Hepatic transit time of ultrasound contrast in biopsy characterized liver disease.

PURPOSE: To study the hepatic transit time of an ultrasound contrast agent in patients with liver disease, and to evaluate the mechanism(s) of the well-established shorter cubital vein to hepatic vein transit time in cirrhosis. MATERIAL AND METHODS: Thirty-four patients scheduled for Menghini liver biopsy were studied by ultrasound after injection of 2.5 g Levovist (Schering, Berlin, Germany) into an arm vein. The time from injection until the first appearance of contrast echoes in the hepatic artery and hepatic veins was registered. Hepatic transit time was the difference between the two. RESULTS: Biopsy showed cirrhosis in 9 patients, other diffuse hepatic pathology in 23 patients, and normal liver in 2 patients. Mean hepatic vein arrival time was earlier in cirrhosis than in other liver disease (19.4 s versus 26.0 s; P = 0.013), and hepatic transit time was shorter (6.6 s versus 11.6 s; P = 0.024). A hepatic transit time <10 s was found in all patients with cirrhosis, but also in 10 of 23 patients with other liver pathology. CONCLUSION: Hepatic transit time measurement could not be used to distinguish between cirrhosis and other hepatic pathology, but a transit time = 10 s excluded cirrhosis. The earlier hepatic vein arrival time in cirrhosis is apparently mainly caused by intrahepatic shunting rather than by early arrival of contrast to the liver.

Reduced mitochondrial adenosine triphosphate synthesis in skeletal muscle in patients with Child-Pugh class B and C cirrhosis.

Patients with cirrhosis of the liver often complain of tiredness and a lack of strength at physical exercise. Other investigators have found that muscle strength, work capacity, and maximal oxygen consumption are reduced in cirrhosis. We hypothesized that mitochondrial maximal rate of ATP synthesis in skeletal muscle may be impaired in these patients. This was tested with (31)P nuclear magnetic resonance spectroscopy in anterior tibial muscle of cirrhotic patients and healthy controls at rest, during exercise, and subsequent recovery. In patients with Child-Pugh class B and C cirrhosis resting PCr/P(i) ratio (8.3 +/- 1.0; n = 7) was lower than in patients with Child-Pugh class A cirrhosis (12.1 +/- 2.1; n = 7) and controls (11. 7 +/- 1.1; n = 6; P =.03), while the resting P(i)/gammaATP ratio was higher in Child-Pugh class B and C patients (0.43, 0.30, and 0.27, respectively; P =.03). Maximal rate of mitochondrial adenosine triphosphate (ATP) synthesis (V(max)) as calculated from the initial rate of phosphocreatine (PCr) recovery after work was lower in Child-Pugh class B and C cirrhosis (0.189 mmol/L/s +/- 0.034) than in both Child-Pugh class A patients (0.402 mmol/L/s +/- 0.103) and controls (0.425 mmol/L/s +/- 0.064; P =.01). V(max) was significantly correlated to intracellular free [Mg(2+)] obtained from the (31)P nuclear magnetic resonance (NMR) spectra (P =.003). Insufficient oxygen delivery did not seem a likely cause of reduced ATP synthesis in the patients. These findings suggest either a decreased number of mitochondria in skeletal muscle of the cirrhotic patient in Child-Pugh class B and C or a defective mitochondrial function that could be related to low intracellular free [Mg(2+)].

Urea synthesis in patients with chronic pancreatitis: relation to glucagon secretion and dietary protein intake.

BACKGROUND & AIMS: Up-regulation of urea synthesis by amino acids and dietary protein intake may be impaired in patients with chronic pancreatitis (CP) due to the reduced glucagon secretion. Conversely, urea synthesis may be increased as a result of the chronic inflammation. The aims of the study were to determine urea synthesis kinetics in CP patients in relation to glucagon secretion (study I) and during an increase in protein intake (study II). METHODS: In study I, urea synthesis rate, calculated as urinary excretion rate corrected for accumulation in total body water and intestinal loss, was measured during infusion of alanine in 7 CP patients and 5 control subjects on spontaneous protein intake. The functional hepatic nitrogen clearance (FHNC), i.e. urea synthesis expressed independent of changes in plasma amino acid concentration, was calculated as the slope of the linear relation between urea synthesis rate and plasma alpha -amino nitrogen concentration. In study II, 6 of the patients of study I had urea synthesis and FHNC determined before and after a period of 14 days of supplementation with a protein-enriched liquid (dietary sequence randomized). RESULTS: Study I: Alanine infusion increased urea synthesis rate by a factor of 10 in the control subjects, and by a factor of 5 in the CP patients (P<0.01). FHNC was 31.9+/-2.4 l/h in the control subjects and 16.5+/-2.0 l/h (P<0.05) in the CP patients. The glucagon response to alanine infusion (AUC) was reduced by 75 % in the CP patients. The reduction in FHNC paralleled the reduced glucagon response (r(2)=0.55, P<0.01). Study II: The spontaneous protein intake was 0.75+/-0.14 g/(kg x day) and increased during the high protein period to 1.77+/-0.12 g/(kg x day). This increased alanine stimulated urea synthesis by a factor of 1.3 (P<0.05), FHNC from 13.5+/-2.6 l/h to 19.4+/-3.1 l/h (P<0.01), and the glucagon response to alanine infusion (AUC) by a factor of 1.8 (P<0.05). CONCLUSIONS: Urea synthesis rate and FHNC are markedly reduced in CP patients. This is associated with, and probably a result of, impaired glucagon secretion, and predicts a lower than normal postprandial hepatic loss of amino nitrogen. An increase in dietary protein intake increases alanine stimulated urea synthesis and FHNC by a mechanism that involves an increase in glucagon. This indicates that the low FHNC during spontaneous protein intake included an adaptation to the low protein intake, effectuated by a further decrease in glucagon secretion.

Effects of budesonide and prednisolone on hepatic kinetics for urea synthesis.

BACKGROUND/AIMS: Glucocorticoids upregulate hepatic urea synthesis and cause protein breakdown to prevail over synthesis, releasing amino acids into the blood stream and increasing the substrate supply for hepatic urea synthesis. Budesonide is a new generation glucocorticoid that may be used for treatment of inflammatory diseases, e.g. Crohn's disease and autoimmune hepatitis. Due to its extensive first-pass metabolism in the liver, it has a potential adverse effect profile superior to that of prednisolone. Little attention has been directed towards differences in nitrogen catabolic properties between budesonide and prednisolone. METHODS: Eight normal male subjects (age 20-44 years; BMI 21.6-28.2 kg/m2) were randomly studied 3 times: 1) At baseline, 2) after 6 days of prednisolone (50 mg/day), and 3) after 6 days of budesonide (9 mg/ day). We measured urea nitrogen synthesis rates (UNSR) and blood alpha-amino-nitrogen (N) levels before, during, and after a 3-h constant infusion of alanine (2 mmol/(kg BW x h)). UNSR was estimated hourly as urinary excretion corrected for gut hydrolysis and accumulation in body water. The slope of the linear relationship between UNSR and amino-N concentration represents the hepatic kinetics of conversion of amino- to urea-N, and is denoted the functional hepatic nitrogen clearance (FHNC). RESULTS: Prenisolone, but not budesonide, administration increased basal blood and amino nitrogen concentrations (3.5 +/- 0.1 mmol/l (control) vs 3.8 +/- 0.1 mmol/l (prednisolone) (p<0.05) and 3.6 +/- 0.1 mmol/l (budesonide) (NS). Basal UNSR values were significantly increased following prednisolone (23.3 +/- 6.5 (control) vs 51.2 +/- 6.3 (prednisolone) (p<0.05)), while budesonide had no effect on basal UNSR (33.7 +/- 4.2 (budesonide) (NS)). Prednisolone administration increased FHNC (from 24.6 +/- 4.7 l/h (control) to 47.3 +/- 5.9 l/h (prednisolone) (p<0.05). Budesonide administration did not significantly increase FHNC (33.7 +/- 4.2 l/h (budesonide), (vs control; p=0.12, vs prednisolone: p<0.05)). CONCLUSIONS: Prednisolone administration led to increased levels of amino acids in blood and loss of N as urea, the latter in part due to a specific hepatic mechanism as shown by the increased FHNC. Budesonide led to unaltered levels of amino acids in blood, no changes in loss of N as urea, and unaltered hepatic kinetics for urea synthesis. Thus, oral budesonide administration had very limited effects on the hepatic contribution to nitrogen homeostasis and metabolism via urea synthesis, making treatment with budesonide superior to that of conventional glucocorticoids in this respect.

Effect of a new starch-free bread on metabolic control in NIDDM patients.

BACKGROUND AND AIM: The aim of the study was to evaluate the effect on blood glucose levels in non-insulin-dependent diabetics (NIDDM) of reduction of the carbohydrate content through the use of a new, almost starch-free type of bread (SF-bread). We only substituted the bread in the breakfast meal. METHODS AND RESULTS: The study consisted of two parts: 1) a two-day randomized study of the effect of SF-bread on the morning blood glucose levels of NIDDM patients and 2) an open, crossover trial of three months duration where each patient was given SF- or ordinary bread. Ten patients participated in the first part and eight in the second part of the study. All patients had well established non insulin-dependent diabetes mellitus. In the first part of the study, the area under the curve describing time-dependent changes in blood glucose level after a standard breakfast was significantly lower in patients on SF-bread (182 +/- 154 Units; mean value +/- SD) than in the controls (630 +/- 258 Units; p < 0.00001). Peak blood glucose concentration was 14.8 +/- 2.3 mM on the control day and 11.6 +/- 1.7 mM on the SF-bread day (p < 0.001). In the second part of the study, the diet including SF-bread reduced fasting blood glucose from 13.3 +/- 3.5 mM to 10.2 +/- 2.0 mM (p < 0.006) and the fraction of HbA1c from 0.090 +/- 0.014 to 0.081 +/- 0.015 (p < 0.02). Similar changes were not seen on the ordinary diet. Serum cholesterol levels were significantly reduced by the SF-bread as compared to the ordinary diet (5.8 +/- 0.6 to 5.5 +/- 0.5 mM versus 5.7 +/- 0.8 to 5.8 +/- 0.7 mM; p < 0.05). CONCLUSIONS: Substitution of ordinary bread with starch-free bread at breakfast causes significant improvements in blood glucose levels in NIDDM patients on both a short and long term basis. Possibly secondary to this, a favorable influence on lipid levels was noted.

Effects of xylitol on urea synthesis in patients with cirrhosis of the liver.

BACKGROUND: In individuals with cirrhosis the normal inhibiting effect of glucose on urea synthesis is lost, probably because of very high concentrations of glucagon. In agreement, glucose does not prevent the inducing effect of glucagon on urea synthesis in normal humans. In contrast, the sugar alcohol, xylitol, prevents the increasing effect of glucagon in normal humans. We, therefore, examined the effect of xylitol on urea synthesis in individuals with cirrhosis and hyperglucagonemia. METHODS: Urea synthesis, calculated as urinary excretion rate corrected for accumulation in total body water and intestinal loss, was measured during infusion of alanine (2 mmol/[h x kg body wt]) and during infusion of alanine superimposed on infusion of xylitol (0.12 g/[h x kg body wt]) in 8 individuals with biopsy-proven alcoholic cirrhosis. The functional hepatic nitrogen clearance (FHNC), ie, urea synthesis expressed independent of changes in plasma amino acid concentration, was calculated as the slope of the linear relation between the urea synthesis rate and the plasma amino acid concentration. RESULTS: All individuals had elevated basal plasma glucagon concentration (261 +/- 61 ng/L; mean +/- SEM) and a markedly increased response to alanine infusion (1037 +/- 226 ng/L). This was not changed by xylitol. Neither the basal urea synthesis rate (13.2 +/- 2.5 mmol/h) nor the alanine-stimulated urea synthesis rate (76.8 +/- 3.64 mmol/h) was changed by xylitol. FHNC during the infusion of alanine alone was 10.5 +/- 0.9 L/h and did not change during the concomitant infusion of xylitol (10.1 +/- 1.1 L/h). CONCLUSIONS: Xylitol reduces neither urea synthesis nor FHNC. The data do not support an important role of xylitol as a nitrogen-sparing agent in cirrhosis.

[Increased urea synthesis in patients with active inflammatory bowel disease]. / Accelereret urinstofsyntese hos patienter med aktiv inflammatorisk tarmsygdom.

Patients with active inflammatory bowel disease are often reported to be in negative nitrogen balance. Therefore, we examined basal and amino acid stimulated urea synthesis in 11 patients with active inflammatory bowel disease and in 10 patients with non-active disease. A primed continuous infusion of an amino acid mixture was given from t = 1 h to t = 5 h; during the first and the last two hours no amino acid infusion was given. Urea nitrogen synthesis rate was quantified independently of changes in blood amino acid concentration by means of the functional hepatic nitrogen clearance, i.e. the linear slope of the regression of urea nitrogen synthesis rate on blood amino acid concentration. Basal and amino acid stimulated urea nitrogen synthesis rate as well as functional hepatic nitrogen clearance were elevated twofold in the patients with active disease. No differences between the two groups were observed as regards basal or stimulated plasma glucagon, cortisol, catecholamines and serum levels of interleukin-1 alpha, interleukin-1 beta, tumor necrosis factor-alpha and interleukin-6. The results show that liver function related to conversion of amino-nitrogen to urea is increased and may contribute to the less efficient nitrogen economy in patients with active inflammatory bowel disease.

Regulation of urea synthesis by diet protein and carbohydrate in normal man and in patients with cirrhosis. Relationship to glucagon and insulin.

Diet protein increases whereas carbohydrates decrease urea synthesis. Traditionally, these effects have been explained by changes in substrate supply. Diet protein intake increases whereas carbohydrate decreases blood amino acid concentration. However, glucose also decreases urea synthesis by a hepatic mechanism independent of the decrease in blood amino acid concentration. Whether this is due to an effect of glucose in itself, or whether the fall in glucagon or the rise in insulin is responsible, was not known. This survey deals with the effect of an increase in diet protein intake and of the separate effects of glucose, glucagon and insulin on functional hepatic nitrogen clearance in normal man and in patients with cirrhosis of the liver. The functional hepatic nitrogen clearance is calculated as the slope of the linear regression analysis of alanine-stimulated urea synthesis rate and blood alpha-amino nitrogen concentration, and expresses urea synthesis independent of changes in blood amino acid concentration. In patients with cirrhosis, hepatic nitrogen clearance is reduced in parallel with liver cell mass, despite high glucagon concentration that would normally up-regulate the process. In both healthy subjects and in patients with cirrhosis, an increase in diet protein intake (plus approximately 50 g/day) for 14 days increases hepatic nitrogen clearance by 40%. Thus, in addition to the substrate effect, protein intake increases urea synthesis by an effect in the liver, probably by enzyme formation. What induces this is not clear but high postprandial levels of glucagon may be involved. Although the effect is qualitatively intact in the patients, the response relative to the increase in protein intake is reduced by two-thirds. The effect may be important to control blood amino acid concentration during a high protein diet and may partly explain why patients with cirrhosis usually tolerates protein hyperalimentation without developing hepatic encephalopathy. It is shown that the reduction of hepatic nitrogen clearance by glucose depends on hyperglycaemia, and is accomplished by the additive effects of a direct hormone-independent action of glucose, and indirectly via suppression of glucagon. Insulin is not a direct controller of hepatic nitrogen clearance, but is still considered an important regulator of urea synthesis by its reducing effects on blood amino acid concentration. High experimental glucagon levels overrule the normal suppressive effect of glucose. In contrast, it is shown that the sugar-alcohol xylitol normalises the glucagon induced increase in hepatic nitrogen clearance. During normal glucagon levels xylitol exerts only a very little decrease in hepatic nitrogen clearance. In patients with cirrhosis, glucose does not down-regulate hepatic nitrogen clearance. However, when the spontaneous high glucagon levels are normalised by somatostatin, glucose decreases hepatic nitrogen clearance. This shows that the direct hormone-independent effect of glucose is intact. These findings indicate that the high glucagon levels during spontaneous hormone responses overrule the suppressive effect of glucose. Incomplete glucose suppression of glucagon secretion during alanine infusion contributes to the high glucagon levels. The removal of the high glucagon levels decreases hepatic nitrogen clearance in itself. Thus, the hyperglucagonaemia may be a compensatory mechanism by which the cirrhotic liver to some extent reestablishes its capacity to produce urea. The consequence is the defective down-regulation of hepatic nitrogen clearance by glucose. The reduction in urea synthesis by glucose, i.e. its nitrogen sparing effect, is accomplished by two different mechanisms: A hepatic component (reduction of the hepatic nitrogen clearance) and a peripheral component (reduced substrate availability mediated by the insulin response). This is an extension of former thoughts according to which glucose reduces urea synthesis due solely to

Increased hepatic urea synthesis in patients with active inflammatory bowel disease.

BACKGROUND/METHODS: Patients with active inflammatory bowel disease are often reported to be in negative nitrogen balance. Therefore, we examined basal and amino acid stimulated urea synthesis in 11 patients with active inflammatory bowel disease (six with Crohn's disease and five with ulcerative colitis) and in 10 patients with non-active disease (six with Crohn's disease and four with ulcerative colitis). A primed continuous infusion of an amino acid mixture was given from t = 1 h to t = 5 h; during the first and the last 2 h no amino acid infusion was given. Urea nitrogen synthesis rate was calculated in hourly intervals for 7 consecutive hours. Urea nitrogen synthesis rate was quantified independent of changes in blood amino acid concentration by means of the functional hepatic nitrogen clearance, i.e. the linear slope of the regression of urea nitrogen synthesis rate of blood amino acid concentration. RESULTS: Basal urea nitrogen synthesis rate was 24.5 +/- 2.9 mmol/h in the patients with no disease activity and 43.8 +/- 2.2 mmol/h in patients with active disease (p < 0.01). During amino acid infusion urea nitrogen synthesis rate was elevated two-fold in the patients with active disease. Functional hepatic nitrogen clearance was 28.2 +/- 1.5 1/h in patients with no disease activity and 56.1 +/- 4.1 1/h in patients with active disease (p < 0.01). No differences between the two groups were observed as regards basal or stimulated plasma glucagon and cortisol and serum levels of interleukin-1 alpha, interleukin-1 beta, tumor necrosis factor alpha and interleukin-6. CONCLUSIONS: The results show that the liver function related to conversion of amino-nitrogen to urea is increased in patients with active inflammatory bowel disease. No differences among known and possible regulators of urea synthesis were found between the two groups. The accelerated hepatic amino-nitrogen conversion contributes to the less efficient nitrogen economy in patients with active inflammatory bowel disease.

Effects of xylitol on urea synthesis in normal humans: relation to glucagon.

BACKGROUND: Xylitol exerts a nitrogen-sparing effect in stress catabolic states with hyperglucagonemia, but the mechanism(s) is unknown. We examined the effects of xylitol on urea synthesis during physiologic glucagon concentrations and during hyperglucagonemia. METHODS: Urea synthesis was measured independently of blood amino acid concentration by means of functional hepatic nitrogen clearance (FHNC) (ie, the linear slope of the relation between urea synthesis rate and blood alpha-amino nitrogen concentration during infusion of alanine). FHNC was measured on four separate occasions in each of seven healthy subjects: during constant infusion of alanine alone, alanine superimposed on a constant infusion of xylitol (blood xylitol 1 mmol/L), alanine superimposed on infusion of glucagon, and alanine superimposed on infusions of xylitol and glucagon. RESULTS: During alanine infusion alone, plasma glucagon rose to -170 ng/L, and FHNC was (mean +/- sem) 27.9 +/- 1.3 L/h. Xylitol did not affect plasma glucagon and only moderately reduced FHNC to 24.3 +/- 1.0 L/h (p < .05). Glucagon infusion increased plasma glucagon to -450 ng/L and FHNC twofold to 50.9 +/- 6.2 L/h; this increase was totally prevented by the addition of xylitol that reduced FHNC to 27.4 +/- 2.6 L/h (p < .01). CONCLUSIONS: The results show that xylitol only inhibited FHNC minimally during spontaneous glucagon levels. In contrast, xylitol completely inhibits the increase in FHNC by glucagon. This suggests that the mechanism whereby xylitol reduces nitrogen loss in stress catabolic conditions with hyperglucagonemia involves an effect on liver metabolism. The mechanism is unknown but may be related to depletion of hepatocyte adenine nucleotides.

Hormonal regulation of circulating insulin-like growth factor-binding protein-1 phosphorylation status.

Insulin-like growth factor (IGF)-binding protein-1 (IGFBP-1) normally circulates as a single, highly phosphorylated species. However, IGFBP-1 phosphorylation status can be altered, such as in pregnancy where non- and lesser phosphorylated isoforms are also present. We have examined how hormonal regulators of circulating IGFBP-1 influence its phosphorylation status and, hence, its ability to modulate IGF activity. In response to insulin-induced hypoglycemia (0.2 U/kg, iv), an increase in the highly phosphorylated isoform was observed after 5 h [16 (range, 11.5-35.5) to 77 (range, 63-250) microgram/L; 4.8-fold increase; P = 0.009], but no non- or lesser phosphorylated variants could be detected. Glucagon (1 mg, sc), increased IGFBP-1 from 27 (range, 13-36.5) to 112 (range, 100.5-129) micrograms/L (4.1-fold increase; P = 0.009) after 90 min despite preceding insulin concentrations of more than 500 pmol/L, but again the IGFBP-1 remained in the highly phosphorylated form. Regulation of IGFBP-1 phosphorylation by sex steroids was studied by comparing women receiving a combined oral contraceptive with women on no medication. Although plasma IGFBP-1 levels were significantly elevated in the treatment group [120 (range, 97.5-237.5) vs. 52 (range, 38-70) micrograms/L; P < 0.004], there was no difference in the form of IGFBP-1 present. The acute effect of somatostatin (500 micrograms/h) on IGFBP-1 phosphorylation status was also studied. Somatostatin only increased the phosphoform characteristic of normal subjects; the appearance of non- or lesser phosphorylated variants was not induced. The effect of rhIGF-I (80 or 120 micrograms, sc) on plasma IGFBP-1 was studied in three subjects with Laron's syndrome. A transient increase in the highly phosphorylated isoform of IGFBP-1 was noted; there was no rise in the non- and lesser phosphorylated isoforms also found in the plasma of Laron's syndrome subjects. These data suggest that only the highly phosphorylated species of IGFBP-1 is under hormonal control; regulation of the non- and lesser phosphorylated variants remains to be determined.

Effects of insulin and glucose on urea synthesis in normal man, independent of pancreatic hormone secretion.

We investigated the inhibitory effect of insulin and glucose on hepatic amino- to urea-nitrogen conversion independent of endogenous insulin and glucagon secretion. Alanine-stimulated urea synthesis kinetics, as quantified by functional hepatic nitrogen clearance, i.e. the slope of the linear relation between blood alpha-amino nitrogen concentration and urea synthesis rate, were measured four times in each of six healthy volunteers, namely during spontaneous hormone responses, and during hormonal control by somatostatin and maintenance of basal hormone levels and euglycaemia, hyperinsulinaemia (85 +/- 8 mU/l), or hyperglycaemia (8.4 +/- 0.5 mmol/l). Hormonal control and euglycaemia reduced functional hepatic nitrogen clearance (mean +/- SD) by two-thirds (from 32.9 +/- 5.2 l/h to 12.2 +/- 3.4 l/h, p < 0.01). Hyperinsulinaemia did not change this (13.2 +/- 2.8 l/h), whereas hyperglycaemia further reduced functional hepatic nitrogen clearance by 40% to 7.4 +/- 1.3 l/h (p < 0.01). The reduction by hormonal control and euglycaemia is attributable to the abolition of the glucagon response to alanine infusion, as glucagon is known to up-regulate functional hepatic nitrogen clearance. Insulin did not regulate hepatic amino- to urea-nitrogen conversion, implying that the effect of insulin on urea production is due to its effect on blood amino acid supply to the liver. In contrast, glucose in itself reduced hepatic amino nitrogen conversion, independent of the hormonal responses to glucose. This means that the hepatic component of the amino-N-sparing effect of glucose depends on hyperglycaemia but not on hyperinsulinaemia.

A rapid method for determination of hepatic amino nitrogen to urea nitrogen conversion ('the Functional Hepatic Nitrogen Clearance').

The Functional Hepatic Nitrogen Clearance (FHNC) is a measure of the functional liver mass as to conversion of amino-N to urea-N. FHNC is the slope of the linear regression of multiple samples (10-20) of urea-N synthesis rates (UNSR) on blood alpha-amino-N concentrations (alpha-AN) during infusion of amino acids. UNSR is measured as urinary urea-N excretion rate corrected for accumulation in total body water (TBW) and loss in gut. A simplified method which estimates FHNC from only two samples of UNSR and alpha-AN was developed. Urine was collected in two hourly intervals: before infusion of alanine, and from 2 to 3 h after start of alanine infusion. Blood-urea-N and alpha-amino-N was measured at the beginning and at the end of each urine sampling interval. TBW was estimated from a nomogram, and gut loss of urea was assigned a fixed value (14%). The two-sample FHNC was calculated as delta UNSR (mmol h-1)/delta mean alpha-AN (mmol l-1). Linear regression analysis of the two-sample estimates of FHNC on the 'true' multiple-sample values of FHNC in an independent population of control and cirrhotic subjects showed the two-sample estimates to be closely related with values of the multiple-sample method, the regression equation being: two-sample FHNC = -0.24 + 0.99 x multiple-sample FHNC, r2 = 0.98. A close relationship was also obtained when cirrhotic patients were considered alone: two-sample FHNC = 0.01 + 0.94 x multiple-sample FHNC, r2 = 0.98.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of urea synthesis by glucose and glucagon in normal man.

The separate effects of glucose and glucagon on alanine stimulated hepatic amino-N to urea-N conversion, quantified by the Functional Hepatic Nitrogen Clearance (FHNC) (i.e. the linear slope of the relation between urea synthesis rate and blood alpha-amino-N concentration), were studied in 7 healthy subjects. FHNC was measured four times in each: during constant infusion of alanine alone; alanine superimposed on constant glucose infusion; alanine superimposed on glucose and low stepwise glucagon infusions; and alanine super-imposed on glucose and high constant glucagon infusions. Glucose halved the glucagon response to alanine. This reduction was abolished by the low stepwise glucagon infusion, aimed at re-establishing portal glucagon levels. The high glucagon infusion resulted in 3-fold elevated glucagon levels. During alanine infusion alone FHNC was (mean +/- SEM) 32.5 +/- 1.9 l/h. Glucose reduced FHNC by 43% to 18.4 +/- 0.9 l/h (p < 0.01). The low stepwise glucagon infusion only partially normalized FHNC as reduced by glucose (to 24.6 +/- 1.5 l/h, (p < 0.01 vs alanine alone)). The high glucagon infusion increased FHNC by 35% despite hyperglycaemia (to 44.1 +/- 1.5 l/h, (p < 0.01 vs alanine alone)). The results show that both glucose and glucagon are independent but opposite regulators of hepatic amino-N conversion. The physiological glucose effect is accomplished by a combination of both the effect of glucose itself and the inhibition by glucose of the glucagon response to alanine. Hyperglucagonaemia increases FHNC and overrules the inhibition by glucose. This may explain the defect nitrogen sparing by glucose and to some extent the catabolism in hyperglucagonaemic stress conditions, despite prevailing hyperglycaemia.

Effect of lanreotide, a somatostatin analogue, on urea synthesis in normal man.

The aim was to investigate the effect of lanreotide (Angiopeptin) on urea synthesis. Lanreotide is a somatostatin analogue used in therapy trials of certain cancers. Cancer patients are often protein catabolic, thus the effect of lanreotide on whole body protein metabolism is of importance. We investigated the effect of lanreotide by measuring urea nitrogen synthesis rate (UNSR) and blood alpha-amino nitrogen levels before, during and after a 30 min iv infusion of 25 g of an electrolyte-free amino acid solution. 6 healthy male subjects were studied following, i) placebo (saline), ii) lanreotide 5 mug/kg, and iii) lanreotide 80 mug/kg. Lanreotide decreased urea nitrogen synthesis rate (mmol/h) during amino acid infusion significantly compared to saline, independent of dose of lanreotide (max +/- SE of urea nitrogen synthesis rate measurements in each study: 117 +/- 8 mmol/h (saline), 85 +/- 10 mmol/h (high dose) and 85 +/- 12 mmol/h (low dose)). This occurred in spite of significantly higher plasma alpha-amino nitrogen following lanreotide (peak +/- SE of alpha-amino nitrogen level in each study: 3.7 +/- 0.1 mmol/l placebo versus 4.8 +/- 0.2 mmol/l low dose and 4.7 +/- 0.4 mmol/l high dose (p < 0.01). We conclude that a single dose of lanreotide decreases whole body urea nitrogen synthesis rate thereby conserving body protein. The results indicate that long term lanreotide therapy may not lead to further protein catabolism in cancer patients.

Somatostatin-stimulated insulin-like growth factor binding protein-1 release is abolished by hyperinsulinemia.

It was demonstrated recently that administration of lanreotide and octreotide, two somatostatin octapeptide analogs, increased circulating insulin-like growth factor binding protein 1 (IGFBP-1) levels. The present study demonstrates that native somatostatin 14 shares this ability and that the increase in abolished by concomitant hyperinsulinemia within the physiological range. Five fasting healthy volunteers underwent a hyperinsulinemic as well as a normo-insulinemic (i.e. basal insulinemic) euglycemic clamp lasting 8 h (serum insulin levels remained constant, about 570 vs. 16 pmol/L). Immediately before the clamps, a somatostatin infusion (500 micrograms/h) was started and continued throughout. During normo-insulinemia, IGFBP-1 levels increased slowly from 6.3 +/- 6.2 to 36.1 +/- 14.8 micrograms/L (P < 0.05) reaching maximum after 7 h constant somatostatin infusion, whereas hyperinsulinemia induced a significant decrease from basal levels (from 4.7 +/- 5.4 to 1.1 +/- 1.5 micrograms/L) after 8 h (mean +/- SD, n = 5). These results may indicate hitherto unnoticed interactions of somatostatin and insulin on IGFBP-1 release with possible impact on IGF-I action at the cellular level.

Effects of glucose on hepatic conversion of aminonitrogen to urea in patients with cirrhosis: relationship to glucagon.

Glucose reduces the hepatic conversion of aminonitrogen to urea, quantified by the functional hepatic nitrogen clearance (i.e., the slope of the linear relation between urea synthesis rate and blood alpha-aminonitrogen concentration). This is due to a direct effect of glucose and to inhibition of glucagon. In this study, the effect of glucose on functional hepatic nitrogen clearance was examined during spontaneous hormone responses and during hormonal control by somatostatin. In 7 control subjects (study 1) and 9 patients with cirrhosis (study 2), functional hepatic nitrogen clearance was assessed twice in each subject: during infusion of alanine and during alanine administration superimposed on a continuous glucose infusion (blood glucose, on average = 8.4 mmol/L). In study 3, 6 patients with cirrhosis had functional hepatic nitrogen clearance determined on three occasions: during infusions of alanine and of alanine superimposed on infusion of somatostatin with either euglycemia or hyperglycemia (blood glucose = 8.4 mmol/L). In the control subjects (study 1), functional hepatic nitrogen clearance was 32.5 +/- 1.9 L/hr, and glucose reduced it to 18.4 +/- 0.9 L/hr (p < 0.01). In the cirrhotic patients, functional hepatic nitrogen clearance was only 9.8 +/- 1.3 L/hr (p < 0.01 vs. controls), and glucose did not change it. In the control subjects, glucose reduced the glucagon response to alanine from 204 +/- 36 ng/L to 106 +/- 8 ng/L (p < 0.05). In the cirrhotic patients the mean fasting glucagon level was increased twofold (180 +/- 21 ng/L). The response to alanine increased to 968 +/- 265 ng/L; it was not reduced by glucose. In study 3, somatostatin and hyperglycemia reduced functional hepatic nitrogen clearance from 13.2 +/- 1.5 L/hr to 6.4 +/- 0.7 L/hr (p < 0.01). Somatostatin and euglycemia reduced functional hepatic nitrogen clearance to 9.2 +/- 1.2 L/hr (p < 0.01 vs. alanine and hyperglycemia). The results show that the reduction by glucose of hepatic aminonitrogen conversion is lost in cirrhotic patients. The markedly increased glucagon response to alanine was not suppressed by glucose. Inhibition of the glucagon response by somatostatin reestablished the glucose effect, which was in part due to inhibition of glucagon in itself. Thus hepatic aminonitrogen conversion in cirrhosis depends on increased glucagon levels. The hormone-independent effect of glucose is preserved if the hyperglucagonemia is abolished, but the spontaneous high glucagon level overrules the glucose effect. The results indicate reduced hepatic contribution to the nitrogen-sparing effect of glucose in cirrhotic patients.

[Nutritional therapy in patients with liver cirrhosis]. / Ernaeringsterapi hos patienter med levercirrose.

Malnutrition is common among patients with cirrhosis of the liver. During the last seven years a total of eight randomized studies concerning the effect of nutritional therapy on the clinical course of these patients have been published. In five of these trials nutritional therapy had an effect on the clinical course (reduced mortality, lessening of ascites and encephalopathy) and in the last three trials only effects on clinical chemistry variables related to liver function could be demonstrated. Overall one-month mortality decreased from 30% in the control groups to 14% in the treated groups, when all the trials were added together (total of 320 patients). Patients with liver cirrhosis have an increased requirement for protein to achieve nitrogen balance. Prescribing diets with restricted protein is no longer warranted in these patients, since protein intolerance is actually uncommon. In patients intolerant of protein, substitution of conventional protein with branched chain amino acids can be effective.