Evaluation of hemodynamic effects of xenon in dogs undergoing hemorrhagic shock

Franceschi, Ruben C.; Malbouisson, Luíz Marcelo Sá; Yoshinaga, Eduardo Muracca; Auler, José Otávio Costa; Figueiredo, Luiz Francisco Poli de; Carmona, Maria José Carvalho

doi:10.6061/clinics/2013(02)oa18

Cited by 3 publications

(3 citation statements)

References 26 publications

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“…This is a much lower driving pressure for the blood flow than the systemic circulation, where the arterial-venous pressure gradient is approximately 90 mmHg in humans. Table 1 summarizes the pulmonary hemodynamic parameters for other species from different studies (Barer and Nusser, 1957a;Drougas et al, 1996;Holm et al, 1998;Morris et al, 2000;Grant and Canty, 1989;Baxter et al, 1952;Duke and Stedeford, 1960;Chen et al, 2005;Yuan et al, 2011;Liu et al, 2005;Emery et al, 2001;Fesler et al, 2006;Chick et al, 1988;Franceschi et al, 2013;Chaliki et al, 2002;Romand et al, 1994;Takeda et al, 1987;Johnson et al, 1992;Ravikumar et al, 2011;Reddy et al, 1995;Polglase et al, 2006;Newman et al, 1993;Nachar et al, 2001;Krebs et al, 2007;Hinder et al, 1998;Pennington et al, 1992;Patschova et al, 2010;Stickland et al, 2007;Li et al, 2013;Goetz et al, 1999;Tournoux et al, 2011;Ortiz et al, 2002;Ullrich et al, 1999). Although the blood flow through the pulmonary circulation is essentially the same as the blood flow through the systemic circulation, the pulmonary vascular resistance is 10-to 15-fold lower than the systemic vascular resistance.…”

Section: Pulmonary Hemodynamicsmentioning

confidence: 97%

“…These vessels compress and distort during lung inflation, and the degree to which these forces and blood pressures interact determines blood flow through that region of the lung (Franceschi et al, 2013;Keilholz et al, 2001;Milic-Emili et al, 1966). However, as the lung inflates, the inflation or pleural pressures have additional effects on other segments of the pulmonary vasculature.…”

Section: Ventilatory Effects On Pulmonary Hemodynamicsmentioning

confidence: 98%

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Pulmonary Hemodynamics

Aggarwal¹,

Groß²,

Porcelli³

et al. 2015

Comparative Biology of the Normal Lung

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Section: Pulmonary Hemodynamicsmentioning

confidence: 97%

Section: Ventilatory Effects On Pulmonary Hemodynamicsmentioning

confidence: 98%

Pulmonary Hemodynamics

Aggarwal¹,

Groß²,

Porcelli³

et al. 2015

Comparative Biology of the Normal Lung

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“…The heart rate (HR) was measured using a surface electrocardiogram (Philips, Eindhoven, Netherlands). Cardiac shock was defined as a mean arterial pressure (MAP) b 40 mmHg [16].…”

Section: Animal Model and Hemodynamic Measurementmentioning

confidence: 99%

Establishment of a canine model of acute pulmonary embolism with definite right ventricular dysfunction through introduced autologous blood clots

Zhao

Jia

et al. 2015

Thrombosis Research

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A Prospective, Randomized Trial of Intravenous Hydroxocobalamin Versus Whole Blood Transfusion Compared to No Treatment for Class III Hemorrhagic Shock Resuscitation in a Prehospital Swine Model

Bebarta

Garrett

Boudreau

et al. 2015

Academic Emergency Medicine

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Objectives: The objective was to compare systolic blood pressure (sBP) over time in swine that have had 30% of their blood volume removed (Class III shock) and treated with intravenous (IV) whole blood or IV hydroxocobalamin, compared to nontreated control animals.Methods: Thirty swine (45 to 55 kg) were anesthetized, intubated, and instrumented with continuous femoral and pulmonary artery pressure monitoring. Animals were hemorrhaged a total of 20 mL/kg over a 20-minute period. Five minutes after hemorrhage, animals were randomly assigned to receive 150 mg/ kg IV hydroxocobalamin solubilized in 180 mL of saline, 500 mL of whole blood, or no treatment. Animals were monitored for 60 minutes thereafter. A sample size of 10 animals per group was determined based on a power of 80% and an alpha of 0.05 to detect an effect size of at least a 0.25 difference (>1 standard deviation) in mean sBP between groups. sBP values were analyzed using repeated-measures analysis of variance (RANOVA). Secondary outcome data were analyzed using repeated-measures multivariate analysis of variance (RMANOVA).Results: There were no significant differences between hemodynamic parameters of IV hydroxocobalamin versus whole blood versus control group at baseline (MANOVA; Wilks' lambda; p = 0.868) or immediately posthemorrhage (mean sBP = 47 mm Hg vs. 41 mm Hg vs. 37 mm Hg; mean arterial pressure = 39 mm Hg vs. 28 mm Hg vs. 34 mm Hg; mean serum lactate = 1.2 mmol/L vs. 1.4 mmol/L vs. 1.4 mmol/L; MANOVA; Wilks' lambda; p = 0.348). The outcome RANOVA model detected a significant difference by time between groups (p < 0.001). Specifically, 10 minutes after treatment, treated animals showed a significant increase in mean sBP compared to nontreated animals (mean sBP = 76.3 mm Hg vs. 85.7 mm Hg vs. 51.1 mm Hg; p < 0.001). RMANOVA modeling of the secondary data detected a significant difference in mean arterial pressure, heart rate, and serum lactate (p < 0.001). Similar to sBP, 10 minutes after treatment, treated animals showed a significant increase in mean arterial pressure compared to nontreated animals (mean arterial pressure = 67.7 mm Hg vs. 61.4 mm Hg vs. 40.5 mm Hg). By 10 minutes, mean heart rate was significantly slower in treated animals compared to nontreated animals (mean heart rate = 97.3 beats/min vs. 95.2 beats/min vs. 129.5 beats/min; p < 0.05). Serum lactate, an early predictor of shock, continued to rise in the control group, whereas it did not in treated animals. Thirty minutes after treatment, serum lactate values of treated animals were significantly lower compared to nontreated animals (p < 0.05). This trend continued throughout the 60-minute observation period such that 60-minute values for lactate were 1.4 mmol/L versus 1.1 mmol/L versus 3.8 mmol/L. IV hydroxocobalamin produced a statistically significant increase in systemic vascular resistance compared to control, but not whole blood, with a concomitant decrease in cardiac output.

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Evaluation of hemodynamic effects of xenon in dogs undergoing hemorrhagic shock

Cited by 3 publications

References 26 publications

Pulmonary Hemodynamics

Pulmonary Hemodynamics

Establishment of a canine model of acute pulmonary embolism with definite right ventricular dysfunction through introduced autologous blood clots

A Prospective, Randomized Trial of Intravenous Hydroxocobalamin Versus Whole Blood Transfusion Compared to No Treatment for Class III Hemorrhagic Shock Resuscitation in a Prehospital Swine Model

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