Elite apnea divers have considerably extended the limits of dive depth and duration but the mechanisms allowing humans to tolerate the compression- and decompression-induced changes in alveolar gas partial pressures are still not fully understood. Therefore we measured arterial blood gas tensions and acid-base-status in two elite apnea divers during simulated wet dives lasting 3 : 55 and 5 : 05 minutes, respectively. Arterial pO2 followed the compression-(from 13.8/16.9 kPa before the dive to 30 kPa at the start of the bottom time) and decompression-induced (from 13.7/21.0 kPa to 3.3/4.9 kPa immediately after surfacing) variations of ambient pressure, while the arterial pCO2 remained within the physiologic range (3.0/3.9 kPa before diving vs. 5.7/5.9 kPa at the end of the bottom time), probably due to the CO2 storage capacity of the blood. These findings may help to explain why humans can sustain deep and long apnea dives without major increases in respiratory drive.
Given the uninfluenced parameters of the ileal mucosal microcirculation in our model of long-term porcine endotoxemia, selective iNOS inhibition probably improved the PCO(2) gap due to a redistribution of the microvascular perfusion within the gut wall and/or an amelioration of the cellular respiration.
There are no data available on the kinetics of blood concentrations of xenon during the wash-in phase of an inhalation anaesthesia aiming at 1 MAC end-expiratory concentration. Therefore, we anaesthetized eight pigs with continuous propofol and fentanyl and measured arterial, mixed venous and end-expiratory xenon concentrations by gas chromatography-mass spectrometry 1, 2, 3, 4, 5, 7, 10, 15, 20, 30, 60 and 120 min after starting the anaesthetic gas mixture [67% xenon/33% oxygen; 3 litre x min(-1) during the first 10 min, thereafter minimal flow with 0.48 (SD 0.03) litre x min(-1)]. End-expiratory xenon concentrations plateaued (defined as <5% change from the preceding value) at 64 (6) vol% after 7 min, and arterial and mixed venous xenon concentrations after 5 and 15 min respectively. The highest arterio-venous concentration difference occurred after 3 min. Using the Fick principle, we calculated a mean xenon uptake of 3708 (829) and 9977 (3607) ml after 30 and 120 min respectively.
During long-term hyperdynamic porcine endotoxemia, ATP-MgCl2 normalized the otherwise progressive rise of the ileal mucosal-arterial Delta PCO2. Furthermore, it allowed blunting of the continuous decrease in hepatic lactate clearance, thus preserving the metabolic coupling between lactate release from the intestine and lactate utilization by the liver.
Activation of the poly(ADP-ribose)polymerase (PARP), a highly energy-consuming DNA-repairing enzyme, plays a crucial role in the pathogenesis of multiorgan failure. Most results, however, were derived from experiments with hypodynamic shock states characterized by a markedly decreased cardiac output (CO) and/or using a pretreatment approach. Therefore, we investigated the effects of the novel potent and selective PARP-1 inhibitor PJ34 in a posttreatment model of long-term, volume-resuscitated porcine endotoxemia. Anesthetized, mechanically ventilated and instrumented pigs received continuous intravenous (i.v.) lipopolysaccharide (LPS) over 24 h. Hydroxyethyl starch was administered to maintain a mean arterial pressure > 65 mmHg. After 12 h of LPS infusion, the animals were randomized to receive either vehicle (Control, n = 9) or i.v. PJ34 (n = 6; 10 mg/kg over 1 h followed by 2 mg/kg/h until the end of the experiment). Measurements were performed before as well as at 12, 18, and 24 h of LPS infusion. In all animals CO increased because of reduced systemic vascular resistance (SVR) and fluid resuscitation. PJ34 further raised CO (P < 0.05 vs. control group) as the result of a higher stroke volume indicating its positive inotropic effect. In addition, it diminished the rise in the ileal mucosal-arterial PCO2 gap, which returned to baseline levels at 24 h of LPS, and improved the gut lactate balance (P = 0.093 PJ34 vs. control) together with significantly lower portal venous lactate/pyruvate ratios. By contrast, it failed to influence the LPS-induced derangements of liver metabolism. Incomplete PARP inhibition because of dilutional effects and/or an only partial efficacy when used in post-treatment approaches may account for this finding.
Heme oxygenase (HO) has both deleterious and protective effects in various shock models. Most of these data have been derived from experiments with hypodynamic shock states associated with depressed cardiac output. Therefore we studied the role of HO during long-term porcine hyperdynamic endotoxemia characterized by a sustained increase in cardiac output resulting from colloid resuscitation to maintain mean arterial pressure > 60 mmHg. Systemic, pulmonary, and hepatosplanchnic hemodynamic and metabolic effects of the HO-inhibitor tin-mesoporphyrin (SnMP) were assessed in anesthetized and mechanically ventilated animals. After 12 h of continuous intravenous lipopolysaccharide (LPS), animals received either vehicle (n = 6) or SnMP (n = 8; 6 micromol kg(-1) i.v. over 30 min at 12 and 18 h of LPS). Measurements were performed before LPS, before SnMP infusion, and at 24 h of LPS. SnMP did not influence systemic hemodynamics but significantly increased mean pulmonary artery pressure. Although liver blood flow was not affected, SnMP markedly impaired liver lactate clearance. HO inhibition was associated with increased plasma nitrate levels likely the result of increased NO production. Our results suggest a protective role of HO activation during hyperdynamic porcine endotoxemia possibly as a result of an interaction with the LPS-induced increase in NO formation.
In anesthetized pigs, short-term inhalation of xenon or nitrous oxide over 4 h when compared with total IV anesthesia had no additional deleterious effects on the metabolic balance of the gut wall during intestinal obstruction, no matter whether the arterial blood flow was reduced or not.
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