about
Bench-to-bedside review: the effects of hyperoxia during critical illnessPrevention of acute respiratory distress syndromeNitric oxide and hyperoxic acute lung injury4-hydroxynonenal regulates mitochondrial function in human small airway epithelial cellsHyperoxemia and long-term outcome after traumatic brain injury.Postnatal development of eupneic ventilation and metabolism in rats chronically exposed to moderate hyperoxia.Analysis of the transcriptome in hyperoxic lung injury and sex-specific alterations in gene expression.Induced pluripotent stem cell therapy ameliorates hyperoxia-augmented ventilator-induced lung injury through suppressing the Src pathwayNovel Flurometric Tool to Assess Mitochondrial Redox State of Isolated Perfused Rat Lungs after Exposure to Hyperoxia.Can we optimize long-term outcomes in acute respiratory distress syndrome by targeting normoxemia?Adenosine promotes vascular barrier function in hyperoxic lung injury.NLRP3 protein deficiency exacerbates hyperoxia-induced lethality through Stat3 protein signaling independent of interleukin-1βIn vivo detection of hyperoxia-induced pulmonary endothelial cell death using (99m)Tc-duramycin.Blunt Chest Trauma in Mice after Cigarette Smoke-Exposure: Effects of Mechanical Ventilation with 100% O2.Resolvins Decrease Oxidative Stress Mediated Macrophage and Epithelial Cell Interaction through Decreased Cytokine Secretion.Enhanced Resolution of Hyperoxic Acute Lung Injury as a result of Aspirin Triggered Resolvin D1 Treatment.Activation of Src-dependent Smad3 signaling mediates the neutrophilic inflammation and oxidative stress in hyperoxia-augmented ventilator-induced lung injury.Immunological mechanisms of the antitumor effects of supplemental oxygenation.Targeting Abl kinases to regulate vascular leak during sepsis and acute respiratory distress syndrome.Probucol attenuates hyperoxia-induced lung injury in mice.Fasudil, an inhibitor of Rho-associated coiled-coil kinase, attenuates hyperoxia-induced pulmonary fibrosis in neonatal ratsSomething in the air: hyperoxic conditioning of the tumor microenvironment for enhanced immunotherapyRecommendations for the implementation of a Patient Blood Management programme. Application to elective major orthopaedic surgery in adults.An endothelial TLR4-VEGFR2 pathway mediates lung protection against oxidant-induced injuryDeletion of P2X7 attenuates hyperoxia-induced acute lung injury via inflammasome suppressionHyperoxemia as a risk factor for ventilator-associated pneumonia.NLRP3 deletion protects from hyperoxia-induced acute lung injuryMiR-15a/16 Regulates Apoptosis of Lung Epithelial Cells after Oxidative Stress.Potential effects of medicinal plants and secondary metabolites on acute lung injury.SOCS-1 rescues IL-1β-mediated suppression of epithelial sodium channel in mouse lung epithelial cells via ASK-1.VEGF-D promotes pulmonary oedema in hyperoxic acute lung injury.Hyperoxia induces alveolar epithelial-to-mesenchymal cell transition.NOX1 is responsible for cell death through STAT3 activation in hyperoxia and is associated with the pathogenesis of acute respiratory distress syndrome.Inhibition of extracellular HMGB1 attenuates hyperoxia-induced inflammatory acute lung injury.Calcitonin gene-related peptide protects type II alveolar epithelial cells from hyperoxia-induced DNA damage and cell death.Novel concepts of acute lung injury and alveolar-capillary barrier dysfunction.Oxygen regulates molecular mechanisms of cancer progression and metastasis.Critical asthma syndrome in the ICU.Hyperoxia in intensive care, emergency, and peri-operative medicine: Dr. Jekyll or Mr. Hyde? A 2015 update.Free radicals and related reactive species as mediators of tissue injury and disease: implications for Health.
P2860
Q26798077-1B82A573-8D9A-49A8-9BEF-DD3BFD78F098Q27009192-1A6ABD68-35EB-4A51-84F7-75D9FC44DAC5Q28080203-8C2E297A-5DF3-4324-B7EC-730B11E13BA0Q28386368-B79E1B7F-F437-46DD-B155-E3C1F30FBA93Q33752883-D62843A0-813B-4310-8EAA-7E54C57571E1Q33791359-53C78762-0792-44CE-8556-864D3216A5FCQ33863629-70E87BCC-A211-45AC-BDEF-7CB2D0AC8553Q34332173-4B8CDBC8-1191-4DF9-8514-072DBDF5ABFDQ34449656-073C2502-F1FC-4D7B-B4B9-8ED9EDF4FCBAQ34479165-6EC5E6E5-4F1A-4767-9116-ACC73B46AF41Q34730524-251987D9-905F-4D60-B6AE-E66E1C3A9EAEQ35104002-D1D1215F-8934-482E-8846-EA6351C81916Q35249137-785A99A6-A717-48CD-A37D-F13D46009608Q35726117-4929140B-5027-49A7-81C0-64D5D1E3B42DQ35759118-FDB1E82D-CF4E-46F6-B351-3C9BD6E970CEQ36049293-CC1A5CD5-416F-4122-A4F9-E5C86B2B5920Q36071210-A2C60D32-33FA-4051-AD0C-C21070280745Q36269330-1DD636CC-F070-495B-B041-BA062DE66BE6Q36306823-A4BF5E62-3AFE-4150-B034-83A56E4733C8Q36338270-5606235C-43F4-4BD3-8B46-C035FD430046Q36375039-6FA905EB-60A7-44D4-A5E4-8978921554B7Q36416362-A5EE883D-B693-407B-B422-C04685F8E9F2Q36515685-EB377540-2621-41C1-8471-534902238512Q36570882-F7276261-933C-453B-8D80-151412EF15D0Q36698698-0ABA256C-F0B3-4A9D-B1DE-C3FA0D3D3B62Q37031079-C480058F-381F-47BC-8F27-A6EA6EB85575Q37051324-7EEB56C3-E960-44AE-813E-69E2ED09470BQ37256332-6072707A-88CC-4151-B887-BE39A74A87F7Q37260532-E5123462-650F-4773-9C87-320F96E24075Q37301742-44B51297-BA55-404E-9445-D141E4DC8BA1Q37352264-E4105D64-F824-44EF-BD21-87F734AAA32CQ37576118-B09D521B-D7CA-45E2-A741-5270ACE53E47Q37587341-C2E8CCCE-ED39-413F-A9BC-F0BD353E2BCFQ37587820-210F661E-2C30-4678-B127-DA92109C9CBDQ37734580-6F9D1CF1-7F6D-42DA-8DCA-931A3BA414EBQ38138015-764B195B-F7BD-4D38-B126-20908467AD40Q38171333-FB2DB6CF-D543-470E-8353-BF3D4C8E8AC0Q38373406-CD213A8C-6944-41D2-B4BE-F0F2F9F72539Q38639006-D923A34C-D3E6-4F96-9229-48CFC7F4AF34Q38648995-DE8635AF-BBC3-4B40-949A-FC7B89EFD13E
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Hyperoxic acute lung injury.
@en
type
label
Hyperoxic acute lung injury.
@en
prefLabel
Hyperoxic acute lung injury.
@en
P2860
P356
P1433
P1476
Hyperoxic acute lung injury.
@en
P2093
Richard H Kallet
P2860
P304
P356
10.4187/RESPCARE.01963
P577
2013-01-01T00:00:00Z