Gerd Albuszies

Glucose metabolism and catecholamines.

Until now, catecholamines were the drugs of choice to treat hypotension during shock states. Catecholamines, however, also have marked metabolic effects, particularly on glucose metabolism, and the degree of this metabolic response is directly related to the &bgr;2-adrenoceptor activity of the individual compound used. Under physiologic conditions, infusing catecholamine is associated with enhanced rates of aerobic glycolysis (resulting in adenosine triphosphate production), glucose release (both from glycogenolysis and gluconeogenesis), and inhibition of insulin-mediated glycogenesis. Consequently, hyperglycemia and hyperlactatemia are the hallmarks of this metabolic response. Under pathophysiologic conditions, the metabolic effects of cate-cholamines are less predictable because of changes in receptor affinity and density and in drug kinetics and the metabolic capacity of the major gluconeogenic organs, both resulting from the disease per se and the ongoing treatment. It is also well-established that shock states are characterized by a hypermetabolic condition with insulin resistance and increased oxygen demands, which coincide with both compromised tissue microcirculatory perfusion and mitochondrial dysfunction. This, in turn, causes impaired glucose utilization and may lead to inadequate glucose supply and, ultimately, metabolic failure. Based on the landmark studies on intensive insulin use, a crucial role is currently attributed to glucose homeostasis. This article reviews the effects of the various catecholamines on glucose utilization, both under physiologic conditions, as well as during shock states. Because, to date (to our knowledge), no patient data are available, results from relevant animal experiments are discussed. In addition, potential strategies are outlined to influence the catecholamine-induced effects on glucose homeostasis.

Effect of increased cardiac output on hepatic and intestinal microcirculatory blood flow, oxygenation, and metabolism in hyperdynamic murine septic shock

Objective:Septic shock-associated organ dysfunction is attributed to derangements of microcirculatory perfusion and/or impaired cellular oxygen utilization. The hepatosplanchnic organs are regarded to play a pivotal role in the pathophysiology of sepsis-related organ failure. In a murine model of septic shock, we tested the hypothesis whether achieving normotensive, hyperdynamic hemodynamics characterized by a sustained increase in cardiac output would allow maintenance of regional microvascular perfusion and oxygenation and, thus, hepatic metabolic capacity. Design:Prospective, controlled, randomized animal study. Setting:University animal research laboratory. Subjects:Male C57Bl/6 mice. Interventions:Fifteen hours after sham operation (n = 11) or cecal ligation and puncture (CLP) (n = 9), mice were anesthetized, mechanically ventilated, and instrumented (central venous and left ventricular pressure-conductance catheter, portal vein and superior mesenteric artery ultrasound flow probes). Animals received continuous intravenous hydroxyethylstarch and norepinephrine to achieve normotensive and hyperdynamic hemodynamics, and glucose was infused to maintain normoglycemia. Measurements and Main Results:Measurements were recorded 18, 21, and 24 hrs post-CLP. In CLP mice, titration of hemodynamic targets were affiliated superior mesenteric artery and portal vein flow. Using a combined laser-Doppler flowmetry and remission spectrophotometry probe, we found well-maintained gut and liver capillary perfusion as well as intestinal microcirculatory hemoglobin oxygen saturation, whereas hepatic microcirculatory hemoglobin oxygen saturation was even increased. At 24 hrs post-CLP, the rate of de novo gluconeogenesis as derived from hepatic 13C-glucose isotope enrichment after continuous intravenous 1,2,3,4,5,6-13C6-glucose infusion (condensation biosynthesis modeling after gas chromatography-mass spectrometry isotope measurements) was similar in the two experimental groups. Conclusions:During murine septic shock achieving normotensive hyperdynamic hemodynamics with fluid resuscitation and norepinephrine, exogenous glucose requirements together with the lack of norepinephrine-induced increase in the rate of gluconeogenesis mirror impaired metabolic capacity of the liver despite well-maintained hepatosplanchnic microvascular perfusion and oxygenation.

Cardiac and metabolic effects of hypothermia and inhaled hydrogen sulfide in anesthetized and ventilated mice.

Objective: To test the hypothesis whether inhaled hydrogen sulfide amplifies the effects of deliberate hypothermia during anesthesia and mechanical ventilation as hypothermia is used to provide organ protection after brain trauma or circulatory arrest. Awake mice inhaling hydrogen sulfide exhibit reduced energy expenditure, hypothermia, and bradycardia despite unchanged systolic heart function. In rodents, anesthesia alone causes decreased metabolic rate and thus hypothermia and bradycardia. Design: Prospective, controlled, randomized study. Setting: University animal research laboratory. Subjects: Male C57/B6 mice. Interventions: After surgical instrumentation (central venous, left ventricular pressure-conductance catheters, ultrasound flow probes on the portal vein and superior mesenteric artery), normo- or hypothermic animals (core temperature = 38°C and 27°C) received either 100 ppm hydrogen sulfide or vehicle over 5 hrs (3 hrs hydrogen sulfide during normothermia). Measurements and Main Results: During normothermia, hydrogen sulfide had no hemodynamic or metabolic effect. With or without hydrogen sulfide, hypothermia decreased blood pressure, heart rate, and cardiac output, whereas stroke volume, ejection fraction, and end-diastolic pressure remained unaffected. Myocardial and hepatic oxidative deoxyribonucleic acid damage (comet assay) and endogenous glucose production (rate of appearance of 1,2,3,4,5,6-13C6-glucose) were similar in all groups. Hypothermia comparably decreased CO2 production with or without inhaled hydrogen sulfide. During hypothermia, inhaled hydrogen sulfide increased the glucose oxidation rate (derived from the expiratory 13CO2/12CO2 ratio). This shift toward preferential carbohydrate utilization coincided with a significantly attenuated responsiveness of hepatic mitochondrial respiration to stimulation with exogenous cytochrome-c-oxidase (high-resolution respirometry). Conclusions: In anesthetized and mechanically ventilated mice, inhaled hydrogen sulfide did not amplify the systemic hemodynamic and cardiac effects of hypothermia alone. The increased aerobic glucose oxidation together with the reduced responsiveness of cellular respiration to exogenous cytochrome-c stimulation suggest that, during hypothermia, inhaled hydrogen sulfide improved the yield of mitochondrial respiration, possibly via the maintenance of mitochondrial integrity. Hence, inhaled hydrogen sulfide may offer metabolic benefit during therapeutic hypothermia.

The effect of superoxide dismutase overexpression on hepatic gluconeogenesis and whole-body glucose oxidation during resuscitated normotensive murine septic shock.

ABSTRACT Besides excess cytokine and NO production, enhanced oxygen radical formation was referred to contribute to the impaired hepatic gluconeogenesis during sepsis or endotoxemia. Therefore, we tested the hypothesis that genetic overexpression of the Cu/Zn-superoxide dismutase (SOD-1) may restore the sepsis-related lack of the norepinephrine-induced increase in hepatic gluconeogenesis and whole-body glucose oxidation. Anesthetized, ventilated, and instrumented wild-type control, and heterozygous and homozygous SOD-1-overexpressing mice received hydroxyethyl starch and norepinephrine to maintain normotensive hemodynamics measured at 18, 21, and 24 h after cecal ligation and puncture (CLP) or sham operation. Hepatic gluconeogenesis and whole-body glucose oxidation were calculated from liver tissue isotope and expiratory 13CO2 enrichments during continuous i.v. 1,2,3,4,5,6-13C6-glucose. Superior mesenteric artery and portal vein flows (ultrasound flow probes) and hepatic microcirculatory perfusion (Laser Doppler flowmetry) and O2 saturation (remission spectrophotometry) were comparable in the CLP and sham-operated animals, without any difference related to the mouse strain. Despite continuous i.v. norepinephrine necessary in the CLP mice, both glycemia and hepatic gluconeogenesis were similar, irrespective of the presence of sepsis and the genetic strain. Glucose oxidation rate progressively increased in the CLP groups, again without difference between the genetic strains. The surgery- and CLP-induced increase in liver cell oxidative DNA damage (tail moment in the comet assay) was less pronounced in the homozygous mice. Heterozygous nor homozygous SOD-1 overexpression did not improve the sepsis-related impairment of carbohydrate metabolism, possibly because of the lacking increase of the tissue catalase and the mitochondrial SOD activity, and the ongoing i.v. norepinephrine.

FRACTIONAL SYNTHESIS OF INDIVIDUAL HEPATIC PROTEINS UNDER SEPTIC SHOCK

TOWARDS RESOLVING THE CHALLENGE OF SEPSIS DIAGNOSTIC. Thomas Herget* and Thomas Joos . *Merck KGaA, Darmstadt, Germany; NMI Natural and Medical Sciences Institute at the University of Tübingen, Reutlingen, Germany Biomarkers have proven to be very useful in clinical conditions such as heart attack, stroke and cancer. There are characteristics linked to sepsis like in blood pressure, body temperature and heart rate. Efforts over the last decade to improve diagnosis for infectious inflammation have been unsuccessful in identifying a single and universal biomarker that provides sufficiently high sensitivity and specificity. In gramnegative septicemia and following major abdominal trauma, the determination of endotoxin continues to be a leading candidate which could become adopted into clinical practice. The importance of endotoxin measurement continues to grow as more clinicians recognize the added value of measuring endotoxin in critically ill patients and with the emergence of major pharmaceutical trials directly targeting endotoxin in the bloodstream. However, hundreds of other candidates potentially serving as biomarker for sepsis have been recently described, e.g. cysteinyl-leukotriene (LTC4) generation, procalcitonin (PCT) and C-reactive protein (CRP). However, none of them fulfils the criteria requested by clinicians, namely being specific and sensitive. The presentation will discuss criteria for a sepsis biomarker, will give an overview of obtaining samples from appropriate cell systems and from patients. Furthermore, tools will be described to identify marker candidates on genetic-, proteinand metabolite level. The integration of these data sets covering e.g. signal transduction, protein : protein interaction, gene expression with the help of bioinformatics and systems biology will help to validate such candidates. The final goal is manufacturing a robust diagnostic device for clinical routine work. A solid sepsis diagnostics method will be beneficial for patients, but also for the healthcare systems and will open challenges for the pharmaceutical industry.

GLUCOSE OXIDATION IN MURINE SEPTIC SHOCK: A ROLE FOR SUPEROXIDE DISMUTASE?

TOWARDS RESOLVING THE CHALLENGE OF SEPSIS DIAGNOSTIC. Thomas Herget* and Thomas Joos . *Merck KGaA, Darmstadt, Germany; NMI Natural and Medical Sciences Institute at the University of Tübingen, Reutlingen, Germany Biomarkers have proven to be very useful in clinical conditions such as heart attack, stroke and cancer. There are characteristics linked to sepsis like in blood pressure, body temperature and heart rate. Efforts over the last decade to improve diagnosis for infectious inflammation have been unsuccessful in identifying a single and universal biomarker that provides sufficiently high sensitivity and specificity. In gramnegative septicemia and following major abdominal trauma, the determination of endotoxin continues to be a leading candidate which could become adopted into clinical practice. The importance of endotoxin measurement continues to grow as more clinicians recognize the added value of measuring endotoxin in critically ill patients and with the emergence of major pharmaceutical trials directly targeting endotoxin in the bloodstream. However, hundreds of other candidates potentially serving as biomarker for sepsis have been recently described, e.g. cysteinyl-leukotriene (LTC4) generation, procalcitonin (PCT) and C-reactive protein (CRP). However, none of them fulfils the criteria requested by clinicians, namely being specific and sensitive. The presentation will discuss criteria for a sepsis biomarker, will give an overview of obtaining samples from appropriate cell systems and from patients. Furthermore, tools will be described to identify marker candidates on genetic-, proteinand metabolite level. The integration of these data sets covering e.g. signal transduction, protein : protein interaction, gene expression with the help of bioinformatics and systems biology will help to validate such candidates. The final goal is manufacturing a robust diagnostic device for clinical routine work. A solid sepsis diagnostics method will be beneficial for patients, but also for the healthcare systems and will open challenges for the pharmaceutical industry.

DOES SUPEROXIDE DISMUTASE PROTECT AGAINST OXIDATIVE STRESS-INDUCED DNA DAMAGE IN MURINE SEPTIC SHOCK?

TOWARDS RESOLVING THE CHALLENGE OF SEPSIS DIAGNOSTIC. Thomas Herget* and Thomas Joos . *Merck KGaA, Darmstadt, Germany; NMI Natural and Medical Sciences Institute at the University of Tübingen, Reutlingen, Germany Biomarkers have proven to be very useful in clinical conditions such as heart attack, stroke and cancer. There are characteristics linked to sepsis like in blood pressure, body temperature and heart rate. Efforts over the last decade to improve diagnosis for infectious inflammation have been unsuccessful in identifying a single and universal biomarker that provides sufficiently high sensitivity and specificity. In gramnegative septicemia and following major abdominal trauma, the determination of endotoxin continues to be a leading candidate which could become adopted into clinical practice. The importance of endotoxin measurement continues to grow as more clinicians recognize the added value of measuring endotoxin in critically ill patients and with the emergence of major pharmaceutical trials directly targeting endotoxin in the bloodstream. However, hundreds of other candidates potentially serving as biomarker for sepsis have been recently described, e.g. cysteinyl-leukotriene (LTC4) generation, procalcitonin (PCT) and C-reactive protein (CRP). However, none of them fulfils the criteria requested by clinicians, namely being specific and sensitive. The presentation will discuss criteria for a sepsis biomarker, will give an overview of obtaining samples from appropriate cell systems and from patients. Furthermore, tools will be described to identify marker candidates on genetic-, proteinand metabolite level. The integration of these data sets covering e.g. signal transduction, protein : protein interaction, gene expression with the help of bioinformatics and systems biology will help to validate such candidates. The final goal is manufacturing a robust diagnostic device for clinical routine work. A solid sepsis diagnostics method will be beneficial for patients, but also for the healthcare systems and will open challenges for the pharmaceutical industry.

THE ROLE OF iNOS FOR HEPATIC GLUCOSE PRODUCTION IN MURINE SEPTIC SHOCK

TOWARDS RESOLVING THE CHALLENGE OF SEPSIS DIAGNOSTIC. Thomas Herget* and Thomas Joos . *Merck KGaA, Darmstadt, Germany; NMI Natural and Medical Sciences Institute at the University of Tübingen, Reutlingen, Germany Biomarkers have proven to be very useful in clinical conditions such as heart attack, stroke and cancer. There are characteristics linked to sepsis like in blood pressure, body temperature and heart rate. Efforts over the last decade to improve diagnosis for infectious inflammation have been unsuccessful in identifying a single and universal biomarker that provides sufficiently high sensitivity and specificity. In gramnegative septicemia and following major abdominal trauma, the determination of endotoxin continues to be a leading candidate which could become adopted into clinical practice. The importance of endotoxin measurement continues to grow as more clinicians recognize the added value of measuring endotoxin in critically ill patients and with the emergence of major pharmaceutical trials directly targeting endotoxin in the bloodstream. However, hundreds of other candidates potentially serving as biomarker for sepsis have been recently described, e.g. cysteinyl-leukotriene (LTC4) generation, procalcitonin (PCT) and C-reactive protein (CRP). However, none of them fulfils the criteria requested by clinicians, namely being specific and sensitive. The presentation will discuss criteria for a sepsis biomarker, will give an overview of obtaining samples from appropriate cell systems and from patients. Furthermore, tools will be described to identify marker candidates on genetic-, proteinand metabolite level. The integration of these data sets covering e.g. signal transduction, protein : protein interaction, gene expression with the help of bioinformatics and systems biology will help to validate such candidates. The final goal is manufacturing a robust diagnostic device for clinical routine work. A solid sepsis diagnostics method will be beneficial for patients, but also for the healthcare systems and will open challenges for the pharmaceutical industry.

Effects of epinephrine on glucose metabolism in patients with alcoholic liver cirrhosis

ConclusionIn contrast to its preserved stimulatory effect on lipolysis epinephrine failed to enhance hepatic glucose production in cirrhotic patients. Since this blunted response was not related to changes of ß-adrenoreceptors our findings suggest that epinephrine resistance in cirrhosis was due to a postreceptor defect.