About Some Specific Features of TLC in an Ultra-Small Volume S-Chamber and a Chamber with a Closed Sorption Layer

The chromatographic chamber plays a significant role in plate development. The main characteristics of planar chromatography chromatographic processes (the efficiency, the duration of plate development, the separation factor and the analyzed compounds' retention) are studied in this article in two new variants of chromatographic chambers proposed in our laboratory: the O-chamber with a zero gas volume and the S_min-chamber with an ultra-small gas volume (the distance between the adsorption layer of the plate and the side cover is 0.1?C0.2 mm). The S_min-chamber application permits reducing the duration of TLC plate development by more than 25% (in comparison with the identical process in an N-chamber). The possibility of using the S_min-chamber for saturated TLC implementation is also demonstrated. A new, simple S_min-chamber is expedient for use in practical TLC.     

Low-Pressure Chromatographic Separation of p-Hydroxybenzoates Using Sequential Injection with Lab-on-Valve System and Miniature Monolithic Column

The use of a small guard column (5-mm length) as a miniature analytical column in low-pressure liquid chromatography based on a sequential injection with lab-on-valve system was demonstrated. A strong initial mobile phase was used to rapidly deliver the sample zone to the column prior to simultaneous separation of analytes with weaker mobile phase. Separation of methyl-, ethyl-, propyl-, and butyl-4-hydroxybenzoates (MP, EP, PP, and BP) was achieved within about 120 s with sufficient peak resolution (all higher than 1.3) using 2,500 µL of mobile phase (composed of 1,087 µL of MeOH) per run. Detection limits were found to be 6.5, 8.0, 0.5, and 0.6 μmol L^?1 for MP, EP, PP, and BP, respectively. The system was tested with common commercially available skin lotions and wet wipe products. The analysis results were in good agreement with those obtained from the high-performance liquid chromatography with a 10-cm-length packed column.     

Effect of Chamber Gas Phase on Mobile Phase pH and on Separation Efficiency in TLC. A New Mode of Chromatography

A new variant of thin-layer chromatography (TLC), based on a gradual change of mobile phase acidity during elution, is proposed. The pH change occurs in the mobile phase moving along the TLC plate as a result of its contact with an acidic or a basic gas phase that replaces the initial mobile phase vapor in the TLC chamber. The potential of this approach has been demonstrated by using carbon dioxide and ammonia gases to improve the resolution of benzoic acids and aromatic amines on polyamide TLC plates.     

Two-Dimensional Planar Chromatography with a Closed Adsorbent Layer

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

An Improved Method to Resolve Plant Saponins and Sugars by TLC

Thin-layer chromatography (TLC) plays an important role in the initial selection of mutants having a unique seed saponin composition from the germplasm collections of the subgenus Soja. In the conventional TLC procedure, the dehydrated free sugars are retained just below the major saponins and interrupt the identification of some minor saponin constituents. To resolve this problem, we developed an efficient and reliable method to move sugars from the saponin area on TLC. A developing chamber was saturated with the lower phase of chloroform:methanol:water (65:35:10, v/v) for 2 h and the TLC plates were developed in it for 50 min. Plates were then dried at 100 °C for 10 min to evaporate the excess mobile phase and developed again with 10 % H₂SO₄ for 15 min. While sulfuric acid migrates over the surface of SiO₂, sugar molecules are dehydrated and hydrophilic interactions between free sugars and SiO₂ are strongly reduced. Thus, the positions of dehydrated sugars were shifted to above the saponin area on the TLC plate. This resulted in easy recognition of the saponin composition without any discrimination. This amended protocol would be applicable to all TLC analyses in which the target components should be separate from the interrupting sugar molecules.

     

The use of vacuum in thin-layer chromatography with a forced flow of the mobile phase on plates with covered polymer layer

A new version of TLC with a forced flow of the mobile phase has been suggested. The variant involves the use of a TLC plate, the sorption layer on which is covered with a polymer film, and evacuation as an additional driving force for the mobile phase. The advantages of the new method were analyzed; the velocity coefficient of the movement of the mobile phase front was found to be linearly dependent on the rarefaction at the end of the plate.Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 5, pp. 1143–1146, May, 1996.     

HPTLC Determination of Cefpodoxime Proxetil in Formulations

An HPTLC method has been developed that coelutes both the isomers of cefpodoxime proxetil (CFP). CFP was chromatographed on a silica gel 60 F₂₅₄ TLC plate using toluene:acetonitrile (6:4) as a mobile phase and was quantified at 234 nm. The method was validated with respect to linearity, accuracy, precision and specificity. The limit of detection and limit of quantification for CFP were found to be 0.150 and 0.4 μg spot^?1, respectively. The proposed method was successfully used to determine the amount of CFP present in the marketed tablets and self-nanoemulsifying systems.     

Thin-layer chromatography with high-boiling mobile phase. part 2: Effect of temperature on retention characteristics in TLC with high-boiling mobile phases

A study has been undertaken on the effect of temperature on retention characteristics in thin-layer chromatography (TLC) with low-volatility mobile phases (MP). It is shown that temperature variations in TLC in melts bring about variations in both the relative retention values and, in some cases, in the order of migration of the chromatographic zones across the layer. The variation in the capacity factor k' with temperature agrees well with Martin's equation. To explain the temperature dependence of R_f one must, in general, take into account the variations with temperature in both the partition coefficient and the phase ratio. To describe the variation in R_f with temperature in TLC with low-volatile MP one can use an approximate equation in which In R_f is a linear function of 1/T. The experiments indicate that temperature is a major factor in TLC in melts.     

TLC Determination of Amitriptyline HCl,Trifluoperazine HCl,Risperidone and Alprazolam in Pharmaceutical Products

A simple, sensitive, and precise thin layer chromatographic (TLC) method for simultaneous analysis of psychopharmacological drugs like amitriptyline HCl, trifluoperazine HCl, risperidone and alprazolam in their single dosage forms has been developed, validated, and used for determination of the compounds in commercial pharmaceutical products. The TLC separation was carried out on Merck TLC aluminium sheets of silica gel 60 F254 using carbon tetrachloride:acetone:triethylamine (8:2:0.3, v/v/v), as mobile phase. Densitometric measurements of their spots were achieved at 250 nm over the concentration range for amitriptyline HCl (50–1,200 ng spot⁻¹), trifluoperazine HCl (50–1,200 ng spot⁻¹), risperidone (100–2,400 ng spot⁻¹) and alprazolam (25–600 ng spot⁻¹). Limit of detection (LOD) for amitriptyline HCl (20 ng spot⁻¹), trifluoperazine HCl (20 ng spot⁻¹), risperidone (40 ng spot⁻¹) and alprazolam (5 ng spot⁻¹) was obtained. The study showed that TLC was sensitive and selective for determination of amitriptyline HCl, trifluoperazine HCl, risperidone and alprazolam using a single mobile phase. This proposed method is able for simultaneous determination of psychopharmacological drugs and also applicable for analysis of pharmaceutical formulations.

     

A variant of circular thin-layer chromatography with a forced flow of the mobile phase produced by an electroosmotic pump

A new variant of circular thin-layer chromatography (TLC) with a closed sorption layer in which a forced flow of the mobile phase was produced and controlled by an external electroosmotic pump placed at the center of a TLC plate was suggested. It was shown experimentally that the method operated properly and could be used in planar chromatography.     

HPTLC Determination of Cefpodoxime Proxetil in Formulations

An HPTLC method has been developed that coelutes both the isomers of cefpodoxime proxetil (CFP). CFP was chromatographed on a silica gel 60 F₂₅₄ TLC plate using toluene:acetonitrile (6:4) as a mobile phase and was quantified at 234 nm. The method was validated with respect to linearity, accuracy, precision and specificity. The limit of detection and limit of quantification for CFP were found to be 0.150 and 0.4 μg spot⁻¹, respectively. The proposed method was successfully used to determine the amount of CFP present in the marketed tablets and self-nanoemulsifying systems.

     

A Validated Quantification of Benzocaine in Lozenges Using TLC and a Flatbed Scanner

We present a video-densitometric quantification method for benzocaine in lozenges. The quantification is based on a derivatisation reaction with 4-dimethylaminobenzaldehyde. Measurements were carried out using a 16-bit flatbed scanner. Benzocaine was separated to a distance of 50 mm in a vertical developing chamber without vapour saturation. We present an RP-18 phase separation on a cyanopropyl plate (Merck, Darmstadt, Germany) using water, CH₃CN, dioxane, ethanol, and NH₃ (25 %) (8 + 2 + 1 + 1 + 0.05, v/v) as the mobile phase. We also separated benzocaine in a normal phase system on silica gel 60 LiChrospere^® plates (Merck, Darmstadt, Germany) with the mobile phase MTBE/cyclohexane (1 + 1, v/v). The calibration functions for benzocaine in both separations were linear in the range from 1 to 1,000 ng per spot. The range of linearity covers two magnitudes of power because the Kubelka–Munk expression was used for data transformation. In the cyanopropyl-system, the benzocaine amount was quantified as 242.5 ± 18.2 ng in a spot or 6.86 ± 0.52 mg in a single lozenge. The amount of 7.0 mg benzocaine per lozenge was labelled. The combined uncertainty of sample and calibration measurements was statistically calculated using a significance level of α = 0.05 to a total relative uncertainty of 7.49 %. The separation method is inexpensive, fast and reliable.     

Anticircular high performance thin-layer chromatography

The principal analytical details for the third of three possible modes in high performance thin-layer chromatography are given, namely the anticircular mode. Separation is achieved by allowing the mobile phase to enter the plate layer on a precise outer circle line, from where it flows towards the centre with nearly constant speed. This technique is theoretically and practically the fastest of all three possible in HPTLC. It permits maximum sample capacity with a minimum of time, layer and mobile phase consumption. It is therefore the most economical HPTLC technique. A new carrier-free mobile phase transfer principle is used. The conditions for qualitative and quantitative analysis are good: repeatability, reproducibility and accuracy of routine TLC analyses are superior to those achieved by the classical trough technique. The specially narrow spot-path in anticircular HPTLC facilitates automated quantitation. Compared with the linear and circular modes, the anticircular mode shows better separation and significantly increased sensitivity at higher Rf-values. The drawback, however, is that the separation power (expressed by the separation number) is lower compared with the other two modes.     

药物分析中薄层色谱的方法认证

在药物分析中,针对所要求的性能参数,对一个薄层色谱程序的各个环节必须进行的认证方法和认可标准进行了讨论。建议当提出结果报告时,应附上关于对方法的认证参数和认证方法的说明。     

Planar chromatography with a forced flow of the mobile phase produced by an electroosmotic pump on a plate with a closed sorption layer

A new variant of thin-layer chromatography (TLC) with a forced flow of the mobile phases produced by an electroosmotic pump on a plate with a closed sorption layer is proposed. The new variant of TLC is tested for separation of dyes with ethanol and acetonitrile as mobile phases. It is established that the new method is 15–33% faster compared to traditional TLC and provides the same or higher efficiency.     

QbD-driven development and validation of an efficient bioanalytical UPLC method for estimation of olmesartan medoxomil

The present studies describe quality by design-based development of bioanalytical ultra performance liquid chromatography method of olmesartan medoxomil. Initially, method objectives were defined and critical analytical attributes (CAAs) earmarked. Method optimization was conducted using a central composite design for optimizing mobile phase ratio and injection volume as the critical method parameters (CMPs) identified from risk assessment and factor screening studies, and evaluated for their influence on peak area, theoretical plates, and asymmetry factor as CAAs. Chromatographic separation was achieved using acetonitrile:water solvent system containing 0.1% orthophosphoric acid (54:46, v/v) as the mobile phase with UV detection at 243 nm. Further optimization of bioanalytical extraction process was accomplished using a Box–Behnken design selecting extraction time, centrifugation speed, and centrifugation time as the CMPs identified from failure mode and effect analysis, and evaluated for percent recovery, peak asymmetry, and theoretical plate count as the CAAs. Establishment of calibration curve indicated linearity between concentration range of 100 and 800 ng mL^?1, excellent accuracy and precision with limit of detection and limit of quantification as 6.2 and 19.0 ng mL^?1, respectively. Drug stability studies indicated mean percent recovery ranging between 92.4 and 97.3% under various stress conditions.     

A New Efficient Analytical Method for Picolinate Ion Measurements in Complex Aqueous Solutions

This study focuses on the development of a new simple but sensitive, fast and quantitative liquid chromatography method for picolinate ion measurement in high ionic strength aqueous solutions. It involves cation separation over a chromatographic CS16 column using methane sulfonic acid as a mobile phase and detection by UV absorbance (254 nm). The CS16 column is a high-capacity stationary phase exhibiting both cation exchange and RP properties. It allows interaction with picolinate ions which are in their zwitterionic form at the pH of the mobile phase (1.3–1.7). Analysis is performed in 30 min with a detection limit of about 0.05 μM and a quantification limit of about 0.15 μM. Moreover, this analytical technique has been tested efficiently on complex aqueous samples from an effluent treatment facility.     

Identification of Impurities in 5-Aminolevulinic Acid by Two-Dimensional Column-Switching Liquid Chromatography Coupled with Linear Ion Trap Mass Spectrometry

Identification of impurities in 5-aminolevulinic acid (ALA) by mass spectrometry is difficult, because MS-incompatible mobile phases, such as phosphate buffers or ion-pair reagents, need to be used to separate the major component from impurities. In this study, the unknown impurities in ALA have been identified by two-dimensional (2D) column-switching high-performance liquid chromatography (HPLC) coupled with linear ion trap mass spectrometry (LIT MS). The first-dimensional analytical column was a Gemini C18 (150 mm × 4.6 mm, 5 μm) with a non-volatile salt mobile phase at a flow rate of 1.0 mL min⁻¹, and the second-dimensional analytical column was a ZORBAX SB C8 (150 mm × 4.6 mm, 3.5 μm) with a volatile salt mobile phase at a flow rate of 1.0 mL min⁻¹. The detection wavelength was 205 nm. Mass spectra were acquired with an ESI source, in both positive and negative ion modes. Six impurities were identified by their MS² and MS³ fragments, and the mass fragmentation patterns and structural assignments of these impurities were studied. The results obtained by the two-dimensional column-switching method were further compared with those of the conventional one-dimensional normal-phase HPLC–MS using an amide column and an MS-compatible mobile phase for separation. The two-dimensional column-switching method described herein proved to be advantageous in terms of the number of impurities identified. The column-switching and online demineralization technique made the mobile phase conditions compatible with mass spectrometry. Thus, the method solves the problem of incompatibility between non-volatile salt mobile phases and mass spectrometry, making it worthy of popularization and application in impurity identification.

     

Liquid chromatographic separation and UV determination of certain antihypertensive agents

Three antihypertensive agents were extracted and isolated from commercial formulations. These were purified and characterized by melting point, lambdamax and IR. The percentage recovery by extraction process was in the range 81-91%. Active ingredients from binary formulations were separated by RP-HPLC using methanol-water (50:50 v/v) and by TLC using CHCl3-CH3OH (6:1) as mobile phase. Detection was by UV at 210 nm in HPLC, and by iodine vapors in TLC. The solvent conditions from TLC were transferred to open column chromatographic separation. Quantitative determination was carried out using TLC and column chromatography supplemented with UV spectrophotometry. Recovery was in the range 82-93%. Two combination of drugs, viz. amlodipine+ramipril and amlodipine+enalapril, were separated by the three modes of liquid chromatography. The percentage recovery was in the range 80-92% by open column.     

Ethylene Glycol as New Mobile Phase for Resolution of Two-Component Mixture of Cationic Surfactants on Alumina Surface

Aqueous ethylene glycol (ethane 1,2 diol) as a green mobile phase has been used for thin layer chromatographic (TLC) studies of cationic surfactants on alumina layers. Nineteen solvent systems were used to examine the mobility of the surfactants and to discover the best TLC system for the selective separation of dodecyl trimethylammonium bromide (DTAB) from multi-component mixture of other surfactants. Among the TLC systems studied, M₃ (ethylene glycol: water, 8:2) was best for achieving the selective separation of DTAB from multi-component mixture of other surfactants because in this mobile phase mobility of all surfactants except DTAB were insignificant. Effect of organic additives in aqueous ethylene glycol mobile phase on the mobility of surfactants was examined. The results obtained on laboratory made alumina TLC plates and commercially available precoated alumina HPTLC plates were compared. The lower limits of detection of DTAB, CPC, CTAB, HDTAC, and TTAB were 0.02, 0.05, 0.04, 0.06, or 0.08 µg per zone respectively. The resolution of mixture of cationic surfactants was also examined in the presence metal cations as an impurity in the analyzed sample.