Ileal VO(2)-O(2) alterations induced by endotoxin correlate with severity of mitochondrial injury

Sepsis is usually associated with altered O(2) metabolism in systemic organs. Until recently, inadequate O(2) delivery was thought to be the putative mechanism underlying these metabolic alterations. However, current investigations suggest that impaired O(2) consumption due to disrupted O(2) use by mitochondria may be the culprit. Therefore, we hypothesized that endotoxin (LPS)-induced V O(2)- O(2) alterations would correlate with the severity of mitochondrial injury in a systemic organ (i.e., the ileum). Using an in situ autoperfused feline ileum preparation, we assessed V O(2)- O(2) relationships and mitochondrial ultrastructure after 2 h in LPS-treated (3 mg/kg, intravenous; n = 11) and time-matched control (n = 5) animals. Mitochondrial injury was graded in a blinded fashion on the basis of characteristics associated with established stages of cell injury. LPS-treated animals developed severe mitochondrial injury in the ileal mucosa despite unchanged regional tissue perfusion and ileal oxyhemoglobin levels compared with controls. Worsening of mitochondrial injury correlated with increases in the critical O(2) delivery (r = 0.85; p < 0.002) and decreases in the maximum O(2) extraction (r = -0.61; p < 0.02) in the ileum. These results suggest that mitochondrial injury, leading to impaired O(2) utilization, may be primarily responsible for altered V O(2)- O(2) relationships in systemic organs during sepsis.

Endotoxin-induced ileal mucosal injury and nitric oxide dysregulation are temporally dissociated

Despite recent investigations, the mechanisms responsible for intestinal epithelial injury during endotoxemia remain unclear. The present study tests the hypothesis that epithelial necrosis and/or apoptosis correlate with nitric oxide (NO) dysregulation in a nonischemic model of sepsis-induced ileal injury. To test this hypothesis, a well-established in situ, autoperfused, feline ileal preparation was employed. After endotoxin (lipopolysaccharide [LPS], 3 mg/ kg, intravenously; n = 9) or vehicle (control; n = 5) treatment, ileal segments were obtained at baseline, 2 and 4 h for simultaneous evaluations of cellular and mitochondrial ultrastructure, immunoprevalence of inducible nitric oxide synthase (iNOS) and 3-nitrotyrosine (a stable biomarker of peroxynitrite), and histochemical evidence of apoptosis. Epithelial necrosis was prominent by 2 h post-LPS, despite unaltered global ileal tissue oxygen content, blood volume, and blood flow. Significant evidence of apoptosis and increases in the immunoprevalence of iNOS and 3-nitrotyrosine were not evident until 4 h post-LPS. These results suggest that the early ileal mucosal necrosis may be due to LPS-induced activation of inflammatory pathways and/or microcirculatory disturbances, whereas NO dysregulation may participate in later events, including protein nitration and epithelial apoptosis.

Metabolic consequences of sepsis. Correlation with altered intracellular calcium homeostasis

The availability of adequate substrate for energy homeostasis is a minimal requirement for vital organ function that normally is provided through dietary intake. When dietary sources of nutrients are inadequate, the body relies on alternate sources of energy provided by gluconeogenesis, lipolysis, and ketogenesis. Sepsis is associated with disruption of virtually all these provisional sources of energy substrate (see Fig. 4). In addition, sepsis impairs the function of the glycolytic pathway, the integrity of which is necessary for glucose to be used effectively for energy production. These abnormalities, coupled with disruption of the intracellular energy-producing machinery (e.g., glycolytic and gluconeogenic enzymes, mitochondria) eventually lead to a reduction in intracellular ATP. Furthermore, a reduction in intracellular ATP can undermine virtually all the energy-consuming functions of the cell, including energy substrate formation (e.g., failed gluconeogenesis), antioxidant production, and calcium homeostasis. High levels of intracellular calcium, in turn, are known to activate many potentially destructive enzymatic pathways (e.g., proteases, phospholipases, endonucleases) that further diminish cell function and may result in cell death. In this context, iCa2+ accumulation may play an important role in the progression from early sepsis to MODS, the most common cause of mortality in the ICU.

Endotoxin-induced ileal Vo2-Do2 alterations do not correlate with the severity of ileal injury

PURPOSE

Altered Vo2-Do2 relationships are most often noted to occur in the setting of sepsis or endotoxin (LPS)-induced systemic organ microvascular injury and are generally thought to be causally linked to that injury. However, we have recently shown that ileal microvascular injury is not associated with altered ileal Vo2-Do2, relationships. Thus, we hypothesized that the severity of LPS-induced systemic organ microvascular injury would not correlate with the development of systemic organ Vo2-Do2 alterations.

MATERIALS AND METHODS

To test this hypothesis, we used the in situ autoperfused feline ileal preparation to simultaneously examine microvascular permeability, reflected as the ileal lymph to plasma protein concentration ratio (CL/CP), and ileal Vo2-Do2 relationships 2 hours after intravenous LPS (0.75-2.0 mg/kg; n = 9) and in matching controls (n = 5).

RESULTS

As expected, all LPS-treated animals were found to have extensive ileal histological damage and marked increases in the CL/CP compared with controls (0.308 +/- 0.019 v 0.097 +/- 0.009; P < .001). In addition, although the critical Do2 (Do2c) was elevated in the LPS-treated animals relative to controls (34.2 +/- 5.0 v 16.7 +/- 1.4 mL/min/kg; P < .03), there was no correlation between the Do2c and the CL/CP in the LPS-treated animals. Finally, ileal wet to dry weight ratios after LPS did not differ from controls.

CONCLUSION

Taken together, these data suggest that factors other than organ injury, as assessed by morphological and permeability alterations, are important in the pathogenesis of altered systemic organ Vo2-Do2 relationships after LPS.

Acid aspiration results in ileal injury without altering ileal V(O2)-D(O2) relationships

Systemic organ endothelial injury and V(O2)-D(O2) relationship alterations occur frequently in the setting of acute lung injury, and they are believed to play an important role in the pathogenesis of the multiple organ dysfunction syndrome (MODS). However, the relationship, if any, between systemic organ endothelial injury and V(O2)-D(O2) relationship alterations remains unknown. We hypothesized that microvascular endothelial injury and attendant interstitial edema would result in increased diffusion distances for oxygen and altered systemic organ V(O2)-D(O2) relationships. To test this hypothesis, we utilized the in situ autoperfused feline ileal preparation to evaluate ileal V(O2)-D(O2) relationships in control animals (n = 5) and in animals with HCl-induced acute lung and systemic organ injury (n = 5). As expected, ileal endothelial protein permeability (CL/CP) was increased in HCl-injured animals compared to control animals (0.187 +/- 0.024 versus 0.097 +/- 0.009; p < 0.01). However, contrary to our original hypothesis and despite marked morphologic and endothelial protein permeability alterations, ileal V(O2)-D(O2) relationships were not altered in the HCl-injured animals. Moreover, V(O2)-D(O2) relationships in the ileum remained unchanged even when ileal venous pressures were increased to 15 mm Hg. Taken together, these findings do not support an important role for oxygen diffusion limitation in the pathogenesis of altered systemic organ V(O2)-D(O2) relationships.

Ischemia/reperfusion injury to the ileum does not account for the ileal VO2-DO2 alterations induced by endotoxin

PURPOSE

Endotoxin (lipopolysaccharide [LPS])-induced systemic organ injury leads to disruption of normal systemic organ metabolic processes, which are manifest clinically by signs of accelerated anaerobic metabolism (e.g., tissue acidosis and hyperlactatemia) and altered VO2-DO2 relationships. The association of increased anaerobic metabolism with VO2-DO2 alterations has led to the notion that ischemia/ reperfusion (I/R) injury may be a prerequisite for the development of VO2-DO2 alterations during endotoxemia. However, in contrast to sepsis, in which oxygen consumption is often increased, oxygen consumption is severely decreased after I/R injury. Based on these observations, we hypothesized that I/R injury would result in systemic organ VO2-DO2 alterations, which are distinct from those that occur in sepsis.

MATERIALS AND METHODS

We used the in situ autoperfused feline ileal preparation to simultaneously examine microvascular permeability, reflected as the ileal lymph to plasma protein concentration ratio (CL/CP), and ileal VO2-DO2 relationships after either intravenous LPS (2.0 mg/kg; n = 5) or I/R injury (n = 5), and in matching controls (n = 5).

RESULTS

As expected, all LPS-treated and I/R-injured animals were found to have extensive ileal histological damage and marked increases in the CL/CP compared with controls (0.315 +/- 0.009 and 0.329 +/- 0.034, respectively, v 0.097 +/- 0.009; P < .001, both comparisons). In addition, the critical DO2 (DO2c) was elevated, and the critical oxygen extraction was decreased in both the I/R and LPS groups relative to controls. However, as initially hypothesized, the VO2 at the critical DO2 was markedly decreased in the I/R group compared with that of the LPS group.

CONCLUSIONS

These data indicate that I/R injury is insufficient to account for the systemic organ VO2-DO2 alterations that occur with LPS injury.

Relationship of substrate level to turnover rate in fasted adult and newborn dogs

Glucose turnover, clearance and response to insulin were determined in fasted newborn and adult dogs. Fasting levels of glucose and insulin and rates of glucose turnover and clearance were not different between the two groups. Blood glucose correlated with basal glucose turnover in newborn pups but not in adult dogs. Glucose turnover was not related to fasting plasma insulin levels. Glucose clearance was an inverse function of blood glucose levels among newborn but not adult dogs. Glucose clearance and blood glucose levels were not related to insulin concentrations. In response to euglycemic hyperinsulinemia, glucose metabolism increased 4-fold among adults but only 1.7-fold in pups. Hyperglycemic hyperinsulinemia increased glucose metabolism in both groups but to a much greater extent in the pups. Euglycemic hyperinsulinemia increased the metabolic clearance rate of glucose 4.2-fold among adults but only 1.8-fold in newborn dogs. In response to hyperglycemic hyperinsulinemia glucose clearance rates were now similar. Despite euglycemic hyperinsulinemia, the newborn dog had an attenuated response to insulin, demonstrating lower rates of glucose metabolism and glucose clearance. The response to the hyperglycemic stimuli suggests that maximal glucose uptake was not achieved during hyperinsulinemia alone. This response supports the concept of glucose-mediated regulation of glucose disposal in newborn animals.

Herpes simplex type 2 causing fulminant hepatic failure

Although exceedingly rare, fulminant hepatic failure (FHF) in immunocompetent patients can develop with primary or recurrent infection due to herpes simplex virus (HSV). The diagnosis is frequently obscured by the absence of mucocutaneous involvement. Elevated transaminase values with leukopenia and a relatively low bilirubin level may provide clues to the diagnosis. We describe an immunocompetent woman who died of FHF before a definitive diagnosis of HSV type 2 hepatitis was established. Herpes simplex virus hepatitis is one of the few causes of FHF for which potentially effective therapy is available. Thus, early diagnosis is paramount and usually requires liver biopsy. Recent studies suggest that transjugular liver biopsy is safe and effective in establishing the cause of FHF. Since the diagnosis and management of FHF are frequently influenced by the results of transjugular liver biopsy, it may become a standard diagnostic tool for managing FHF in centers where such expertise exists.

Gastrointestinal tract dysfunction in critical illness: pathophysiology and interaction with acute lung injury in adult respiratory distress syndrome/multiple organ dysfunction syndrome

The adult respiratory distress syndrome (ARDS), a common complication of critical illness, is associated with a > 50% mortality rate. Refractory respiratory failure is, however, an uncommon cause of mortality in these patients. Most deaths are due to a syndrome of relentless organ dysfunction accompanied by abnormal organ system interactions, collectively referred to as the multiple organ dysfunction syndrome (MODS). MODS is associated with two chief pathophysiologic derangements: a) the unregulated activation of systemic inflammatory cascades; and b) alterations of oxygen uptake (VO2)-oxygen delivery (DO2) relationships. Current concepts regarding the pathophysiology of MODS, specifically its relationship to unregulated systemic inflammation and alterations in VO2-DO2 alterations, are discussed. Within this framework, current and future areas for investigation that may result in mechanism-specific innovations with the potential to interrupt events mediated by gastrointestinal dysfunction that lead to MODS are presented.