2024
Quantitative Assessment of Mitochondrial Morphology and Electrophysiological Function in the Diabetic Heart
Cacheux M, Rudokas M, Tieu A, Rizk J, Hummel M, Akar F. Quantitative Assessment of Mitochondrial Morphology and Electrophysiological Function in the Diabetic Heart. Methods In Molecular Biology 2024, 2803: 75-86. PMID: 38676886, DOI: 10.1007/978-1-0716-3846-0_6.Peer-Reviewed Original ResearchConceptsMitochondrial shapeMitochondrial networkMitochondrial architectureSubcellular localizationMitochondrial morphologyDiabetic heartOxidative phosphorylationATP synthesisAction potentialsSarcolemmal ion channelsExcitation-contraction couplingFission eventsOptical action potentialsExcitation-contractionCardiac myocytesElectrophysiological properties
2018
Optical Action Potential Mapping in Acute Models of Ischemia–Reperfusion Injury: Probing the Arrhythmogenic Role of the Mitochondrial Translocator Protein
Ilkan Z, Strauss B, Campana C, Akar FG. Optical Action Potential Mapping in Acute Models of Ischemia–Reperfusion Injury: Probing the Arrhythmogenic Role of the Mitochondrial Translocator Protein. Methods In Molecular Biology 2018, 1816: 133-143. PMID: 29987816, DOI: 10.1007/978-1-4939-8597-5_10.Peer-Reviewed Original ResearchConceptsOptical action potential mappingIschemia-reperfusion injuryTranslocator proteinPost-ischemic arrhythmiasIonotropic propertiesPostischemic arrhythmiasR injuryHypertensive ratsAcute modelArrhythmogenic roleElectrophysiological substrateElectrophysiological propertiesArrhythmia mechanismsPharmacological inhibitionIntact heartInjuryTSPO ligandsMitochondrial translocator proteinArrhythmiasTSPO geneHeartPatientsRatsQuantitative assessmentIncidence
2013
Electrophysiological Remodeling in Heart Failure
Akar F, Tomaselli G. Electrophysiological Remodeling in Heart Failure. 2013, 369-386. DOI: 10.1007/978-1-4471-4881-4_22.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsHeart failureTreatment of arrhythmiasCellular electrophysiological propertiesIon channelsSafe therapyConduction abnormalitiesElectrophysiological remodelingSudden deathNovel pharmacologicalArrhythmogenic triggersElectrophysiological propertiesAction potentialsArrhythmiasFunctional consequencesIonic mechanismsMolecular mechanismsOrgan levelFailureTherapyAbnormalitiesPharmacologicalRepolarization
2006
Mapping arrhythmias in the failing heart: from Langendorff to patient
Akar JG, Akar FG. Mapping arrhythmias in the failing heart: from Langendorff to patient. Journal Of Electrocardiology 2006, 39: s19-s23. PMID: 16920143, DOI: 10.1016/j.jelectrocard.2006.03.011.Peer-Reviewed Educational MaterialsConceptsHeart failureVentricular arrhythmiasOptical action potential mappingSudden cardiac deathCardiac deathIntact tissue preparationsCardiac remodelingMost arrhythmiasArrhythmic substrateArrhythmiasElectrophysiological propertiesMapping arrhythmiasTissue levelsIndividual myocytesMajor causeReentrant excitationOrgan system levelPatientsMultiple mechanismsTissue preparationsHeartRecent findingsHost of changesCellular studiesLangendorff
1998
Modulated Dispersion Explains Changes in Arrhythmia Vulnerability During Premature Stimulation of the Heart
Laurita K, Girouard S, Akar F, Rosenbaum D. Modulated Dispersion Explains Changes in Arrhythmia Vulnerability During Premature Stimulation of the Heart. Circulation 1998, 98: 2774-2780. PMID: 9851966, DOI: 10.1161/01.cir.98.24.2774.Peer-Reviewed Original ResearchConceptsVentricular fibrillation thresholdSingle premature stimulusPremature stimuliArrhythmia vulnerabilityBaseline levelsPremature stimulationS1S2 intervalRepolarization gradientsGuinea pig heartsBaseline pacingFibrillation thresholdArrhythmogenic substrateVentricular fibrillationVentricular sitesStimulus-induced changesVentricular repolarizationCoupling intervalCardiac arrhythmiasS2 beatElectrophysiological propertiesAction potentialsOptical action potentialsHeterogeneous electrophysiological propertiesPig heartsRepolarization