Plant Cell, Tissue and Organ Culture (PCTOC) 146 (2), 225–236 (2021). Samples were hydro-ethanolic extracts of Musa acuminata and M. balbisiana (Musaceae) plantlets, obtained from in vitro meristem-derived gel cultures with saccharose, temperature or jasmonic acid as elicitors of production of secondary metabolites. HPTLC on silica gel  (RP18W phase for genotoxicity assay) with ethyl acetate – toluene – formic acid – water 34:5:7:5. Evaluation under white light, UV 254 nm and 366 nm. Effect-directed assays (EDA) were performed (by immersion or by automated piezoelectrical spraying) for free radical (DPPH•) scavengers, and, after neutralization, for enzymatic inhibitors (acetyl-cholinesterase, α-glucosidase) and for genotoxicity (SOS response – UMU-C test). For comparison, positive control standards were applied but not developed, before the assays (gallic acid, physostigmine, acarbose, nitroquinoline-1-oxide, respectively). After the first assay, absorbance densitometry was performed through inverse scanning at 546 nm using mercury lamp (fluorescence mode without optical filter). Antioxidant activity was found the highest when cultures were maintained at 20 °C (vs. 15 and 26 °C) and supplemented with saccharose (40-50 g/L) or jasmonic acid (200 µM).

ALTEX - Alternatives to animal experimentation, 38(3), 387-397 (2021). Samples were standards of food contact contaminants with genotoxicity (4-nitroquinoline-1-oxide (NQO), aflatoxin B1, hexachloroethane, nitroso-ethylurea, phenformin, PhIP) or negative controls (alosetron, mannitol), and extracts of coated tin cans (extracted with n-hexane – acetone at 25°C for 16 h or by heating at 60 °C with ethanol 95 % for 240 h). HPTLC on RP18W layer, pretreated to harden the binder by heating 1 h at 120 °C, prewashed with methanol and with ethyl acetate and dried 4 min in cold air stream after each development. Application areas were focused to their upper edges by a two-fold elution with ethyl acetate, followed by 1 min drying in cold air stream. Development with toluene – ethyl acetate 8:5, followed by 5 min drying, neutralization with citrate buffer (pH 12) and 4 min drying. Effect-directed analysis for genotoxicity (SOS response – UMU-C test, using NQO as positive control) by immersion (speed 3.5 cm/s, time 3 s) into Salmonella typhimurium suspension and, after 3 h incubation at 37 °C and 4 min drying in cold air stream, into one of two fluorogenic substrate solutions (methylumbelliferyl- vs. resorufin-galactopyranoside). After 1 h incubation at 37 °C, visualization of mutagenic compounds as (blue vs. red) fluorescent zones at FLD 366 nm, and densitometry performed with mercury lamp for fluorescence (at  366 / >400nm vs. 550 / >580 nm, respectively). Further validation experiments, including spiking extracts with NQO, were performed showing good mean reproducibility, no quenching or other matrix effects. Lowest effective concentration of NQO was 0.53 nM (20 pg/band), 176 times lower than in the corresponding microtiter plate assays.

Antioxidants, 10(1), 117 (2019). Samples were methanolic extracts of Camellia sinensis leaves or commercial black, white or green tea powdered extracts (Theaceae), as well as standards of caffeine (methylxanthine alkaloid), of flavonols (quercetin, rutin) and of flavanols (catechin, catechin-gallate, epicatechin, epicatechin-gallat, epigallocatechin, epigallocatechin-gallate, gallocatechin, and the thearubigin theaflavin). HPTLC on RP18-W phase (with classical irregular particles (SP1) vs. LiChrospher phase with spherical particles (SP2)), prewashed with methanol – water 4:1 and dried 20 min at 110 °C, developed with citric acid 0,295 % in acetonitrile – water 3:10 for SP1, with citric acid 0,17 % in acetonitrile – water 1:2 for SP2. Visualization under white light, UV 254 nm and 366 nm. Absorbance densitometry was performed at UV 275 nm (deuterium lamp). Derivatization with A) Fast Blue B salt reagent followed by 3 min heating at 100 °C, and by absorbance densitometry at 546 nm for flavanols (mercury lamp); B) natural product reagent (on the same plate), followed by fluorescence densitometry of flavonols at FLD 366/>400 nm (mercury lamp); C) anisaldehyde sulfuric acid reagent, followed by 2 min heating at 110 °C, to detect all flavonoids. Effect-directed analysis was performed using piezoelectric spraying: A) for free radical (DPPH•) scavengers (vs. gallic acid as positive control); B) for activity against Gram-negative Aliivibrio fischeri (bioluminescence assay, vs. caffeine) or Gram-positive Bacillus subtilis (vs. tetracycline); C) for enzymatic inhibition of acetyl-cholinesterase, α- and β-glucosidase, β-glucuronidase, tyrosinase (vs. rivastigmine, acarbose, imidazole, D–saccharolactone and kojic acid, respectively). When SP2 was used, previous neutralization was required through spraying of sodium bicarbonate buffer (2.5 %, pH 8). AChE inhibition assay was performed with indoxyl acetate (0.1 % in ethanol) as substrate, sprayed before the enzyme. After incubation (30min at 37°C), inhibition bands appeared indigo or blue under white light, but the substrate coloured theaflavin in yellow.

J Chromatogr A, 1605, 460371 (2019). HPTLC of toluene – ethyl acetate extracts of Primula boveana leaves and of P. veris (Primulaceae) on silica gel with n-hexane – ethyl acetate 7:3. Visualization under white light, UV 254 nm and 366 nm. Derivatization by spraying with anisaldehyde sulfuric acid reagent, followed by heating for 4 min at 105 °C. Effect-directed analysis: A) for activity against Gram-negative (Aliivibrio fischeri bioluminescence assay) or Gram-positive bacteria (Bacillus subtilis bioassay) using automated immersion; B) for enzymatic inhibition (acetyl- and butyryl-cholinesterase) using piezoelectric spraying, with rivastigmine as standard, and absorbance spectra (500 nm) for P. boveana active bands measured by inverse scanning. Active bands were eluted from the untreated layer with methanol through the oval elution head of a TLC-MS interface pump, into a quadrupole-Orbitrap mass spectrometer to record full scan mass spectra (m/z 100−1000) using electrospray ionization (ESI voltage 3.5kV for P. boveana, -3kV for P. veris, source temperature 250°C). With the further help of preparative HPLC – NMR, they were identified as linoleic and linolenic acids in P. veris, and as flavone and its derivatives: hydroxyflavone, methoxyflavone and zapotin, in P. boveana.

J Chromatogr A, 1605, 460366 (2019). Samples were standards and complex mixtures of non-ribosomally synthesized cyclic lipopeptides (CLPs) from Bacillus strains (Bacillaceae) found in soil or in manure: B. amyloliquefaciens (SS-12.6, SS-13.1, SS-27.2, SS-38.4) and B. pumilus (SS-10.7). Two extraction methods were compared: ethyl acetate extraction (Ex1), and the acidic precipitation followed by methanol extraction (Ex2). HPTLC on silica gel with chloroform – methanol – water 65:25:4. Detection under white light, UV 254 nm and 366 nm. Absorption densitometry measured at 190 nm. Derivatization for peptides, amino acids and amino derivatives, by immersion into ninhydrin – collidine reagent (ninhydrin 0.3 %, collidine 5 %, acetic acid 5 %, in ethanol), followed by heating 5 min at 110 °C. Effect-directed analysis using automated immersion: A) for free radical (DPPH•) scavengers; B) for enzymatic inhibition (acetyl-cholinesterase, α-glucosidase); C) for activity against Gram-negative (Aliivibrio fischeri bioluminescence assay) or Gram-positive bacteria (Bacillus subtilis bioassay). Active bands were eluted with methanol through the oval elution head of a TLC-MS interface pump, into a quadrupole-Orbitrap mass spectrometer. Full scan mass spectra (m/z 200−2000) in positive and in negative ionization modes were recorded using heated electrospray ionization (HESI, spray voltage 3.5 kV, capillary temperature 270 °C). Active zones were assigned to be CLPs: iturin A, surfactin dimethyl-ester, and surfactin, fengycin and kurstakin homologues. Ex1 provided richer extracts compared to Ex2. Standards were seen to contain a free radical scavenging impurity.

J Chromatogr A, 1609, 460438 (2020). HPTLC of defatted hydro-methanolic extract of Anarrhinum pubescens (= A. duriminium) aerial parts (Plantaginaceae) on silica gel with chloroform – methanol 9:2. When intended for MS experiments, layers were previously washed twice with methanol – water 4:1 and heated 20 min at 110 °C. Derivatization by automatic piezoelectric spraying of anisaldehyde sulfuric acid reagent, followed by heating 4 min at 105 °C. Effect-directed analysis for acetyl-cholinesterase (AChE) inhibitors was performed by successive piezoelectric sprayings with TRIS buffer, with AChE solution and (after 30 min incubation at 37 °C) with naphthyl acetate and Fast Blue salt B solution. White inhibiting zones on purple background were documented under white light, and densitometry was measured by scanning in fluorescence mode at 500 nm. One of the active bands was eluted from untreated layer with methanol through the oval elution head of a TLC-MS interface pump, into a quadrupole-Orbitrap mass spectrometer using heated electrospray ionization (HESI); a full scan mass spectrum (m/z 50−750) in the positive ionization mode was recorded, as well as HRMS/MS data across a range of collision energies (10–50 V). The compound was identified as foliamenthoyl-cinnamoyl-antirrhinoside. It was applied with two other active antirrhinosides (iridoids), all isolated from the extract through column chromatography, on an HPTLC layer without migration and submitted to AChE assay; their activity was expressed as equivalency towards rivastigmine tartrate as positive control. 

J Chromatogr A, 1616, 461434 (2020). Samples were acetonic extracts of Malus domestica fruit peels (Rosaceae) and of Salvia officinalis, Thymus vulgaris and Origanum vulgare spice powders (Lamiaceae), as well as standards of maleic acid (dicarboxylic acid), carvacrol, thymol (phenolic monoterpenes), rosmanol (phenolic diterpene), betulinic acid, corosolic acid (CA), maslinic acid (MA), oleanolic acid (OA) and its isomer ursolic acid (UA) (triterpenes). HPTLC on silica gel, when intended for MS and NMR experiments, layers were prewashed twice with methanol – water 3:1, followed by 30 min drying at 120 °C. When intended for quantitative densitometry, start zones were submitted to prechromatographic derivatization with iodine solution (10 g/L in chloroform) allowed to migrate up to 12 mm, incubated 10 min at 27 °C and dried under cold air stream; this allowed separation of isomeric triterpenes. Separation with toluene – methanol – ethyl acetate 17:2:1 after 5 min chamber saturation at 50 % relative humidity. CA coeluted with MA, and OA with UA. Four hyphenations: A) Quantitative HPTLC densitometry for active analytes was performed by measuring absorption at 665 nm with a tungsten lamp after immersion of the chromatograms in anisaldehyde sulfuric acid reagent and heating 5 min at 110 °C. Linear range was obtained at 25 - 200 ng/band for OA and 100 - 400 ng/band for UA. B) Effect-directed analysis by immersing the chromatograms into Gram-positive Bacillus subtilis suspension for antibacterial activity and into acetyl-cholinesterase and tyrosinase solutions for enzymatic inhibition. C) Active bands were eluted with methanol through the oval elution head and in-line filter frit of a TLC-MS interface pump, into a quadrupole-Orbitrap mass spectrometer. Full scan mass spectra (m/z 100−1000) in the positive and negative ionization modes were recorded using heated electrospray ionization (HESI, spray voltage 3.5 kV, capillary temperature 270 °C, probe heater temperature 200 °C). D) With higher amounts applied, preparative HPTLC, by scraping the multipotent band corresponding to OA and UA, and dissolving these analytes in methanol, for NMR analyses (1H raw or deconvoluted, and 2D 1H–13C Heteronuclear Single Quantum Coherence). Both isomers were distinguished by their allylic H-18 protons and separately quantified by applying PULCON method (PUlse Length-based CONcentration). LOQ was 267 μM for OA and 173 μM for UA; optimal range was 300 – 4600 mM, corresponding to 126 - 2090 μg of triterpenes.

J Chromatogr A, 1637, 461836 (2021). Successive ultrasonic macerates of Ficus religiosa leaves (Moraceae) were separated with toluene – ethyl acetate – methanol 6:3:1 on HPTLC silica gel or (for yeast and genotoxicity assays) on RP18W phase. For MS experiments, layers were previously washed twice with methanol – formic acid 10:1, once with acetonitrile – methanol 2:1 and air-dried. Chromatograms were documented under white light, UV 254 nm and 366 nm. Afterwards, 11 derivatization assays were performed with the following reagents, either without heating: Dragendorff’s reagent; Fast Blue B salt; ferric chloride; natural product reagent - PEG 400; primuline; or requiring heating for 5 min at 120 °C: anisaldehyde sulfuric acid; diphenylamine aniline phosphoric acid; 2-naphthol sulfuric acid; ninhydrin; Tillmans' reagent; vanillin sulfuric acid. Besides, 12 effect-directed assays (EDA) were performed for free radical (DPPH• and ABTS•) scavengers, for enzyme inhibitors (α-amylase, acetyl- and butyryl-cholinesterase, α- and β-glucosidase, tyrosinase), for antimicrobial compounds (Gram-positive Bacillus subtilis assay, Gram-negative Aliivibrio fischeri bioluminescence assay), for phytoestrogens (planar yeast estrogen assay) and genotoxicity (SOS response – UMU-C test by successive immersions into citric buffer, into Salmonella typhimurium suspension and into methylumbelliferyl-galactopyranoside solution, followed by FLD at 366nm of mutagenic compounds as blue fluorescent zones, using 4-nitroquinoline 1-oxide as positive control). No activity was found for the last two assays. Ethyl acetate extracts of all samples were the most active. After EDA, most active bands were scanned for semi-quantitative equivalence densitometry at 546 nm using mercury lamp, compared to the following standards: acarbose, gallic acid, imidazole, kojic acid, physostigmine, tetracycline, depending on the assay. The bands of 3 multipotent compounds were eluted with methanol through the oval elution head and in-line filter frit of a TLC-MS interface pump, into a quadrupole-Orbitrap mass spectrometer. Full scan mass spectra (m/z 50−750) in the positive and negative ionization mode were recorded using heated electrospray ionization (HESI, spray voltage 3.5 kV, capillary temperature 270 °C, probe heater temperature 200 °C). MS-MS spectra were recorded in the negative mode using HCD-NCE (higher-energy collisional dissociation –normalized collision energy, with stepped negative collision energies from 10 to 40 eV). The three active zones were assigned to palmitic acid, to linolenic acid and to its di-oxygenated derivative.