Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0243026 (sepsis)
52,417 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Cytokines are thought to play an important role in the hepatocellular dysfunction that occurs during sepsis. Some cytokines have been shown to increase lipogenesis and to induce toxicity in isolated hepatocytes. Oxygen free radicals have been implicated as mediators of some cytokine effects. In this study we investigate a possible protection action of S-adenosyl-L-methionine against the toxic effects of cytokines on isolated hepatocytes. Isolated rat hepatocytes were precultured for 24 hr and then cultured for 1, 2, 3, 6, 12, or 24 hr in the presence or absence of S-adenosyl-L-methionine (12 micromol/l0) and/or either tumor necrosis factor (100, 200, or 500 ng/ml) or interleukin-1 (30, 60, or 120 IU/ml). Lactate dehydrogenase (media), and malondialdehyde, reduced glutathione, and the incorporation of D-[U- 14 C] glucose into different lipid fractions (cells) were determined. Both cytokines significantly increased hepatocyte malondialdehyde content, lactate dehydrogenase release, and triacylglycerol synthesis. None of these effects were observed in the presence of S-adenosyl--L-methionine. In addition, S-adenosyl-L-methionine was able to attenuate the decrease in phosphatidylcholine labeling also induced by both cytokines, and to prevent the increase in free fatty acid synthesis induced by tumor necrosis factor. Incubation in the presence of S-adenosyl-L-methionine also increased hepatocyte glutathione content (7.1 +/- 0.7, after 24 hr, vs 3.6 +/- 0.3 nmole/mg protein, P < 0.01), and prevented the decrease in glutathione induced by tumor necrosis factor (5.4 +/- 0.2 vs 2.1 +/- 0.1 nmole/mg protein, 100 ng/ml TNF alpha at 24 hr, P < 0.01). Our results show that S-adenosyl-L-methionine has a protective effect on hepatocytes against the in vitro effect of cytokines.
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PMID:S-adenosylmethionine protects hepatocytes against the effects of cytokines. 860 15

The aim of this study was to investigate mucosal pH and lactate production in a porcine model of ischemia/reperfusion and sepsis using both tonometry and a technique for segmental intestinal perfusion. Eighteen pigs (17-23 kg) were anesthetized and mechanically ventilated. They were divided into three groups and followed for 4 h. Group C (n = 6) served as controls. In the ischemia/reperfusion group (I/R; n = 6), the superior mesenteric artery was totally occluded for 60 min. In group P (n = 6), sepsis was induced by fecal peritonitis. Cardiac index (CI) was determined by thermodilution and blood flow in the superior mesenteric artery (QSMA), using a Transonic flow probe. Intramucosal pH (pHi) was calculated using tonometry. A special balloon tube for segmental perfusion was introduced in the midileum for lactate measurement. Lactate and oxygen saturation were measured in arterial blood and in the superior mesenteric vein. CI, QSMA, pHi, and lactate in blood and perfusate remained unchanged in controls. Occlusion of intestinal blood flow induced a fall in pHi from 7.28 +/- .02 to 6.76 +/- .04, a marked rise in lactate in the perfusate, and an increased arteriovenous lactate difference. During reperfusion, pHi tended to return to baseline values. Lactate in the perfusate and the arteriovenous lactate difference decreased. In sepsis there was a continuous reduction in CI and QSMA to 45 +/- 13% and 40 +/- 20% of baseline, respectively. pHi decreased moderately from 7.22 +/- .09 to 6.98 +/- .25. Lactate remained unchanged in blood and perfusate. Microscopic mucosal injury was observed in all animals subjected to ischemia/reperfusion and in three of six pigs in group P. A good association between pHi and lactate production was seen in ischemia/reperfusion. However, in sepsis, lactate in superior mesenteric venous blood or in intestinal perfusate did not increase, despite the fall in pHi. The mechanism causing ischemic mucosal injury has different characteristics in sepsis and in ischemia caused by arterial occlusion.
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PMID:Small intestinal mucosal pH and lactate production during experimental ischemia-reperfusion and fecal peritonitis in pigs. 903 89

Hyperlactatemia is a frequent complication of sepsis. We investigated the effect of pentoxifylline on plasma lactate concentrations and lactate release by epitrochlearis incubated in vitro following intravenous injection of Escherichia coli. Plasma lactate concentrations were elevated on day 2 postinfection and remained elevated for at least another 4 days. Lactate production by incubated epitrochlearis was not increased in septic rats on day 2 postinfection, and lactate production from muscles incubated with insulin (2 nM) or insulin-like growth factor-I, (10 nM) was similar in control and septic rats. On day 6 postinfection, lactate production was augmented 1.8-fold in muscles from septic rats and both insulin and IGF-I caused an exaggerated stimulation of lactate production compared with control. Pentoxifylline decreased plasma TNF concentrations 100-fold following injection of bacteria and prevented the sepsis-induced hyperlactatemia and increase in lactate production by incubated muscles in presence or absence of insulin or IGF-I. Thus, pentoxifylline prevented the sepsis-induced abnormalities in skeletal muscle lactate production and plasma lactate concentrations.
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PMID:Modulation of skeletal muscle lactate metabolism following bacteremia by insulin or insulin-like growth factor-I: effects of pentoxifylline. 918 44

We prospectively investigated the effect of conventional resuscitation on gastric intramucosal pH and lactate over 5 days in a group of patients with newly diagnosed severe sepsis. Lactate and gastric intramucosal pH were measured on entry into the study, as soon as resuscitation end points were met, eight hourly for 48 h and daily for 5 days. Sixteen of 18 patients had a low gastric intramucosal pH (mean (SD) 7.17 (0.12)) at the time of diagnosis of severe sepsis. At no time did gastric intramucosal pH or lactate distinguish between shocked and nonshocked patients. Lactate distinguished survivors from nonsurvivors over time (p = 0.02). Gastric intramucosal pH did not distinguish survivors from nonsurvivors over time (p = 0.72). At 48 h lactate was lower in survivors (p < 0.01) and gastric intramucosal pH higher in survivors (p < 0.05). Receiver operating characteristic curves at this time indicate that lactate is a better predictor of survival. It is likely, based on the inability of gastric intramucosal pH to distinguish survivors from nonsurvivors until 48 h, that it is not possible to use this measurement to guide resuscitation in patients who are severely ill and who have gastric intramucosal acidosis.
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PMID:Gastric intramucosal pH and blood lactate in severe sepsis. 929 55

Lactate is released in large quantity from sites of sepsis and inflammation. We asked whether the increased lactate production found in sepsis can be explained by the augmented glycolysis of inflammatory cells. The glycolytic metabolism of rat peritoneal leukocytes was measured following cecal ligation and perforation (CLP) or sham laparotomy. CLP augmented glucose uptake, the pentose phosphate pathway, and glucose oxidation. Lactate output increased from 1.03 +/- 0.05 to 1.20 +/- 0.05 fmol x cell(-1) x min(-1) (P < .001). Total lactate output of peritoneal lavage fluid increased from 7.94 +/- 2.59 to 28.12 +/- 5.60 nmol L x min(-1) (P < .005). The effect of lipopolysaccharide (LPS) on the lactate output of whole blood from 31 critically ill patients was measured. Leukocyte lactate production was calculated by multiple linear regression analysis. Following exposure to LPS, human leukocyte lactate output increased from 0.20 +/- 0.09 to 1.22 +/- 0.14 fmol x cell(-1) x min(-1) (P < .001). This rate of production is so high that it suggests that the lactate output of different tissue beds in sepsis may be affected by their different cell populations and state of activation. This study supports the hypothesis that lactate may be more a product of inflammation than a marker of tissue hypoxia in sepsis.
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PMID:Leukocyte glycolysis and lactate output in animal sepsis and ex vivo human blood. 1038 Nov 54

Metabolic acidosis frequently complicates sepsis and septic shock and may be deleterious to cellular function. Different types of metabolic acidosis (e.g., hyperchloremic and lactic acidosis) have been associated with different effects on the immune response, but direct comparative studies are lacking. Murine macrophage-like RAW 264.7 cells were cultured in complete medium with lactic acid or HCl to adjust the pH between 6.5 and 7.4 and then stimulated with LPS (Escherichia coli 0111:B4; 10 ng/ml). Nitric oxide (NO), IL-6, and IL-10 levels were measured in the supernatants. RNA was extracted from the cell pellets, and RT-PCR was performed to amplify corresponding mediators. Gel shift assay was also performed to assess NF-kappa B DNA binding. Inc easing concentrations of acid caused increasing acidification of the media. Trypan blue exclusion and lactate dehydrogenase release demonstrated that acidification did not reduce cell viability. HCl significantly increased LPS-induced NO release and NF-kappa B DNA binding at pH 7.0 but not at pH 6.5. IL-6 and IL-10 expression (RNA and protein) were reduced with HCl-induced acidification, but IL-10 was reduced much more than IL-6 at low pH. By contrast, lactic acid significantly decreased LPS-induced NO, IL-6, and IL-10 expression in a dose-dependent manner. Lactic acid also inhibited LPS-induced NF-kappa B DNA binding. Two common forms of metabolic acidosis (hyperchloremic and lactic acidosis) are associated with dramatically different patterns of immune response in LPS-stimulated RAW 264.7 cells. HCl is essentially proinflammatory as assessed by NO release, IL-6-to-IL-10 ratios, and NF-kappa B DNA binding. By contrast, lactic acidosis is anti-inflammatory.
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PMID:Lactic and hydrochloric acids induce different patterns of inflammatory response in LPS-stimulated RAW 264.7 cells. 1469 14

For much of the 20th century, lactate was largely considered a dead-end waste product of glycolysis due to hypoxia, the primary cause of the O2 debt following exercise, a major cause of muscle fatigue, and a key factor in acidosis-induced tissue damage. Since the 1970s, a 'lactate revolution' has occurred. At present, we are in the midst of a lactate shuttle era; the lactate paradigm has shifted. It now appears that increased lactate production and concentration as a result of anoxia or dysoxia are often the exception rather than the rule. Lactic acidosis is being re-evaluated as a factor in muscle fatigue. Lactate is an important intermediate in the process of wound repair and regeneration. The origin of elevated [lactate] in injury and sepsis is being re-investigated. There is essentially unanimous experimental support for a cell-to-cell lactate shuttle, along with mounting evidence for astrocyte-neuron, lactate-alanine, peroxisomal and spermatogenic lactate shuttles. The bulk of the evidence suggests that lactate is an important intermediary in numerous metabolic processes, a particularly mobile fuel for aerobic metabolism, and perhaps a mediator of redox state among various compartments both within and between cells. Lactate can no longer be considered the usual suspect for metabolic 'crimes', but is instead a central player in cellular, regional and whole body metabolism. Overall, the cell-to-cell lactate shuttle has expanded far beyond its initial conception as an explanation for lactate metabolism during muscle contractions and exercise to now subsume all of the other shuttles as a grand description of the role(s) of lactate in numerous metabolic processes and pathways.
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PMID:Lactate metabolism: a new paradigm for the third millennium. 1513 Dec 40

Lactate is a key metabolite that is produced by every cell and oxidized by most of them, provided that they do contain mitochondria. Its metabolism is connected to energetic homeostasis and the cellular redox state. It is well recognized as an indicator of severe outcome in severely ill patients, however, it is not a detrimental factor per se. Conversely, some recent data tend even to indicate a beneficial effect in several metabolic disorders. Although the liver has long been recognized as a key organ in lactate homeostasis, the kidney also plays a major role as a gluconeogenic organ significantly involved in the glucose-lactate cycle. In acute renal failure, sodium lactate is widely used as a buffer in replacement fluids because the anion (lactate - ) is metabolized and the cation (Na + ) remains, leading to decreased water dissociation and proton concentration. The metabolic disorders related to acute renal failure or associated with it, such as liver failure, may affect lactate metabolism, and therefore they are often regarded as limiting factors for the use of lactate-containing fluids in such patients. By investigating endogenous lactate production in severe septic patients with acute renal failure, we found that an acute exogenous load of lactate did not affect the basal endogenous lactate production and metabolism. This indicates that exogenous lactate is well metabolized even in patients suffering from acute renal failure and severe sepsis with a compromised hemodynamic status.
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PMID:Lactate metabolism in acute uremia. 1564 9

Sepsis and multiple organ failure are characterized by an excessive release of inflammatory mediators and a marked stimulation of stress hormones. These in turn have profound effects on energy and substrate metabolism: energy expenditure is generally increased, and increased lipolysis and fat oxidation are observed. Net protein breakdown occurs and leads to accelerated wasting. Most of these effects can be produced in healthy humans by administration of bacterial endotoxin or by tumor necrosis factor-alpha. Hyperlactatemia is a hallmark of sepsis and critical illness, and its severity is related to mortality. An increased lactate production, possibly secondary to activation of Na-K adenosine 5'-triphosphatase and to muscle mitochondrial dysfunction, is involved. Lactate production by immune cells and wound tissue may also play a role. Long-chain, n-3 polyunsaturated fatty acids have anti-inflammatory effects that may be beneficial in sepsis. They also decrease the stimulation of stress hormones induced by bacterial endotoxin, possibly through an effect exerted at the level of the central nervous sytem. Their use in patients with sepsis does not lead to adverse metabolic effects.
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PMID:Substrate utilization in sepsis and multiple organ failure. 1771 4

Organ function is critically linked to the way tissues use available oxygen. In sepsis, tissue-related hypoxic injury is the result of hypoxemia and hypoperfusion and cytokine-mediated mitochondrial dysfunction termed cytopathic hypoxia. Organ dysfunction in sepsis is more likely related to derailment of the metabolic processes of cells to use available oxygen. Cellular dysoxia rather than hypoxia may be the most appropriate way of describing sepsis-related tissue injury. Lactate is a marker of aerobic mitochondrial dysfunction and anaerobic tissue metabolism and in some circumstances is considered the fuel of choice for certain tissues. The concept of cellular metabolic derangement or cytopathic hypoxia as a potential cause for multiorgan system dysfunction in sepsis may direct efforts to optimize outcome in septic patients from the classic targets of CO, tissue perfusion, DVo(2), and Vo(2) toward moderating sepsis-related early cytokine response, maximizing mitochondrial function, and using biomarkers to monitor treatment response.
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PMID:Detection of hypoxia at the cellular level. 2038 29


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