systems TP, TQ, TR and TSW. Lund, ed., Pharmaceutical Codex, 11th Edn, London, Pharmaceutical Press, 1979, 940.
System TAMProfessor George Maylin: personal communication.
Plates: Silica gel G, 250 μm thick.Mobile phase: The plate is run to 5 cm in a TLC system of chloroform:ethylacetate:methanol (50:45:5), dried and then re-run to 7 cm in the solvent composition ofsystem TE, ethyl acetate:methanol:strong ammonia solution (85:10:5).
Location reagents for systems TP, TQ, TR, TS and TAM
DPST solutionSulfuric acid–ethanol reagentSpray the plate and then heat at 105° for 10 min.p-Toluenesulphonic acid solutionHeat the plate at 120° for 15 min, cool, spray with the reagent, heat again at 120° for 10min, and respray.
Molecule TA TB TE TF TP TQ TR TS TAE TAJ TAK TAL TAM
Systems TT, TU and TVH. De Clercq et al. ,J. Pharm. Sci. 1977, 66, 1269–1275Sulfonamides are difficult toseparate, but these systems are effective and may be used in combination. System TF,previously described, may also be used.
System TT
Plates: Silica gel G, 250 μm thick.Mobile phase: Hexanol.
Acidified potassium permanganate solutionYellow-brown spots on a violet background are given by sulfonamides.Copper sulfate solutionThis detects N-substituted sulfonamides.Mercuric chloride–diphenylcarbazone reagentBlue spots are given by sulfonamides.Van Urk reagent