2023
Unique DUOX2+ACE2+ small cholangiocytes are pathogenic targets for primary biliary cholangitis
Li X, Li Y, Xiao J, Wang H, Guo Y, Mao X, Shi P, Hou Y, Zhang X, Zhao N, Zheng M, He Y, Ding J, Tan Y, Liao M, Li L, Peng Y, Li X, Pan Q, Xie Q, Li Q, Li J, Li Y, Chen Z, Huang Y, Assis D, Cai S, Boyer J, Huang X, Tang C, Liu X, Peng S, Chai J. Unique DUOX2+ACE2+ small cholangiocytes are pathogenic targets for primary biliary cholangitis. Nature Communications 2023, 14: 29. PMID: 36759512, PMCID: PMC9911648, DOI: 10.1038/s41467-022-34606-w.Peer-Reviewed Original ResearchConceptsPrimary biliary cholangitisPrimary biliary cholangitis patientsBiliary cholangitisEtiology of primary biliary cholangitisScRNA-seqPathogenic targetsSeverity of diseaseSingle-cell RNA sequencingAMA-M2PBC patientsAutoantibody levelsPolymeric immunoglobulin receptorMemory BMultiplex immunofluorescenceCholangiocyte injuryPlasma cellsAutoimmune diseasesRNAscope analysisCholangiocytesImmunoglobulin receptorBile formationPatientsTherapeutic interventionsMultiplexed IFRNA sequencing
2020
Introduction to the Physiology, Immunology and Pathology of the Liver and Biliary Tree
Carbone M, Strazzabosco M. Introduction to the Physiology, Immunology and Pathology of the Liver and Biliary Tree. 2020, 3-20. DOI: 10.1002/9781119532637.ch1.Peer-Reviewed Original ResearchBile acidsBile formationDietary lipid absorptionMetabolism of bilirubinBiliary tree stem cellsBiliary treeLiver synthesisHepatic metabolismLipid absorptionEnergy homeostasisCholesterol homeostasisMetabolic homeostasisLiverCanalicular secretionStem cellsSecretionHomeostasisRegenerative abilityMetabolismBilirubinPathologyEndotoxinImmunology
2010
Cholestasis: Genetic and Acquired
Boyer J. Cholestasis: Genetic and Acquired. Seminars In Liver Disease 2010, 30: 113-115. PMID: 20422493, DOI: 10.1055/s-0030-1253220.Peer-Reviewed Original ResearchConceptsBile salt export pumpCholestatic liver diseaseMultidrug resistance protein 3Cholestatic liver injuryLiver diseaseBile acidsBile salt transportersIssue of SeminarsLiver injuryCholestatic disordersBile flowSulfate conjugatesSodium taurocholate co-transporting polypeptideBile duct-cannulated animalsBile formationExport pumpProtein 3Bile acid-independent bile flowSalt transportersTaurocholate co-transporting polypeptideOrganic solute transporters alphaDependent bile salt transporterApical sodium-dependent bile salt transporterFamilial intrahepatic cholestasis-1Drug-induced cholestasis
2007
Clinical Use of Immunopathology Techniques in Liver Diseases
Liu C, Crawford J. Clinical Use of Immunopathology Techniques in Liver Diseases. 2007, 123-136. DOI: 10.1007/978-1-59745-518-3_11.Peer-Reviewed Original ResearchSplanchnic circulationDendritic cellsHepatic injuryLiver diseaseHepatocellular damageImmune responseImmunological siteKupffer cellsSystemic circulationInfectious agentsImmunopathology techniquesResident macrophagesBile formationClinical useImmunological processingExogenous substancesAnatomic structuresLargest organLiverSimultaneous damageCritical roleCellsPropensity of humansLymphocytesInjury
1998
Role of glutathione in hepatic bile formation during reperfusion after cold ischemia of the rat liver
Koeppel T, Trauner M, Albert M, Arrese M, Rios-Velez L, Boyer J. Role of glutathione in hepatic bile formation during reperfusion after cold ischemia of the rat liver. Journal Of Hepatology 1998, 28: 812-819. PMID: 9625316, DOI: 10.1016/s0168-8278(98)80231-6.Peer-Reviewed Original ResearchConceptsBiliary glutathione excretionBile duct injuryCold ischemiaBile flowHepatic bile formationDuct injuryLiver transplantationBiliary tractBiliary excretionRat liverGlutathione excretionBasal bile flow ratesBile formationBile acid-independent bile flowOxidative stressLate reperfusion periodBile duct damageBile flow rateOnset of reperfusionIndependent bile flowBile duct morphologyBiliary glutathione concentrationsWistar rat liverLiver reperfusionDuct damage
1997
Transport systems in cholangiocytes: their role in bile formation and cholestasis.
Strazzabosco M. Transport systems in cholangiocytes: their role in bile formation and cholestasis. The Yale Journal Of Biology And Medicine 1997, 70: 427-34. PMID: 9626763, PMCID: PMC2589334.Peer-Reviewed Original ResearchConceptsBiliary epitheliumCa-activated Cl channelsChronic cholestatic disorderPathogenesis of cholestasisBile duct diseaseCholangiocyte deathFormation of bilePortal inflammationBiliary cirrhosisProinflammatory mediatorsLiver diseaseClinical picturePathophysiological pointCholestatic disordersDuct diseaseProliferative responseBiliary constituentsBile acidsCystic fibrosisPortal spacesSecretory functionBile formationCholestasisDuctular secretionSecretory activity
1989
Voltage-driven, taurocholate-dependent secretion in isolated hepatocyte couplets
Weinman S, Graf J, Boyer J. Voltage-driven, taurocholate-dependent secretion in isolated hepatocyte couplets. American Journal Of Physiology 1989, 256: g826-g832. PMID: 2719107, DOI: 10.1152/ajpgi.1989.256.5.g826.Peer-Reviewed Original ResearchConceptsBile secretionBile acidsSecretion rateFluid secretionIntracellular current injectionCanalicular areaHepatocyte coupletsMembrane potentialRat hepatocyte coupletsAbsence of taurocholateMicroM taurocholateFluid secretion rateBile formationSecretionCarrier-mediated transportTaurocholateLiverIntracellular voltage
1988
Mechanisms of Bile Secretion: lnsights from the Isolated Rat Hepatocyte Couplet
Boyer J, Gautam A, Graf J. Mechanisms of Bile Secretion: lnsights from the Isolated Rat Hepatocyte Couplet. Seminars In Liver Disease 1988, 8: 308-316. PMID: 2850606, DOI: 10.1055/s-2008-1040552.Peer-Reviewed Original Research
1987
Ursodeoxycholate stimulates Na+-H+ exchange in rat liver basolateral plasma membrane vesicles.
Moseley R, Ballatori N, Smith D, Boyer J. Ursodeoxycholate stimulates Na+-H+ exchange in rat liver basolateral plasma membrane vesicles. Journal Of Clinical Investigation 1987, 80: 684-690. PMID: 3040805, PMCID: PMC442291, DOI: 10.1172/jci113122.Peer-Reviewed Original Research
1986
Slow biliary elimination of methyl mercury in the marine elasmobranchs, Raja erinacea and Squalus acanthias
Ballatori N, Boyer J. Slow biliary elimination of methyl mercury in the marine elasmobranchs, Raja erinacea and Squalus acanthias. Toxicology And Applied Pharmacology 1986, 85: 407-415. PMID: 3764924, DOI: 10.1016/0041-008x(86)90348-0.Peer-Reviewed Original ResearchConceptsMarine elasmobranchsExcretory processesMarine speciesGlutathione biosynthesisDogfish sharkSharksRaja erinaceaMammalsSkateL-buthionineElasmobranchsR-sulfoximineMethyl mercuryFishSpeciesGlutathioneFree-swimming fishBiosynthesisErinaceaSwimming fishSmall fractionSlower rateBile formationSqualusMercury chlorideNa-H exchange in rat liver basolateral but not canalicular plasma membrane vesicles
Moseley RH, Meier PJ, Aronson PS, Boyer JL. Na-H exchange in rat liver basolateral but not canalicular plasma membrane vesicles. American Journal Of Physiology 1986, 250: g35-g43. PMID: 3002192, DOI: 10.1152/ajpgi.1986.250.1.g35.Peer-Reviewed Original ResearchMeSH Keywords4,4'-Diisothiocyanostilbene-2,2'-Disulfonic Acid4-Acetamido-4'-isothiocyanatostilbene-2,2'-disulfonic AcidAcridine OrangeAmilorideAmmoniaAnimalsBasement MembraneBiological Transport, ActiveCarrier ProteinsCell MembraneFiltrationHydrogen-Ion ConcentrationLithiumLiverMaleMembrane PotentialsOsmolar ConcentrationPotassiumRatsRats, Inbred StrainsSodiumSodium-Hydrogen ExchangersValinomycin
1985
Mechanisms of Electrolyte Transport in the Liver Their Functional Significance
Moseley R, Boyer J. Mechanisms of Electrolyte Transport in the Liver Their Functional Significance. Seminars In Liver Disease 1985, 5: 122-135. PMID: 3161181, DOI: 10.1055/s-2008-1063917.Peer-Reviewed Original Research
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