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Inhaled carbon monoxide protects against the development of shock and mitochondrial injury following hemorrhage and resuscitation

PLoS ONE (2015) 10(9)
DOI: 10.1371/journal.pone.0135032
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Abstract

Aims: Currently, there is no effective resuscitative adjunct to fluid and blood products to limit tissue injury for traumatic hemorrhagic shock. The objective of this study was to investigate the role of inhaled carbon monoxide (CO) to limit inflammation and tissue injury, and specifically mitochondrial damage, in experimental models of hemorrhage and resuscitation. Results: Inhaled CO (250 ppm for 30 minutes) protected against mortality in severe murine hemorrhagic shock and resuscitation (HS/R) (20% vs. 80%; P<0.01). Additionally, CO limited the development of shock as determined by arterial blood pH (7.25±0.06 vs. 7.05±0.05; P<0.05), lactate levels (7.2±5.1 vs 13.3±6.0; P<0.05), and base deficit (13±3.0 vs 24±3.1; P<0.05). A dose response of CO (25-500 ppm) demonstrated protection against HS/R lung and liver injury as determined by MPO activity and serum ALT, respectively. CO limited HS/R-induced increases in serum tumor necrosis factor-α and interleukin-6 levels as determined by ELISA (P<0.05 for doses of 100-500ppm). Furthermore, inhaled CO limited HS/R induced oxidative stress as determined by hepatic oxidized glutathione:reduced glutathione levels and lipid peroxidation. In porcine HS/R, CO did not influence hemodynamics. However, CO limited HS/R-induced skeletal muscle and platelet mitochondrial injury as determined by respiratory control ratio (muscle) and ATP-linked respiration and mitochondrial reserve capacity (platelets). Conclusion: These preclinical studies suggest that inhaled CO can be a protective therapy in HS/R; however, further clinical studies are warranted.

Figures

  • Fig 1. CO therapy protects against mortality in a model of murine hemorrhagic shock and resuscitation. A severe hemorrhagic shock and resuscitation model resulted in 80%mortality by 36 hours. CO therapy (250 ppm) limited mortality to 20% (P<0.05). Kaplan-Meier method was used to compare survival.
  • Table 1. Arterial blood gasmeasurements in mice bled to andmaintained at a MAP of 20 mmHg for 30 minutes with and without inhaled CO (250 ppm). Shammice underwent anesthesia and surgical manipulation without hemorrhage. Mice were bled to a pressure of 20 mm Hg over 15 minutes. CO therapy was started once a pressure of 20 mm Hg was reached.
  • Fig 2. CO protects against organ injury and inflammation in a dose dependent fashion in murine model of hemorrhagic shock and resuscitation. Lung myeloperoxidase activity (MPO; A.) and serum ALT (B.) at 4 hours after resuscitation in mice demonstrates lung and liver injury, respectively. CO limits this injury in a dose-dependent fashion when treated for 30 minutes (25–500 ppm) starting 90 minutes into hypotension. C. Serum TNF-alpha and IL-6 levels were also increased by hemorrhagic shock and resuscitation at a 4 hour time point, and CO therapy limited these markers of inflammation in a dose dependent fashion. Results are mean±SEM for 8 mice per group. *P<0.05 compared to sham and #P<0.05 compared to shock. ANOVA was utilized for above comparisons.
  • Fig 3. Hemorrhagic shock and resuscitation-induced oxidant stress is limited by CO. A. The ratio of oxidized glutathione (GSSG) to reduced glutathione (GSH) is increased in the liver of mice following HS/R (0.43±0.08 vs. 1.9±0.42; *P<0.05 compared to shammice). CO treatment limited this increase in GSSG:GSH (1.1±0.27; #P<0.05 compared to shock mice). Results are mean±SEM for 8 mice per group.B, C. Representative immunohistochemistry and quantification of mean fluorescence of lipid peroxidation in liver tissue staining using 4-HNE at 4 hours after resuscitation in sham and shock mice with or without CO. ANOVA was utilized for above comparisons.
  • Fig 4. CO decreases oxygen consumption and limits the development of cellular hypoxia in hepatocytes in vitro. A. Oxygen consumption rates of primary murine hepatocytes were demonstrated in vitro in normoxic cells or in hepatocytes immediately following 30 minutes of hypoxia. CO treatment (250ppm) occurred during this normoxic or hypoxic periods. Hypoxia decreased oxygen consumption rates (*P<0.01 compared to normoxic cells) and this was further decreased by CO therapy (#P<0.05 compared to hypoxia alone). Results of four independent experiments, with each condition performed in triplicate. B, C. Representative immunocytochemistry and quantitative mean fluorescence of hypoxyprobe staining in hepatocytes under normoxic, normoxic+CO, hypoxic, or hypoxic +CO conditions for 30 minutes. Increased green staining represents increased cellular hypoxia. ANOVA was utilized for above comparisons.
  • Fig 5. CO hasminimal influence on gross cardiovascular parameters in porcine hemorrhagic shock and resuscitation. Hemodynamic data are shown at time points throughout the experiments [baseline, end of hemorrhage (H1), 30 minutes into hypotension (H30), 60 minutes into hypotension (H60), immediately prior to resuscitation (resusc), at the end of the initial hextend bolus (hextend), 2 hours into the resuscitation (Obs2h), and 4 hours into the resuscitation (Obs4h)]. Data is shown for mean arterial pressure (MAP, A.), heart rate (B.), central venous pressure (CVP,C.), mixed venous saturation (SVO2%,D.), and mean pulmonary arterial pressure (E.). Expected changes in hemodynamics are seen in shock and resuscitation, with no significant influences demonstrated in the CO treated pigs. ANOVA was utilized for above comparisons.
  • Fig 6. Hemorrhagic shock and resuscitation-induced skeletal muscle mitochondrial injury was limited by CO therapy. A. The change in respiratory control ratio (RCR; state 3:state4) from baseline to 2 hours after resuscitation in the porcine model demonstrated that HS/R led to mitochondrial injury. CO treatment resulted in an overall increase in the mean RCR, representing decreased mitochondrial injury (*P<0.05 compared to HS/R). B. Changes in RCR in murine thigh skeletal muscle from baseline to 2 hours after resuscitation demonstrated mitochondrial injury following HS/R, and inhaled CO protected against this injury (N = 8 mice per group; *P<0.05 compared to baseline; #P<0.05 compared to control treated-HS/R mice). ANOVA was utilized for above comparisons.
  • Fig 7. CO protects against hemorrhagic shock and resuscitation-induced platelet activation and mitochondrial injury. A. HS/R results in decreased ATP linked respiration (*P<0.05 compared to sham), while CO treatment prevented these changes (#P<0.05 compared to HS/R).B. HS/R had a minimal effect on mitochondrial reserve capacity, while CO treated HS/R pigs demonstrated an increase in this parameter (*P<0.05 compared to sham and HS/R)C. HS/R increased platelet activation by 2.33±0.1 fold over sham pigs at a 2 hour time point as determined by staining for CD62p by FACS (*P<0.05 compared to sham). CO treatment limited this activation to only a 1.64±0.08 increase over sham (#P<0.05 compared to HS/R). n = 7–11 pigs per group in each experiment. ANOVA was utilized for above comparisons.

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Gomez, H., Kautza, B., Escobar, D., Nassour, I., Luciano, J., Botero, A. M., … Zuckerbraun, B. S. (2015). Inhaled carbon monoxide protects against the development of shock and mitochondrial injury following hemorrhage and resuscitation. PLoS ONE, 10(9). https://doi.org/10.1371/journal.pone.0135032

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