Highlights from the Lipid Analysis Literature - 2024

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".

Ahmed, F., Torrens, A., Mahler, S.V., Ferlenghi, F., Huestis, M.A. and Piomelli, D. A sensitive ultrahigh-performance liquid chromatography/tandem mass spectrometry method for the simultaneous analysis of phytocannabinoids and endocannabinoids in plasma and brain. Cannabis Cannabinoid Res., 9, 371-385 (2024); DOI.
Al Sazzad, M.A., Fabritius, M., Bostrom, P. and Yang, B. Advanced tandem mass spectrometric analysis of complex mixtures of triacylglycerol regioisomers: a case study of bovine milk fat. J. Agric. Food Chem., 72, 8849-8858 (2024); DOI.
Alabed, H.B.R. and others. LipidOne 2.0: a web tool for discovering biological meanings hidden in lipidomic data. Curr. Protocols, 4, e70009 (2024); DOI.
Allwright, M. and others. ReTimeML: a retention time predictor that supports the LC-MS/MS analysis of sphingolipids. Sci. Rep., 14, 4375 (2024); DOI.
Anderson, B.J., Brademan, D.R., He, Y.C., Overmyer, K.A. and Coon, J.J. LipiDex 2 integrates MSn tree-based fragmentation methods and quality control modules to improve discovery lipidomics. Anal. Chem., 96, 6715-6723 (2024); DOI.
Arendowski, A. Matrix- and surface-assisted laser desorption/ionization mass spectrometry methods for urological cancer biomarker discovery-metabolomics and lipidomics approaches. Metabolites, 14, 173 (2024); DOI.
Arendowski, A., Sibinska, E., Mista, W., Fijalkowski, P., Zloch, M., Gabrys, D. and Pomastowski, P. Study of sample preparation influence on bacterial lipids profile in matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. Lipids, 59, 13-26 (2024); DOI.
Auñon-Lopez, A., Alberdi-Cedeño, J., Pignitter, M. and Castejón, N. Microalgae as a new source of oxylipins: a comprehensive LC-MS-based analysis using conventional and green extraction methods. J. Agric. Food Chem., 72, 16749-16760 (2024); DOI.
Banahene, N. and others. Chemical proteomics strategies for analyzing protein lipidation reveal the bacterial O-mycoloylome. J. Am. Chem. Soc., 146, 12138-12154 (2024); DOI.
Barone, C.M., Heaver, L., Gruber, L., Zundel, F., Vu, D.L. and Ley, R.E. Spatially resolved lipidomics shows conditional transfer of lipids produced by Bacteroides thetaiotaomicron into the mouse gut. Cell Host Microbe, 32, P1025-1036.E5 (2024); DOI.
Bates, T.L. and Sacks, G.L. Rapid analysis of C6 aldehydes by solid-phase microextraction sheets and direct analysis in real-time mass spectrometry (SPMESH-DART-MS). ACS Food Sci. Technol., 4, 2115–2123 (2024); DOI.
Battaglia, G. and others. Determination of Gb3 and lyso-Gb3 in Fabry disease-affected patients by LC-MRM/MS. Separations, 11, 239 (2024); DOI.
Batteau, M., Bouju, E., Ramirez-Romero, A., Nuccio, S., De Vaumas, R., Delrue, F. and Faure, K. Resolving phytosterols in microalgae using offline two-dimensional reversed phase liquid chromatography-supercritical fluid chromatography coupled with quadrupole time-of-flight mass spectrometry. Anal. Methods, 16, 2278-2285 (2024); DOI.
Beck, O., Barroso, M., Hermansson, S., Widen, C., Wallin, C., Nilsson-Wallmark, C. and de Bejczy, A Volumetric dried blood spots for determination of phosphatidylethanol: Validation of a liquid chromatography tandem mass spectrometry method and clinical application. Drug Test. Anal., in press (2024); DOI.
Benktander, J., Sundh, H., Sundell, K., Sharba, S., Teneberg, S. and Linden, S.K. Characterization of the rainbow trout (Oncorhynchus mykiss) mucosal glycosphingolipid repertoire and Aeromonas salmonicida binding to neutral glycosphingolipids. Glycobiology, 34, cwae055 (2024); DOI.
Besch, D., Seeger, D.R., Schofield, B., Golovko, S.A., Parmer, M. and Golovko, M.Y. A simplified method for preventing postmortem alterations of brain prostanoids for true in situ level quantification. J. Lipid Res., 65, 100583 (2024); DOI.
Biagini, D. and others. A MEPS-UHPLC-MS/MS analytical platform to detect isoprostanoids and specialized pro-resolving mediators in the urinary extracellular vesicles of mountain ultramarathon runners. Talanta, 279, 126619 (2024); DOI.
Biricioiu, M.R., Sarbu, M., Ica, R., Vukelic, Z., Clemmer, D.E. and Zamfir, A.D. Human cerebellum gangliosides: a comprehensive analysis by ion mobility tandem mass spectrometry. J. Am. Soc. Mass Spectrom., 35, 683-695 (2024); DOI.
Biricioiu, M.R., Sarbu, M., Ica, R., Vukelic, Z., Kalanj-Bognar, S. and Zamfir, A.D. Advances in mass spectrometry of gangliosides expressed in brain cancers. Int. J. Mol. Sci., 25, 1335 (2024); DOI.
Bocková, J., Garcia, A.D., Jones, N.C., Hoffmann, S.V. and Meinert, C. Chiroptical properties of membrane glycerophospholipids and their chiral backbones. Chirality, 36, e23654 (2024); DOI.
Bogusiewicz, J., Kupcewicz, B., Wnuk, K., Gaca-Tabaszewska, M., Furtak, J., Harat, M., Buszko, K. and Bojko, B. The impact of sampling time point on the lipidome composition. J. Pharm. Biomed. Anal., 251, 116429 (2024); DOI.
Bonney, J.R. and Prentice, B.M. Structural elucidation and relative quantification of fatty acid double bond positional isomers in biological tissues enabled by gas-phase charge inversion ion/ion reactions. Analysis Sensing, 4, e202300063 (2024); DOI.
Brydon, S.C. and others. Cross-validation of lipid structure assignment using orthogonal ion activation modalities on the same mass spectrometer. J. Am. Soc. Mass Spectrom., 35, 1976-1990 (2024); DOI.
Busquets-Hernández, C., Ribó, S., Gratacós-Batlle, E., Carbajo, D., Tsiotsia, A., Blanco-Canosa, J.B., Chamberlain, L.H. and Triola, G. Quantitative analysis of protein lipidation and acyl-CoAs reveals substrate preferences of the S-acylation machinery. Chem. Sci., 15, 12845-12855 (2024); DOI.
Byeon, S.K and others. Development of a multiplexed sphingolipids method for diagnosis of inborn errors of ceramide metabolism. Clin. Chem., in press (2024); DOI.
Cai, Y.P., Chen, X., Ren, F.D., Wang, H.M., Yin, Y.D. and Zhu, Z.J. Fast and broad-coverage lipidomics enabled by ion mobility-mass spectrometry. Analyst, 149, 5063-5072 (2024); DOI.
Canez, C.R. and Li, L. Studies of labware contamination during lipid extraction in mass spectrometry-based lipidome analysis. Anal. Chem., 96, 3544-3552 (2024); DOI.
Carpenter, J.M., Hynds, H.M., Bimpeh, K. and Hines, K.M. HILIC-IM-MS for simultaneous lipid and metabolite profiling of bacteria. ACS Meas. Sci. AU, 4, 104-116 (2024); DOI.
Castillo-Ribelles, L. and others. Evaluation of a liquid chromatography-tandem mass spectrometry method for the analysis of glucosylceramide and galactosylceramide isoforms in cerebrospinal fluid of Parkinson's disease patients. Anal. Chem., 96, 12875-12882 (2024); DOI.
Cerrato, A., Cavaliere, C., Laganà, A., Montone, C.M., Piovesana, S., Sciarra, A., Taglioni, E. and Capriotti, A.L. First proof of concept of a click inverse electron demand Diels-Alder reaction for assigning the regiochemistry of carbon-carbon double bonds in untargeted lipidomics. Anal. Chem., 96, 10817-10826 (2024); DOI.
Chandramouli, A. and Kamat, S.S. A facile LC-MS method for profiling cholesterol and cholesteryl esters in mammalian cells and tissues. Biochemistry, 63, 2300-2309 (2024); DOI.
Chan, Y.H. and others. Gel-assisted mass spectrometry imaging enables sub-micrometer spatial lipidomics. Nature Commun., 15, 5036 (2024); DOI.
Chappel, J.R., Kirkwood-Donelson, K.I., Reif, D.M. and Baker, E.S. From big data to big insights: statistical and bioinformatic approaches for exploring the lipidome. Anal. Bioanal. Chem., 416, 2189-2202 (2024); DOI.
Chen, C.J., Chang, C.T., Lin, Z.R., Chiu, W.C., Liu, J.Y., Ye, Z.C., Wang, C.J., Shieh, Y.T. and Liu, M.Y. Coupling capillary electrophoresis with mass spectrometry for the analysis of oxidized phospholipids in human high-density lipoproteins. Electrophoresis, 45, 333-345 (2024); DOI.
Chen, J., Xie, P.S., Wu, P.F., He, Y., Lin, Z. and Cai, Z.W. MALDI coupled with laser-postionization and trapped ion mobility spectrometry contribute to the enhanced detection of lipids in cancer cell spheroids. Chin. Chem. Letts., 35, 108895 (2024); DOI.
Chen, L., Xu, R. and Zhu, J.J. Lipidome isotope labelling of gut microbes (LILGM): A method of discovering endogenous microbial lipids. Talanta, 271, 125730 (2024); DOI.
Cheng, S.M., Cao, C.X., Qian, Y., Yao, H., Gong, X.Y., Dai, X.H., Ouyang, Z. and Ma, X.X. High-throughput single-cell mass spectrometry enables metabolic network analysis by resolving phospholipid C=C isomers. Chem. Sci., 15, 6314-6320 (2024); DOI.
Chistyakov, D.V. and others. Plasma oxylipin profiles reflect Parkinson's disease stage. Prostaglandins Other Lipid Mediators, 171, 106788 (2024); DOI.
Chocholousková, M., Vivó-Truyols, G., Wolrab, D., Jirásko, R., Antonelli, M., Peterka, O., Vanková, Z. and Holcapek, M. Lipid Quant 2.1: Open-source software for identification and quantification of lipids measured by lipid class separation QTOF high-resolution mass spectrometry methods. Chemom. Intell. Lab. Systems, 251, 105169 (2024); DOI.
Couacault, P., Avella, D., Londoño-Osorio, S., Lorenzo, A.S., Gradillas, A., Karkkainen, O., Want, E. and Witting, M. Targeted and untargeted metabolomics and lipidomics in dried blood microsampling: Recent applications and perspectives. Anal. Sci. Adv., 5, e2400002 (2024); DOI.
Chuang, J.C., Clifford, A.J., Kim, S.H., Novotny, J.A., Kelly, P.B., Holstege, D.M. and Walzem, R.L. Separation of lipoproteins for quantitative analysis of 14C-labeled lipid-soluble compounds by accelerator mass spectrometry. Int. J. Mol. Sci., 25, 1856 (2024); DOI.
Dabija, L.G., Yousefi-Taemeh, M., Duli, E., Lemaire, M. and Ifa, D.R. Assessment of MALDI matrices for the detection and visualization of phosphatidylinositols and phosphoinositides in mouse kidneys through matrix-assisted laser desorption ionization mass spectrometry imaging (MALDI-MSI). Anal. Bioanal. Chem., 416, 1857-1865 (2024); DOI.
Dakic, A. and others. Imputation of plasma lipid species to facilitate integration of lipidomic datasets. Nature Commun., 15, 1540 (2024); DOI.
Di Mola, A., de Ferra, L., Anibaldi, M., Monaco, G. and Massa, A. An effective method for the evaluation of the enantiomeric purity of 1,2-diacyl-sn-glycero-3-phosphocholine-based lipids by NMR analysis. Symmetry-Basel, 16, 624 (2024); DOI.
Ding, S., von Meijenfeldt, F.A.B., Bale, N.J., Damsté, J.S.S. and Villanueva, L. Production of structurally diverse sphingolipids by anaerobic marine bacteria in the euxinic Black Sea water column. ISME J., 18, wrae153 (2024); DOI.
Ding, W.P., Li, Y.Q., Li, X.Y., Yin, J.J., Shi, S.B., Tian, X.P., Zhang, S. and Yin, H. Discovery of a novel chromone enantiomer and the precursors of nonactic acid from the coral-reef-derived Streptomyces sp. SCSIO 66814. Marine Drugs, 22, 181 (2024); DOI.
Djambazova, K.V., Gibson-Corley, K.N., Freiberg, J.A., Caprioli, R.M., Skaar, E.P. and Spraggins, J.M. MALDI TIMS IMS reveals ganglioside molecular diversity within murine S. aureus kidney tissue abscesses. J. Am. Soc. Mass Spectrom., 35, 1692-1701 (2024); DOI.
Dooley, M., Saliani, A. and Dalli, J. Development and validation of methodologies for the identification of specialized pro-resolving lipid mediators and classic eicosanoids in biological matrices. J. Am. Soc. Mass Spectrom., 35, 2331-2343 (2024); DOI.
Dörnyei, A., Kilár, A. and Sándor, V. Identification of a chimera mass spectrum of isomeric lipid A species using negative ion tandem mass spectrometry. Toxins, 16, 322 (2024); DOI.
Eisenberg, S.M. and Muddiman, D.C. Improved detection in untargeted lipidomics through silver-doped infrared matrix-assisted laser desorption electrospray ionization. Rapid Commun. Mass Spectrom., 38, e9832 (2024); DOI.
Elloumi, A. and others. From MS/MS library implementation to molecular networks: Exploring oxylipin diversity with NEO-MSMS. Sci. Data, 11, 193 (2024); DOI.
Elshoura, Y., Herz, M., Gad, M.Z. and Hanafi, R. Nitro fatty acids: A comprehensive review on analytical methods and levels in health and disease. Anal. Biochem., 694, 115624 (2024); DOI.
Forrester, M.T., Egol, J.R., Tata, A., Tata, P.R. and Foster, M.W. Analysis of protein cysteine acylation using a modified suspension trap (acyl-trap). J. Proteome Res., 23, 3716-3725 (2024); DOI.
Fu, X.Q., Knappe, C., Rohlfing, A.K., Gawaz, M.P. and Lämmerhofer, M. Non-enantioselective, enantioselective, and two-dimensional liquid chromatography coupled with tandem mass spectrometry for the study of stereochemical disposition of oxylipins in cGMP-regulated hemin-treated platelets. J. Pharm. Biomed. Anal., 248, 116328 (2024); DOI.
Gadara, D., Berka, V. and Spacil, Z. High-throughput microbore LC-MS lipidomics to investigate APOE phenotypes. Anal. Chem., 96, 59-66 (2024); DOI.
Gao, J.Y. and others. Lipidomics and mass spectrometry imaging unveil alterations in mice hippocampus lipid composition exposed to hypoxia. J. Lipid Res., 65, 100575 (2024); DOI.
Garcia, E. and others. A high-throughput NMR method for lipoprotein-X quantification. Molecules, 29, 564 (2024); DOI.
Garcia-Queiruga, J. and others. Meibum lipidomic analysis in evaporative dry eye subjects. Int. J. Mol. Sci., 25, 4782 (2024); DOI.
Garza, S., James, G., Park, H.G., Baker, P.R.S. and Brenna, J.T. Analysis of intact in vivo peroxidized phospholipids from bovine retina via LC-MS/MS and GC-MS/MS using autoxidized retina reference standards. Anal. Chem., 96, 15406-15413 (2024); DOI.
Genva, M., Fougère, L., Bahammou, D., Mongrand, S., Boutté, Y. and Fouillen, L. A global LC-MS2-based methodology to identify and quantify anionic phospholipids in plant samples. Plant J., 117, 956-971 (2024); DOI.
Gerhardtova, I., Jankech, T., Majerova, P., Piestansky, J., Olesova, D., Kovac, A. and Jampilek, J. Recent analytical methodologies in lipid analysis. Int. J. Mol. Sci., 25, 2249 (2024); DOI.
Gianazza, E., Brioschi, M., Eligini, S. and Banfi, C. Mass spectrometry for the study of adipocyte cell secretome in cardiovascular diseases. Mass Spectrom. Rev., 43, 752-781 (2024); DOI.
González-Valdez, A., Hernández-Pineda, J. and Soberón-Chávez, G. Detection and quantification of mono-rhamnolipids and di-rhamnolipids produced by pseudomonas aeruginosa. JOVE-J. Vis. Exp., e65934 (2024); DOI.
Goodwin, J.M., Kuiper, H.C., Brister, B. and Vesper, H.W. Impact of internal standard selection on measurement results for long chain fatty acids in blood. J. Mass Spectrom. Adv. Clin. Lab, 33, 22-30 (2024); DOI.
Gorina, S.S., Lantsova, N.V., Iljina, T.M., Toporkova, Y.Y. and Grechkin, A.N. Oxylipin biosynthesis via an unprecedented 16-hydroperoxide lyase pathway in green tissues of cucumber (Cucumis sativus L.) plants. Phytochemistry, 224, 114151 (2024); DOI.
Gosset-Erard, C., Han, G.H., Kyrko, D., Hueber, A., Nay, B., Eparvier, V. and Touboul, D. Structural characterization of N-acyl-homoserine lactones from bacterial quorum sensing using LC-MS/MS analyses after Paternò-Büchi derivatization in solution. Anal. Bioanal. Chem., 416, 5431-5443 (2024); DOI.
Gowda, S., Hou, F.J., Gowda, D., Chiba, H., Kawakami, K., Fukiya, S., Yokota, A. and Hui, S.P. Synthesis and quantification of short-chain fatty acid esters of hydroxy fatty acids in rat intestinal contents and fecal samples by LC-MS/MS. Anal. Chim. Acta, 1288, 342145 (2024); DOI.
Gowda, S.G.B., Shekhar, C., Gowda, D., Chen, Y.F., Chiba, H. and Hui, S.P. Mass spectrometric approaches in discovering lipid biomarkers for COVID-19 by lipidomics: Future challenges and perspectives. Mass Spectrom. Rev., 43, 1041-1065 (2024); DOI.
Grumov, D., Kostarnoy, A., Gancheva, P. and Kondratev, A. A simple and rapid microscale method for isolating bacterial lipopolysaccharides. Int. J. Mol. Sci., 25, 6345 (2024); DOI.
Gu, T.J., Liu, PK., Wang, Y.W., Flowers, M.T., Xu, S.L., Liu, Y., Davis, D.B. and Li, L.J. Diazobutanone-assisted isobaric labelling of phospholipids and sulfated glycolipids enables multiplexed quantitative lipidomics using tandem mass spectrometry. Nature Chem., 16, 762-770 (2024); DOI.
Guo, X.Y., Cao, W.B., Fan, X.M., Chen, Q.H., Wu, L., Ma, X.X., Ouyang, Z. and Zhang, W.P. MS3 imaging enables the simultaneous analysis of phospholipid CC and sn-position isomers in tissues. Anal. Chem., 96, 4259-4265 (2024); DOI.
Habra, H. and others. metabCombiner 2.0: disparate multi-dataset feature alignment for LC-MS metabolomics. Metabolites, 14, 125 (2024); DOI.
Haedar, J.R., Yoshimura, A. and Wakimoto, T. New variochelins from soil-isolated Variovorax sp. H002. Beilstein J. Org. Chem., 20, 692-700 (2024); DOI.
Hamzah, K.A., Turner, N., Nichols, D. and Ney, L.J. Advances in targeted liquid chromatography-tandem mass spectrometry methods for endocannabinoid and N-acylethanolamine quantification in biological matrices: A systematic review. Mass Spectrom. Rev., in press (2024); DOI.
Han, T., Fu, Z., Yang, M.Y. and Cao, X.L. Sweet space strategy for solvent system selection in countercurrent chromatography: A case study on separation of polyunsaturated fatty acids from borage oil. J. Sep. Sci., 47, 2400195 (2024); DOI.
Harris, R.A., May, J.C., Harvey, S.R., Wysocki, V.H. and Mclean, J.A. Evaluation of surface-induced dissociation ion mobility-mass spectrometry for lipid structural characterization. J. Am. Soc. Mass Spectrom., 35, 214-223 (2024); DOI.
Harrison, A. and others. PeakQC: A software tool for omics-agnostic automated quality control of mass spectrometry data. J. Am. Soc. Mass Spectrom., in press (2024); DOI.
He, S.S., Shi, L.L., Zheng, Z.W., Wu, F.L. and Ding, C.F. Differentiation of cis/trans-geometrical isomers in long-chain unsaturated fatty acids based on ion mobility and theoretical calculations. Food Chem., 457, 140156 (2024); DOI.
Hendriks, T.F.E., Krestensen, K.K., Mohren, R., Vandenbosch, M., De Vleeschouwer, S., Heeren, R.M.A. and Cuypers, E. MALDI-MSI-LC-MS/MS workflow for single-section single step combined proteomics and quantitative lipidomics. Anal. Chem., 96, 4266-4274 (2024); DOI.
Henschel, J.M., de Andrade, A.N., dos Santos, J.B.L., da Silva, R.R., da Mata, D.A., Souza, T. and Batista, D.S. Lipidomics in plants under abiotic stress conditions: an overview. Agronomy-Basel, 14, 1670 (2024); DOI.
Hildebrand, F., Koellensperger, G. and Causon, T. MobiLipid: A tool for enhancing CCS quality control of ion mobility-mass spectrometry lipidomics by internal standardization. Anal. Chem., 96, 7380-7385 (2024); DOI.
Hirai, T. and others. Arachidonic acid-derived dihydroxy fatty acids in neonatal cord blood relate symptoms of autism spectrum disorders and social adaptive functioning: Hamamatsu Birth Cohort for Mothers and Children (HBC Study). Psych. Clin. Neurosci., 78, 546-557 (2024); DOI.
Hirota, S., Ito, Y., Inoue, S., Kitaoka, N., Taniguchi, T., Monde, K., Takahashi, K. and Matsuura, H. Isolation and structure determination of cis-OPDA-α-monoglyceride from Arabidopsis thaliana. J. Nat. Prod., 87, 1358-1367 (2024); DOI.
Hohenwallner, K., Lamp, L.M., Peng, L.Y., Nuske, M., Hartler, J., Reid, G.E. and Rampler, E. FAIMS shotgun lipidomics for enhanced class- and charge-state separation complemented by automated ganglioside annotation. Anal. Chem., 96, 12296-12307 (2024); DOI.
Hooshmand, K., Xu, J., Simonsen, A.H., Wretlind, A., de Zawadzki, A., Sulek, K., Hasselbalch, S.G. and Legido-Quigley, C. Human cerebrospinal fluid sample preparation and annotation for integrated lipidomics and metabolomics profiling studies. Mol. Neurobiol., 61, 2021-2032 (2024); DOI.
Hopmans, E.C., Grossi, V., Sahonero-Canavesi, D.X., Bale, N.J., Cravo-Laureau, C. and Damsté, J.S.S. Mono- to tetra-alkyl ether cardiolipins in a mesophilic, sulfate-reducing bacterium identified by UHPLC-HRMSn: a novel class of membrane lipids. Front. Microbiol., 15, 1404328 (2024); DOI.
Horejsi, K. and Holcapek, M. Unraveling the complexity of glycosphingolipidome: the key role of mass spectrometry in the structural analysis of glycosphingolipids. Anal. Bioanal. Chem., 416, 5403-5421 (2024); DOI.
Horejsi, K., Kolárová, D., Jirásko, R. and Holcapek, M. Recent advances, challenges, and future directions in the mass spectrometry analysis of glycosphingolipids in biological samples. Trends Anal. Chem., 178, 117827 (2024); DOI.
Huang, L.H., Huang, M.H. and Zhou, T. Efficient strategy for characterization and quantification of polyunsaturated lipids by microwave-assisted MMPP epoxidation. Anal. Chem., 96, 11189-11197 (2024); DOI.
Huang, P.H., Zhang, H., Liu, Y. and Li, L.J. Rapid characterization of phospholipids from biological matrix enabled by indium tin oxide (ITO) coated slide assisted enrichment MALDI mass spectrometry. Anal. Sens., 4, e202300097 (2024); DOI.
Hwang, J.H. and others. Evaluation of simplified ester-linked fatty acid analysis (ELFA) for phospholipid fatty acid (PLFA) analysis of bacterial population. Anal. Biochem., 695, 115638 (2024); DOI.
Igarashi, Y. and others. Sporangimicins A-D, acylated maltose derivatives from a rare actinomycete of the genus Pseudosporangium. J. Antibiotics (Tokyo), 77, 713-720 (2024); DOI.
Ishikawa, T., Domergue, F., Amato, A. and Corellou, F. Characterization of unique eukaryotic sphingolipids with temperature-dependent ?8-unsaturation from the picoalga Ostreococcus tauri. Plant Cell Physiol., 65, 1029-1046 (2024); DOI.
Ivica, J., Adam, F., Wortel, L., Kalika, T., Pelly, H., Gauthier, J. and Potter, M. Development of a second-tier method for C4, C5 and C2 acylcarnitine analysis in plasma. Clin. Biochem., 123, 110698 (2024); DOI.
Iwama, T., Kano, K., Kawana, H., Shindou, H., Shimizu, T., Kono, N. and Aoki, J. Visualization of phospholipid synthesis on tissue sections using functional mass spectrometry imaging. Anal. Chem., 96, 11771-11779 (2024); DOI.
Inamassu, C.H., Silva, L.R.E. and Marchioni, C. Recent advances in the chromatographic analysis of endocannabinoids and phytocannabinoids in biological samples. J. Chromatogr. A, 1732, 465225 (2024); DOI.
Isom, M. and Desaire, H. Skin surface sebum analysis by ESI-MS. Biomolecules, 14, 790 (2024); DOI.
Jankech, T., Gerhardtova, I., Majerova, P., Piestansky, J., Jampilek, J. and Kovac, A. Derivatization of carboxylic groups prior to their LC analysis - A review. Anal. Chim. Acta, 1300, 342435 (2024); DOI.
Jaspers, Y.R.J. and others. Four-dimensional lipidomics profiling in X-linked adrenoleukodystrophy using trapped ion mobility mass spectrometry. J. Lipid Res., 65, 100567 (2024); DOI.
Jensen, M. and others. Opto-lipidomics of tissues. Adv. Sci., 11, e2302962 (2024); DOI.
Jeon, E., Park, M., Mojumdar, A., Kim, Y.H., Choi, J.S. and Cho, K. Optimized quantification of fatty acids in complex media using advanced analytical techniques. Rapid Commun. Mass Spectrom., 38, e9764 (2024); DOI.
Jha, D., Blennow, K., Zetterberg, H., Savas, J.N. and Hanrieder, J. Spatial neurolipidomics-MALDI mass spectrometry imaging of lipids in brain pathologies. J. Mass Spectrom., 59, e5008 (2024); DOI.
Ji, G.H., Xiong, Y.Y., Li, Y.Y., Yan, G.Q., Yao, J., Fang, C.Y. and Lu, H.J. Global analysis of N-myristoylation and its heterogeneity by combining N-terminomics and nanographite fluoride-based solid-phase extraction. Talanta, 276, 126300 (2024); DOI.
Ji, Y.Y., Morel, Y., Tran, A.Q., Lipinski, M.M., Sarkar, C. and Jones, J.W. Development and evaluation of a liquid chromatography-tandem mass spectrometry method for simultaneous measurement of toxic aldehydes from brain tissue. J. Chromatogr. B, 1242, 124208 (2024); DOI.
Jitsukawa, T., Watanabe, S., Shigeri, Y. and Fujisaki, S. Quantification of polyprenyl diphosphates in Escherichia coli cells using high-performance liquid chromatography. Biosci. Biotechn. Biochem., 88, 429-436 (2024); DOI.
Joblin-Mills, A., Wu, Z.X.E., Sequeira-Bisson, I.R., Miles-Chan, J.L., Poppitt, S.D. and Fraser, K. Utilising a clinical metabolomics LC-MS study to determine the integrity of biological samples for statistical modelling after long term -80 °c storage: A TOFI_Asia sub-study. Metabolites, 14, 313 (2024); DOI.
Keener, J.E., Goh, B., Yoo, J.S., Oh, S.F. and Brodbelt, J.S. Top-down characterization of bacterial lipopolysaccharides and lipooligosaccharides using activated-electron photodetachment mass spectrometry. Anal. Chem., 96, 9151-9158 (2024); DOI.
Keller, M.J., Zhang, Q., Qian, S., Sanders, B.C., O'Neill, H.M. and Hettich, R.L. Characterization of the in vivo deuteration of native phospholipids by mass spectrometry yields guidelines for their regiospecific customization. Anal. Chem., 96, 212-219 (2024); DOI.
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