Linopirdine-supplemented resuscitation fluids reduce mortality in a model of ischemia-reperfusion injury induced acute respiratory distress syndrome.

Previously, we demonstrated that supplementation of resuscitation fluids with the Kv7 voltage-activated potassium channel inhibitor linopirdine reduces fluid resuscitation requirements and stabilizes hemodynamics in various rat models of hemorrhagic shock. To further evaluate the therapeutic potential of linopirdine, we tested the effects of linopirdine-supplemented resuscitation fluids in a rat model of ischemia-reperfusion injury-induced acute respiratory distress syndrome (ARDS). Ventilated rats underwent unilateral lung ischemia from t=0-75 min, followed by lung reperfusion and fluid resuscitation to a mean arterial blood pressure of 60 mmHg with normal saline (NS, n=9) or NS supplemented with 50 µg/ml linopridine (NS-L), n=7) until t=360 min. As compared with NS, fluid resuscitation with NS-L stabilized blood pressure and reduced fluid requirements by 40% (p<0.05 vs. NS at t=240-360 min). While NS-L did not affect ARDS development, it reduced mortality from 66% with NS to 14% with NS-L (p=0.03, hazard ratio 0.14; 95% confidence interval of the hazard ratio: 0.03-0.65). Median survival time was 240 min with NS and >360 min with NS-L. As compared with NS treated animals that survived the observation period (n=3), however, plasma lactate and creatinine concentrations at t=360 min were higher with NS-L (n=6; p<0.05). Our findings extend therapeutic potential of NS-L from hypovolemic/hemorrhagic shock to hemodynamic instability under normovolemic conditions during organ ischemia-reperfusion injury. Possible adverse effects of NS-L, such as impairment of renal function and/or organ hypoperfusion, require further evaluation in long-term pre-clinical models.

Effects of a caspase and a calpain inhibitor on resting energy expenditures in normal and hypermetabolic rats: a pilot study.

Several diseases induce hypermetabolism, which is characterized by increases in resting energy expenditures (REE) and whole body protein loss. Exaggerated protein degradation is thought to be the driving force underlying this response. The effects of caspase and calpain inhibitors on REE in physiological and hypermetabolic conditions, however, are unknown. Thus, we studied whether MDL28170 (calpain inhibitor) or z-VAD-fmk (caspase inhibitor) affect REE under physiological conditions and during hypermetabolism post-burn. Rats were treated five times weekly and observed for 6 weeks. Treatment was started 2 h (early) or 48 h (late) after burn. In normal rats, MDL28170 transiently increased REE to 130 % of normal during week 2-4. z-VAD-fmk reduced REE by 20-25 % throughout the observation period. Within 14 days after burns, REE increased to 130+/-5 %. Whereas MDL28170/early treatment did not affect REE, MDL28170/late transiently increased REE to 180+/-10 % of normal by week 4 post-burn. In contrast, with z-VAD-fmk/early REE remained between 90-110 % of normal post-burn. z-VAD-fmk/late did not affect burn-induced increases in REE. These data suggest that caspase cascades contribute to the development of hypermetabolism and that burn-induced hypermetabolism can be pharmacologically modulated. Our data point towards caspase cascades as possible therapeutic targets to attenuate hypermetabolism after burns, and possibly in other catabolic disease processes.