Highlights from the Lipid Analysis Literature - 2019

The following references were collected as part of a weekly literature search that reflects my (former) personal research interests. However, most mainstream lipid analytical topics are covered. Among the exceptions are "steroidal hormones", "prostanoids", "fat-soluble vitamins" and "terpenoids", although some papers in these categories may be posted. My intention is to list only those papers that exhibit novel analytical methodology as opposed to tried and tested methods, although this may appear to introduce a bias towards modern mass spectrometry techniques. References are listed alphabetically by the first author.

References for the next month are added at approximately monthly intervals by merging with the existing references. The most recent references of all will be found in the web page - "This month's references".

Acquaro, V.R., Gomez-Rios, G.A., Tascon, M., Queiroz, M.E.C. and Pawliszyn, J. Analysis of endocannabinoids in plasma samples by biocompatible solid-phase microextraction devices coupled to mass spectrometry. Anal. Chim. Acta, 1091, 135-145 (2019); DOI.
Ahern, K.W., Serbulea, V., Wingrove, C.L., Palas, Z.T., Leitinger, N. and Harris, T.E. Regioisomer-independent quantification of fatty acid oxidation products by HPLC-ESI-MS/MS analysis of sodium adducts. Sci. Rep., 9, 11197 (2019); DOI.
Akchich, A., Charton, J. and Lipka, E. Application of tandem coupling of columns in supercritical fluid chromatography for stereoisomeric separation: Optimization and simulation. J. Chromatogr. A, 1588, 115-126 (2019); DOI.
Alberdi-Cedeno, J., Ibargoitia, ML. and Guillen, MD Monitoring of minor compounds in corn oil oxidation by direct immersion-solid phase microextraction-gas chromatography/mass spectrometry. New oil oxidation markers. Food Chem., 290, 286-294 (2019); DOI.
Alcoriza-Balaguer, M.I., Garcia-Canaveras, J.C., Lopez, A., Conde, I., Juan, O., Carretero, J. and Lahoz, A. LipidMS: An R package for lipid annotation in untargeted liquid chromatography-data independent acquisition-mass spectrometry lipidomics. Anal. Chem., 91, 836-845 (2019); DOI.
Alfatah, M., Wong, J.H., Nge, C.E.N., Kong, K.W., Low, K.N., Leong, C.Y., Crasta, S., Munusamy, M., Chang, A.M.L., Hoon, S., Ng, S.B., Kanagasundaram, Y. and Arumugam, P. Hypoculoside, a sphingoid base-like compound from Acremonium disrupts the membrane integrity of yeast cells. Sci. Rep., 9, 710 (2019); DOI.
An, J.U., Lee, I.G., Ko, Y.J. and Oh, D.K. Microbial synthesis of linoleate 9S-lipoxygenase derived plant C18 oxylipins from C18 polyunsaturated fatty acids. J. Agric. Food Chem., 67, 3209-3219 (2019); DOI.
Ando, A., Oka, M. and Satomi, Y. Deoxysphingolipids and ether-linked diacylglycerols accumulate in the tissues of aged mice. Cell Biosci., 9, 61 (2019); DOI.
Anthonymuthu, T.S., Kenny, E.M., Hier, Z.E., Clark, R.S.B., Kochanek, P.M., Kagan, V.E. and Bayir, H. Detection of brain specific cardiolipins in plasma after experimental pediatric head injury. Exp. Neurol., 316, 63-73 (2019); DOI.
Anthonymuthu, T.S., Kenny, E.M., Lamade, A.M., Gidwani, H., Krehel, N.M., Misse, A., Gao, X.T., Amoscato, A.A., Straub, A.C., Kagan, V.E., Dezfulian, C. and Bayir, H. Lipidomics detection of brain cardiolipins in plasma is associated with outcome after cardiac arrest. Crit. Care Med., 47, E292-E300 (2019); DOI.
Antonelli, M., Benedetti, B., Cavaliere, C., Cerrato, A., La Barbera, G., Montone, C.M., Piovesana, S. and Lagana, A. Enrichment procedure based on graphitized carbon black and liquid chromatography-high resolution mass spectrometry for elucidating sulfolipids composition of microalgae. Talanta, 205, 120162 (2019); DOI.
Aoki, K., Heaps, A.D., Strauss, K.A. and Tiemeyer, M. Mass spectrometric quantification of plasma glycosphingolipids in human GM3 ganglioside deficiency. Clin. Mass Spectrom., 14, 106-114 (2019); DOI.
Aristizabal-Henao, J.J., Fernandes, M.F., Duncan, R.E. and Stark, K.D. Development of a rapid ultra high-performance liquid chromatography/tandem mass spectrometry method for the analysis of sn-1 and sn-2 lysophosphatidic acid regioisomers in mouse plasma. Lipids, 54, 479-486 (2019); DOI.
Atapattu, S.N. and Rosenfeld, J.M. Micro scale analytical derivatizations on solid phase. Trends Anal. Chem., 113, 351-356 (2019); DOI.
Ayakannu, T., Taylor, A.H., Marczylo, T.H., Maccarrone, M. and Konje, J.C. Identification of novel predictive biomarkers for endometrial malignancies: N-acylethanolamines. Front. Oncol., 9, 430 (2019); DOI.
Azab, S., Ly, R. and Britz-McKibbin, P. Robust method for high-throughput screening of fatty acids by multisegment injection-nonaqueous capillary electrophoresis-mass spectrometry with stringent quality control. Anal. Chem., 91, 2329-2336 (2019); DOI.
Baedke, P.E., Rucker, H.R., Mason, R.T. and Parker, M.R. Chemical isolation, quantification, and separation of skin lipids from reptiles. JOVE-J. Vis. Exp., 144, e59018 (2019); DOI.
Bai, A.P., Liu, X., Bielawski, J. and Hannun, Y.A. Bioactive sphingolipid profile in a xenograft mouse model of head and neck squamous cell carcinoma. PLOS One, 14, e0215770 (2019); DOI.
Balas, L., Rise, P., Gandrath, D., Rovati, G., Bolego, C., Stellari, F., Trenti, A., Buccellati, C., Durand, T. and Sala, A. Rapid metabolization of protectin D1 by beta-oxidation of its polar head chain. J. Med. Chem., 62, 9961-9975 (2019); DOI.
Baldensperger, T., Di Sanzo, S., Ori, A. and Glomb, M.A. Quantitation of reactive acyl-coA species mediated protein acylation by HPLC-MS/MS. Anal. Chem., 91, 12336-12343 (2019); DOI.
Balgoma, D., Guitton, Y., Evans, J.J., Le Bizec, B., Dervilly-Pinel, G. and Meynier, A. Modeling the fragmentation patterns of triacylglycerides in mass spectrometry allows the quantification of the regioisomers with a minimal number of standards. Anal. Chim. Acta, 1057, 60-69 (2019); DOI.
Balis, F.M., Busch, C.M., Desai, A.V., Hibbitts, E., Naranjo, A., Bagatell, R., Irwin, M. and Fox, E. The ganglioside G(D2) as a circulating tumor biomarker for neuroblastoma. Pediatric Blood Cancer, e28031 (2019); DOI.
Barre, F., Rocha, B., Dewez, F., Towers, M., Murray, P., Claude, E., Cillero-Pastor, B., Heeren, R. and Siegel, T.P. Faster raster matrix-assisted laser desorption/ionization mass spectrometry imaging of lipids at high lateral resolution. Int. J. Mass Spectrom., 437, 38-48 (2019); DOI.
Barrientos, R.C. and Zhang, Q.B. Differential isotope labeling by permethylation and reversed-phase liquid chromatography-mass spectrometry for relative quantification of intact neutral glycolipids in mammalian cells. Anal. Chem., 91, 9673-9681 (2019); DOI.
Barrientos, R.C. and Zhang, Q.B. Fragmentation behavior and gas-phase structures of cationized glycosphingolipids in ozone-induced dissociation mass spectrometry. J. Am. Soc. Mass Spectrom., 30, 1609-1620 (2019); DOI.
Basu, S.S., McMinn, M.H., Lopez, B.G.C., Regan, M.S., Randall, E.C., Clark, A.R., Cox, C.R. and Agar, N.Y.R. Metal oxide laser ionization mass spectrometry imaging (MOLI MSI) using cerium(IV) oxide. Anal. Chem., 91, 6800-6807 (2019); DOI.
Benham, K., Fernandez, F.M. and Orlando, T.M. Sweep jet collection laser-induced acoustic desorption atmospheric pressure photoionization for lipid analysis applications. J. Am. Soc. Mass Spectrom., 30, 647-658 (2019); DOI.
Bestard-Escalas, J., Maimo-Barcelo, A., Perez-Romero, K., Lopez, D.H. and Barcelo-Coblijn, G. Ins and outs of interpreting lipidomic results. J. Mol. Biol., 431, 5039-5062 (2019); DOI.
Blevins, M.S., Klein, D.R. and Brodbelt, J.S. Localization of cyclopropane modifications in bacterial lipids via 213 nm ultraviolet photodissociation mass spectrometry. Anal. Chem., 91, 6820-6828 (2019); DOI.
Bloor, S., Catchpole, O., Mitchell, K., Webby, R. and Davis, P. Antiproliferative acylated glycerols from New Zealand propolis. J. Nat. Prod., 82, 2359-2367 (2019); DOI.
Blum, M., Dogan, I., Karber, M., Rothe, M. and Schunck, W.H. Chiral lipidomics of monoepoxy and monohydroxy metabolites derived from long-chain polyunsaturated fatty acids. J. Lipid Res., 60, 135-148 (2019); DOI.
Borden, S.A., Damer, H.N., Krogh, E.T. and Gill, C.G. Direct quantitation and characterization of fatty acids in salmon tissue by condensed phase membrane introduction mass spectrometry (CP-MIMS) using a modified donor phase. Anal. Bioanal. Chem., 411, 291-303 (2019); DOI.
Bowman, A.P., Heeren, R.M.A. and Ellis, S.R. Advances in mass spectrometry imaging enabling observation of localised lipid biochemistry within tissues. Trends Anal. Chem., 120, 115197 (2019); DOI.
Bredehoft, J., Bhandari, D.R., Pflieger, F.J., Schulz, S., Kang, J.X., Laye, S., Roth, J., Gerstberger, R., Mayer, K., Spengler, B. and Rummel, C. Visualizing and profiling lipids in the OVLT of Fat-1 and wild type mouse brains during LPS-induced systemic inflammation using AP-SMALDI MSI. ACS Chem. Neurosci., 10, 4394-4406 (2019); DOI.
Brogden, G., Husein, D.M., Steinberg, P. and Naim, H.Y. Isolation and quantification of sphingosine and sphinganine from rat serum revealed gender differences. Biomolecules, 9, 459 (2019); DOI.
Burnum-Johnson, K.E., Zheng, X., Dodds, J.N., Ash, J., Fourches, D., Nicora, C.D., Wendler, J.P., Metz, T.O., Waters, K.M., Jansson, J.K., Smith, R.D. and Baker, E.S. Ion mobility spectrometry and the omics: Distinguishing isomers, molecular classes and contaminant ions in complex samples. Trends Anal. Chem., 116, 292-299 (2019); DOI.
Buszewski, B., Walczak, J., Skoczylas, M. and Haddad, P.R. High performance liquid chromatography as a molecular probe in quantitative structure-retention relationships studies of selected lipid classes on polar-embedded stationary phases. J. Chromatogr. A, 1585, 105-112 (2019); DOI.
Butovich, I.A., Bhat, N. and Wojtowicz, J.C. Comparative transcriptomic and lipidomic analyses of human male and female meibomian glands reveal common signature genes of meibogenesis. Int. J. Mol. Sci., 20, 4539 (2019); DOI.
Calderon, C., Sanwald, C., Schlotterbeck, J., Drotleff, B. and Lammerhofer, M. Comparison of simple monophasic versus classical biphasic extraction protocols for comprehensive UHPLC-MS/MS lipidomic analysis of Hela cells. Anal. Chim. Acta, 1048, 66-74 (2019); DOI.
Calvano, C.D., Ventura, G., Sardanelli, A.M., Losito, I., Palmisano, F. and Cataldi, T.R.I. Identification of neutral and acidic glycosphingolipids in the human dermal fibroblasts. Anal. Biochem., 581, 113348 (2019); DOI.
Canzi, E.F., Lopes, B.R., Robeldo, T., Borra, R., Da Silva, M.F.G.F., Oliveira, R.V., Maia, B.H.N.S. and Cass, Q.B. Prostaglandins E-2 and F-2 alpha levels in human menstrual fluid by online solid phase extraction coupled to liquid chromatography tandem mass spectrometry (SPE-LC-MS/MS). J. Chromatogr. B, 1109, 60-66 (2019); DOI.
Cao, G.D., Ding, C., Ruan, D.L., Chen, Z.B., Wu, H.Q., Hong, Y.J. and Cai, Z.W. Gas chromatography-mass spectrometry based profiling reveals six monoglycerides as markers of used cooking oil. Food Control, 96, 494-498 (2019); DOI.
Carballo-Marrero, S., Prats-Moya, M., Maestre-Perez, S.E. and Todoli-Torro, J.L. Microwave assisted high performance liquid chromatography for the separation of triacylglycerols in vegetable oils using an evaporative light scattering detector. Food Chem., 300, 125203 (2019); DOI.
Casabuono, A.C., Sisti, F., Fernandez, J., Hozbor, D. and Couto, A.S. Bordetella bronchiseptica glycosyltransferase core mutants trigger changes in lipid A structure. J. Am. Soc. Mass Spectrom., 30, 1679-1689 (2019); DOI.
Casati, S., Ravelli, A., Angeli, I., Durello, R., Minoli, M. and Orioli, M. An automated sample preparation approach for routine liquid chromatography tandem-mass spectrometry measurement of the alcohol biomarkers phosphatidylethanol 16:0/18:1, 16:0/16:0 and 18:1/18:1. J. Chromatogr. A, 1589, 1-9 (2019); DOI.
Castillo-Peinado, L.S., Lopez-Bascon, M.A., Mena-Bravo, A., de Castro, M.D.L. and Priego-Capote, F. Determination of primary fatty acid amides in different biological fluids by LC-MS/MS in MRM mode with synthetic deuterated standards: Influence of biofluid matrix on sample preparation. Talanta, 193, 29-36 (2019); DOI.
Cetraro, N., Cody, R.B. and Yew, J.Y. Carbon-carbon double bond position elucidation in fatty acids using ozone-coupled direct analysis in real time mass spectrometry. Analyst, 144, 5848-5855 (2019); DOI.
Chagovets, V., Kononikhin, A., Tokoreva, A., Bormotov, D., Starodubtseva, N., Kostyukevich, Y., Popov, I., Frankevich, V. and Nikolaev, E. Relative quantitation of phosphatidylcholines with interfered masses of protonated and sodiated molecules by tandem and Fourier-transform ion cyclotron resonance mass spectrometry. Eur. J. Mass Spectrom., 25, 259-264 (2019); DOI.
Chan, W., Zhao, Y. and Zhang, J.Y. Evaluating the performance of sample preparation methods for ultra-performance liquid chromatography/mass spectrometry based serum metabonomics. Rapid Commun. Mass Spectrom., 33, 561-568 (2019); DOI.
Chauhan, M.Z., Valencia, A.K., Piqueras, M.C., Algeciras, M.E. and Bhattacharya, S.K. Optic nerve lipidomics reveal impaired glucosylsphingosine lipids pathway in glaucoma. Invest. Ophthalmol. Vis. Sci., 60, 1789-1798 (2019); DOI.
Chaves, A.B., Yoshinaga, M.Y., Dantas, L.S., Diniz, L.R., Pinto, I.F.D. and Miyamoto, S. Mass spectrometry characterization of thiol conjugates linked to polyoxygenated polyunsaturated fatty acid species. Chem. Res. Toxicol., 32, 2028-2041 (2019); DOI.
Chechetkin, I.R., Blufard, A.S., Yarin, A.Y., Fedina, E.O., Khairutdinov, B.I. and Grechkin, A.N. Detection and identification of complex oxylipins in meadow buttercup (Ranunculus acris) leaves. Phytochemistry, 157, 92-102 (2019); DOI.
Chen, G.Y. and Zhang, Q.B. Comprehensive analysis of oxylipins in human plasma using reversed-phase liquid chromatography-triple quadrupole mass spectrometry with heatmap-assisted selection of transitions. Anal. Bioanal. Chem., 411, 367-385 (2019); DOI.
Chen, H.Q., Krishnamachari, S., Guo, J.S., Yao, L.H., Murugan, P., Weigh, C.J. and Turesky, R.J. Quantitation of lipid peroxidation product DNA adducts in human prostate by tandem mass spectrometry: a method that mitigates artifacts. Chem. Res. Toxicol., 32, 1850-1862 (2019); DOI.
Chen, J.Z. and Panthi, S. Lipidomic analysis of meibomian gland secretions from the tree shrew: Identification of candidate tear lipids critical for reducing evaporation. Chem. Phys. Lipids, 220, 36-48 (2019); DOI.
Chen, J.Z., Nichols, K.K., Wilson, L., Barnes, S. and Nichols, J.J. Untargeted lipidomic analysis of human tears: A new approach for quantification of O-acyl-omega hydroxy fatty acids. Ocular Surface, 17, 347-355 (2019); DOI.
Chen, Z., Gao, Z.J., Wu, Y., Shrestha, R., Imai, H., Uemura, N., Hirano, K., Chiba, H. and Hui, S.P. Development of a simultaneous quantitation for short-, medium-, long-, and very long-chain fatty acids in human plasma by 2-nitrophenylhydrazine-derivatization and liquid chromatography-tandem mass spectrometry. J. Chromatogr. B, 1126, 121771 (2019); DOI.
Chen, K., Baluya, D., Tosun, M., Li, F. and Maletic-Savatic, M. Imaging mass spectrometry: a new tool to assess molecular underpinnings of neurodegeneration. Metabolites, 9, 135 (2019); DOI.
Chen, L.S., Xiu, R., Wang, H., Wang, L.X., Wu, G.M., Liang, J. and Han, X.F. Simultaneous quantification of ten oxysterols based on LC-MS/MS and its application in atherosclerosis human serum samples. Chromatographia, 82, 553-564 (2019); DOI.
Cheng, X.X., Jiang, X., Tam, K.Y., Li, G., Zheng, J. and Zhang, H.J. Sphingolipidomic analysis of C. elegans reveals development- and environment-dependent metabolic features. Int. J. Biol. Sci., 15, 2897-2910 (2019); DOI.
Cherif, A., Boukhchina, S. and Angers, P. GC-MS characterization of cyclic fatty acid monomers and isomers of unsaturated fatty acids formed during the soybean oil heating process. Eur. J. Lipid Sci. Technol., 121, 1800296 (2019); DOI.
Chernova, A., Mazin, P., Goryunova, S., Goryunov, D., Demurin, Y., Gorlova, L., Vanyushkina, A., Mair, W., Anikanov, N., Yushina, E., Pavlova, A., Martynova, E., Garkusha, S., Mukhina, Z., Savenko, E. and Khaitovich, P. Ultra-performance liquid chromatography-mass spectrometry for precise fatty acid profiling of oilseed crops. PeerJ, 7, e6547 (2019); DOI.
Chetwynd, A.J., Ogilvie, L.A., Nzakizwanayo, J., Pazdirek, F., Hoch, J., Dedi, C., Gilbert, D., Abdul-Sada, A., Jones, B.V. and Hill, E.M. The potential of nanoflow liquid chromatography-nano electrospray ionisation-mass spectrometry for global profiling the faecal metabolome. J. Chromatogr. A, 1600, 127-136 (2019); DOI.
Chmielarz, M., Sampels, S., Blomqvist, J., Brandenburg, J., Wende, F., Sandgren, M. and Passoth, V. FT-NIR: a tool for rapid intracellular lipid quantification in oleaginous yeasts. Biotechn. Biofuels, 12, 169 (2019); DOI.
Cho, Y., Woo, J.H., Kwon, O.S., Yoon, S.S. and Son, J. Alterations in phospholipid profiles of erythrocytes deep-frozen without cryoprotectants. Drug Test. Anal., 11, 1231-1237 (2019); DOI.
Chollet, C., Boutet-Mercey, S., Laboureur, L., Rincon, C., Mejean, M., Jouhet, J., Fenaille, F., Colsch, B. and Touboul, D. Supercritical fluid chromatography coupled to mass spectrometry for lipidomics. J. Mass Spectrom., 54, 791-801 (2019); DOI.
Chonglo, L., Tian, R., Shi, R.Y., Ouyang, Z. and Xia, Y. Coupling the Paterno-Buchi (PB) reaction with mass spectrometry to study unsaturated fatty acids in mouse model of multiple sclerosis. Front. Chem., 7, 807 (2019); DOI.
Chung, S. Update on low-density lipoprotein cholesterol quantification. Curr. Opinion Lipidol., 30, 273-283 (2019); DOI.
Colombo, S., Domingues, P. and Domingues, M.R. Mass spectrometry strategies to unveil modified aminophospholipids of biological interest. Mass Spectrom. Rev., 38, 323-355 (2019); DOI.
Colombo, S., Criscuolo, A., Zeller, M., Fedorova, M., Domingues, M.R. and Domingues, P. Analysis of oxidised and glycated aminophospholipids: Complete structural characterisation by C30 liquid chromatography-high resolution tandem mass spectrometry. Free Rad. Biol. Med., 144, 144-155 (2019); DOI.
Colsch, B., Damont, A., Junot, C., Fenaille, F. and Tabet, J.C. Experimental evidence that electrospray-produced sodiated lysophosphatidyl ester structures exist essentially as protonated salts. Eur. J. Mass Spectrom., 25, 333-338 (2019); DOI.
Coras, R., Kavanaugh, A., Boyd, T., Huynh, Q., Pedersen, B., Armando, A.M., Dahlberg-Wright, S., Marsal, S., Jain, M., Paravar, T., Quehenberger, O. and Guma, M. Pro- and anti-inflammatory eicosanoids in psoriatic arthritis. Metabolomics, 15, 65 (2019); DOI.
Cossignani, L., Pollini, L. and Blasi, F. Authentication of milk by direct and indirect analysis of triacylglycerol molecular species. J. Dairy Sci., 102, 5871-5882 (2019); DOI.
Dasilva, G. and Medina, I. Lipidomic methodologies for biomarkers of chronic inflammation in nutritional research: omega-3 and omega-6 lipid mediators. Free Rad. Biol. Med., 144, 90-109 (2019); DOI.
Dasilva, G., Munoz, S., Lois, S. and Medina, I. Non-targeted LC-MS/MS assay for screening over 100 lipid mediators from ARA, EPA, and DHA in biological samples based on mass spectral fragmentations. Molecules, 24, 2276 (2019); DOI.
D'Auria, M. The Paterno-Buchi reaction - a comprehensive review. Photochem. Photobiol. Sci., 18, 2297-2362 (2019); DOI.
Dator, R.P., Solivio, M.J., Villalta, P.W. and Balbo, S. Bioanalytical and mass spectrometric methods for aldehyde profiling in biological fluids. Toxics, 7, 32 (2019); DOI.
Dempsey, S.K., Gesseck, A.M., Ahmad, A., Daneva, Z., Ritter, J.K. and Poklis, J.L. Formation of HETE-EAs and dihydroxy derivatives in mouse kidney tissue and analysis by high-performance liquid chromatography tandem mass spectrometry. J. Chromatogr. B, 1126, 121748 (2019); DOI.
Deng, J.W., Yang, Y.Y., Liu, Y.H., Fang, L., Lin, L. and Luan, T.G. Coupling Paterno-Buchi reaction with surface-coated probe nanoelectrospray ionization mass spectrometry for in vivo and microscale profiling of lipid C=C location isomers in complex biological tissues. Anal. Chem., 91, 4592-4599 (2019); DOI.
Dias, I.H.K., Ferreira, R., Gruber, F., Vitorino, R., Rivas-Urbina, A., Sanchez-Quesada, J.L., Silva, J.V., Fardilha, M., de Freitas, V. and Reis, A. Sulfate-based lipids: Analysis of healthy human fluids and cell extracts. Chem. Phys. Lipids, 221, 53-64 (2019); DOI.
Dong, X.R., Li, L.L., Ye, Y.H., Zhang, D.G., Zheng, L.X., Jiang, Y. and Shen, M. Surrogate analyte-based quantification of main endocannabinoids in whole blood using liquid chromatography-tandem mass spectrometry. Biomed. Chromatogr., 33, e4439 (2019); DOI.
Drotleff, B., Illison, J., Schlotterbeck, J., Lukowski, R. and Lammerhofer, M. Comprehensive lipidomics of mouse plasma using class-specific surrogate calibrants and SWATH acquisition for large-scale lipid quantification in untargeted analysis. Anal. Chim. Acta, 1086, 90-102 (2019); DOI.
Du, H.Q., Yu, H.J., Ma, T.R., Yang, F.Q., Jia, L.Y., Zhang, C., Zhang, J.X., Niu, L.L., Yang, J.J., Zhang, Z.W., Zhang, K. and Li, Z. Analysis of glycosphingolipid glycans by lectin microarrays. Anal. Chem., 91, 10663-10671 (2019); DOI.
Duarte, S., Melo, T., Domingues, R., Alche, J.D. and Perez-Sala, D. Insight into the cellular effects of nitrated phospholipids: Evidence for pleiotropic mechanisms of action. Free Rad. Biol. Med., 144, 192-202 (2019); DOI.
Duarte, T.T., Ellis, C.C., Grajeda, B.I., De Chatterjee, A., Almeida, I.C. and Das, S. A targeted mass spectrometric analysis reveals the presence of a reduced but dynamic sphingolipid metabolic pathway in an ancient protozoan, Giardia lamblia. Front. Cell. Infect. Microbiol., 9, 245 (2019); DOI.
Dufresne, M., Patterson, N.H., Norris, J.L. and Caprioli, R.M. Combining salt doping and matrix sublimation for high spatial resolution MALDI imaging mass spectrometry of neutral lipids. Anal. Chem., 91, 12928-12934 (2019); DOI.
Dutta, M., Cai, J.W., Gui, W. and Patterson, A.D. A review of analytical platforms for accurate bile acid measurement. Anal. Bioanal. Chem., 411, 4541-4549 (2019); DOI.
Duval, J., Colas, C., Bonnet, P. and Lesellier, E. Hyphenation of ultra-high performance supercritical fluid chromatography with atmospheric pressure chemical ionisation high resolution mass spectrometry: Part 2. Study of chromatographic and mass spectrometry parameters for the analysis of natural non-polar compounds. J. Chromatogr. A, 1596, 199-208 (2019); DOI.
Engel, K.M., Griesinger, H., Schulz, M. and Schiller, J. Normal-phase versus reversed-phase thin-layer chromatography (TLC) to monitor oxidized phosphatidylcholines by TLC/mass spectrometry. Rapid Commun. Mass Spectrom., 33, 60-65 (2019); DOI.
Evans, T.W., Coffinet, S., Konneke, M., Lipp, J.S., Becker, K.W., Elvert, M., Heuer, V. and Hinrichs, K.U. Assessing the carbon assimilation and production of benthic archaeal lipid biomarkers using lipid-RIP. Geochim. Cosmochim. Acta, 265, 431-442 (2019); DOI.
Fagundes, M.B., Falk, R.B., Facchi, M.M.X., Vendruscolo, R.G., Maroneze, M.M., Zepka, L.Q., Jacob-Lopes, E. and Wagner, R. Insights in cyanobacteria lipidomics: A sterols characterization from Phormidium autumnale biomass in heterotrophic cultivation. Food Res. Int., 119, 777-784 (2019); DOI.
Fahy, E., Alvarez-Jarreta, J., Brasher, C.J., Nguyen, A., Hawksworth, J.I., Rodrigues, P., Meckelmann, S., Allen, S.M. and O'Donnell, V.B. LipidFinder on LIPID MAPS: peak filtering, MS searching and statistical analysis for lipidomics. Bioinformatics, 35, 685-687 (2019); DOI.
Fan, S.L., Kind, T., Cajka, T., Hazen, S.L., Tang, W.H.W., Kaddurah-Daouk, R., Irvin, M.R., Arnett, D.K., Barupal, D.K. and Fiehn, O. Systematic error removal using random forest for normalizing large-scale untargeted lipidomics data. Anal. Chem., 91, 3590-3596 (2019); DOI.
Fan, X.M., Jiang, J.F., Huang, Z.Q., Gong, J.M., Wang, Y.M., Xue, W., Deng, Y., Wang, Y.F., Zheng, T.P., Sun, A.J. and Luo, G.A. UPLC/Q-TOF-MS based plasma metabolomics and clinical characteristics of polycystic ovarian syndrome. Molecular. Med. Rep., 19, 280-292 (2019); DOI.
Fasciotti, M., Souza, G.H.M.F., Astarita, G., Costa, I.C.R., Monteiro, T.V.C., Teixeira, C.M.L.L., Eberlin, M.N. and Sarpal, A.S. Investigating the potential of ion mobility-mass spectrometry for microalgae biomass characterization. Anal. Chem., 91, 9266-9276 (2019); DOI.
Feng, Y., Chen, B.M., Yu, Q.Y. and Li, L.J. Identification of double bond position isomers in unsaturated lipids by m-CPBA epoxidation and mass spectrometry fragmentation. Anal. Chem., 91, 1791-1795 (2019); DOI.
Ferreira, N.P., Chiavelli, L.U.R., Lucca, D.L., Santin, S.M.D., Pavli, F., Nychas, G.J., Zuluaga, M.Y.A., de Oliveira, A.L.M. and Pomini, A.M. Identification and characterization of a long-chain N-acyl homoserine lactone from Rhizobium sp. isolated from Zea x mays rhizosphere. Rhizosphere, 9, 34-37 (2019); DOI.
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