R.J. Nijveldt

Accurate prediction of xanthine oxidase inhibition based on the structure of flavonoids.

The flavonoid family shows a high potential for inhibition of xanthine oxidase. Currently, more than 4,000 flavonoids are known. The data of this study indicate that a planar structure is necessary for high inhibitory activity towards xanthine oxidase. Moreover, the contribution of a hydroxyl conjugate turns out to be a constant factor when the natural logarithm of IC(50) values is taken. This finding allows us to accurately predict the IC(50) value of any given hydroxyl group added to the basic flavone structure towards xanthine oxidase. This new method may provide an important research tool for elucidating the role that flavonoids may have in radical related diseases.

The human liver clears both asymmetric and symmetric dimethylarginine

Asymmetric (ADMA) and symmetric dimethylarginine (SDMA) inhibit production of nitric oxide. The concentration of both dimethylarginines is regulated by urinary excretion, although ADMA, but not SDMA, is also subject to degradation by dimethylarginine dimethylaminohydrolase, which is highly expressed in the liver but also present in the kidney. The exact roles of the human liver and kidney in the metabolism of dimethylarginines are currently unknown. Therefore, we aimed to investigate renal and hepatic handling of ADMA and SDMA in detail in 24 patients undergoing hepatic surgery. To calculate net organ fluxes and fractional extraction (FE) rates, blood was collected from an arterial line, the portal vein, hepatic vein, and renal vein, and blood flow of the hepatic artery, portal vein, and renal vein was determined using Doppler ultrasound techniques. Results showed a significant net uptake (median [IQR]) of ADMA in both the liver (9.6 nmol/min [5.6–13.2]) and the kidney (12.1 nmol/min [1.3–17.1]). SDMA uptake was present not only in the kidney (12.7 nmol/min [3.5–25.4]), but also in the liver (7.7 nmol/min [2.8–16.4]). FE rates of ADMA for the liver and kidney were 5.0% (3.5%–7.4%) and 8.4% (1.3%–13.9%), respectively. For SDMA, hepatic and renal FE rates were 3.4% (2.1%–7.5%) and 12.5% (3.6%–16.2%), respectively. In conclusion, this study gives a detailed description of the hepatic and renal elimination of dimethylarginines and shows that the clearing of SDMA is not only confined to the kidney, but the human liver also takes up substantial amounts of SDMA from the portal and systemic circulation. (HEPATOLOGY 200541:559–565.)

Low plasma concentrations of arginine and asymmetric dimethylarginine in premature infants with necrotizing enterocolitis

Several studies have described reduced plasma concentrations of arginine, the substrate for nitric oxide synthase (NOS) in infants with necrotizing enterocolitis (NEC). No information on the plasma concentrations of the endogenous NOS inhibitor asymmetric dimethylarginine (ADMA) in patients with NEC is currently available. We investigated whether plasma concentrations of arginine, ADMA, and their ratio differ between premature infants with and without NEC, and between survivors and non-survivors within the NEC group. In a prospective case-control study, arginine and ADMA concentrations were measured in ten premature infants with NEC (median gestational age 193 d, birth weight 968 g), and ten matched control infants (median gestational age 201 d, birth weight 1102 g), who were admitted to the Neonatal Intensive Care Unit. In the premature infants with NEC, median arginine and ADMA concentrations (micromol/l), and the arginine:ADMA ratio were lower compared to the infants without NEC: 21.4 v. 55.9, P= 0.001; 0.59 v. 0.85, P=0.009 and 36.6 v. 72.3, P=0.023 respectively. In the NEC group, median arginine (micromol/l) and the arginine:ADMA ratio were lower in non-surviving infants than in surviving infants: 14.7 v. 33.8, P=0.01 and 32.0 v. 47.5, P=0.038 respectively. In premature infants with NEC not only the NOS substrate arginine, but also the endogenous NOS inhibitor ADMA and the arginine:ADMA ratio were lower than in infants without NEC. In addition, low arginine and arginine:ADMA were associated with mortality in infants with NEC. Overall, these data suggest that a diminished nitric oxide production may be involved in the pathophysiology of NEC, but this needs further investigation.

The transplanted liver graft is capable of clearing asymmetric dimethylarginine

Asymmetric dimethylarginine (ADMA) has been recognized as an endogenous inhibitor of the arginine–nitric oxide (NO) pathway. Its concentration is tightly regulated by urinary excretion and degradation by the enzyme dimethylarginine dimethylaminohydrolase (DDAH), which is highly expressed in the liver. Considering the liver as a crucial organ in the clearing of ADMA, we hypothesized increased ADMA levels during hepatic failure and, consequently, a decline of ADMA concentrations after successful liver transplantation. The aim of the present study was to investigate the role of the liver in the metabolism of ADMA in patients undergoing liver transplantation. In this prospective study, we investigated the course of ADMA concentrations in 42 patients undergoing liver transplantation and results showed that preoperative ADMA concentrations were higher in patients with acute (1.26 μmol/L, P < .001) and in patients with chronic (.69 μmol/L, P < .001) hepatic failure compared with healthy volunteers (.41 μmol/L). In addition, ADMA concentrations decreased from the preoperative day to the first postoperative day in both the acute (ΔADMA: −.63 μmol/L, P = .005) and the chronic hepatic failure group (ΔADMA: −0.15 μmol/L, P < .001). Furthermore, in patients who experienced acute rejection, ADMA concentrations were higher during the whole first postoperative month compared with nonrejectors (P = .012). Moreover, in 11 of 13 rejectors (85%) a clear increase in ADMA concentration preceded the onset of the first episode of rejection, which was confirmed by liver biopsy. In conclusion, our results indicate that the transplanted liver graft is quickly capable of clearing ADMA, suggesting preservation of DDAH. In addition, increased ADMA concentrations in the posttransplantation period reflect serious dysfunction of the liver graft during acute rejection. (Liver Transpl 2004;10:1524–1530.)

Preoperative Fasting: An Outdated Concept?

Recent studies have shown that fasting during the preoperative period for elective surgery induces a metabolic state that seems unfavorable for patients. Results from animal studies indicate that rapid depletion of liver glycogen before surgery leads to mobilization of muscle glycogen after surgery, in turn leading to reduced muscle strength. Depletion of liver glycogen also influences the function of the mononuclear phagocytic system (MPS), which is located predominantly in the liver. The MPS is essential in restricting endotoxin, which may translocate from the gut. In addition, surgery per se puts a substantial physical strain on the patient, and fasting may adversely affect the metabolic response to surgery. This paper presents experimental and clinical data that, when combined together, prove that fasting before surgery has adverse consequences for the patient.

Elimination of Asymmetric Dimethylarginine by the Kidney and the Liver: A Link to the Development of Multiple Organ Failure?

Asymmetric dimethylarginine (ADMA) is a recently recognized endogenous inhibitor of nitric oxide production. Its role in cardiovascular disease is emerging, and ADMA appears to be an important causal factor in dysfunction of the vascular system. Several studies show that ADMA accumulates during renal failure, and ADMA has been identified as causing the cardiovascular complications accompanying renal failure. In addition to the kidney, we recently suggested an important role for the liver as an ADMA-eliminating organ. In a population of critically ill patients, hepatic failure was the most prominent determinant of ADMA concentration, and, notably, high ADMA concentration proved to be a strong and independent risk factor for intensive care unit mortality in these patients. We here summarize the role of both the kidney and the liver in the regulation of ADMA levels. In addition, the potential central role of ADMA as a causative factor in the development of multiple organ failure is discussed.

Use of a mixture of medium-chain triglycerides and long-chaintriglycerides versus long-chain triglycerides in critically ill surgical patients: a randomized prospective double-blind study

Twenty critically-ill surgical patients who needed total parenteral nutrition were randomly enrolled in a double-blind study comparing two intravenous fat emulsions: one containing a mixture of 50% medium-chain triglycerides and 50% long-chain triglycerides and another containing 100% longchain triglycerides. The purpose of this study was to investigate metabolic and biochemical differences between both emulsions with special reference to liver enzymes. After a baseline period of 24 h with only glucose and NaCl infusion, the lipid emulsion was added continuously during 24 h over 5 days. The parenteral nutrition was administered in mixture bags containing amino-acids, glucose and lipids together. Two-thirds of the non-protein calories were administered as glucose 40% and one third as either long-chain triglycerides or a mixture of medium-chain triglycerides and long-chain triglycerides. The total amount of non-protein calories received was the measured energy expenditure during the baseline period plus 10% and was fixed during the study. Plasma substrate concentrations, energy expenditure, and nitrogen balance were determined and arterial blood samples were taken. No toxic effects or complications attributable to one of the two emulsions were observed. There was no significant difference in energy expenditure, nitrogen balance, liver function tests, carnitine, transferrin, pre-albumin, albumin, cholesterol, triglycerides and free fatty acids. The only parameter that showed a different pattern of reaction between the two emulsions was serum bilirubin concentration. In this study no evidence of any advantageous effect of a mixture of medium-chain triglycerides and long-chain triglycerides was seen.

Low arginine plasma levels in patients after thoracoabdominal aortic surgery

Objective: Thoracoabdominal aortic surgery is a high-risk procedure and associated with a significant morbidity and mortality. Ischemia reperfusion of visceral organs and lower extremities is one of the most important determinants of this morbidity. Arginine is the precursor of nitric oxide and arginine plasma levels are important in maintaining organ blood flow. Furthermore, arginine is important in wound healing and the immune system. Because of increased utilization of arginine, low arginine plasma levels could be expected after thoracoabdominal aortic surgery. We therefore measured arginine plasma levels in these patients.Design: Six patients with thoracoabdominal aortic aneurysm were included in this study.Setting: University Hospital Vrije Universiteit, Department of Surgery, Amsterdam, The Netherlands.Subjects: Six patients undergoing thoracoabdominal aortic surgery.Intervention: Plasma levels of arginine were measured by high-performance liquid chromatography.Results: Very low arginine plasma levels were seen on the first postoperative day. From day 1 arginine slowly increased, but did not reach normal plasma levels on day 6.Conclusions: A significant decrease of arginine plasma levels was found and because of the fact that arginine has multiple functions, it may be important to keep these arginine plasma levels at normal or even higher levels in patients undergoing major vascular surgery.European Journal of Clinical Nutrition (2000) 54, 615–617.

High plasma arginine concentrations in critically ill patients suffering from hepatic failure

Objective: In physiological conditions, the liver plays an important role in the regulation of plasma arginine concentrations by taking up large amounts of arginine from the hepatic circulation. When hepatic failure is present, arginine metabolism may be disturbed. Therefore, we hypothesized high arginine plasma concentrations in critically ill patients suffering from hepatic failure.Design: We prospectively collected blood samples from a cross-section of intensive care unit patients.Setting: Surgical intensive care unit of a Dutch university medical center.Subjects: A total of 52 critically ill patients with clinical evidence of dysfunction of more than two organs were recruited.Measurements: Plasma arginine concentrations were determined by HPLC. We identified correlations of arginine concentrations with organ failure scores and laboratory variables by univariate and multiple regression analyses.Results: High plasma arginine concentrations were found in critically ill patients developing organ failure. Patients who were in the highest quartile of plasma arginine concentrations had significantly lower fibrinogen concentrations, higher lactic acid concentrations, and longer prothrombin time. Stepwise multiple regression analysis showed that concentrations of arginine were independently associated with the presence of hepatic failure (P=0.03) and renal failure (P=0.048). In addition, lactic acid proved to be an independent determinant of plasma arginine concentration (P=0.014).Conclusions: Critically ill patients who suffer from hepatic failure have elevated plasma arginine concentrations. Additional arginine in the treatment of these patients can be harmful, and therefore should not be used as a standard nutritional regimen until further evaluation.

The effect of mild endotoxemia during low arginine plasma levels on organ blood flow in rats

Objective Arginine is the sole precursor in the generation of the vasodilating agent nitric oxide. Arginine plasma levels are low in situations associated with endotoxemia such as major trauma, sepsis, and experimental obstructive jaundice. The aim of the study was to evaluate hemodynamics at low arginine plasma levels during a low-grade endotoxemia. Design Randomized, placebo-controlled animal laboratory investigation. Subjects Male Wistar rats (n = 29), anesthetized. Interventions Rats were randomly assigned to receive (at t = 0 mins) an intravenous infusion of 1.5 mL of 0.9% NaCl (SAL, n = 12) or 1.5 mL of an arginase (3200 IU) solution (ASE, n = 17) over a 20-min period. After the SAL or ASE infusion, rats were randomly assigned to receive an intravenous endotoxin (lipopolysaccharide [LPS], 150 &mgr;g/kg in 1.0 mL of 0.9% NaCl; ASE/LPS, n = 10 and SAL/LPS, n = 6) challenge or a control infusion (1.0 mL of 0.9% NaCl; ASE/SAL, n = 7 and SAL/SAL, n = 6) at t = 30 mins. Measurements and Main Results Organ blood flow was measured at t = 270 mins, using radiolabeled microspheres. At this time point, arginine plasma levels were lower in the ASE-treated rats (ASE/SAL vs. SAL/SAL and ASE/LPS vs. SAL/LPS, both p < .005, respectively). Cardiac output, mean arterial pressure, and therefore total peripheral resistance were similar for all groups. In the LPS-treated animals (SAL/LPS and ASE/LPS), cardiac output was maintained by a higher heart rate compensating the lower stroke volume. Organ blood flow to the small intestine and splanchnic blood flow was lower in the ASE/LPS-treated rats (both p < .05 when compared with other groups). Total liver blood flow was similar for all groups; the lower splanchnic blood flow was compensated for by a higher hepatic arterial blood flow. Conclusion The present study shows that low arginine plasma levels do not influence organ blood flow, whereas, during a low-grade endotoxemia, low arginine plasma levels result in reduced blood flow to the small intestine.