Impact of Acute Intestinal Ischemia and Reperfusion Injury on Hemodynamics and Remote Organs in a Rat Model.

BACKGROUND: Acute mesenteric ischemia following cardiovascular surgery is a rare but fatal complication. We established a new rat model for hemodynamic monitoring during mesenteric ischemia/reperfusion (I/R) and evaluated the impact of mesenteric I/R on hemodynamics and remote organ injury. METHODS: Mesenteric I/R was induced in male Wistar rats by superior mesenteric artery occlusion for 90 minutes, followed by 120 minutes of reperfusion. Before I/R, ventilation and hemodynamic monitoring including mean arterial blood pressure (MAP) and cardiac output (CO) were established. During reperfusion Geloplasma (I/R + Geloplasma, N = 6) and Ringer's solution (I/R + Ringer, N = 6) were titrated according to CO and compared with I/R without volume resuscitation (I/R only, N = 6) and a sham group (sham, N = 6). Blood samples were regularly taken for serum marker measurements. After reperfusion organs were harvested for histology studies. RESULTS: After acute mesenteric I/R, MAP and CO decreased (p < 0.01) while systemic and pulmonary vascular resistance increased (p < 0.01) continuously in the I/R group. Volume substitution according to CO initially stabilized hemodynamic parameters, but CO declined independently in the late stage. Compared with the I/R + Ringer group, the I/R + Geloplasma group required less volume for resuscitation (p < 0.01), experienced less metabolic acidosis. I/R groups had more organ injuries, more neutrophils sequestration, and higher creatine phosphokinase-MB levels than sham group. CONCLUSION: A new model for CO monitoring after mesenteric I/R injury demonstrated severe hypovolemic shock during reperfusion followed by remote myocardial and lung injury. Far less colloid volume is needed for hemodynamic stabilization after I/R compared with crystalloid volume.

Safety of poly (ethylene glycol)-coated perfluorodecalin-filled poly (lactide-co-glycolide) microcapsules following intravenous administration of high amounts in rats.

The host response against foreign materials designates the biocompatibility of intravenously administered microcapsules and thus, widely affects their potential for subsequent clinical use as artificial oxygen/drug carriers. Therefore, body distribution and systemic parameters, as well as markers of inflammation and indicators of organ damage were carefully evaluated after administration of short-chained poly (vinyl alcohol, (PVA)) solution or poly (ethylene glycol (PEG))-shielded perfluorodecalin-filled poly (d,l-lactide-co-glycolide, PFD-filled PLGA) microcapsules into Wistar rats. Whereas PVA infusion was well tolerated, all animals survived the selected dose of 1247 mg microcapsules/kg body weight but showed marked toxicity (increased enzyme activities, rising pro-inflammatory cytokines and complement factors) and developed a mild metabolic acidosis. The observed hypotension emerging immediately after start of capsule infusion was transient and mean arterial blood pressure restored to baseline within 70 min. Microcapsules accumulated in spleen and liver (but not in other organs) and partly occluded hepatic microcirculation reducing sinusoidal perfusion rate by about 20%. Intravenous infusion of high amounts of PFD-filled PLGA microcapsules was tolerated temporarily but associated with severe side effects such as hypotension and organ damage. Short-chained PVA displays excellent biocompatibility and thus, can be utilized as emulsifier for the preparation of drug carriers designed for intravenous use.

Hypothermia causes a marked injury to rat proximal tubular cells that is aggravated by all currently used preservation solutions.

Cold preservation results in cell death via iron-dependent formation of reactive oxygen species, leading to apoptosis during rewarming. We aimed to study cold-induced damage (i.e., injury as a consequence of hypothermia itself and not cold ischemia) in proximal tubular cells (PTC) in various preservation solutions presently applied and to clarify the role of mitochondria in this injury. Primary cultures of rat PTC were incubated at 4 degrees C for 24 h in culture medium, UW, Euro-Collins or HTK solution with and without the iron chelator desferal and rewarmed at 37 degrees C in culture medium. Cell damage, morphology, and apoptosis were studied and mitochondrial membrane potential was assessed by fluorescence microscopy. Cold incubation of PTC in culture medium followed by rewarming caused marked cell damage compared to warm incubation alone (LDH release 39+/-10% vs. 1.6+/-0.3%). Cold-induced damage was aggravated in all preservation solutions (LDH release 85+/-2% for UW; similar in Euro-Collins and HTK). After rewarming, cells showed features suggestive for apoptosis. Desferal prevented cell injury in all solutions (e.g., 8+/-2% for UW). Mitochondrial membrane potential was lost during rewarming and this loss could also be inhibited by desferal. Trifluoperazine, which is known to inhibit mitochondrial permeability transition (MPT), was able to prevent cold-induced injury (LDH 85+/-5% vs. 12+/-2%). We conclude that cold-induced injury occurs in PTC and is aggravated by UW, Euro-Collins, and HTK solution. Iron-dependent MPT is suggested to play a role in this damage. Strategies to prevent cold-induced injury should aim at reducing the availability of "free" iron.

Enhancement of iron toxicity in L929 cells by D-glucose: accelerated(re-)reduction.

It has recently been shown that an increase in the cellular chelatable iron pool is sufficient to cause cell damage. To further characterize this kind of injury, we artificially enhanced the chelatable iron pool in L929 mouse fibroblasts using the highly membrane-permeable complex Fe(III)/8-hydroxyquinoline. This iron complex induced a significant oxygen-dependent loss of viability during an incubation period of 5 h. Surprisingly, the addition of L-glucose strongly enhanced this toxicity whereas no such effect was exerted by L-glucose and 2-deoxyglucose. The assumption that this increase in toxicity might be due to an enhanced availability of reducing equivalents formed during the metabolism of L-glucose was supported by NAD(P)H measurements which showed a 1.5-2-fold increase in the cellular NAD(P)H content upon addition of L-glucose. To assess the influence of this enhanced cellular reducing capacity on iron valence we established a new method to measure the reduction rate of iron based on the fluorescent iron(II) indicator PhenGreen SK. We could show that the rate of intracellular iron reduction was more than doubled in the presence of L-glucose. A similar acceleration was achieved by adding the reducing agents ascorbate and glutathione (the latter as membrane-permeable ethyl ester). Glutathione ethyl ester, as well as the thiol reagent N -acetylcysteine, also caused a toxicity increase comparable with L-glucose. These results suggest an enhancement of iron toxicity by L-glucose via an accelerated (re-)reduction of iron with NAD(P)H serving as central electron provider and ascorbate, glutathione or possibly NAD(P)H itself as final reducing agent.