Use of rat models to mimic alterations in iron homeostasis during human alcohol abuse and cirrhosis.

With alcoholism, there are marked disturbances in iron homeostasis that are linked to alterations in serum transferrin and ferritin concentrations. This study identifies rat models of alcohol abuse that closely mimic these disturbances. Male rats were placed in one of the following three protocols: (1) pair-feeding of liquid diets for 1-8 weeks; (2) agar-block feeding for 8 weeks; or (3) generation of cirrhosis with CCl(4). Serum samples were analyzed for ferritin, transferrin, and iron levels, and the transferrin iron saturation and ferritin/transferrin ratios were calculated. Liver iron concentrations were also determined. Serum transferrin levels were elevated in animals fed alcohol for 8 weeks in pair-feeding and agar-block feeding protocols, but reduced in rats with cirrhosis. Serum ferritin concentration was reduced in rats fed ethanol in the liquid diet, but increased in rats consuming ethanol in agar blocks, in rats pair-fed the liquid control diet, and in rats with cirrhosis. This finding was mirrored by liver nonheme iron concentrations in all experimental groups, but not in the corresponding control groups. Serum iron levels were significantly elevated only in rats fed the liquid control diet. There was a progressive decrease in transferrin iron saturation and ferritin/transferrin ratios for animals fed ethanol in the liquid diet, but not when ethanol was ingested from agar blocks. The development of cirrhosis resulted in elevated liver iron concentrations and doubled ferritin/transferrin ratios. It is concluded that these models may be used to study disturbances in iron homeostasis that occur during alcohol abuse and the (subsequent) development of liver disease.

Effects of endotoxin on neutrophil-mediated ischemia/reperfusion injury in the rat heart in vivo.

We have previously shown that a nonlethal dose of lipopolysaccharide (LPS) decreases L-selectin expression of neutrophils (PMNs), thereby preventing PMN-mediated reperfusion injury in the isolated heart. In the present study we determined whether or not that dose of LPS would protect hearts during in vivo ischemia and reperfusion by preventing PMN-induced reperfusion injury. Rats receiving saline vehicle showed marked myocardial injury (necrotic area/area at risk = 82%+/-2%) and significant depression in left ventricular function as assessed in the isolated isovolumic heart preparation at constant flow rates of 5, 10, 15, and 20 ml/min. The administration of LPS (100 microg/kg body wt) 7 hr prior to ischemia resulted in a reduction in myocardial damage (necrotic area/area at risk = 42%+/-3%) and preservation of function. Myocardial function was similar to that of sham ischemic saline- and LPS-treated rats. Moreover, PMN infiltration as determined by histology was quantitatively more severe in hearts of saline-treated rats than in hearts of LPS-treated rats. Isolated hearts from vehicle- and LPS-treated animals undergoing sham ischemia in vivo recovered to the same extent after in vitro ischemia/reperfusion, suggesting that LPS did not induce protection by altering intrinsic properties of the heart. Our results indicate that LPS-induced protection of the heart from in vivo PMN-mediated ischemia/reperfusion injury may be due to decreased L-selectin expression of PMNs in LPS-treated animals.

The role of K+ATP channels in the control of pre- and post-ischemic left ventricular developed pressure in septic rat hearts.

Myocardial function is impaired 24 h after the induction of sepsis, however, recovery of left ventricular (LV) function after 35 min of global ischemia is complete. The mechanisms by which this protection occurs are unknown. Ischemic preconditioning, another form of myocardial protection from ischemia/reperfusion (I/R) injury, has been shown to be modulated by ATP-sensitive potassium (K+ATP) channels. To investigate the role of K+ATP channels in the regulation of coronary flow (CF) and protection from I/R injury in septic rat hearts, we assessed the effects of the K+ATP channel antagonist glibenclamide (GLIB) and the agonist cromakalim (CROM) on pre- and post-ischemic CF and left ventricular developed pressure (LVDP). Although GLIB decreased pre-ischemic CF in both control and septic rat hearts, LVDP was unaffected. After I/R, CF was decreased in GLIB-treated control and septic rat hearts and LVDP was more severely depressed in control rat hearts than in septic rat hearts. CROM increased pre-ischemic CF in the septic group although LVDP was unaltered in both groups. After I/R, control rat heart CF was depressed but LVDP completely recovered. Post-ischemic CF in septic rat hearts was elevated compared with vehicle-treated septic rat hearts, but the recovery of LVDP was not improved. These results suggest that K+ATP channels modulate CF in septic rat hearts, but do not mediate cardioprotection as observed in control rat hearts.

Effects of endotoxin on neutrophil-mediated I/R injury in isolated perfused rat hearts.

With the use of a syngeneic model, we demonstrate that rat polymorphonuclear neutrophils (PMNs) exacerbate ischemia-reperfusion injury in the isolated rat heart. However, PMNs (19 x 10(6) cells) from lipopolysaccharide (LPS)-treated rats (LPS-PMNs; 100 mg/kg administered 7 h before exsanguination) induce less reperfusion injury in the isolated heart. Average recovery of left ventricular developed pressure after 20 min of ischemia and 60 min of reperfusion was 51 +/- 4% in hearts receiving PMNs from saline-treated control rats (saline-PMNs) versus 78 +/- 2% in hearts receiving LPS-PMNs. Ischemic hearts reperfused with LPS-PMNs recovered to the same extent as did hearts reperfused with Krebs buffer only. LPS-PMNs and saline-PMNs showed no difference in basal or phorbol ester-induced superoxide production. Whereas twice the number of LPS-PMNs was positive for nitroblue tetrazolium, the percent positive for L-selectin, a receptor integral in PMN-adhesion to endothelium, was 50% less in LPS-PMNs than in controls. After reperfusion, three-fourths of the saline-PMNs remained within the hearts, whereas only one-fourth of LPS-PMNs were trapped. These data suggest that PMNs from LPS-treated rats do not exacerbate ischemia-reperfusion injury as do control PMNs, possibly, due to impaired PMN adhesion to endothelium as a result of decreased L-selectin receptors.

The effect of acute ethanol exposure on the chronotropic and inotropic function of the rat right atrium.

Consumption of ethanol (CH2CH3OH), both acutely and chronically, is known to affect cardiac function and may alter the autonomic control of the heart. This study investigated the effects of two modes of acute exposure to ethanol on the chronotropy and inotropy of the rat right atrium with emphasis on alterations in the adrenergic responses. Atria from rats infused with an anesthetizing level of ethanol for 21 h showed a tendency for a greater increase of the unstimulated beating rate with isoproterenol (ISO), while both unstimulated inotropy and the inotropic response to ISO were significantly decreased compared with the control. Right atria in the presence of ethanol in-vitro demonstrated decreased basal active tension development and decreased inotropic responses to ISO. No alteration of the chronotropic response to ISO was evident with any concentration of ethanol. These results demonstrate both an immediate as well as a persistent effect of ethanol on right atrial chronotropy and inotropy. Alterations in the G-stimulatory subunit of the adenylate cyclase system and alterations in myofilament binding of Ca2+ are consistent with these observed ethanol effects.

Effects of blood resuscitation versus dextran resuscitation after hemorrhage on intrinsic myocardial function.

BACKGROUND: Myocardial function is altered by many factors present in hemorrhaged and resuscitated animals. The purpose of this study was to determine whether resuscitation after a short period of hemorrhagic shock, which by itself did not alter intrinsic cardiac function, causes dysfunction. METHODS: Guinea pigs were instrumented to measure blood pressure and cardiac output, and several days later 50% of their blood volume was removed at a rate of 1 mL/min. Some animals were resuscitated with the shed blood and some with 6% dextran. Hearts were studied 1 or 24 hours after resuscitation. RESULTS: Isolated hearts from animals after 1 hour of resuscitation demonstrated dysfunction whether resuscitated with blood or dextran, although dysfunction was more severe with blood resuscitation. By 24 hours, dysfunction was essentially reversed. CONCLUSIONS: Resuscitation after hemorrhagic shock caused injury to the myocardium independent of the hemorrhage. Blood resuscitation resulted in greater dysfunction than did resuscitation with dextran.

Dexamethasone blocks sepsis-induced protection of the heart from ischemia reperfusion injury.

Previous investigations have shown that sepsis, while causing cardiac dysfunction, can protect the heart from ischemia-reperfusion injury. Sepsis-induced protection may be due to nitric oxide produced by an inducible form of nitric oxide synthase generated in response to cytokines released during sepsis. The glucocorticoid dexamethasone has been shown to inhibit the synthesis of the inducible form of nitric oxide synthase (iNOS). The goals of this study were to determine if dexamethasone would prevent sepsis-induced cardiac dysfunction and sepsis-induced protection of the heart from ischemia-reperfusion injury. In this experiment, rats were made septic by injecting Escherichia coli into the dorsal subcutaneous space. Control rats were injected with sterile saline. At the time of surgery, some of the control and septic animals were injected intraperitoneally with dexamethasone (3 mg/kg). The next day, 24-26 hr after injection of the first dose of E. coli, animals were anesthetized, and hearts were removed and studied in the isovolumic beating-heart preparation. Left ventricular end diastolic pressure was set to 5 mmHg, and left ventricular pressure was measured continuously throughout the protocol. Left ventricular developed pressure (LVDP) was used as an index of LV function. After stabilization, hearts were made globally ischemic for 35 min and then reperfused for 25 min. As has been shown previously, sepsis depressed LVDP but also protected the heart from further depression of LVDP by ischemia and reperfusion. Dexamethasone prevented both sepsis-induced cardiac dysfunction and sepsis-induced protection of the heart from ischemia-reperfusion injury. In addition plasma nitrite/nitrate levels were not different from control levels in the dexamethasone-treated septic rats whereas levels were elevated in the septic animals. The dexamethasone mediated abrogation of sepsis-induced cardiac dysfunction and protection during ischemia-reperfusion injury may be due to suppression of nitric oxide production.

The role of alcohol in the oxidant antioxidant balance in heart.

The myocardium, like other tissues, has enzyme and non-enzyme systems to neutralize free radicals. The enzymes superoxide dismutase, catalase and glutathione peroxidase and glutathione reductase as well as the non-enzyme antioxidants vitamin E and ascorbic acid are the main antioxidants. Oxidants are produced by the mitochondria under normal conditions and by other sources under pathologic conditions. The quantity of antioxidants present in the myocardium is matched to the production of oxygen free radicals that may be produced under basal physiological conditions. However, the myocardium can be exposed to increased levels of oxygen free radicals under conditions in which myocardial metabolism, i.e. mitochondrial oxidative phosphorylation, is accelerated to match the adenosine triphosphate utilized to support the increased work load on the heart or can be exposed to oxygen free radicals under pathologic conditions such as ischemia and reperfusion, inflammation, and cardiotoxic drugs such as anti-cancer agents. Under such circumstances the normal heart has been shown to increase its antioxidant production and to be, with time, protected from further sources of oxygen free radicals. In particular, hearts previously exposed to a stimulus to produce greater antioxidant levels show less damage during ischemia reperfusion injury presumably because of neutralization of oxygen free radicals. This review will present several situations in which the myocardium increases its tolerance to ischemia reperfusion injury as a result of an initial oxidative stress.

Intrinsic myocardial function in hemorrhagic shock.

Hemorrhage is a stress on the cardiovascular system that results in decreased loading of the heart but also decreased blood pressure and thus decreased perfusion pressure for tissue blood flow. The heart's response to hemorrhage is governed by both an increase in sympathetic nervous system activation of the heart and decreased preload and afterload for the heart. Whether the heart can maintain normal contractile function and reserves under conditions of prolonged hemorrhagic shock is not clear. To assess the effects of hemorrhagic shock of different lengths on intrinsic cardiac contractile function, guinea pigs were surgically prepared for the measurement of blood pressure, heart rate, and cardiac output and blood samples were taken for the measurement of metabolic indices of cardiovascular stress. Fifty percent of the animals' blood volume was removed and then animals were followed for 1, 2, or 3 h of hemorrhagic shock. Hearts were then removed for measurement of intrinsic contractile function. Hearts from animals exposed to 1 or 2 h of shock exhibited normal ventricular function although hearts removed after 3 h exhibited changes in ventricular function. Maintenance of normal cardiac function through at least 2 h of shock must represent adequate physiologic modulation of coronary blood flow to deliver adequate oxygen to match the myocardial oxygen demands under conditions of severe blood loss. This balance may be disrupted by 3 h of shock thus resulting in loss of contractile reserve.

Carnitine deprivation adversely affects cardiac performance in the lipopolysaccharide- and hypoxia/reoxygenation-stressed piglet heart.

Sepsis and hypoxia are important stressors for the neonate. Newborn infants receiving total parenteral nutrition are routinely deprived of carnitine and develop low carnitine plasma and tissue levels. Because of its high metabolic rate and dependence on fatty acids for energy, the newborn heart may be particularly vulnerable to stress in the face of an inadequate carnitine supply. To investigate whether carnitine deprivation affects cardiac performance under stress, 23 neonatal piglets received parenteral nutrition for 2-3 weeks that was either carnitine free (CARN -) or supplemented (CARN +) with L-carnitine (400 mg/L). Bacterial endotoxin (lipopolysaccharide (LPS), 250 microg/kg intravenous bolus) or saline vehicle was administered to anesthetized piglets 3 h prior to study of isolated perfused hearts. Left ventricular systolic pressure (LVSP), left ventricular end diastolic pressure, and left ventricular developed pressure (LVDP) were measured in vitro under aerobic, hypoxic, and reoxygenation conditions in all animals. Plasma and tissue carnitine values were lower in CARN - than in CARN + piglets. In hearts from LPS-treated animals prior to hypoxia, there was no difference in ventricular compliance between CARN - and CARN + groups. LVSP and LVDP were lower in CARN - than CARN + hearts. During hypoxia, LVSP and LVDP fell, but left ventricular end diastolic pressure increased in hearts from both LPS- and saline- treated piglets. Reoxygenation led to poorer recovery in CARN - than CARN + hearts from LPS-treated animals, but not from saline controls. During hypoxia/reoxygenation, lactate efflux initially rose and then fell, while carnitine efflux increased continually. Acetyl- and medium-chain acylcarnitines were detected in the coronary effluent. Our findings suggest that carnitine deprivation diminishes heart carnitine concentrations and impairs cardiac recovery from combined endotoxic and hypoxic stress. Possible mechanisms include reduced acyl buffering and/or impaired transport of fatty acyl groups into mitochondria.

Priming of Peyer's patch lymphoid cells by hemorrhagic shock and resuscitation to produce superoxide radical.

Hemorrhagic shock (HS) can cause whole body ischemia including the gastrointestinal tract. We investigated whether cells from small intestine Peyer's patches (PP) were capable of producing superoxide radical when animals underwent HS or HS followed by resuscitation (HS/RS). HS was initiated by removing 60% of the blood volume of surgically prepared guinea pigs. PP lymphoid cells were purified and stimulated with phorbol 12-myristate 13-acetate in the presence of spin trap 5-diethoxyphosphoryl-5-methyl-1-pyrroline-N-oxide (DEPMPO). Electron paramagnetic resonance spectra of PP lymphoid cells from sham-treated control, HS, and HS/RS animals produced DEPMPO radical adducts characterized as the adducts of superoxide (DEPMPO/*OOH) and hydroxyl (DEPMPO/*OH) radicals. The formation of both radical adducts was totally inhibited by superoxide dismutase or a nicotinamide adenine dinucleotide phosphate (reduced form) oxidase inhibitor, diphenyleneiodonium chloride. HS/RS increased radical adduct formation, expressed as a percentage control, by 160% and 225% for DEPMPO/*OOH, and DEPMPO/*OH, respectively. When animals were allowed to recover for 24 h post-HS/RS treatment, PP cells decreased the superoxide generation to the same level as controls. Thus, RS following HS may prime PP lymphoid cells for increased nicotinamide adenine dinucleotide phosphate (reduced form) oxidase-dependent superoxide generation, and this process may have cytotoxic and/or immunomodulatory effects on the host.

Myocardial dysfunction in the septic rat heart: role of nitric oxide.

Previous studies have demonstrated that sepsis, endotoxin, and cytokine administration cause myocardial dysfunction. Nitric oxide has been implicated in this dysfunction, since in isolated cardiac tissues, dysfunction is prevented when nitric oxide synthase (NOS) inhibitors are present. To determine whether nitric oxide produced by the inducible form of the enzyme (iNOS) contributed to Escherichia coli sepsis-induced myocardial dysfunction, the effects of preventing the induction of the enzyme or inhibiting the activity of the enzyme were determined. Rats, made septic by the injection of E. coil into the dorsal subcutaneous space, demonstrated a decreased intrinsic contractile function when hearts were studied the next day. Perfusion of hearts in vitro with the iNOS inhibitor S-methylisothiourea did not reverse the sepsis-induced contractile dysfunction. However, treatment of animals with S-methylisothiourea or dexamethasone, a glucocorticoid that prevents the synthesis of the iNOS, at the time of induction of sepsis resulted in partial but not complete attenuation of myocardial contractile dysfunction induced by sepsis. Thus, nitric oxide contributed to myocardial dysfunction in an intact animal treated with E. coli but was not the sole factor involved.

Carnitine deprivation adversely affects cardiovascular response to bacterial endotoxin (LPS) in the anesthetized neonatal pig.

Sepsis and endotoxemia are important stressors for the neonate. Newborn infants receiving total parenteral nutrition are routinely deprived of carnitine. To investigate whether carnitine deprivation affects the neonate's ability to respond to endotoxin, 19 newborn piglets received parenteral nutrition for 2-3 weeks that was either carnitine free (CARN-) or supplemented (CARN+) with L-carnitine (400 mg/L). Cardiovascular performance, i.e., heart rate; blood pressure (BP); cardiac output (CO); systemic vascular resistance (SVR), and metabolic response, i.e., plasma glucose; lactate; tumor necrosis factor alpha; tissue nitric oxide; and urinary nitrites, were studied serially in anesthetized piglets for 3 h after endotoxin (lipopolysaccharide (LPS), 250 microg/kg intravenous bolus) or vehicle administration. Plasma and tissue carnitine values were lower in CARN- than in CARN+ piglets. Prior to LPS, no differences were found for most parameters (excepting lower diastolic BP and SVR in CARN- animals). Systolic, diastolic, and mean BP fell after LPS but recovered by the end of the experiment. Nadirs were lower in CARN- than in CARN+ piglets. CO tended to be higher in CARN- than in CARN+ animals and fell after LPS. SVR fell after LPS and was lower in CARN- than in CARN+ piglets. LPS-treated animals transiently increased urinary flow. By all measures (plasma tumor necrosis factor alpha, glucose and lactate, tissue nitric oxide, and urinary nitrite excretion), LPS provocation was similar for both groups. Chronologically, BP changes were more closely related to SVR than to CO. Our findings suggest that carnitine deprivation diminishes tissue carnitine concentrations and adversely affects cardiovascular response to LPS, in part mediated by the peripheral vasculature.

The role of coronary flow and adenosine in postischemic recovery of septic rat hearts.

Sepsis depresses myocardial function but prevents subsequent ischemia-reperfusion injury. Elevated coronary flow (CF) and endogenous adenosine may be important factors in the complete recovery of postischemic myocardial function observed in septic rat hearts. The purpose of this study was to determine the effects of manipulating CF and of antagonizing adenosine receptors on the postischemic recovery of left ventricular developed pressure (LVDP) in septic and control rat hearts. The relationship between CF and LVDP in septic rat hearts before ischemia was depressed compared with control. However, this relationship was unaltered by ischemia in septic hearts, whereas in control hearts it was severely depressed. Preventing the elevation of CF during reperfusion did not significantly affect the recovery of LVDP in septic rat hearts. Adenosine antagonism by 8-phenyltheophylline (0.1 and 1 nM) prevented the elevated CF during reperfusion, and the higher dose significantly depressed postischemic function. We conclude that elevated CF did not contribute to the recovery of postischemic LVDP in septic rat hearts but that endogenous adenosine may provide protection from ischemia.

Modulation of the insulin-like growth factor system by chronic alcohol feeding.

Insulin-like growth factor (IGF)-I is a potent anabolic agent that plays an important role in regulating muscle protein balance. Alterations in one or more of the various components of the IGF system may be in part responsible for the muscle wasting that accompanies chronic alcohol consumption. The purpose of the present study was to characterize changes in the growth hormone-IGF axis produced by chronic alcohol consumption in rats. After 8 weeks of alcohol feeding, the IGF-I concentration was decreased in plasma (31%) as well as in the liver and skeletal muscle (40-50%), compared with pair-fed control animals. In addition, alcohol consumption decreased IGF-I mRNA abundance in liver and muscle (approximately 50%). IGF-I content in duodenum and kidney, however, was not altered by alcohol feeding. Concomitantly, the relative concentration of IGF binding protein (IGFBP)-1 was increased in plasma, liver, and muscle of alcohol-fed rats, compared with control values. In contrast, no changes in the plasma concentrations of IGFBP-2, -3, or -4 were detected in alcohol-fed rats at this time point Previous studies have indicated that elevations in glucocorticoids or decreases in insulin or growth hormone might be responsible for the decrease in IGF-I and/or the increase in IGFBP-1 in other catabolic conditions. However, there was no difference in the plasma concentrations of these hormones between alcohol-fed and control animals in this study. These data indicate that chronic alcohol feeding in rats decreases IGF-I and increases IGFBP-1 in the circulation and in skeletal muscle and that these changes appear to be independent of changes in classical hormonal regulators of the IGF system. The observed alterations in the IGF system are consistent with a reduction in the anabolic actions of IGF-I induced by chronic alcohol consumption.

The effects of Escherichia coli sepsis and short-term ischemia on coronary vascular reactivity and myocardial function.

Ischemia and reperfusion stun the myocardium and the coronary vasculature. We have previously shown that a short period (15 min) of global ischemia in the isolated rat heart causes impaired coronary constriction in response to a thromboxane analog U46619 during reperfusion. Sepsis has also been shown to affect myocardial and vascular function. In the present study, we determined whether Escherichia coli-induced sepsis would exacerbate the effects of ischemia on the coronary circulation. Sepsis prolonged the impairment in the coronary constriction response to U46619 following short term ischemia. We hypothesized that sepsis-induced increases in nitric oxide (NO) production caused the delay in the recovery of the contractile response to U46619. Perfusion with NO synthase inhibitors however indicated that the impaired response was not due to NO. However, NO did appear to have a significant role in the development of myocardial ischemic contracture and on the recovery of diastolic function after ischemia. Inhibitors of NO synthase also caused a significant increase in basal coronary perfusion pressure as well as in the maximum coronary pressure generated in response to U46619, suggesting a role of NO in regulating basal coronary vascular resistance in the isolated rat heart. Some of these effects were more pronounced in septic rat hearts than in the sham surgical rat hearts, consistent with altered nitric oxide production in the septic rat hearts.

Chronic alcohol consumption causes accelerated myocardial preconditioning to ischemia-reperfusion injury.

We have previously demonstrated that chronic alcohol consumption (8 to 10 weeks with ethanol as 36% of the caloric intake) does not exacerbate the effects of ischemia reperfusion injury on the heart. In those same studies, however, Gram-negative sepsis caused myocardial depression in both control and alcoholic rats, but also protected hearts from further damage due to ischemia-reperfusion. In the present study, we determined if preconditioning, a very short ischemia-reperfusion episode that protects the heart from more prolonged ischemia, would have similar effects on hearts from alcoholic and control rats with or without sepsis. Thus, rats were fed a liquid diet supplemented with ethanol or dextrin for 8 to 10 weeks. Some alcoholic and control rats were made septic with Escherichia coli injected into the subcutaneous space, whereas others received an injection of sterile saline. Isolated, isovolumically beating hearts were studied the following day. Hearts were made ischemic for 5 min, reperfused for 5 min, and then made ischemic for 35 min and reperfused for 25 min. Data from similar groups of hearts receiving only 35 min ischemia, and studied at the same time as the present groups, have been previously reported. The 5-min preconditioning episode was more effective in protecting hearts in the alcohol group than in the control group. Postischemic left ventricular developed pressure and +dP/dtmax were not significantly decreased from the preischemic values in the alcohol group, but were significantly decreased in the control group. The time to recovery of spontaneous contractions was decreased by preconditioning in the alcohol group but not in the control group, and the recovery of coronary flow was enhanced in the alcohol group, but not in the control group by pre-conditioning. Thus a single 5-min ischemic procedure was effective in protecting the heart from prolonged ischemia in the alcohol group, whereas it was not sufficient to elicit protection in the control group. Sepsis depressed preischemic function in both groups, but recovery from ischemia was complete.

Effect of chronic alcohol consumption by rats on tumor necrosis factor-alpha and interleukin-6 clearance in vivo and by the isolated, perfused liver.

The effects of chronic (16-week) alcohol consumption by rats on [125I] tumor necrosis factor (TNF)-alpha and [125I]interleukin (IL)-6 plasma clearance and organ distribution in vivo and uptake and metabolism by the isolated, perfused liver were studied. Alcohol was administered to rats in a liquid diet for 16 weeks, and caused a decreased (48%) plasma clearance rate of IL-6 and converted the plasma clearance kinetics of the cytokine from a biphasic exponential in normal rats to a monophasic exponential decay. Alcohol feeding significantly increased (101%) plasma clearance of TNF-alpha, which followed a biphasic exponential decay and decreased the T1/2 for both the alpha (67%) and beta (76%) elimination components. The distribution of both cytokines in trichloroacetic acid precipitable and non-precipitable fractions of liver, spleen, stomach, small intestine (ileum), lung, kidney, and blood was also studied. The only effect of alcohol treatment was a significant decrease in IL-6 uptake and metabolism by the small intestine. Perfused livers, isolated from alcohol-fed rats, took up and metabolized larger amounts of IL-6 than did livers isolated from pair-fed rats. TNF-alpha uptake and metabolism by the isolated, perfused liver were not affected by chronic alcohol consumption. Regardless of the animal treatment, the isolated perfused liver took up and metabolized significantly larger (17-fold) amounts of TNF-alpha than IL-6, in spite of identical concentrations of cytokines (6 nM) in the perfusion medium. The data presented in this study along with our previous results demonstrating the effects of alcohol consumption on TNF-alpha and IL-6 receptors on various liver cells suggest that the effects of chronic alcohol treatment on cytokine clearance cannot be ascribed to changes in the receptors for the two cytokines. Also, no correlation was found between the effects of alcohol treatment on plasma cytokine clearance and uptake and metabolism of cytokines by the isolated, perfused liver. Experimental data and theoretical considerations suggest that cytokine receptor recycling may play an important role in mediating alcohol effects on cytokine clearance.

Interleukin-6 tumor necrosis factor-alpha clearance and metabolism in vivo and by the isolated, perfused liver in the rat: effect of acute alcohol administration.

Plasma clearance and organ distribution of intravenously injected human recombinant [125I]interleukin (IL)-6 and [125I]tumor necrosis factor (TNF)-alpha were studied in male rats, 2 hr after intravenous alcohol (ethanol) administration (single dose, 2.2 g.kg-1 body weight). Also, the rate of uptake and degradation of the two cytokines by the isolated, perfused rat liver was studied in the absence or in the presence of ethanol (35 mM) in the perfusate. Acute ethanol administration significantly increased plasma clearance rate for both cytokines (36% and 72%, for IL-6 and TNF-alpha, respectively), decreased the t1/2 alpha (30% and 11%, for IL-6 and TNF-alpha, respectively), abolished the slow (beta)-phase component for TNF-alpha, and increased t1/2 beta for IL-6 (31%). Although alcohol did not affect organ distribution of TNF-alpha, it increased the IL-6 content in the liver, kidney, and blood. IL-6 uptake rate by the isolated, perfused rat liver was 2-fold higher than TNF-alpha uptake, whereas the rate of degradation was larger for TNF-alpha than for IL-6, despite the fact that both cytokines were presented to the liver at the same concentration (6 nM). Ethanol addition to the perfusate (35 mM, final concentration) significantly increased TNF-alpha uptake (24%), without affecting IL-6 uptake or the degradation rate of either cytokine. Also, the kinetics of degradation by the isolated, perfused rat liver was linear for TNF-alpha, but exponential for IL-6. Data presented in this study demonstrate that: (1) acute alcohol consumption can alter the kinetic behavior of IL-6 and TNF-alpha in the bloodstream, mainly by accelerating their clearance which, in turn, may counteract the outcome of cytokine secretion and delivery to the blood; and (2) short exposure of liver to ethanol levels commonly seen in humans after binge drinking may alter its capacity to take up cytokines.

Effects of endotoxin on the guinea pig heart response to ischemia reperfusion injury.

Ischemia causes significant damage to the heart as manifested by decreases in ventricular performance. Several different methods have been shown to protect the heart from ischemic injury--one is operative over a short period (an hour) and the other over longer periods (a day). The latter form of protection has been demonstrated in rats after induction of Gram-negative sepsis or administration of endotoxin or cytokines. In the present study we determined whether guinea pigs would also show induction of cardiac protection subsequent to a dose of endotoxin. Male guinea pigs were injected with 1 mg of endotoxin and studied the following day. Hearts were perfused at a constant perfusion pressure and studied in an isovolumic mode. Left ventricular developed pressure was significantly lower in the endotoxin-treated group than in the control group. After 35 min of total ischemia and 25 min of reperfusion, recovery of left ventricular developed pressure was complete in the endotoxin group but significantly decreased in the control group such that after ischemia and reperfusion, there was no significant difference in left ventricular performance between the two groups. Coronary flow was significantly greater in the endotoxin group than in the control group both prior to and after ischemia. Hearts from endotoxin-treated guinea pigs resumed spontaneous contractile activity sooner and released less lactate upon reperfusion than did the control group. Thus prior treatment of guinea pigs with endotoxin resulted in depression of the isolated heart but also resulted in protection of the isolated heart from further damage due to ischemia/reperfusion injury.