Quantifying hyperoxia-mediated damage to mammalian respiratory cilia-driven fluid flow using particle tracking velocimetry optical coherence tomography
Gamm UA, Huang BK, Syed M, Zhang X, Bhandari V, Choma MA. Quantifying hyperoxia-mediated damage to mammalian respiratory cilia-driven fluid flow using particle tracking velocimetry optical coherence tomography. Journal Of Biomedical Optics 2015, 20: 080505-080505. PMID: 26308164, PMCID: PMC4874052, DOI: 10.1117/1.jbo.20.8.080505.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsHyperbaric OxygenationHyperoxiaImage Interpretation, Computer-AssistedMiceMucusReproducibility of ResultsRespiratory MucosaRheologySensitivity and SpecificityTomography, Optical CoherenceConceptsOptical coherence tomographyMouse tracheaCoherence tomographyDrug-mediated modulationIntensive care unitRisk-benefit profileRespiratory failureCare unitOxygen supplementationRespiratory mucosaRespiratory epitheliumIndispensable treatmentImpaired capacityClinical useHyperoxiaTracheaFlow quantificationTomographyTreatmentDamagePatientsMucosaSupplementationEpithelium