2025
Dietary oleic acid drives obesogenic adipogenesis via modulation of LXRα signaling
Wing A, Jeffery E, Church C, Goodell J, Saavedra-Peña R, Saha M, Holtrup B, Voisin M, Alavi N, Floody M, Wang Z, Zapadka T, Garabedian M, Varshney R, Rudolph M, Rodeheffer M. Dietary oleic acid drives obesogenic adipogenesis via modulation of LXRα signaling. Cell Reports 2025, 44: 115527. PMID: 40208790, PMCID: PMC12073628, DOI: 10.1016/j.celrep.2025.115527.Peer-Reviewed Original ResearchAdipocyte precursor cellsDietary fatPlasma monounsaturated fatty acidsAssociated with human obesityHuman adipocyte precursor cellsMonounsaturated fatty acidsDietary fat compositionDietary screeningFatty acidsDietary fatty acidsHuman obesityAdipose expansionMetabolic healthObesity epidemicAkt2 signalingLXR activationPrecursor cellsAdipose biologyOleic acidHyperplasiaObesityAdipocyte hyperplasiaDietary oleic acidPhysiological regulationAdipogenesis
2024
Oleic acid differentially affects lipid droplet storage of de novo synthesized lipids in hepatocytes and adipocytes
Castillo H, Shuster S, Tarekegn L, Davis C. Oleic acid differentially affects lipid droplet storage of de novo synthesized lipids in hepatocytes and adipocytes. Chemical Communications 2024, 60: 3138-3141. PMID: 38329230, PMCID: PMC10939124, DOI: 10.1039/d3cc04829b.Peer-Reviewed Original Research
2021
Oleic acid restores suppressive defects in tissue-resident FOXP3 regulatory T cells from patients with multiple sclerosis
Pompura SL, Wagner A, Kitz A, Laperche J, Yosef N, Dominguez-Villar M, Hafler D. Oleic acid restores suppressive defects in tissue-resident FOXP3 regulatory T cells from patients with multiple sclerosis. Journal Of Clinical Investigation 2021, 131 PMID: 33170805, PMCID: PMC7810477, DOI: 10.1172/jci138519.Peer-Reviewed Original ResearchConceptsMultiple sclerosisAdipose tissueFoxp3 regulatory T cellsExpression of Foxp3Regulatory T cellsTreg suppressive functionProinflammatory arachidonic acidHuman adipose tissuePhosphorylation of STAT5Treg homeostasisFatty acidsPeripheral bloodTissue residencyHealthy donorsInflammatory signalsT cellsTregsFree fatty acidsSuppressive functionArachidonic acidPatientsOleic acidOxidative phosphorylationTranscriptomic programsFoxp3
2013
Mechanism for strong binding of CdSe quantum dots to multiwall carbon nanotubes for solar energy harvesting
Azoz S, Jiang J, Keskar G, McEnally C, Alkas A, Ren F, Marinkovic N, Haller GL, Ismail-Beigi S, Pfefferle LD. Mechanism for strong binding of CdSe quantum dots to multiwall carbon nanotubes for solar energy harvesting. Nanoscale 2013, 5: 6893-6900. PMID: 23783269, DOI: 10.1039/c3nr00928a.Peer-Reviewed Original ResearchCharge transferCdSe QDsCarbon nanotubesOrganic capping agentsDifferent functionalization strategiesFast charge transferTemperature-programmed decompositionDirect bond formationWalled carbon nanotubesCdSe quantum dotsMultiwall carbon nanotubesSolar cell devicesFunctionalization strategiesHybrid nanomaterialsBond formationCapping agentEXAFS characterizationTunable propertiesCovalent attachmentSolar energy harvestingMyriad of applicationsCell devicesOleic acidMWNTsStrong binding
This site is protected by hCaptcha and its Privacy Policy and Terms of Service apply