Pyruvate alleviates lipid peroxidation and multiple-organ dysfunction in rats with hemorrhagic shock.

OBJECTIVE: Pyruvate can reduce lipid peroxidation, which plays a critical role in organ injury, in various models. However, it is not fully understood if this inhibition occurs in resuscitation of hemorrhagic shock (HS). This study examines effects of pyruvate Ringer solution (PR) in this respect in rats. METHODS: Rats, subjected to 45% blood loss, were randomly allocated to the 3 groups (n = 18): HS with no fluid resuscitation (group NR), HS resuscitated with lactated Ringer solution (LR) (group LR), and HS resuscitated with PR (group PR). Mean arterial pressure, plasma levels of thiobarbituric acid reactive substances (TBARS), and superoxide dismutase were measured at various time points until 360 minutes after hemorrhage. Visceral organs were harvested at the end for evaluations of the TBARS, antioxidant enzyme, and tissue water content. Other 54 rats with identical procedures without sampling were documented for 24-hour survival rates (n = 18) after fluid resuscitation. RESULTS: Pyruvate Ringer solution significantly increased mean arterial pressure and decreased blood TBARS levels after lethal HS. It also reduced TBARS concentrations and glutathione peroxidase activities but significantly enhanced glutathione reductase activities in most organs and greatly improved the ratios of reduced glutathione over oxidized glutathione in various organs in group PR, compared to group LR. Furthermore, PR significantly improved various organ function and water contents relative to LR. Group PR showed a more than 2-fold higher 24-hour survival rate of group LR. CONCLUSIONS: Pyruvate Ringer solution alleviated organ edema and injury and prompted survival partially through inhibition of lipid peroxidation in various organs in severe HS rats.

Pyruvate Ringer's solution corrects lactic acidosis and prolongs survival during hemorrhagic shock in rats.

BACKGROUND: Lactic acidosis is a life-threatening complication of hemorrhagic shock. There is no ideal therapy for it in the clinical setting. OBJECTIVE: This study was designed to investigate whether pyruvate Ringer's solution could treat hypoxic lactic acidosis associated with lethal hemorrhagic shock in rats. METHODS: A total of 54 rats were subjected to hemorrhagic shock with mean arterial pressure (MAP) of 40 mm Hg for 1 h. They were then randomly divided into three groups (n = 18 each): Group N had no fluid resuscitation; Group L received lactated Ringer's solution infusion; and Group P received pyruvate Ringer's solution infusion. The survival rate was investigated after 24 h. In addition, a second set of 54 rats was selected for blood sampling, with identical methods for shock and resuscitation being followed, to determine arterial pH, blood gas analysis, lactate, pyruvate, and organs' enzyme activities at various time points. The MAP was monitored for 6 h in both populations. RESULTS: Pyruvate Ringer's solution significantly increased the survival rate of rats subjected to fatal shock and receiving pyruvate Ringer's solution (Group P) by 1.5 times the survival rate in Group L at 24 h after fluid resuscitation (55.6% vs. 22.2%, respectively; p < 0.05). Pyruvate infusion maintained a higher MAP and fully corrected severe acidosis 1 h after resuscitation in comparison to the lactated infusion, and markedly decreased blood lactate levels and the lactate-to-pyruvate ratio 4 h after resuscitation. It also significantly improved serum markers of organ dysfunction. CONCLUSION: Pyruvate Ringer's solution efficiently treated hypoxic lactic acidosis and significantly increased the survival rate in rats with lethal hemorrhagic shock. Pyruvate Ringer's solution is potentially applicable to clinical resuscitation in humans.