The Journal of surgical research
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Prolonged sedation with propofol at high doses may lead to fatal multi-organ dysfunction, know as propofol infusion syndrome. We tested the hypothesis that propofol plus remifentanil co-administration attenuates propofol tolerance to its sedative effect and assessed if such an effect has an impact on propofol toxicity in rabbits under prolonged mechanical ventilation. ⋯ Although propofol tolerance is attenuated in propofol plus remifentanil receiving rabbits under prolonged mechanical ventilation, fatal multi-organ injury occurs resembling human propofol infusion syndrome.
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Obstetric hemorrhage remains a leading cause of maternal death internationally. Polydatin is an effective drug in ameliorating microcirculatory insufficiency and increasing survival rate in non-pregnant animal model of controlled hemorrhagic shock. In the present study, we investigated the effects of hypotensive resuscitation combined with Polydatin administration on microcirculation and survival rate in a clinically relevant model of uncontrolled hemorrhagic shock in pregnancy. ⋯ On the basis of hypotensive resuscitation, Polydatin administration improved microcirculation and prolonged survival time in pregnant rabbit model of uncontrolled hemorrhagic shock.
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Activated protein C (aPC) confers survival benefit in patients with sepsis, yet its protective mechanism(s) remain unclear. Herein, we determined time-dependent severity of renal dysfunction during polymicrobial sepsis. We hypothesized aPC restores renal function by preserving organ architecture and reducing inflammation. ⋯ Our data demonstrate that renal dysfunction occurs as early as 6 h following sepsis and continues thereafter. Treatment with aPC attenuated INFγ and IL-1β changes, and preserved renal function in sepsis. These data suggest aPC may confer a survival advantage by reducing systemic inflammation and, in doing so, preserving organ function.
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The breakdown of skin microcirculation and the leukocyte-endothelium interaction are assumed to play a key role in the pathophysiology of frostbite injuries. However, little is known as yet. The aim was to develop an in vivo frostbite model to monitor microcirculatory changes and angiogenesis after frostbite injury. ⋯ This novel frostbite model provides a simple and nonetheless highly effective technique of creating locally limited reproducible frostbite injuries using a no touch technique. Tissue damage can be fully attributed to the thermal trauma, and the model allows repetitive intravital fluorescent microscopy of the microcirculation, leukocyte-endothelium interaction, and angiogenesis.