Hepatocytes produce nitrogen oxides from L-arginine in response to inflammatory products of Kupffer cells.

A metabolic pathway by which L-arginine (L-arg) is converted to the biologically active compound NO. has recently been described in macrophages (M phi) and endothelial cells. This report demonstrates that transferable products from activated Kupffer cells (KC) induce the conversion of large quantities of L-arg to nitrogen oxides within hepatocytes (HC). In M phi and endothelial cells, citrulline and NO2-/NO3- are the stable endproducts of this metabolic pathway. In contrast, HC L-arg metabolism resulted in significantly greater production of NO2-/NO3- than citrulline. The generation of NO. within HC was associated with a concurrent decrease in total protein synthesis.

An L-arginine-dependent mechanism mediates Kupffer cell inhibition of hepatocyte protein synthesis in vitro.

The hepatic failure associated with severe sepsis is characterized by specific, progressive, and often irreversible defects in hepatocellular metabolism (1). Although the etiologic microbe can often be identified, the direct causes and mechanisms of the hepatocellular dysfunction are poorly understood. We have hypothesized that Kupffer cells (KC), which interact with ambient septic stimuli, respond by providing signals to adjacent hepatocytes (HC) in sepsis . Furthermore, we have provided evidence (2, 3) that KC activated by LPS from Gram-negative bacteria can induce profound changes in the function of neighboring HC in coculture. In our model, coculture of either KC (2) or peritoneal macrophages (Mphi)(3) with HC normally promotes HC protein synthesis ([(3)H]leucine incorporation). The addition of LPS or killed Escherichia colt' to such cocultures induces a profound decrease in HC protein synthesis, as well as qualitative changes ([(35)S]methionine, SDS-gel electrophoresis) in protein synthesis without inducing HC death (2, 3) . In this report we show that the inhibition in protein synthesis is mediated via an L-arginine-dependent mechanism. The metabolism of L-arginine by activated Mphi to substances with cytostatic and even lethal effects on target cells is a relatively recent discovery. After the description by Stuehr and Marletta (4, 5) that LPS- triggered Mphi produced nitrite/nitrate (NO(2)(-)/NO(3)(-)), Hibbs et al. (6, 7) and Iyengar et al. (8) demonstrated that L-arginine was the substrate for the formation of both these nitrogen end products and citrulline. A role for the arginine-dependent mechanism in Mphi tumor cytotoxicity (6, 7) and microbiostatic activity (9) has been suggested. However, the in vivo functions of this novel Mphi mechanism have not yet been defined, but it is possible that there are both physiologic as well as pathologic roles. Our in vitro results raise the possibility that some metabolic responses to microbial invasion maybe partially mediated by the L-arginine-dependent mechanism. What other metabolic responses are affected and the possible pathologic consequences remain to be studied.

Modulation of nitrogen oxide synthesis in vivo: NG-monomethyl-L-arginine inhibits endotoxin-induced nitrate/nitrate biosynthesis while promoting hepatic damage.

Attempts were made to promote or inhibit nitric oxide (. N = O) synthesis in a murine model of hepatic damage (Corynebacterium parvum followed by lipopolysaccharide; LPS) to determine the role of . N = O in the liver injury. Moderate hepatic damage and increases in circulating NO2-/NO3- levels were detectable after C. parvum alone. Administration of LPS to these mice resulted in severe hepatic damage and acute elevations in circulating nitrogen oxide levels. L-arg had no influence on the C. parvum or LPS-induced changes. NG-monomethyl-L-arginine (NMA) had no effect in the absence of LPS, but when given with LPS, a dose-dependent suppression in plasma NO2-/NO3- levels and an increase in liver injury were seen. The NMA-induced changes were partially reversed by the simultaneous administration of L-arg. These findings suggest a protective role for . N = O in this model.

Hepatocyte modulation of Kupffer cell prostaglandin E2 production in vitro.

It is likely that dynamic interactions between hepatocytes and Kupffer cells contribute to the responses of these cell types both under normal conditions and during sepsis. In this study, we examined the influences of hepatocytes on the concentration of the inflammatory mediator PGE2 in Kupffer cell cultures. Evidence to suggest that cultured rat hepatocytes both metabolize PGE2 and produce a substance that promotes LPS-stimulated Kupffer cell PGE2 biosynthesis include the following: 1) PGE2 levels in Kupffer cell: hepatocyte coculture were lower than the levels in Kupffer cell cultures early after LPS stimulation; 2) 36 h after LPS, coculture PGE2 levels exceeded the levels in Kupffer cell cultures despite the demonstrated capacity for hepatocytes to metabolize PGE2; 3) a transferable, non-dialyzable, and heat-unstable factor in hepatocyte supernatant promoted PGE2 production when added to Kupffer cells with LPS or after LPS; 4) there was no increased PGE2 synthesis when the hepatocyte supernatant was added without LPS or if hepatocyte supernatant was preincubated with the Kupffer cells for 6 or 18 h before LPS administration; 5) there was an inability of the hepatocyte factor to promote PGE2 production in response to other macrophage-activating agents, including calcium ionophore A23187 or phorphol myristate acetate; and 6) there was no increased cell replication or protein synthesis in the Kupffer cell cultures following hepatocyte supernatant incubation. The increased Kupffer cell PGE2 production by the hepatocyte supernatant was not due to contamination of the hepatocyte supernatant by endotoxin or PGE2. These in vitro results raise the possibility that hepatocytes have the capacity to modulate local PGE2 levels by two distinct mechanisms. Hepatocytes can metabolize PGE2 as well as release factor(s) which promote LPS-induced PGE2 production by Kupffer cells.

Endogenous nitric oxide inhibits the synthesis of cyclooxygenase products and interleukin-6 by rat Kupffer cells.

Macrophage production of nitric oxide (.N = O) leads to considerable alterations of vital metabolic pathways in various target cells. The present study tested whether .N = O synthesis by Kupffer cells (KCs), the resident macrophages of the liver, interferes with the secretory function of these cells. As in other macrophage-type cells, the combination of lipopolysaccharide (LPS) and interferon-gamma (IFN-gamma) was a potent stimulus of .N = O synthesis by KC. Treatment with LPS and IFN-gamma also induced significant production of prostaglandin E2 (PGE2), thromboxane B2 (TBX2), tumor necrosis factor alpha (TNF-alpha), interleukin-1 (IL-1), and IL-6. Inhibition of .N = O synthesis by KC. Treatment with LPS and IFN-gamma also induced significant production of prostaglandin E2 (PGE2), thromboxane B2 (TBX2), tumor necrosis factor alpha (TNF-alpha), interleukin-1 (IL-1), and IL-6. Inhibition of .N = O synthesis by the L-arginine analogue of NG-monomethyl-L-arginine (NMA) resulted in a further increase of PGE2, TXB2, and IL-6 but not IL-1 and TNF-alpha production, indicating specific inhibitory effects of endogenous .N = O synthesis on the secretory activity of KCs. PGE2 production was most sensitive to the suppressive effect of .N = O and increased 24 h after stimulation with LPS and IFN-gamma from 16.3 +/- 4.9 ng/10(6) KCs without NMA to 94.3 +/- 17.9 ng/10(6) KCs with NMA. This effect of NMA was reversed by a 10-fold increase of the L-arginine concentration. No recovery of PGE2 production was seen when .N = O synthesis was blocked after 24 h. NMA treatment increased cyclooxygenase activity more than threefold, suggesting that .N = O inhibits PGE2 and TXB2 production through diminished PGH2 availability. .N = O synthesis did not significantly affect total protein synthesis or viability of the KCs. These results show that .N = O influences the production of specific inflammatory mediators by KCs.

Inhibition of nitric oxide synthesis during endotoxemia promotes intrahepatic thrombosis and an oxygen radical-mediated hepatic injury.

Corynebacterium parvum-treated mice produce large amounts of circulating nitrogen oxides and develop a severe liver injury in response to lipopolysaccharide (LPS). Concurrent administration of NG-monomethyl-L-arginine not only suppresses nitric oxide synthesis in these animals but also profoundly increases the hepatic damage following LPS. In this report, we present evidence that the increased hepatic damage from inhibition of nitric oxide synthesis is mediated in part by superoxide and hydroxyl radicals. The hepatic damage induced by suppressing nitric oxide production during endotoxemia could be reduced by treating mice with superoxide dismutase and deferoxamine, scavengers of superoxide and hydroxyl radicals, respectively. This damage could also be prevented by treating mice with the anticoagulant heparin sodium. The results suggest that nitric oxide synthesis during endotoxemia is important in preventing hepatic damage by reducing oxygen radical-mediated hepatic injury and preventing intravascular thrombosis.

Evidence that activation of Kupffer cells results in production of L-arginine metabolites that release cell-associated iron and inhibit hepatocyte protein synthesis.

Activated macrophages are known to metabolize L-arginine to unstable intermediates that induce cytotoxic activity through the release of mitochondrial iron in target cells. We have recently shown that rat Kupffer cells (KC) use L-arginine to inhibit cocultured hepatocyte (HC) protein synthesis. Based on these two facts, a hypothesis is proposed that endotoxin-triggered KC release intermediates of L-arginine metabolism that inhibit HC protein synthesis by oxidizing iron at critical mitochondrial enzymes, thus interfering with mitochondrial respiration and energy production. Results of experiments testing this hypothesis showed that the metabolism of L-arginine was required for inhibition of protein synthesis and iron release and that the end products of L-arginine metabolism did not possess cytostatic or cytotoxic activity toward HC. The possibility that this cell culture phenomenon might provide insights into the mechanism of hepatic insufficiency in sepsis is raised.

Fatty acid intake and Kupffer cell function: fish oil alters eicosanoid and monokine production to endotoxin stimulation.

Diets high in n-3 fatty acids appear to have an anti-inflammatory effect, which is thought to be due to decreased macrophage prostaglandin (PG) and thromboxane (Tx) production after incorporation of these fatty acids into cell membrane phospholipids. The effect of n-3 fatty acids incorporation on macrophage monokine release in response to septic stimuli is not well established. Kupffer cells, the fixed macrophages of the liver, were obtained from rats fed diets with fat sources derived from corn oil (CO, control), fish oil (FO, high in n-3 fatty acids), or safflower oil (SO, high in n-6 fatty acids) for 2 or 6 weeks. After exposure to bacterial lipopolysaccharide, Kupffer cells from rats fed FO for 2 or 6 weeks produced less PG and Tx than Kupffer cells from rats fed CO or SO. After 2 weeks of defined diets, interleukin-1 (IL-1) and tumor necrosis factor release were not affected by dietary fat source. In contrast, after 6 weeks of feeding, Kupffer cells from both the FO and the SO groups released less IL-1 and tumor necrosis factor when triggered by lipopolysaccharide than Kupffer's cells from animals fed the control diet that contained CO. These data suggest that altered monokine release from macrophages may contribute to the anti-inflammatory effect of diets high in n-3 fatty acids. Also shown in our results is that prolonged changes in membrane phospholipid content induced by dietary fat source can influence not only PG and Tx production but monokine release as well.

Hepatocytes enhance Kupffer cell-mediated tumor cell cytostasis in vitro.

Kupffer cells (KC) are believed to play a major role in protecting the liver from metastases. In vitro, activated KC mediate both tumor cell cytostasis and cytolysis. Because hepatocytes (HC) occupy a position adjacent to KC in vivo, we investigated the influence of HC on KC tumoricidal activity. Using an in vitro assay of KC-mediated tumor cell cytostasis against murine P815 mastocytoma cells, we found that the presence of HC in the culture profoundly increased KC tumoricidal activity. HC enhanced KC inhibition of P815 proliferation and lowered the concentration of lipopolysaccharide and interferon-gamma necessary to activate the KC to a tumoricidal state. This stimulatory HC effect was dependent on the number of HC present and was transferable in cell-free supernatants, indicating that it was mediated by a soluble secreted product of HC. Furthermore, unlike other macrophage-priming or -potentiating factors, the transferable HC factor(s) was effective only if added simultaneously with lipopolysaccharide or interferon-gamma and not effective if added before these activating agents. These data show that HC produce a soluble mediator that enhances KC tumoricidal activity, suggesting that HC and KC interactions may be critical to the antitumor defense mechanisms of the liver.

Kupffer cell cytotoxicity to hepatocytes in coculture requires L-arginine.

Activated macrophages convert L-arginine to citrulline and unstable nitrogen oxides that have cytotoxic properties. We recently have shown that the inhibition of protein synthesis in Kupffer cell (KC):hepatocyte (HC) coculture, following exposure to gram-negative bacterial endotoxin (lipopolysaccharide), is due to the metabolism of L-arginine by this cytotoxic pathway. Although this finding supports a role for activated KCs and the L-arginine-dependent mechanism in the HC dysfunction seen in sepsis, it and previous studies have failed to demonstrate direct damage to HCs by adjacent KCs. The current study was undertaken to determine if KCs exposed to lipopolysaccharide could directly damage HCs and, if so, whether the damage was dependent on the metabolism of L-arginine. By using the release of aspartate aminotransferase as a marker of HC damage, it was found that a significant aspartate aminotransferase release by KC:HC cocultures in response to lipopolysaccharide occurred only if L-arginine was present. In addition, requirements for significant aspartate aminotransferase release included KC:HC ratios of 7.5:1 or greater and L-arginine concentrations of 1 mmol or more. Although the KC-induced damage was mild, these results show that in vitro HC damage in KC:HC coculture does require the metabolism of L-arginine and supports a hypothesis that toxic L-arginine metabolites may contribute to liver cell damage in patients with sepsis.

Effect of interleukin 2 on Kupffer cell activation. Interleukin 2 primes and activates Kupffer cells to suppress hepatocyte protein synthesis in vitro.

Interleukin 2 (IL-2) is an essential mediator of the immune response and has also been shown to be protective in experimental models of sepsis. Macrophages have IL-2 receptors but their function is unknown. We investigated the effect of IL-2 on Kupffer cells, the fixed macrophages of the liver, using an in vitro rat hepatocyte-Kupffer cell coculture system. In this model, endotoxin (lipopolysaccharide) triggers Kupffer cells to induce suppression of hepatocyte protein synthesis. We found that pretreatment with 10 U/mL or more of IL-2 primed Kupffer cells, significantly reducing the concentration of lipopolysaccharide necessary to trigger Kupffer cell-mediated suppression of hepatocyte protein synthesis. Higher concentrations of IL-2 (greater than or equal to 1 x 10(4) U/mL) alone were capable of priming and triggering Kupffer cells to suppress hepatocyte protein synthesis. These data show that IL-2 increases Kupffer cell sensitivity to endotoxin, suggesting that IL-2 may play an important role in regulating macrophage responses to septic stimuli.

Liver nonparenchymal cells are stimulated to provide interleukin 6 for induction of the hepatic acute-phase response in endotoxemia but not in remote localized inflammation.

It has been postulated that Kupffer cells provide signals that regulate hepatocyte responses in sepsis and inflammation. Although in vitro data support such a hypothesis, to our knowledge, no in vivo evidence has been reported. We injected rats with lipopolysaccharide intraperitoneally to simulate sepsis or turpentine intramuscularly to mimic localized inflammation. Both treatments are known to induce the hepatic acute-phase response. Liver nonparenchymal cells and hepatocytes were isolated and placed in culture. Hepatocyte fibrinogen synthesis was measured as an indication of interleukin 6 exposure, while nonparenchymal interleukin 6 production was measured directly. Both lipopolysaccharide and turpentine stimulated a sharp increase in hepatocyte fibrinogen synthesis (turpentine greater than lipopolysaccharide). However, only lipopolysaccharide injection was associated with increased nonparenchymal cell interleukin 6 synthesis. Increased circulating levels of interleukin 6 could be found only after lipopolysaccharide injection. In addition, tumor necrosis factor synthesis was enhanced by lipopolysaccharide but not turpentine. Our data show that nonparenchymal cells are stimulated to provide the interleukin 6 signal to hepatocytes in endotoxemia but not in remote localized inflammation, even though both treatments stimulate the hepatic acute-phase response. Our findings support paracrine functions for liver sinusoidal cells in certain septic states.

Effect of endogenous nitric oxide on mitochondrial respiration of rat hepatocytes in vitro and in vivo.

Nitric oxide, a highly reactive radical, was recently identified as an intermediate of L-arginine metabolism in mammalian cells. We have shown that nitric oxide synthesis is induced in vitro in cultured hepatocytes by supernatants from activated Kupffer cells or in vivo by injecting rats with nonviable Corynebacterium parvum. In both cases, nitric oxide biosynthesis in hepatocytes was associated with suppression of total protein synthesis. This study attempts to determine the effect of nitric oxide biosynthesis on the activity of specific hepatocytic mitochondrial enzymes and to determine whether inhibition of protein synthesis is caused by suppression of energy metabolism. Exposure of hepatocytes to supernatants from activated Kupffer cells led to a 30% decrease of aconitase (Krebs cycle) and complex I (mitochondrial electron transport chain) activity. Using NG-monomethyl-L-arginine, an inhibitor of nitric oxide synthesis, we demonstrated that the inhibition of mitochondrial aconitase activity was due, in part, to the action of nitric oxide. In contrast, in vivo nitric oxide synthesis of hepatocytes from Corynebacterium parvum-treated animals had no effect on mitochondrial respiration. This suggests that inhibition of protein synthesis by nitric oxide is not likely to be mediated by inhibition of energy metabolism.

Method for creation of the aortotomy site for saphenous vein grafts.

Saphenous vein coronary artery bypass grafting requires a proximal anastomosis of the vein to the aorta. A variety of techniques have been described to create the aortotomy. We have developed a four-sided knife (Xcision Scalpel; patent pending, Research Medical, Inc, Midvale, UT) that facilitates the creation of a more uniform circular aortotomy. The purpose of this communication is to describe the knife and the technique for its use.

Management of massive pulmonary thromboembolism complicating diabetic ketoacidosis.

Intravascular volume depletion secondary to diabetic ketoacidosis may result in thrombosis of major blood vessels. Without anticoagulation these thrombi can embolize to the lungs and compromise cardiopulmonary function. When this occurs early surgical pulmonary embolectomy is indicated to salvage a failing right heart.

Inhaled nitric oxide for children with congenital heart disease and pulmonary hypertension.

BACKGROUND: Endothelium-derived nitric oxide (NO) is a potent vasodilator and a major mediator of pulmonary vascular tone. METHODS: Five infants underwent a trial of inhaled NO with hemodynamic monitoring in the operating room after atrioventricular canal repair. An additional 15 patients with congenital heart disease and refractory pulmonary hypertension were treated with inhaled NO for 1 day to 10 days postoperatively. RESULTS: In the 5 infants with atrioventricular canal, corrective surgical intervention and conventional therapy (hyperventilation, inspired oxygen fraction of 0.80, and inotropic agents) lowered mean pulmonary artery pressure from 49.5 +/- 10.5 to 20.0 +/- 2.2 mm Hg (p < 0.001). Adding inhaled NO further decreased mean pulmonary artery pressure to 18.0 +/- 2.8 mm Hg (p = not significant). Inhaled NO had no effect on ventricular function curves (inflow occlusion) in this group. In the 15 patients with refractory postoperative pulmonary hypertension, 11 had a favorable response to inhaled NO, with a decrease in mean pulmonary artery pressure from 30.9 +/- 5.8 to 23.1 +/- 5.4 mm Hg (p < 0.01) in 8 patients with pulmonary artery catheters. CONCLUSIONS: These studies demonstrate that inhaled NO has minimal beneficial effect on pulmonary artery pressure or cardiac output in infants after repair of atrioventricular canal. Inhaled NO is effective in decreasing PAP postoperatively in select patients with congenital heart disease and pulmonary hypertension refractory to conventional therapeutic modalities.

Intraoperative procurement of autologous fibrin glue.

A method of intraoperative procurement of autologous fibrin glue is described. The relative efficacy of our autologous preparation is compared with that of fibrin glue made with homologous cryoprecipitate. Experimentally, the fibrinogen content and the strength are less than those found in cryoprecipitate and appear related to the fibrinogen content of the autologous plasma used as substrate in the fibrin glue reaction. Clinically, no significant differences are noted in the performance of autologous fibrin glue. We believe the absence of the risk of blood-borne infection with the autologous product is a major advantage.

False aneurysm of the right internal mammary artery. Late rupture after sternotomy.

This report describes a late, near-fatal rupture of a false aneurysm of the right internal mammary artery subsequent to coronary artery bypass grafting. The patient presented to us in shock due to hemorrhaging, 8 weeks after bypass surgery that had been complicated by sternal fracture, dehiscence, and infection. Emergent thoracotomy and suture ligation controlled the hemorrhage. To the best of our knowledge, this is the 1st reported case of late massive hemorrhage caused by injury to an internal mammary artery after sternotomy. The literature is reviewed and discussed.

Ascending aortic extension for right pulmonary artery stenosis associated with ventricular-to-pulmonary artery conduit replacement.

BACKGROUND: Ventricular-to-pulmonary artery conduits in growing patients with congenital heart disease will require replacement from time to time due to somatic growth, neointimal hyperplasia, and pulmonary artery stenosis. The purpose of this article is to review our experience with ascending aortic extension for significant long-segment pulmonary artery stenosis in patients undergoing reoperation for right ventricular-to-pulmonary artery conduit replacement. METHODS: From 1989 to 1997, 8 patients had aortic transection, right pulmonary artery augmentation arterioplasty, and aortic interposition graft (Hemashield in 7 and Gore-tex in 1) in association with right ventricular-to-pulmonary artery conduit replacement in 7 patients and completion Fontan operation in 1 patient. Aortic cross-clamp time was 90 +/- 34 minutes, and the cardiopulmonary bypass time was 205 +/- 37 minutes. RESULTS: All patients survived. In those 7 patients who had conduit replacement, the RV/LV ratio declined from 0.78 +/- 0.15 to 0.45 +/- 0.05 postoperatively (P < 0.05). Average length of stay was 8.9 +/- 7.2 days. Follow-up range is 18 months to 8 years (mean 4 years). Two complications included cardiac transplantation for pre-existing poor left ventricular function and accelerated conduit stenosis leading to conduit re-replacement. CONCLUSION: Ascending aortic extension facilitates long-segment pulmonary artery augmentation arterioplasty and enlarges the retroaortic space, preventing future compression restenosis.