Pulmonary function after emergence on 100% oxygen in patients with chronic obstructive pulmonary disease: a randomized, controlled trial.

BACKGROUND: During emergence from anesthesia, breathing 100% oxygen is frequently used to provide a safety margin toward hypoxemia in case an airway problem occurs. Oxygen breathing has been shown to cause pulmonary gas exchange disorders in healthy individuals. This study investigates how oxygen breathing during emergence affects lung function specifically whether oxygen breathing causes added hypoxemia in patients with chronic obstructive pulmonary disease. METHODS: This trial has been conducted in a parallel-arm, case-controlled, open-label manner. Fifty-three patients with chronic obstructive pulmonary disease were randomly allocated (computer-generated lists) to breathe either 100 or 30% oxygen balanced with nitrogen during emergence from anesthesia. Arterial blood gas measurements were taken before induction and at 5, 15, and 60 min after extubation. RESULTS: All participants tolerated the study well. Patients treated with 100% oxygen had a higher alveolar-arterial oxygen pressure gradient (primary outcome) compared with patients treated with 30% oxygen (25 vs. 20 mmHg) and compared with their baseline at the 60-min measurement (25 vs. 17 mmHg). At the 60-min measurement, arterial partial pressure of oxygen was lower in the 100% group (62 vs. 67 mmHg). Arterial partial pressure of carbon dioxide and pH were not different between groups or measurements. CONCLUSIONS: In this experiment, the authors examined oxygen breathing during emergence-a widely practiced maneuver known to generate pulmonary blood flow heterogeneity. In the observed cohort of patients already presenting with pulmonary blood flow disturbances, emergence on oxygen resulted in deterioration of oxygen-related blood gas parameters. In the perioperative care of patients with chronic obstructive pulmonary disease, oxygen breathing during emergence from anesthesia may need reconsideration.

Recombinant angiotensin-converting enzyme 2 suppresses pulmonary vasoconstriction in acute hypoxia.

OBJECTIVE: Alveolar hypoxia as a result of high altitude leads to increased pulmonary arterial pressure. The renin-angiotensin system is involved in the regulation of pulmonary arterial pressure through angiotensin-converting enzyme 2 (ACE2). It remains unknown whether ACE2 administration alters pulmonary vascular pressure in hypoxia. METHODS: We investigated 12 anesthetized pigs instrumented with arterial, central venous, and Swan-Ganz catheters exposed to normobaric hypoxia (fraction of inspired oxygen = 0.125) for 180 minutes. After taking baseline measurements in normoxia and hypoxia, ACE2 400 µg·kg(-1) was administered to 6 animals, and another 6 served as control. Ventilatory variables, arterial blood gases, ventilation/perfusion (V̇A/Q̇) relationships, and plasma angiotensin II concentrations were assessed before and at 30, 90, and 150 minutes in hypoxia after ACE2 or placebo administration. Hemodynamic variables and cardiac output were observed every 30 minutes. RESULTS: We observed lower pulmonary arterial pressure (maximum: 30 vs 39 mm Hg, P < .01) and lower pulmonary vascular resistance (maximum: 4.1 vs 7.5 Wood units, P <.01) in animals treated with ACE2. There was a trend (P =.09) toward lower angiotensin II plasma concentrations among ACE2-treated animals. Cardiac variables and systemic arterial pressure in hypoxia remained unaffected by ACE2. Ventilation/perfusion relationships and Pao(2) did not differ between groups. CONCLUSIONS: In acute pulmonary hypertension, administration of ACE2 blunts the rise in pulmonary arterial pressure that occurs in response to hypoxia. Recombinant ACE2 may be a treatment option for high altitude pulmonary edema and hypoxia-associated pulmonary hypertension.

[Respiratory system at high altitude: pathophysiology and novel therapy options]. / Das Respiratorische System auf großer Höhe: Pathophysiologie und neue Therapieoptionen.

This mini-review conveys information on lung function in hypoxia. Included are presentations of shape and layering of the atmosphere, physiologic basics of lung function at high altitude, pathophysiology of high altitude pulmonary edema (HAPE) and of current and potential therapy approaches for HAPE.

Intravenous tezosentan improves gas exchange and hemodynamics in acute lung injury secondary to meconium aspiration.

OBJECTIVE: Meconium aspiration induces acute lung injury (ALI) and subsequent pulmonary arterial hypertension (PAH) which may lead to right ventricular failure. Increase of endothelin-1, thromboxane-A, and phosphodiesterases are discussed molecular mechanisms. We investigated the intrapulmonary and hemodynamic effects of the intravenous dual endothelin A and B receptor blocker tezosentan and inhalational iloprost in a model of ALI due to meconium aspiration. DESIGN: Animal study. SETTING: University-affiliated research laboratory. SUBJECTS: White farm pigs. INTERVENTIONS: Acute lung injury was induced in 24 pigs by instillation of meconium. Animals were randomly assigned to four groups to receive either intravenous tezosentan, inhalational iloprost, or combined tezosentan and iloprost, or to serve as controls. MEASUREMENTS AND RESULTS: After meconium aspiration-induced lung injury each treatment increased oxyhemoglobin saturations (TEZO: 88 +/- 6% (p = 0.02), ILO: 85 +/- 13% (p = 0.05), TEZO-ILO: 89 +/- 6% (p = 0.02), control: 70 +/- 18%). TEZO but not ILO significantly decreased pulmonary arterial pressure and pulmonary vascular resistance (both p < 0.01). ILO alone decreased intrapulmonary shunt blood flow (p < 0.01). Compared with control, TEZO-ILO yielded the highest arterial partial pressure of oxygen (70 +/- 6 torr vs.49 +/- 9 torr, p = 0.04), although it decreased arterial blood pressure (change from 71 +/- 13 mmHg to 62 +/- 12 mmHg vs.85 +/- 14 mmHg to 80 +/- 11 mmHg (p = 0.01). CONCLUSIONS: Intravenous TEZO improves pulmonary gas exchange and hemodynamics in experimental acute lung injury secondary to meconium aspiration. Inhaled ILO improves gas exchange only, thereby reducing intrapulmonary shunt blood flow. Combination of TEZO and ILO marginally improves pulmonary gas exchange at the disadvantage of pulmonary selectivity.