Highlights from the Lipid Analysis Literature - 2022

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. Some papers in press may be listed here without the full citation, but the DOI address should still be valid, and they may be updated later. References are listed alphabetically by the first author.

New references 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".

Abreu, S., Heron, S., Solgadi, A., Prost, B., Dalloux-Chioccioli, J., Kermarrec, A., Meynier, A., Bertrand-Michel, J., Tchapla, A. and Chaminade, P. Rapid assessment of fatty acyls chains of phospholipids and plasmalogens by atmospheric pressure chemical ionization in positive mode and high-resolution mass spectrometry using in-source generated monoacylglycerol like fragments intensities. J. Chromatogr. A, 1673, 463093 (2022); DOI.
Akasaka, K. A highly selective and sensitive chiral derivatization method for high- performance liquid chromatographic determination of the stereoisomer composition of natural products with chiral branched alkyl chains. J. Chem. Ecol., 48, 554-568 (2022); DOI.
Alcoriza-Balaguer, M.I., Garcia-Canaveras, J.C., Ripoll-Esteve, F.J., Roca, M. and Lahoz, A. LipidMS 3.0: an R-package and a web-based tool for LC-MS/MS data processing and lipid annotation. Bioinformatics, 38, 4826-4828 (2022); DOI.
Ambaw, Y.A., Timbadia, D.P., Raida, M., Torta, F., Wenk, M.R. and Tong, L.I. Profile of tear lipid mediator as a biomarker of inflammation for meibomian gland dysfunction and ocular surface diseases: Standard operating procedures. Ocular Surface, 26, 318-327 (2022); DOI.
Angelini, R., Russo, S., Corcelli, A. and Lobasso, S. Fingerprinting cardiolipin in leukocytes by mass spectrometry for a rapid diagnosis of Barth syndrome. J. Vis. Exp., e63552 (2022); DOI.
Anh, N.H. and 11 others. Caenorhabditis elegans deep lipidome profiling by using integrative mass spectrometry acquisitions reveals significantly altered lipid networks. J. Pharm. Anal., 12, 743-754 (2022); DOI.
Archambault, A.S., Brassard, J., Bernatchez, E., Martin, C., Di Marzo, V., Laviolette, M., Boulet, L.P., Blanchet, M.R. and Flamand, N. Human and mouse eosinophils differ in their ability to biosynthesize eicosanoids, docosanoids, the endocannabinoid 2-arachidonoyl-glycerol and its congeners. Cells, 11, 141 (2022); DOI.
Arends, M. and 12 others. Ganglioside lipidomics of CNS myelination using direct infusion shotgun mass spectrometry. iScience, 25, 105323 (2022); DOI.
Armbruster, M., Grady, S., Agongo, J., Arnatt, C.K. and Edwards, J.L. Neutron encoded derivatization of endothelial cell lysates for quantitation of aldehyde metabolites using nESI-LC-HRMS. Anal. Chim. Acta, 1190, 339260 (2022); DOI.
Bailey, L.S., Prajapati, D.V. and Basso, K.B. Optimization of the sulfo-phospho-vanillin assay for total lipid normalization in untargeted quantitative lipidomic LC-MS/MS applications. Anal. Chem., 94, 17810-17818 (2022); DOI.
Bakar, J., Michael-Jubeli, R., Libong, D., Baillet-Guffroy, A. and Tfayli, A. Stratum corneum ceramide profiles in vitro, ex vivo, and in vivo: characterization of the alpha-hydroxy double esterified ceramides. Anal. Bioanal. Chem., 414, 3675-3685 (2022); DOI.
Bakhytkyzy, I., Hewelt-Belka, W. and Kot-Wasik, A. A method for a comprehensive lipidomic analysis of flaxseed (Linum usitatissimum) with the use of LC-Q-TOF-MS and dispersive micro-solid-phase (mu DSPE) extraction. Food Chem., 381, 132290 (2022); DOI.
Baloni, P. and many others. Multi-omic analyses characterize the ceramide/sphingomyelin pathway as a therapeutic target in Alzheimer's disease. Commun. Biol., 5, 1074 (2022); DOI.
Bartolucci, G., Pallecchi, M., Menicatti, M., Moracci, L., Pucciarelli, S., Agostini, M. and Crotti, S. A method for assessing plasma free fatty acids from C2 to C18 and its application for the early detection of colorectal cancer. J. Pharm. Biomed. Anal., 215, 114762 (2022); DOI.
Bautista, J.S., Falabella, M., Flannery, P.J., Hanna, M.G., Heales, S.J.R., Pope, S.A.S. and Pitceathly, R.D.S. Advances in methods to analyse cardiolipin and their clinical applications. Trends Anal. Chem., 157, 116808 (2022); DOI.
Beger, A.W., Dudzik, B., Woltjer, R.L. and Wood, P.L. Human brain lipidomics: pilot analysis of the basal ganglia sphingolipidome in Parkinson's disease and Lewy body disease. Metabolites, 12, 187 (2022); DOI.
Bhaskar, A.K., Naushin, S., Ray, A., Singh, P., Raj, A., Pradhan, S., Adlakha, K., Siddiqua, T.J., Malakar, D., Dash, D. and Sengupta, S. A high throughput lipidomics method using scheduled multiple reaction monitoring. Biomolecules, 12, 709 (2022); DOI.
Biagini, D. and 15 others. MS-based targeted profiling of oxylipins in COVID-19: A new insight into inflammation. Free Rad. Biol. Med., 180, 236-243 (2022); DOI.
Bianco, A., Neefjes, I., Alfaouri, D., Vehkamaki, H., Kurten, T., Ahonen, L., Passananti, M. and Kangasluoma, J. Separation of isomers using a differential mobility analyser (DMA): Comparison of experimental vs modelled ion mobility. Talanta, 243, 123339 (2022); DOI.
Bin Lee, G., Caner, A. and Moon, M.H. Optimisation of saliva volumes for lipidomic analysis by nanoflow ultrahigh performance liquid chromatography-tandem mass spectrometry. Anal. Chim. Acta, 1193, 339318 (2022); DOI.
Blevins, M.S., Shields, S.W.J., Cui, W., Fallatah, W., Moser, A.B., Braverman, N.E. and Brodbelt, J.S. Structural characterization and quantitation of ether-linked glycerophospholipids in peroxisome biogenesis disorder tissue by ultraviolet photodissociation mass spectrometry. Anal. Chem., 94, 12621-12629 (2022); DOI.
Boeren, N.J., Gruchola, S., de Koning, C.P., Schmidt, P.K., Kipfer, K.A., Ligterink, N.F.W., Tulej, M., Wurz, P. and Riedo, A. Detecting lipids on planetary surfaces with laser desorption ionization mass spectrometry. Planetary Sci. J., 3, 241 (2022); DOI.
Bogl, T., Mlynek, F., Himmelsbach, M. and Buchberger, W. Comparison of one-phase and two-phase extraction methods for porcine tissue lipidomics applying a fast and reliable tentative annotation workflow. Talanta, 236, 122849 (2022); DOI.
Borecka, O., Rhodes, L.E., Webb, A.R., Dutton, J.J. and Fraser, W.D. A newly developed and validated LC-MS/MS method for measuring 7-dehydrocholesterol (7DHC) concentration in human skin: a tool for vitamin D photobiology research. Photochem. Photobiol. Sci., 21, 2001-2009 (2022); DOI.
Bruns, S., Cakic, N., Mitschke, N., Kopke, B.J., Rabus, R. and Wilkes, H. A novel Coenzyme A analogue in the anaerobic, sulfate-reducing, marine Bacterium Desulfobacula toluolica Tol2(T). Chembiochem, e202200584 (2022); DOI.
Byrdwell, W.C., Kotapati, H.K., Goldschmidt, R., Jakubec, P. and Novakova, L. Three-dimensional liquid chromatography with parallel second dimensions and quadruple parallel mass spectrometry for adult/infant formula analysis. J. Chromatogr. A, 1661, 462682 (2022); DOI.
Cao, X.Y., Li, X., Shu, N.X., Tan, C.P., Xu, Y.J. and Liu, Y.F. The characteristics and analysis of polar compounds in deep-frying oil: a mini review. Food Anal. Methods, 15, 1-10 (2022); DOI.
Casati, S., Giannasi, C., Niada, S., Della Morte, E., Orioli, M. and Brini, A.T. Lipidomics of cell secretome combined with the study of selected bioactive lipids in an in vitro model of osteoarthritis. Stem Cells Transl. Med., szac045 (2022); DOI.
Carlsson, H., Vaivade, A., Khoonsari, P.E., Burman, J. and Kultima, K. Evaluation of polarity switching for untargeted lipidomics using liquid chromatography coupled to high resolution mass spectrometry. J. Chromatogr. B, 1195, 123200 (2022); DOI.
Carnovale, V., Castaldo, A., Di Minno, A., Gelzo, M., Iacotucci, P., Illiano, A., Pinto, G., Castaldo, G. and Amoresano, A. Oxylipin profile in saliva from patients with cystic fibrosis reveals a balance between pro-resolving and pro-inflammatory molecules. Sci. Rep., 12, 5838 (2022); DOI.
Cebolla, V.L., Jarne, C., Membrado, L., Escuin, J.M. and Vela, J. Lipidomic studies based on high-performance thin-layer chromatography. J. Planar Chromatogr. - Mod. TLC, 35, 229-241 (2022); DOI.
Cerrato, A., Capriotti, A.L., Cavaliere, C., Montone, C.M., Piovesana, S. and Lagana, A. Novel aza-Paterno-Buchi reaction allows pinpointing carbon-carbon double bonds in unsaturated lipids by higher collisional dissociation. Anal. Chem., 94, 13117-13125 (2022); DOI.
Challen, B. and Cramer, R. Advances in ionisation techniques for mass spectrometry-based omics research. Proteomics, 22, 2100394 (2022); DOI.
Chary, A. and Hedayati, M. Review of laboratory methods to determine HDL and LDL subclasses and their clinical importance. Rev. Cardiovasc. Med., 23, 147 (2022); DOI.
Chen, X., Tang, S.L., Freitas, D., Hirtzel, E., Cheng, H.Y. and Yan, X. Characterization of glycerophospholipids at multiple isomer levels via Mn(II)-catalyzed epoxidation. Analyst, 147, 4838-4844 (2022); DOI.
Chen, X., Yin, Y.D., Luo, M.D., Zhou, Z.W., Cai, Y.P. and Zhu, Z.J. Trapped ion mobility spectrometry-mass spectrometry improves the coverage and accuracy of four-dimensional untargeted lipidomics. Anal. Chim. Acta, 1210, 339886 (2022); DOI.
Chen, Y.Y., Xie, C.Y., Wang, X.X., Cao, G.D., Ru, Y., Song, Y.Y., Iyaswamy, A., Li, M., Wang, J.N. and Cai, Z.W. 3-Acetylpyridine on-tissue Paterno-Buchi derivatization enabling high coverage lipid C=C location-resolved MS imaging in biological tissues. Anal. Chem., 94, 15367-15376 (2022); DOI.
Chen, Z.J., Song, S.Y., Yang, C.X., Dai, Z.Y., Gao, Y., Li, N., Zhu, J., Mao, W.M. and Liu, J.P. Lipid profiling in malignant mesothelioma reveals promising signatures for diagnosis and prognosis: A plasma-based LC-MS lipidomics study. Clin. Chim. Acta, 524, 34-42 (2022); DOI.
Cheng, S.C., Lin, H.J., Lee, C.Y., Huang, M.Z. and Shiea, J. Gas chromatography combined with flame-induced atmospheric pressure chemical ionization mass spectrometry for the analysis of fatty acid methyl esters and saturated hydrocarbons. Anal. Chim. Acta, 1200, 339611 (2022); DOI.
Chistyakov, D.V. and 14 others. Multi-omics approach points to the importance of oxylipins metabolism in early-stage breast cancer. Cancers, 14, 2041 (2022); DOI.
Chitpin, J.G. and 14 others. BATL: Bayesian annotations for targeted lipidomics. Bioinformatics, 38, 1593-1599 (2022); DOI.
Choi, Y. and Chang, P.S. Kinetic modeling of lipase-catalysed hydrolysis of triacylglycerol in a reverse micelle system for the determination of integral stereoselectivity. Catalysis Sci. Technol., 12, 2819-2828 (2022); DOI.
Cifkova, E., Brumarova, R., Ovcacikova, M., Dobesova, D., Micova, K., Kvasnicka, A., Vankova, Z., Siller, J., Sakra, L., Friedecky, D. and Holcapek, M. Lipidomic and metabolomic analysis reveals changes in biochemical pathways for non-small cell lung cancer tissues. Biochim. Biophys. Acta, Lipids, 1867, 159082 (2022); DOI.
Claeson, A.S., Lindberg, R.H., Gouveia-Figueira, S. and Nording, M.L. Feasibility and reliability of measures of bioactive lipids in human plasma and nasal mucosa. J. Chromatogr. B, 1206, 123357 (2022); DOI.
Coniglio, D., Ventura, G., Calvano, C.D., Losito, I. and Cataldi, T.R.I. Positional assignment of C-C double bonds in fatty acyl chains of intact arsenosugar phospholipids occurring in seaweed extracts by epoxidation reactions. J. Am. Soc. Mass Spectrom., 33, 823-831 (2022); DOI.
Coon, A.M., Dane, A.J., Setzen, G., Cody, R.B. and Musah, R.A. Two-dimensional gas chromatographic and mass spectrometric characterization of lipid-rich biological matrices-application to human cerumen (earwax). ACS Omega, 7, 230-239 (2022); DOI.
Crauste, C., Galano, J.M., Guy, A., Lehoux, J., Durand, T. and Balas, L. Synthesis of fatty acid bioconjugates and related derivatives. Eur. J. Org. Chem., e202101502 (2022); DOI.
Cui, J.X., Holzl, G., Karmainski, T., Tiso, T., Kubicki, S., Thies, S., Blank, L.M., Jaeger, K.E. and Dormann, P. The glycine-glucolipid of Alcanivorax borkumensis is resident to the bacterial cell wall. Appl. Environm. Microbiol., 88, e0112622 (2022); DOI.
Da Cunha, P.A., Nitusca, D., Do Canto, L.M., Varghese, R.S., Ressom, H.W., Willey, S., Marian, C. and Haddad, B.R. Metabolomic analysis of plasma from breast cancer patients using ultra-high-performance liquid chromatography coupled with mass spectrometry: an untargeted study. Metabolites, 12, 447 (2022); DOI.
da Silva, K.M., Iturrospe, E., van den Boom, R., van de Lavoir, M., Robeyns, R., Vergauwen, L., Knapen, D., Cuykx, M., Covaci, A. and van Nuijs, A.L.N. Lipidomics profiling of zebrafish liver through untargeted liquid chromatography-high resolution mass spectrometry. J. Sep. Sci., 45, 2935-2945 (2022); DOI.
Daku, A.B., Al-Mhanna, S.B., Abu Bakar, R. and Nurul, A.A. Glycolipids isolation and characterization from natural source: A review. J. Liqu. Chromatogr. Rel. Technol., 45, 165-173 (2022); DOI.
de Mera, R.M.F.M., Villasenor, A., Rojo, D., Carrion-Navarro, J., Gradillas, A., Ayuso-Sacido, A. and Barbas, C. Ceramide composition in exosomes for characterization of glioblastoma stem-like cell phenotypes. Front. Oncol., 11, 788100 (2022); DOI.
Dosedelova, V., Lastovickova, M., Ayala-Cabrera, J.F., Dolina, J., Konecny, S., Schmitz, OJ. and Kuban, P. Quantification and identification of bile acids in saliva by liquid chromatography-mass spectrometry: Possible non-invasive diagnostics of Barrett's esophagus? J. Chromatogr. A, 1676, 463287 (2022); DOI.
Dreisbach, D., Heiles, S., Bhandari, D.R., Petschenka, G. and Spengler, B. Molecular networking and on-tissue chemical derivatization for enhanced identification and visualization of steroid glycosides by MALDI mass spectrometry imaging. Anal. Chem., 94, 15971-15979 (2022); DOI.
du Preez, A., Meijboom, R. and Smit, E. Low-cost 3D-printed reactionware for the determination of fatty acid content in edible oils using a base-catalyzed transesterification method in continuous flow. Food Anal. Methods, in press (2022); DOI.
Du, S.S., Su, M.K., Wang, C., Ding, Z.X., Jiang, Y.F. and Liu, H.L. Pinpointing alkane chain length, saturation, and double bond regio- and stereoisomers by liquid interfacial plasmonic enhanced raman spectroscopy. Anal. Chem., 94, 2891-2900 (2022); DOI.
Duan, L.K., Scheidemantle, G., Lodge, M., Cummings, M.J., Pham, E., Wang, X.Q., Kennedy, A. and Liu, X.J. Prioritize biologically relevant ions for data-independent acquisition (BRI-DIA) in LC-MS/MS-based lipidomics analysis. Metabolomics, 18, 55 (2022); DOI.
Dubland, J.A. Lipid analysis by ion mobility spectrometry combined with mass spectrometry: A brief update with a perspective on applications in the clinical laboratory. J. Mass Spectrom. Adv. Clin. Lab, 23, 7-13 (2022); DOI.
Engel, K.M., Prabutzki, P., Leopold, J., Nimptsch, A., Lemmnitzer, K., Vos, D.R.N., Hopf, C. and Schiller, J. A new update of MALDI-TOF mass spectrometry in lipid research. Prog. Lipid Res., 86, 101145 (2022); DOI.
Enomoto, H. Distribution analysis of jasmonic acid-related compounds in developing Glycine max L. (soybean) seeds using mass spectrometry imaging and liquid chromatography-mass spectrometry. Phytochem. Anal., 33, 194-203 (2022); DOI.
Evans, T.W., Elling, F.J., Li, Y.L., Pearson, A. and Summons, R.E. A new and improved protocol for extraction of intact polar membrane lipids from archaea. Org. Geochem., 165, 104353 (2022); DOI.
Eylem, C.C., Nemutlu, E., Dogan, A., Acik, V., Matyar, S., Gezercan, Y., Altintas, S., Okten, A.I. and Akduman, N.E.B. High-throughput single-step plasma sample extraction optimization strategies with experimental design for LC-MS and GC-MS integrated metabolomics and lipidomics analysis. Microchem. J., 179, 107525 (2022); DOI.
Faedo, R.R., da Silva, G., da Silva, R.M., Ushida, T.R., da Silva, R.R., Lacchini, R., Matos, L.L., Kowalski, L.P., Lopes, N.P. and Leopoldino, A.M. Sphingolipids signature in plasma and tissue as diagnostic and prognostic tools in oral squamous cell carcinoma. Biochim. Biophys. Acta, Lipids, 1867, 159057 (2022); DOI.
Fang, C.N., Wang, H., Lin, Z.K., Liu, X.Y., Dong, L.W., Jiang, T.Y., Tan, Y.X., Ning, Z., Ye, Y.R., Tan, G. and Xu, G.W. Metabolic reprogramming and risk stratification of hepatocellular carcinoma studied by using gas chromatography-mass spectrometry-based metabolomics. Cancers, 14, 231 (2022); DOI.
Farhoosh, R. New insights into the kinetic and thermodynamic evaluations of lipid peroxidation. Food Chem., 375, 131659 (2022); DOI.
Fatch, R. and 10 others. Comparison of automated determination of phosphatidylethanol (PEth) in dried blood spots (DBS) with previous manual processing and testing. Alcohol, 98, 51-54 (2022); DOI.
Feng, G.F., Gao, M., Wang, L.W., Chen, J.Y., Hou, M.L., Wan, Q.Q., Lin, Y., Xu, G.Y., Qi, X.T. and Chen, S.M. Dual-resolving of positional and geometric isomers of C=C bonds via bifunctional photocycloaddition-photoisomerization reaction system. Nature Commun., 13, 2652 (2022); DOI.
Feng, X.H., Liu, N., Yang, Y.Y., Feng, S.N., Wang, J. and Meng, Q.S. Isotope-coded chemical derivatization method for highly accurately and sensitively quantifying short-chain fatty acids. J. Agric. Food Chem., 70, 6253-6263 (2022); DOI.
Feng, Y., Lv, Y.N., Gu, T.J., Chen, B.M. and Li, L.J. Quantitative analysis and structural elucidation of fatty acids by isobaric multiplex labeling reagents for carbonyl-containing compound (SUGAR) tags and m-CPBA epoxidation. Anal. Chem., 94, 13036-13042 (2022); DOI.
Ferre-Gonzalez, L., Pena-Bautista, C., Baquero, M. and Chafer-Pericas, C. Assessment of lipid peroxidation in Alzheimer's disease differential diagnosis and prognosis. Antioxidants, 11, 551 (2022); DOI.
Ferreira, H.B., Barros, C., Melo, T., Paiva, A. and Domingues, M.R. Looking in depth at oxidized cholesteryl esters by LC-MS/MS: reporting specific fragmentation fingerprints and isomer discrimination. J. Am. Soc. Mass Spectrom., 33, 793-802 (2022); DOI.
Ferreira, H.B., Guerra, I.M.S., Melo, T., Rocha, H., Moreira, A.S.P., Paiva, A. and Domingues, M.R. Dried blood spots in clinical lipidomics: optimization and recent findings. Anal. Bioanal. Chem., 414, 7085-7101 (2022); DOI.
Frankfater, C., Fujiwara, H., Williams, S.J., Minnaard, A. and Hsu, F.F. Characterization of Mycobacterium tuberculosis mycolic acids by multiple-stage linear ion-trap mass spectrometry. J. Am. Soc. Mass Spectrom., 33, 149-159 (2022); DOI.
Fu, X., Yin, H.H., Wu, M.J., He, X., Jiang, Q., Zhang, L.T. and Liu, J.Y. High sensitivity and wide linearity LC-MS/MS method for oxylipin quantification in multiple biological samples. J. Lipid Res., 63, 100302 (2022); DOI.
Fu, Z.B., Jia, Q.Q., Zhang, H.Y., Kang, L., Sun, X.Z., Zhang, M., Wang, Y.R. and Hu, P. Simultaneous quantification of eleven short-chain fatty acids by derivatization and solid phase microextraction - Gas chromatography tandem mass spectrometry. J. Chromatogr. A, 1661, 462680 (2022); DOI.
Fujitani, N., Saito, M., Akashi, T., Morita, M., So, T.K.N.R. and Oka, K. Detection of characteristic phosphatidylcholine containing very long chain fatty acids in cerebrospinal fluid from patients with X-linked adrenoleukodystrophy. Biol. Pharm. Bull., 45, 1725-1727 (2022); DOI.
Galor, A., Sanchez, V., Jensen, A., Burton, M., Maus, K., Stephenson, D., Chalfant, C. and Mandal, N. Meibum sphingolipid composition is altered in individuals with meibomian gland dysfunction-a side by side comparison of Meibum and Tear Sphingolipids. Ocular Surface, 23, 87-95 (2022); DOI.
Ganeshalingam, M., Enstad, S., Sen, S., Cheema, S., Esposito, F. and Thomas, R. Role of lipidomics in assessing the functional lipid composition in breast milk. Front. Nutr., 9, 899401 (2022); DOI.
Gao, M., Lee, S.B., Lee, J.E., Kim, G.J., Moon, J., Nam, J.W., Bae, J.S., Chin, J., Jeon, Y.H. and Choi, H. Anti-inflammatory butenolides from a marine-derived Streptomyces sp. 13G036. Applied Sciences-Basel, 12, 4510 (2022); DOI.
Gao, T.Q., Lott, A.A., Huang, F.R., Rohokale, R., Li, Q.J., Olivos, H.J., Chen, S.X. and Guo, Z.W. Structural characterization and analysis of different epimers of neutral glycosphingolipid LcGg4 by ion mobility spectrometry-mass spectrometry. Analyst, 147, 3101-3108 (2022); DOI.
Garg, R., Perez, R. and Maldener, I. Analysis of heterocyst and akinete specific glycolipids in cyanobacteria using thin-layer chromatography. Bio-Protocol, 12, e4355 (2022); DOI.
Gazlay, W. and Evans, J.J. The impact of the complexing agent on the sensitivity of collision-induced dissociation spectra to fatty acid position for a set of XYZ-type triglycerides. Rapid Commun. Mass Spectrom., 36, e9226 (2022); DOI.
Geibel, C., Zhang, L., Serafimov, K., Gross, H. and Lammerhofer, M. Towards enantioselective ultrahigh performance liquid chromatography-mass spectrometry-based metabolomics of branched-chain fatty acids and anteiso-fatty acids under reversed-phase conditions using sub-2-mu m amylose- and cellulose-derived chiral stationary phases. Chirality, 34, 484-497 (2022); DOI.
Gerbaulet, M., Mollerke, A., Weiss, K., Chinta, S., Schneider, JM. and Schulz, S Identification of cuticular and web lipids of the spider Argiope bruennichi. J. Chem. Ecol., 48, 244-262 (2022); DOI.
Ghayad, J.P.E. and Barakett-Hamade, V.P. A tale of two approaches measuring and calculating low-density lipoprotein cholesterol. Am. J. Clin. Pathol., 157, 345-352 (2022); DOI.
Ghorasaini, M., Tsezou, K.I., Verhoeven, A., Mohammed, Y., Vlachoyiannopoulos, P., Mikros, E. and Giera, M. Congruence and complementarity of differential mobility spectrometry and NMR spectroscopy for plasma lipidomics. Metabolites, 12, 1030 (2022); DOI.
Gjessing, G., Johnsen, L.I.G., Antonsen, S.G., Nolsoe, J.M.J., Stenstrom, Y. and Hansen, T.V. The synthesis of 3-(R)- and 3-(S)-hydroxyeicosapentaenoic acid. Molecules, 27, 2295 (2022); DOI.
Gong, G.G., Zheng, J., Li, S., Bai, Y.L. and Feng, Y.Q. Triple chemical derivatization strategy assisted liquid chromatography-mass spectrometry for determination of retinoic acids in human serum. Talanta, 245, 123474 (2022); DOI.
Gonzalez, L.E., Szalwinski, L.J., Sams, T.C., Dziekonski, E.T. and Cooks, R.G. Metabolomic and lipidomic profiling of bacillus using two-dimensional tandem mass spectrometry. Anal. Chem., 94, 16838-16846 (2022); DOI.
Gornas, P., Baskirovs, G. and Siger, A. Free and esterified tocopherols, tocotrienols and other extractable and non-extractable tocochromanol-related molecules: compendium of knowledge, future perspectives and recommendations for chromatographic techniques, tools, and approaches used for tocochromanol determination. Molecules, 27, 6560 (2022); DOI.
Graca, G., Cai, Y.H., Lau, C.H.E., Vorkas, P.A., Lewis, M.R., Want, E.J., Herrington, D. and Ebbels, T.M.D. Automated annotation of untargeted all-ion fragmentation LC-MS metabolomics data with MetaboAnnotatoR. Anal. Chem., 94, 3446-3455 (2022); DOI.
Graceffa, O., Kim, E., Broweleit, R. and Rawle, R.J. Choice of buffer in mobile phase can substantially alter peak areas in quantification of lipids by HPLC-ELSD. J. Chromatogr. B, 1209, 123417 (2022); DOI.
Graham, D.J., Taylor, M.J., Zhang, K.Y. and Gamble, L.J. Fatty acid and sphingosine reference spectra. Surface Science Spectra, 29, 15001 (2022); DOI.
Guzii A.G .and 11 others. Toporosides A and B, cyclopentenyl-containing ?-glycosylated fatty acid amides, and toporosides C and D from the Northwestern Pacific marine sponge Stelodoryx toporoki. J. Nat. Prod., 85, 1186-1191 (2022); DOI.
Gray, J., Guo, B.C., Bearden, R. and Manka, J. A fast, fully validated GC-MS method using a simplified pretreatment for the quantification of short and branched chain fatty acids in human stool. J. Mass Spectrom., 57, e4817 (2022); DOI.
Gu, T.J., Feng, Y., Wang, D.Q. and Li, L.J. Simultaneous multiplexed quantification and C=C localization of fatty acids with LC-MS/MS using isobaric multiplex reagents for carbonyl-containing compound (SUGAR) tags and C=C epoxidation. Anal. Chim. Acta, 1225, 340215 (2022); DOI.
Gunther, M. and others. Yellow polyketide pigment suppresses premature hatching in social amoeba. Proc. Natl. Acad. Sci. USA, 119, e2116122119 (2022); DOI.
Han, X.L. and Gross, R.W. The foundations and development of lipidomics. J. Lipid Res., 63, 100164 (2022); DOI.
Han, Y.H., Chen, P.P., Li, Z.C., Wang, X. and Sun, C.L. Multi-wavelength visible-light induced [2+2] cycloaddition for identification of lipid isomers in biological samples. J. Chromatogr. A, 1662, 462742 (2022); DOI.
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