Cumulative CAMAG Bibliography Service CCBS

Our CCBS database includes more than 11,000 abstracts of publications. Perform your own detailed search of TLC/HPTLC literature and find relevant information.

The Cumulative CAMAG Bibliography Service CCBS contains all abstracts of CBS issues beginning with CBS 51. The database is updated after the publication of every other CBS edition. Currently the Cumulative CAMAG Bibliography Service includes more than 11'000 abstracts of publications between 1983 and today. With the online version you can perform your own detailed TLC/HPTLC literature search:

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      130 141
      Two-dimensional high-performance thin-layer chromatography for the characterization of milk peptide properties and a prediction of the retention behavior – a proof-of-principle study
      M. TREBLIN, T. VON OESEN, L.-C. CLASS, G. KUHNEN, I. CLAWIN-RÄDECKER, D. MARTIN, J. FRITSCHE, S. ROHN* (*Department of Food Chemistry and Analysis, Institute of Food Technology and Food Chemistry, Technical University of Berlin, Berlin, Germany; rohn@tu-berlin.de)

      J Chromatogr A 1653, 462442 (2021). Samples were peptides obtained through tryptic hydrolysis of the 5 most abundant milk proteins: α-lactalbumin (α-LA), β-lactoglobulin (β-LG), α-, β- and κ-casein (CA). As standards, synthetic whey and pea (Pisum sativum, Fabaceae) peptides (selected based on the in silico tryptic digest of α-LA, β-LG, legumin A, and vicilin with one or zero miscleavages) were only used in the last assay for prediction of the RF values of peptides with known amino-acid (AA) sequences. Two-dimensional HPTLC on silica gel (pre-washed with methanol and activated 10 min at 100°), first with basic mobile phase sec-butanol – pyridine – ammonia – water 39:34:10:26, and (after 12h drying) in the orthogonal direction with acidic mobile phase sec-butanol – pyridine – acetic acid – water 11:8:2:5. Derivatization for peptides and proteins by immersion into fluorescamine (0.05 % in acetone); visualization under UV 254 nm and 365 nm. Computer-assisted determination of the x- and y-coordinates of the derivatized zones. Repeatability (n=8) of the 2D-HPTLC was statistically tested with the Kolmogorov-Smirnov test for normal distribution and with Dixon’s Q test for outliers. Relative standard deviation (RSD) for the RF values was 12.9 % for the first dimension (y-coordinates) and 16.5 % for the second dimension (x-coordinates). According to their higher intensity and sharpness, 15 – 20 detected zones from each protein hydrolyzate were selected, manually scraped from the derivatized layer, dissolved in formic acid solution (0.1 % in acetonitrile – water 3:2), mixed with an equal volume of matrix (dihydroxybenzoic acid 2 % in acetonitrile – water 3:7), crystallized on air on a ground steel target, before being desorbed by the laser beam of the MALDI-TOF-MS/MS (matrix-assisted laser desorption/ionization time-of-flight tandem mass spectrometry). Direct hyphenation of HPTLC to MS was not performed, to avoid zone diffusion during plate coating with the matrix and to circumvent the stronger binding of polar peptides on the layer.  The MS spectra were acquired in positive reflector mode in m/z range 340 – 4000 (10 – 2500 for fragments), using an external peptide as calibration standard. Identification of 51 from the 85 selected peptides according to AA sequences was performed, using software programs allowing m/z calculation of protein fragments and estimation of cleavage sites. Correlation of the retention behaviour of the peptides with their properties (molecular weight MW, isoelectric point IEP, charges, polarity) was tested with Student’s two-sided t-test after calculation of Pearson’s correlation coefficients. The correlation was significant with IEP, percentages of anionic AA and of non-polar AA; but not with the following properties: MW, percentages of cationic AA and of uncharged polar AA. Finally, based on the correlation results, regression formulas were found to calculate the x- and y-coordinates of any known peptide from the percentage of non-polar AA (or vice-versa). The prediction power of these formulas was verified by repeating the complete 2D-HPTLC-MS experiment with the standard peptides of whey and of peas, and measuring the absolute and relative deviations between the actual x- and y-coordinates and the predicted values. The absolute deviations were higher in the lower RF zones. The average, relative RF value deviations (range 22.1 – 25.7 %) were not different between whey and pea peptides.

      Classification: 2c, 2d, 4e, 18b, 19, 32e
      130 081
      Applicability of the Universal Mixture for describing system suitability and quality of analytical data in routine normal phase High Performance Thin Layer Chromatography methods
      M. SCHMID, T.K. Tiên Do*, I. TRETTIN, E. REICH (*CAMAG, Muttenz, Switzerland; tien.do@camag.com)

      J Chromatogr A 1666, 462863 (2022). Theoretical discussion on the factors determining the RF value of a given substance in a chromatographic system: A) the stationary phase (SP); B) the mobile phase (MP), the composition of which can be different from the solvent mixture prepared because of evaporation, saturation and liquid or gas adsorption effects over migration time; C) the difference of the free energies for the analyte transfer from SP to MP; D) external parameters like temperature and humidity. The universal HPTLC mixture (UHM) is a mixture of reference compounds that can be used for the system suitability test (SST) for the full RF range in all HPTLC experiments. Its composition is: thioxanthen-9-one (0.001 %), guanosine (0.05 %), phthalimide (0.2 %), 9-hydroxyfluorene, octrizole, paracetamol, sulisobenzone and thymidine (each 0.1 %), in methanol. The purpose was to study the potential of UHM to replace SST (described with specific markers in European Pharmacopoeia monographs) and to assess the quality of HPTLC results. TLC and HPTLC silica gel on different support (aluminium, glass) or with different granulometries and binders (classic, Durasil, Adamant), of the UHM, an acetonitrile extract of Abelmoschus manihot flowers (Malvaceae), a methanol extract of Sambucus canadensis flowers (Adoxaceae), and essential oils of Lavandula angustifolia, of Mentha × piperita (Lamiaceae) and of Myristica fragrans (Myristicaceae), as well as the following specific markers (standards): borneol, bornyl acetate, linalool, linalyl acetate (terpenoids), isoeugenol, isoeugenol acetate, chlorogenic acid (phenylpropanoids), gossypin (flavone), gossypetin-glucuronide, hyperoside (flavonol heterosides). Development (after 20 min plate conditioning with a saturated MgCl2 solution) with one of the following mobile phases: (MP1) toluene – ethyl acetate 19:1, especially for essential oils; (MP2) ethyl acetate – butanone – formic acid – water 5:3:1:1, especially for S. canadensis; (MP3) ethyl acetate – acetic acid – formic acid – water 100:11:11:26, especially for A. manihot. Documentation in UV 254 nm and 350 nm, and with white light (reflection + transmission), before and after derivatization. RF values were determined by scanning densitometry at 254 nm in absorption mode (for octrizole, at 366 nm in fluorescence mode with mercury lamp and optical filter K400 nm). For each HPTLC condition, intra-laboratory precision assay of UHM separation was performed (at least 5 analyses) with average RF values and 95 % prediction intervals, and calculating RF differences between pairs of UHM constituents and 95 % confidence intervals, which were max. +/-0.012 of the RF values for all UHM and markers. The sensitivity of UHM, and thus its usefulness as generic SST was demonstrated by repeating the HPTLC experiments with modifying by 10 % the quantity of one of the solvent each time. There were always significant changes in RF values of UHM components and/or in RF differences between pairs of UHM bands; it was often but no always the case with the official specific markers. UHM underwent also significant changes (although less than A. manihot extract) when several silica gel phases were compared under the same HPTLC conditions. This property is crucial to verify the right stationary phase before doing any RF correlations, and could make UHM a universal tool to identify discrepancies between different analyses. Finally, the use of UHM for a computer-supported evaluation of HPTLC results was discussed, either for zone identification and RF corrections (within confidence intervals), or for correlations of entire fingerprints as first step to implement machine learning algorithms.

      Classification: 2a, 2f, 3g, 7, 8a, 15a, 15b, 32e
      130 148
      Rohitukine content across the geographical distribution of Dysoxylum binectariferum Hook F. and its natural derivatives as potential sources of CDK inhibitors
      E. VARUN, K. BHAKTI, K. AISHWARYA, R. HOSUR SURAJ, M.R. JAGADISH, P. MOHANA KUMARA* (*Department of Biotechnology and Crop improvement, Kittur Rani Channamma College of Horticulture, University of Horticultural Sciences of Bagalkot, Arabhavi, India; mohanakumara.p@uhsbagalkot.edu.in)

      Heliyon 9(2), e13469 (2023). Samples were methanolic extracts of different organs (bark, leaves, fruit pericarps, roots, twigs, seed coats and seedlings) of Dysoxylon binectariferum (= D. gotadhora = D. ficiforme, Meliaceae), as well as rohitukine (chromone piperidine alkaloid) isolated from a bark Soxhlet extract through column chromatography. TLC was used to monitor the purity of rohitukine isolation and to compare the fingerprints of the organ extracts. TLC on silica gel in 2 steps, successively with ethyl acetate – hexane 2:1, and with methanol – chloroform – dichloromethane 4:4:1. Visualization under UV 254 nm and 366 nm. Rohitukine (hRF 16) was very concentrated in bark, but present also in pericarps, leaves, twigs, seed coats and seedlings. (Editors note: Mobile phases and distribution of rohitukine were explained directly by the author (successive 2-step development, not biphasic system). The TLC figures did not show unequivocally the presence in roots, but it was confirmed by the author (and already quantified by other methods in  doi.org/10.1371/journal.pone.0158099).

      Classification: 8b, 22, 32e
      130 143
      Estimation of withaferin-A by HPLC and standardization of the Ashwagandhadi lehyam formulation
      A. K. MEENA*, P. REKHA, A. PERUMAL, M. GOKUL, K.N. SWATHI, R. ILAVARASAN (*Captain Srinivasa Murthy Regional Ayurveda Drug Development Institute, Central Council for Research in Ayurvedic Sciences, Arumbakkam, Chennai, India; ajaysheera@gmail.com)

      Heliyon 7(2), e06116 (2021). Samples were a methanolic extract of a semi-solid ayurvedic conserve (ashwagandhadi lehyam) prepared with Withania somnifera roots (Solanaceae) and five other plants, as well as standards: withaferin A and withanolide A (= withaniol), two ergostane triterpene steroids with lactone cycle and epoxide. HPTLC on silica gel with toluene – ethyl acetate – formic acid 6:4:1. Visualization and densitometric scanning at UV 254 nm and 366 nm (deuterium lamps). Derivatization by immersion into vanillin – sulfuric acid reagent, followed by oven heating at 105 °C until optimal coloration. Documentation under white light and densitometry scanning at 540 nm (tungsten lamp). Both analytes (hRF 35 and 45 respectively) were shown at 254 nm and 540 nm (but not at 366 nm), in the standards and in the extract.

      Classification: 8b, 9, 13c, 15a, 32e
      130 146
      Development of a thin-layer chromatography bioautographic assay for neuraminidase inhibitors hyphenated with electrostatic field induced spray ionisation-mass spectrometry for identification of active Isatis indigotica root compounds
      Y. ZANG (Zang Yichao), Y. MIAO (Miao Yu), T. WU (Wu Tao)*, Z. CHENG (Cheng Zhihong)** (*Institute of Chinese Materia Medica, Shanghai University of Traditional Chinese Medicine, Shanghai, China, laurawu2000@163.com; **Department of Natural Medicine, School of Pharmacy, Fudan University, Shanghai, China, chengzhh@fudan.edu.cn)

      J Chromatogr A 1638, 461597 (2021). Samples were Isatis tinctoria (= I. indigotica) root extracts (Brassicaceae) and their fractions. Standards were oseltamivir acid (OA), a neuraminidase (NA) inhibitor; pinoresinol (PR, a lignan), β-sitosterol (SS, a sterol), and dihydro-neoascorbigen (DHNA, an alkaloid). HPTLC / TLC on silica gel with (1) petroleum ether – ethyl acetate – acetic acid 48:8:1 for petroleum ether extracts and SS, or 30:40:1 for ethyl acetate extracts, or 10:30:1 for PR; (2) with toluene – ethyl acetate – methanol – formic acid 16:3:1:2 or 10:4:1:2 also for ethyl acetate extracts and DHNA; (3) with n-butanol – acetic acid – water 25:4:3 for butanol extracts. OA was applied but not developed. RP-18, polyamide, cellulose, alumina layers were tested, but the resolution was lower. Derivatization by spraying with sulfuric acid (10 % in ethanol). Enzymatic assay by immersion of the plates into neuraminidase solution (6 U/mL), followed by 1 h incubation at 37 °C and by immersion into chromogenic substrate solution (1.75 mM 5-bromo-4-chloro-3-indolyl-α-D-N-acetylneuraminic acid). After 5 min, NA inhibitors were seen as white zones on blue background. The experiment was previously improved for the following parameters: incubation times, substrate and enzyme concentrations, followed by statistical evaluation and calculations using Box-Behnken design. Quantification by absorbance measurement (detection wavelength 605 nm, reference wavelength 420 nm). In optimal conditions, OA had LOD 300 ng/zone. Zones of interest on underivatized plates were directly submitted to MS, using EFISI (electrostatic-field-induced spray ionisation), as follows. Chromatograms were immersed 1–3 s into dimethicone – n-hexane 1:1 to form a hydrophobic film, and dried 30 min at room temperature; on the analyte spot, a hydrophilic droplet was formed with 5 µL methanol – water 1:1, extracting the analyte from the layer; the analyte was further attracted through a capillary tube (3–4 cm long, made of non-deactivated fused silica) under a strong electrostatic field, into the in-let orifice of the triple-quadrupole ­– linear ion-trap MS (induction voltage 4 kV; capillary voltage 40 V; tube lens voltage 100 V; capillary temperature 200 °C). Full-scan spectra were recorded in m/z range 50 – 1000, helium was used for collision-induced dissociation. 11 active compounds were identified in the extract: SS, 6 alkaloids (including cycloanthranilylproline, DHNA, hydroxy-indirubin, isatindigodiphindoside, isatindinoline A and), 3 lignans (including PR and isolariciresinol), 1 fatty acid (trihydroxy-octadecenoic acid).

      Classification: 4e, 8a, 8b, 11a, 13c, 22
      130 149
      HPTLC/HPLC-mass spectrometry identification and NMR characterization of major flavonoids of wild lemongrass (Cymbopogon giganteus) collected in Burkina Faso
      R.K. BATIONO*, C.M. DABIRÉ, A. HEMA, R.H.CH. NÉBIÉ, E. PALÉ, M. NACRO (*Laboratory of Applied Organic Chemistry and Physics, Joseph Ki-Zerbo University, Ouagadougou, Burkina Faso; kindanloun@gmail.com)

      Heliyon 8(8), e10103 (2022). Samples were a methanolic extract of Cymbopogon giganteus leaves (= C. caesius subsp. giganteus, Poaceae), as well as flavones as standards: isorhamnetin, luteolin and orientin (=luteolin 8-C-glucoside). HPTLC on silica gel with ethyl acetate – acetic acid – formic acid – water 100:11:11:26. Derivatization for flavones with Neu’s reagent (ethanolamine diphenylborate – PEG). Visualization under UV 365 nm. The standards (hRF 75, 70-72 and 96, respectively) were not detected in the extract. Some analytes detected by the reagent were scraped from the underivatized plate into a tube, and injected through a TLC-MS interface into a double-quadrupole – time-of-flight MS (electrospray ionization). Full mass scan spectra were recorded in positive and negative ionization modes in m/z range 150–550. For 3 of the compounds, isolated through MPLC columns, the HPTLC-MS results, combined to the NMR and HPLC-MS analyses, allowed the identification as epicatechin (hRF 86, a flavanol, not coloured by Neu’s reagent) and as luteolin 8-C- and 6-C-glucosides (hRF 67-70).

      Classification: 4e, 8a, 32e
      130 040
      Partial characterization of novel inulin-like prebiotic fructooligosaccharides of Sechium edule (Jacq.) Sw. (Cucurbitaceae) tuberous roots
      B. BANDYOPADHYAY, V. MANDAL, N. MANDAL* (*Plant and Microbial Physiology and Biochemistry Laboratory, Department of Botany, University of Gour Banga, Malda –732 103, WB, India, mandalvivek@gmail.com)

      J. Food. Biochem. 45, e13764 (2021). HPTLC of L-arabinose, D-fructose, D-fucose, D-galactose, D-glucose, D-mannose, D-rhamnose, D-xylose in the roots of Sechium edule on silica gel with chloroform - n-butanol - methanol - water - acetic acid 9:15:10:3:3. Detection by spraying with 5 % sulfuric acid in methanol containing 0.1 % orcinol, followed by heating at 80 °C for 5-10 min.

      Classification: 10a
      130 145
      1′-Acetoxychavicol acetate from Alpinia galanga represses proliferation and invasion, and induces apoptosis via HER2-signaling in endocrine-resistant breast cancer cells
      N. PRADUBYAT, A. GIANNOUDIS, T. ELMETWALI, P. MAHALAPBUTR, C. PALMIERI, C. MITRPANT, Wannarasmi KETCHART* (*Department of Pharmacology, Faculty of Medicine, Chulalongkorn University, Pathumwan, Bangkok, Thailand; wannarasmi.k@chula.ac.th)

      Plant Med 88(2), 163-178 (2022). TLC was used to verify the purity of acetoxychavicol acetate (a phenylpropanoid) isolated through column chromatography from a hexane extract of Alpinia galanga rhizomes (Zingiberaceae). TLC on silica gel with n-hexane – ethyl acetate 17:3, evaluation under UV 254 nm.

      Classification: 7, 32e
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