UMLS:C0036690 - FACTA Search

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Query: UMLS:C0036690 (sepsis)
59,461 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Nitric oxide (NO), a free radical that is negatively inotropic in the heart and skeletal muscle, is produced in large amounts during sepsis by an NO synthase inducible (iNOS) by LPS and/or cytokines. The aim of this study was to examine iNOS induction in the rat diaphragm after Escherichia Coli LPS inoculation (1.6 mg/kg i.p.), and its involvement in diaphragmatic contractile dysfunction. Inducible NOS protein and activity could be detected in the diaphragm as early as 6 h after LPS inoculation. 6 and 12 h after LPS, iNOS was expressed in inflammatory cells infiltrating the perivascular spaces of the diaphragm, whereas 12 and 24 h after LPS it was expressed in skeletal muscle fibers. Inducible NOS was also expressed in the left ventricular myocardium, whereas no expression was observed in the abdominal, intercostal, and peripheral skeletal muscles. Diaphragmatic force was significantly decreased 12 and 24 h after LPS. This decrease was prevented by inhibition of iNOS induction by dexamethasone or by inhibition of iNOS activity by N(G)-methyl-L-arginine. We conclude that iNOS was induced in the diaphragm after E. Coli LPS inoculation in rats, being involved in the decreased muscular force.
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PMID:Induction of diaphragmatic nitric oxide synthase after endotoxin administration in rats: role on diaphragmatic contractile dysfunction. 883 3

We tested the hypothesis that selective inhibition of the inducible form of nitric oxide (NO) synthase with aminoguanidine would prevent the loss of vascular contractility after exposure to endotoxin [lipopolysaccharide (LPS)]. Aortic rings were dissected from Sprague-Dawley rats, suspended in organ baths containing Krebs solution, and tested for vascular reactivity. Vessels incubated with LPS (1 microgram/ml) for 5 h exhibited a significant decrease in the maximal contractile response to phenylephrine. Aminoguanidine (100 microM) restored the maximal contractile response of LPS-treated vessels to the level of the control vessels. Aminoguanidine was approximately 250-fold less potent than NG-nitro-L-arginine methyl ester in inhibiting the constitutive NO synthase in vascular tissue as determined by its ability to further increase tone of submaximally contracted aortic rings. NO synthase activity was determined in vascular tissue incubated with and without LPS. Vessels incubated with LPS exhibited a marked increase in the levels of inducible NO synthase activity compared with control vessels. This increase was restored to control levels when tissue homogenates were incubated with aminoguanidine. We conclude that aminoguanidine is a selective concentration-dependent inhibitor of the inducible form of NO synthase and may be a useful probe to evaluate the role of inducible NO synthase in the abnormal vascular contractility characteristic of endotoxemia and sepsis.
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PMID:Inducible nitric oxide synthase and vascular reactivity in rat thoracic aorta: effect of aminoguanidine. 884 14

Vascular pathophysiology at the sites of bacterial infection and cancerous tissues share numerous common events similar to inflammatory tissue. Among them enhanced vascular permeability is the universal and hallmark event mediated by bradykinin. All 16 or more bacterial or fungal proteases we have examined activated one or more steps of the kinin generating Hageman-factor-kallikrein cascade. In the meantime, most of the microbial proteases rapidly inactivated various plasma inhibitors such as alpha 1-protease inhibitor and alpha 2-macroglobulin. In addition to the extracellular proteases, bacterial cell wall components (negatively charged LPS) of gram-negative bacteria and teichoic acid moieties of gram-positive bacteria activate the Hageman-factor-kallikrein system and exert hypotensive effects via kinin generation. Endotoxin (LPS) also induces nitric oxide synthase (NOS) which appears to exhibit a rather slow, but significant, effect in relaxing the vascular tone of the infected animal (thus hypotension). Furthermore, bacterial proteases can activate the matrix metalloproteinase (collagenase) resulting in exacerbation of tissue injury in the diseased animal. Many tumor cells or tissues excrete plasminogen activator, and hence activate plasminogen. The plasmin thus generated activates procollagenases, as well as the Hageman-factor-kallikrein system, resulting in pronounced extravasation. Fluid accumulation in pleural and ascitic carcinomatoses is largely due to the activated bradykinin-generating system. We can also demonstrate and control enhanced vascular permeability using kallikrein inhibitors, especially the polymer-conjugated soybean trypsin inhibitor which exhibits a prolonged plasma t1/2, kinin antagonists, NOS inhibitors, NO scavengers, inhibitors of prostaglandins and others. Bacterial proteases induce shock in mice which can be prevented by the soybean trypsin inhibitor by blocking the kallikrein-kinin cascade. Therapeutic use of kinin antagonists and a kallikrein inhibitor has been made for infectious diseases such as septicemia and in tumor pathology.
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PMID:Bradykinin and nitric oxide in infectious disease and cancer. 885 54

Nitric oxide (NO) is produced by the enzyme nitric oxide synthase (NOS), which exists in different isoforms in various tissues. The inducible NOS (iNOS) isoform of the enzyme is expressed in vascular smooth muscle in response to lipopolysaccharide and inflammatory mediators. When this expression of iNOS occurs in the lung, the NO produced may play a role in the inflammatory process of acute lung injury. This article reviews the research that characterizes iNOS in rat pulmonary artery smooth muscle and discusses current investigation into the role of NO in sepsis and injury.
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PMID:Nitric oxide and the pulmonary artery smooth muscle cell. 885 62

The inducible isoform of nitric oxide synthase (iNOS) is expressed in various organs, including the lung, during systemic endotoxemia. Overproduction of nitric oxide (NO) by iNOS contributes significantly to the vascular failure and end-organ damage in endotoxemia. Using selective pharmacological inhibitors of iNOS, the purpose of this study was to define the role of iNOS in a rat model of endotoxin-induced pulmonary transvascular flux (TVF). Lung TVF was assessed by a method of Evans Blue permeability index (PI). Bacterial lipopolysaccharide (LPS) (15 mg/kg intraperitoneally [IP]) significantly increased pulmonary iNOS activity and serum levels of nitrite/nitrate (NO2/NO3). This was accompanied by a significant elevation of the PI 5 hours after injection. Selective iNOS inhibition with either S-methyl isothiourea (SMT; 5 mg/kg IP) or aminoguanidine (AG; 20 mg/kg IP), administered 2 hours after LPS injection, significantly prevented the increase in PI associated with LPS injection. Similarly, inhibition of the induction of iNOS with dexamethasone (10 mg/kg IP), given 3 hours before LPS, also inhibited the increase in PI. All three treatments significantly prevented the increase in both lung iNOS activity and serum NO2/NO3 associated with endotoxemia. In conclusion, the overproduction of NO generated by iNOS during systemic endotoxemia causes a vascular leak in the lung. Thus, it is speculated that selective inhibition of iNOS may be beneficial in preventing the development of acute respiratory failure in sepsis.
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PMID:Selective inhibition of the inducible isoform of nitric oxide synthase prevents pulmonary transvascular flux during acute endotoxemia. 886 22

To investigate the hypothesis that nitric oxide synthase (NOS) inhibition restores the vasopressor response to norepinephrine (NE) in ovine hyperdynamic sepsis, eight sheep were chronically instrumented. In the non-septic portion of the study, NE was titrated to achieve an increase in mean arterial pressure (MAP) by 15 mm Hg ("small dose"). Small-dose NE was repeated 1 h after administration of the NOS inhibitor NG-nitro-L-arginine methyl ester (L-NAME; bolus 5 mg/kg, followed by 1 mg.kg-1.h-1). After 3 days of recovery, sepsis was induced by a continuous endotoxin infusion (Salmonella typhosa, 10 ng.kg-1.h-1). Three animals died during this period (data excluded). After 24 h, small-dose NE was given. If MAP increased less than 15 mm Hg, the NE dose was increased to achieve the targeted MAP change ("large dose"). Finally, both doses of NE were given after L-NAME administration. To increase MAP by 15 mm Hg in nonseptic animals, the rate of NE infusion was 0.18 +/- 0.03 microgram.kg-1.min-1 (small dose). During L-NAME infusion, this NE dose increased MAP by 32 +/- 8 mm Hg. In septic animals, small-dose NE increased MAP by only 9 +/- 2 mm Hg (P < 0.05 versus nonseptic state). To increase MAP by 15 mm Hg, the NE dose had to be increased to 0.34 +/- 0.06 microgram.kg-1.min-1 (large dose). During L-NAME infusion, NE administration increased MAP by 16 +/- 2 mm Hg and 28 +/- 4 mm Hg (small and large dose, respectively). Thus, L-NAME restored the vasopressor response to NE in sepsis, and increased the vasopressor response to NE in a similar fashion in healthy and septic sheep.
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PMID:Nitric oxide synthase inhibition restores vasopressor effects of norepinephrine in ovine hyperdynamic sepsis. 889 77

Expression of the inducible isoform of nitric oxide synthase (iNOS) contributes to the hypotension and vascular hyporeactivity in various models of shock induced by bacterial lipopolysaccharide (LPS). However, the role of iNOS in response to shock caused by live bacteria is more controversial. In the present study, we investigated the role of iNOS in a rat model of cecal ligation and puncture (CLP). CLP resulted in increased plasma nitrite/nitrate levels (up to 59 microM at 24 h) and increased pulmonary iNOS activity (up to 71 fmoles/mg/min at 12 h) and caused a significant vascular hyporeactivity at 18 h. The degree of NO production and iNOS induction was approximately 30% of that observed several hours after administration of LPS in the same species, and the degree of vascular hyporeactivity was less than that observed after LPS injection. Selective inhibition of iNOS with mercaptoethylguanidine (MEG) reduced plasma nitrite/nitrate levels, but did not prevent the development of vascular hyporeactivity, and did not improve survival in this model of CLP. Thus, CLP-induced sepsis causes low-level induction of iNOS, but factors other than iNOS are the crucial determinants of the vascular failure and mortality in this model.
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PMID:Low-level expression and limited role for the inducible isoform of nitric oxide synthase in the vascular hyporeactivity and mortality associated with cecal ligation and puncture in the rat. 890 40

Bacterial lipopolysaccharides (LPS) induce the activity of guanosine triphosphate (GTP)-cyclohydrolase I (GTP-CHI), the first enzyme in the biosynthesis of tetrahydrobiopterin (H4bip) from GTP in endothelial cells and macrophages. In these and other cells, LPS also acts costimulatory with cytokines, i.e., mainly tumor necrosis factor-alpha (TNF-alpha). H4bip is the cofactor for nitric oxide synthase (NOS). We were interested in comparing the pteridine and nitrate levels in two baboon models: a hyperdynamic sepsis model and a hemorrhagic traumatic shock model. Our results show a similar response of pteridines (H4bip, neopterin) and nitrite/nitrate levels to an immune stimulus. LPS, which peaks rapidly, induces a sustained increase in pteridine levels in septic animals. Since hemorrhagic animals show very little response in terms of cytokine production, it was not possible to measure the induction of neopterin and nitrite/nitrate. This information could aid our understanding of the regulatory mechanisms in various forms of experimental shock.
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PMID:Pteridine and nitrite/nitrate formation in experimental septic and traumatic shock. 890 41

Nitric oxide (NO) produced by the induced NO synthase (NOS) enzyme has been implicated in the mechanisms of the circulatory changes that occur in the later stages of sepsis. As NO produced by the constitutive form of the enzyme is known to play a role in the regulation of normal circulation, we have performed a series of experiments to study the early circulatory effects of inhibition of NOS in a hyperdynamic endotoxemic dog model. Pentobarbital-anesthetized animals were used. Cardiac output (CO) was measured by thermodilution. Myocardial contractility (MC) was estimated from the slope of the left ventricular end-systolic pressure-diameter relationship obtained from sonomicrometer- and catheter-tip manometer signals in closed chest animals. All animals received a 15 mL/kg/h infusion of Ringer's lactate. A hyperdynamic response was elicited by a 2 h infusion of a total dose of 5.3 micrograms/kg Escherichia coli O55:B5 endotoxin (ETX). CO increased initially by about 25%, and total peripheral resistance decreased by 35%. These changes subsided in 60-90 min, after which a sustained decrease in CO occurred. MC elevated transiently by 25% after the first 30 min of ETX infusion, then decreased gradually below the control level. Administration of 2 mg/kg of the NOS inhibitor N-nitro-L-arginine (NNA) between the 45th and 55th min of the ETX infusion increased MC to the level in the control group, but accelerated the decline of the initially increased CO and caused a sustained increase in total peripheral resistance to about 50% above the control level. In normal (nonendotoxin treated) dogs, NNA also caused a similar increase in MC which, however, lasted at least 3 h. Left ventricular diameter increased in the NNA-treated groups. This increase also occurred in the endotoxin-only group but with a delay of about 2.5 h. Our results demonstrate the participation of constitutive NOS-produced NO in the early hyperdynamic response of endotoxemia. Suppression of NO is associated with increased myocardial contractility. NNA treatment may be favorable for the restoration of depressed cardiac contractility during endotoxemia, but this treatment is probably detrimental for the compensatory systemic flow (CO) increase.
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PMID:Effect of nitric oxide synthase inhibition on myocardial contractility in anesthetized normal and endotoxemic dogs. 890 46

During sepsis or inflammation, the liver expresses various protective phenotypes such as the acute phase response or the heat shock response (HSR). Inducible nitric oxide synthase (NOS2) is also expressed in the liver in these conditions and may protect the liver under some circumstances and promote injury in others. We have previously reported that the acute phase response and NOS2 expression are differentially regulated, though both can be expressed simultaneously. The HSR is known to prevent expression of other genes, but its effects on NOS2 expression in the liver is unknown. Therefore, we examined how the HSR influences NOS2 expression in primary rat hepatocytes. Sodium arsenite (Ars) or hyperthermia (43 degrees C) induced the synthesis of hsp72 messenger RNA (mRNA) and protein in hepatocytes, indicating activation of the HSR. In the absence of the HSR, combinations of interleukin-1beta (IL-1beta), tumor necrosis factor alpha (TNF-alpha), and interferon gamma (IFN-gamma) stimulated high levels of NOS2 mRNA and nitric oxide (NO) synthesis. However, treatment with Ars or heat shock significantly attenuated cytokine-induced NOS2 mRNA and NO production. The addition of the nuclear factor kappaB (NF-kappaB) inhibitor pyrrolidine dithiocarbamate also inhibited NOS2 expression, suggesting a role for NF-kappaB in the cytokine induction of NOS2 in hepatocytes. Cytokines induced the appearance of an NF-kappaB complex as shown in gel retardation assays; however, induction of the HSR by Ars partially prevented cytokine-induced formation of this band while hyperthermia had a more complete inhibition. Furthermore, preinduction of the HSR prevented the activation of the NOS2 promoter construct in hepatocytes transfected with a 1.6 kilobase NOS2 promoter linked to luciferase. These findings show that NO production in stressed cells can be modulated by the HSR, possibly through repression of NOS2 gene transcription via the inhibition of NF-kappaB.
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PMID:Heat shock response inhibits cytokine-inducible nitric oxide synthase expression in rat hepatocytes. 890 4

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