The effect of ingestion of meat on hepatic extraction of insulin and glucagon and hepatic glucose output in conscious dogs

The effect of ingestion of protein on hepatic extraction of insulin and glucagon and hepatic glucose output were investigated in conscious dogs. The ingestion of meat stimulated both insulin and glucagon secretion but the glucagon response was much more rapid and greater than that of insulin. Secretion of glucagon demonstrated a biphasic pattern while insulin release was monophasic. The fractional hepatic extraction of glucagon increased gradually from the basal value of 15 +/- 3% to a peak of 36 +/- 5% at 90 min, and that of insulin increased from the basal level of 41 +/- 2% to 54 +/- 4% at 45 and 60 min. The increased hepatic extraction of glucagon and insulin after meat ingestion may be explained by neural or hormonal signals from the gut. The blood glucose and hepatic glucose output did not increase significantly despite the significant decrease of the portal vein insulin to glucagon molar ratio as well as the significant decrease of the molar ratio of the hepatic uptake of these hormones. The absence of greater hepatic glucose production despite the augmented glucagon secretion and decreased portal vein insulin to glucagon molar ratio could reflect down regulation by glucagon.     

Effect of glucagon and glucose load on glucose kinetics, plasma FFA, and insulin in dogs treated with methylprednisolone

Glucose turnover, plasma lactate, FFA, and insulin levels were measured on trained, unanesthetized dogs with indwelling arterial and venous catheters. 2-t-Glucose was used as a tracer according to the primed-constant rate infusion technique to estimate the rate of appearance (R_a) of glucose in and its disappearance (R_d) from the plasma. After establishing base-line values, glucagon (30 or 60 ng/kg/min) or glucose (4.5, 7.5, or 15 mg/kg/min) was infused for 135 min. In normal dogs, glucagon increased the plasma $\text{glucose +}\text{14 mg}\text{100 ml}$, R_a + 1.2 mg/kg/min and caused a transient decrease of plasma FFA. Three days of treatment with methylprednisolone (3–3.5 mg/kg/day) almost doubled the glucose turnover at only slightly elevated plasma glucose and insulin levels. This treatment strikingly potentiated the effect of glucagon on the hepatic glucose output (20-fold) and on plasma sugar (12-fold). In these animals, glucagon also caused a greater decrease of FFA and a greater rise of insulin levels. Plasma lactate was not altered significantly by glucagon. Infusion of glucose decreased R_a and increased R_d to nearly the same extent in both groups. However, the FFA lowering effect of glucose infusion was less pronounced after glucocorticoid treatment. It is concluded that one of the most spectacular consequences of a brief treatment with large doses of glucocorticoid is the greatly increased effect of glucagon on hepatic glycogenolysis. The possible mechanism of this synergism is discussed.     

The effect of intraportal and peripheral infusions of glucagon on insulin and glucose concentrations and glucose tolerance in normal man

Summary The effect of peripheral and intraportal infusions of 0.86 pmol/kg · min^–1 of glucagon on plasma glucose, plasma insulin, and glucose tolerance was examined in four normal subjects. Peripheral glucagon concentrations increased by 60–90 pmol/l during intraportal and 70–180 pmol/l during peripheral infusions. The infusions caused increases in plasma glucose levels of approximately 1 mmol/l, and in plasma insulin levels of 75–100%, regardless of route of administration. Intravenous glucose tolerance tests carried out during the glucagon infusions showed that glucose tolerance remained within the normal range and was uninfluenced by the route of administration.     

The effect of urinary glucose excretion on the plasma glucose clearances and plasma insulin responses to intravenous glucose loads in unanaesthesized dogs

The effect of urinary glucose excretion on the plasma glucose clearance and insulin response to varying sizes of glucose loads was studied in normal unanaesthesized dogs. Glucose loads ranging from 0.15 to 1.25 g/kg b.w. were infused intravenously in a standard time period of 30 seconds. Plasma glucose and plasma immunoreactive insulin (IRI) concentrations were determined during one-hour after infusion. All urine excreted during the one-hour was collected by a catheterization and bladder wash-out procedure. The urinary glucose excretion was expressed as the percent of the glucose load. The urinary glucose excretion varied directly with the size of the glucose load and ranged from minimal to 12%. This would indicate that urinary losses play a considerable role proportionate to the degree of hyperglycaemia above the renal threshold. Thus, urinary loss of glucose must be recognized as an important factor infuencing the plasma glucose clearance and hence the plasma IRI response. A glucose load of 0.5 g/kg b.w. given in 30 seconds with the k-value calculated between 15-45 min would minimize the influence of urinary loss and provide more accurate plasma clearance values.     

Effect of obesity on ambient plasma glucose, free fatty acid, insulin, growth hormone, and glucagon concentrations

Fasting and postprandial plasma concentrations of glucose, FFA, insulin, glucagon, and GH concentrations were determined in 10 nonobese and 10 obese subjects with normal glucose tolerance. Measurements were made at 0800 h (after a 14-h fast) and at hourly intervals from then until 1600 h. During this time period all individuals ate breakfast at 0800 h (20% of total daily calories) and lunch (40% of total daily calories). Although plasma glucose concentrations were similar throughout the 8-h period in the 2 groups, plasma insulin concentrations were significantly (P less than 0.001) higher in the obese individuals. However, despite the presence of hyperinsulinemia, the obese group also had higher (P less than 0.001) plasma FFA concentration throughout the day. On the other hand, both the absolute and the relative declines in plasma FFA concentration after meals were similar in the 2 groups. Since plasma glucagon and GH concentrations were similar in the 2 groups, altered production of these lipolytic hormones was not responsible for the elevated plasma FFA levels in the obese individuals. These data document the presence in obese individuals of a disassociation in their ability to maintain normal plasma glucose as opposed to plasma FFA homeostasis, and indicate that the increase in plasma FFA concentrations in obesity occurs in the presence of hyperinsulinemia and is not related to abnormalities of either glucagon or GH secretion.     

Comparison of hepatic extraction of insulin and glucagon in conscious and anesthetized dogs

Previous studies in anesthetized dogs demonstrated that basal hepatic extraction of insulin and glucagon are approximately 50 and 10-20%, respectively. Because of the stress of anesthesia and surgery, these values may not be relevant to normal physiology. In this study, hepatic extraction of insulin and glucagon were compared in conscious and anesthetized dogs. The conscious dogs had chronically implanted catheters in the portal and hepatic vein and the carotid artery and Doppler flow probes on the portal vein and hepatic artery. The mean basal portal vein insulin (42 +/- 10 and 44 +/- 7 microU/ml, respectively) and glucagon (247 +/- 37 and 219 +/- 20 pg/ml, respectively) concentrations were similar in conscious and anesthetized animals. The mean basal portal vein, but not hepatic artery, plasma flow was significantly increased in conscious dogs (462 +/- 62 vs. 294 +/- 35 ml/min, respectively). Despite the increased portal vein plasma flow in conscious animals, the basal hepatic extractions of insulin (42 +/- 6 vs. 39 +/- 6%, respectively) and glucagon (12 +/- 7 vs. 7 +/- 7%, respectively) were similar in both types of animals. Arginine and cholecystokinin-pancreozymin (CCK-PZ) infusion, which increased the amount of insulin and glucagon presented to the liver in conscious and anesthetized dogs, significantly decreased the hepatic extraction of insulin. Hepatic extraction of glucagon did not change in either group of animals. In contrast, infusion of insulin (1.0 mU/kg X min) and glucagon (4 ng/kg X min) into the portal system did not alter hepatic extraction of insulin even though the amounts of insulin and glucagon presented to that organ were similar to those obtained with arginine and CCK-PZ. The basal arterial glucose level was significantly lower in the conscious dogs but the basal hepatic glucose output was similar in the two groups. The glucose response to the infusion of arginine and CCK-PZ and exogenous hormones was significantly greater in the anesthetized animals.     

The effect of CPR on plasma diltiazem concentrations in dogs

STUDY OBJECTIVE: To determine the effect of cardiac arrest with CPR on diltiazem concentrations in dogs. DESIGN: Prospective, double-blind, randomized trial. SETTING: Laboratory at a large university-affiliated medical center. TYPE OF PARTICIPANTS: Twenty mongrel dogs. INTERVENTIONS: Following administration of anesthesia, catheters were placed in the pulmonary artery, aortic arch, left ventricle, and right ventricle. Dogs were randomized to receive diltiazem (0.5 mg/kg) either 60 minutes before or during cardiac arrest with CPR. After 13 minutes of cardiac arrest, defibrillation was attempted. MEASUREMENTS AND MAIN RESULTS: Frequent blood samples for diltiazem concentrations were obtained before, during, and after cardiac arrest. The mean diltiazem concentration rose 70% during CPR in the group that received diltiazem before cardiac arrest. The group that received diltiazem during CPR had concentrations five times greater than expected during sinus rhythm. CONCLUSION: Increased diltiazem concentrations are observed during CPR and are probably related to altered distribution encountered during CPR.     

Effect of glucagon antibodies on plasma glucose,insulin and somatostatin in the fasting and fed rat

Summary A potent high-titre glucagon antibody pool was used to induce a state of acute glucagon deficiency in order to investigate the importance of glucagon in maintaining euglycaemia in the fed and fasted anaesthetised rat. Binding characteristics of the antiserum and evidence of its neutralisation of the biological effects of exogenous glucagon are described. The amount of antibody administered was capable of neutralising up to 12 times the total content of glucagon (approximately 1nmol) in the rat pancreas. The hyperglycaemic response to 1.43 nmol exogenous glucagon was significantly inhibited in the rat by glucagon antibodies given intravenously or intraperitoneally (p < 0.001). However, no changes in plasma glucose occurred in rats fasted 16 h (4.35±0.1 mmol/l or 24 h (4.0±0.05 mmol/l) after antibody administration. The same dose of glucagon antibodies produced no change in plasma glucose (6.1±0.2 mmol/l), immunoreactive insulin (1.85±0.05 g/l) or immunoreactive somatostatin (110±30 ng/l) in rats after antibody administration. Antibody excess, equivalent to a binding capacity for glucagon of 40 nmol/l in the plasma of recipient animals, was demonstrable at all times after passive immunisation. The absence of any affect on glucose concentrations following immunoneutralisation of glucagon suggests that glucagon secretion may not be a major factor in the maintenance of euglycaemia in the rat.     

Effects of small variations in insulin and glucagon levels on plasma aminoacids concentrations

To determine the effect in normal subjects of small variations of insulin and glucagon on plasma aminoacids concentrations we suppressed endocrine pancreas secretion with somatostatin and measured aminoacids levels during a sequential insulin infusion in the absence (control test, low glucagon level) or in the presence (normal glucagon concentration) of a replacement glucagon infusion. Insulin infusion rates were 0.05, 0.09, 0.15 and 0.30 mU.kg-1.min-1 during the control test and 0.09, 0.15, 0.30 and 0.40 mU.kg-1.min-1 during the replacement test. During the control test, glucagon decreased (p less than 0.01) and insulin levels were successively 8.2 +/- 0.4, 10.1 +/- 0.7, 11.9 +/- 0.14 and 18.5 +/- 0.8 mU.l-1. The only effect on insulin was to decrease branched-chain aminoacids (BCAA). BCAA were inversely related to insulinemia (p less than 0.01). A significant decrease was obtained for an insulin level of 11.9 +/- 0.4 mU.l-1, a value intermediate between those decreasing glycerol (10.1 +/- 0.7 mU.l-1) and stimulating total body glucose uptake (18.5 +/- 0.8 mU.l-1). During the test with glucagon replacement glucagon was maintained at its initial value. Insulin levels were successively 8.3 +/- 0.3, 11.9 +/- 0.3, 19.7 +/- 0.6 and 26.7 +/- 0.5 mU.l-1. Insulin decreased always BCAA but also threonine, proline, tyrosine, methionine and total aminoacid levels. BCAA were always inversely related to insulin levels (p less than 0.01) but the slope of the relationship was modified and more insulin was needed to decrease BCAA concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

空腹血糖水平与胰岛素抵抗的关系

目的探讨美国糖尿病协会2003年修订的空腹血糖受损(IFG)下限新切点(5·6mmol/L)划分出的中国血糖调节异常(IGR)者是否存在胰岛素抵抗。方法选取糖调节正常者(NGR)9例;以新标准划分的单纯IFG者9例;空腹及糖负荷后血糖均异常的糖调节受损者共20例,其中以新空腹血糖(FPG)切点划分的新联合糖耐量低减(IGT)者10例;以旧FPG切点划分的旧联合IGT者10例;2型糖尿病患者10例。以高胰岛素正葡萄糖钳夹技术测定受试对象的胰岛素敏感性,以静脉葡萄糖耐量试验评估其胰岛β细胞分泌功能。结果(1)新单纯IFG组、新联合IGT组和旧联合IGT组的葡萄糖输注率(GIR)[分别为(7·2±0·8、7·0±1·5、4·8±0·4)mg·kg-1·min-1]明显低于NGR组[(10·3±0·9)mg·kg-1·min-1,P值均<0·05];旧IGT组和DM组[(5·6±1·0)mg·kg-1·min-1]处于相近水平。(2)空腹胰岛素水平在所有IGR组均升高,在DM组下降。(3)新IFG组的胰岛素一、二相分泌量和NGR组相似,但随糖代谢紊乱程度加重,胰岛素一相分泌量进行性下降,而二相分泌水平先逐渐升高,后有所降低。结论(1)新空腹血糖切点划分出的中国IGR者已经出现胰岛素抵抗。(2)随糖代谢紊乱程度的加重,胰岛素分泌缺陷趋于明显。     

Effects of neurotensin and substance P on plasma insulin, glucagon and glucose levels.

Neurotensin and substance P given iv 5, 10, 20 and 30 minutes prior to blood collection produce hypoinsulinemia, hyperglucagonemia and hyperglycemia in the rat. Glucagon similarly produces hyperglycemia in rats but results in hyperinsulinemia. On a molar basis neurotensin is ca. 10 and 30 times more active in inducing hyperglycemia than substance P and glucagon, respectively. The enhanced glucogenic effects of neurotensin and substance P over glucagon may well result from their inhibition of insulin release. Neurotensin and substance P may be important in glucose homeostasis.     

The action of hydrocortisone, insulin, and glucagon on chicken liver hexokinase and glucose-6-phosphatase and on the plasma glucose and free fatty acid concentrations.

Chicken liver hexokinase and glucose-6-phosphatase activities were measured i vitro following the administration of glucagon, insulin, and hydrocortisone in vivo. Insulin lowered hexokinase activity but did not affect glucose-6-phosphatase activity. Neither enzyme was altered by glucagon. Hydrocortisone suppressed hexokinase activity 1, 4, and 24 hr after injection. White the glucose-6-phosphatase activity per unit weight of liver was unaltered by hydrocortisone, the total liver weight was increased and the ratio of enzyme activity to wet weight remained constant. Hydrocortisone caused hyperglycaemic at all three time intervals. Hydrocortisone elevated the plasma FFA concentration up to 4 hr but was increased threefold over the fed control values after 24 hr. The effect of these three hormones on the regulation of glucose flux into and out of liver may be partly explained by actions on hexokinase and glucose-6-phosphatase. It is likely that other liver enzyme activities which alter the flux through glucose-6-phosphatase are also changed. Hydrocortisone greatly increases the flux through gluconeogenesis such that hyperglycaemia and a large increase in glycogen content are achieved.     

Basal glucose homeostasis with and without fixed concentrations of glucagon and insulin

The aim of this study was to investigate the extent to which the basal steady state could be maintained with fixed concentrations of glucagon and insulin. To this end, arterial plasma glucose concentrations and peripheral glucose uptake (using the forearm technique) were compared in healthy men (age 19 to 23 years) in the normal postabsorptive state and after suppression of endogenous pancreatic secretion. Two groups (A and B), each consisting of four men, were studied. In group A, the study comprised a control period (I) of 40 minutes followed by a test period (II) of 180 minutes during which normal pancreatic secretion was maintained throughout. In group B, the study comprised a control period (I) of 40 minutes, a stabilization period (II) of 120 minutes, and a test period (III) of 120 minutes. After the control period with normal pancreatic secretion, a new steady state with fixed hormone concentrations was established during the first 90 minutes of period II using simultaneous infusions of somatostatin (250 micrograms/h), insulin (0.15 mU/kg/min) and glucagon, the latter being adjusted to maintain a stable arterial glucose level similar to the preceding control concentration. Thereafter, without further adjustment of the glucagon infusion rate, observations were continued during period III to assess the maintenance of the steady state. In group A, the range of variation in arterial glucose concentrations during periods I and II was 4.0 +/- 0.9 and 6.5 +/- 1.3 mg/dL, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of somatostatin on insulin and glucose levels during insulin infusion in anesthetized dogs

The purpose of the study was to examine the transhepatic and peripheral effects of somatostatin (SN) infusion on plasma glucose and insulin during insulin (IN) infusion. Hepatic blood flow was measured electromagnetically during intermittent sampling from the portal and hepatic veins, femoral artery, and right external jugular vein. Hepatic blood flow [sum of portal vein (PV) and hepatic artery] was similar during IN or IN + SN infusions. IN concentrations decreased in the portal vein from 374.8 +/- 50.3 to 295.8 +/- 25.9 pM (p less than 0.01) when SN was infused with IN. Hepatic venous plasma IN concentration also decreased from 143.6 +/- 26.6 to 88.3 +/- 10.1 pM (p less than 0.01). Plasma IN concentrations in the femoral artery and jugular vein remained unchanged. Hepatic insulin extraction changed from 64 +/- 4% during IN to 72 +/- 3% during IN + SN (p less than 0.01). Hepatic clearance and total body clearance were unchanged. Peripheral venous glucose with a nadir of 3.82 +/- 0.2 mM during IN alone decreased to a nadir of 3.16 +/- 0.27 mM (p less than 0.01) during IN + SN infusion. Mean portal venous glucose concentrations were 5.0 +/- 0.27 and 3.4 +/- 0.19 mM, respectively (p less than 0.01). In two additional experiments in which endogenous C-peptide concentrations were examined in the portal vein and femoral artery, C-peptide levels were lower during IN + SN compared to IN alone. We conclude that SN used to suppress endogenous insulin secretion increases hepatic insulin extraction, lowers glucose concentrations, and suppresses endogenous C-peptide levels to a greater extent than insulin infusion alone.(ABSTRACT TRUNCATED AT 250 WORDS)