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RESEARCH PRODUCT
Dynamic determination of oxygenation and lung compliance in murine pneumonectomy.
Jan P. HoudekBarry C. GibneyMiao LinSteven J. MentzerAkira TsudaKenji ChamotoMoritz A. KonerdingGrace S. LeeLino F. Mielesubject
Pulmonary and Respiratory Medicinemedicine.medical_treatmentClinical BiochemistryPulmonary complianceArticlePositive-Pressure RespirationPneumonectomyMiceTidal VolumeMedicineAnimalsLung volumesAnesthesiaPneumonectomyMolecular BiologyLungLung ComplianceTidal volumeOxygen saturation (medicine)Mechanical ventilationLungbusiness.industryTotal Lung CapacityOxygenationrespiratory systemRespiration ArtificialMice Inbred C57BLOxygenmedicine.anatomical_structureAnesthesiabusinessLung Volume Measurementsdescription
Thoracic surgical procedures in mice have been applied to a wide range of investigations, but little is known about the murine physiologic response to pulmonary surgery. Using continuous arterial oximetry monitoring and the FlexiVent murine ventilator, the authors investigated the effect of anesthesia and pneumonectomy on mouse oxygen saturation and lung mechanics. Sedation resulted in a dose-dependent decline of oxygen saturation that ranged from 55% to 82%. Oxygen saturation was restored by mechanical ventilation with increased rate and tidal volumes. In the mouse strain studied, optimal ventilatory rates were a rate of 200/minute and a tidal volume of 10 mL/kg. Sustained inflation pressures, referred to as a "recruitment maneuver," improved lung volumes, lung compliance, and arterial oxygenation. In contrast, positive end-expiratory pressure (PEEP) had a detrimental effect on oxygenation; an effect that was ameliorated after pneumonectomy. These results confirm that lung volumes in the mouse are dynamically determined and suggest a threshold level of mechanical ventilation to maintain perioperative oxygen saturation.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2011-05-16 | Experimental lung research |