Metabolic response to egg white and cottage cheese protein in normal subjects

In type II diabetic subjects, we previously demonstrated differences in the serum insulin, C-peptide, and glucagon response to ingestion of seven different protein sources when administered with 50 g of glucose. The response was smallest with egg white and greatest with cottage cheese protein. In the present study, we compared the responses to 50 g of the above two proteins ingested without glucose in normal male subjects. We also determined the proportion of each ingested protein converted to urea nitrogen. The incremental area response integrated over 8 hours for serum insulin, C-peptide, glucagon, alpha-amino-nitrogen (AAN), and urea nitrogen were all approximately 50% less following egg white. This was associated with a 50% smaller conversion of protein to urea. Overall, 70% of the cottage cheese but only 47% of the egg white protein could be accounted for by urea formation. Most likely the smaller hormonal response to egg white is due to poor digestibility of this protein.     

The insulin and glucose responses to meals of glucose plus various proteins in type II diabetic subjects

We previously have shown that ingested beef protein is just as potent as glucose in stimulating a rise in insulin concentration in type II diabetic patients. A synergistic effect was seen when given with glucose. Therefore, we considered it important to determine if other common dietary proteins also strongly stimulate an increase in insulin concentration when given with glucose. Seventeen type II (non-insulin-dependent) untreated diabetic subjects were given single breakfast meals consisting of 50 g glucose, or 50 g glucose plus 25 g protein in the form of lean beef, turkey, gelatin, egg white, cottage cheese, fish, or soy. The peripheral plasma concentrations of glucose, insulin, glucagon, alpha amino nitrogen, urea nitrogen, free fatty acids, and triglycerides were measured. Following ingestion of the meals containing protein, the plasma insulin concentration was increased further and remained elevated longer compared with the meal containing glucose alone. The relative area under the insulin response curve was greatest following ingestion of the meal containing cottage cheese (360%) and was least with egg white (190%) compared with that following glucose alone (100%). The glucose response was diminished following ingestion of the meals containing protein with the exception of the egg white meals. The peripheral glucagon concentration was decreased following ingestion of glucose alone and increased following all the meals containing protein. The alpha amino nitrogen concentration varied considerably. It was decreased after glucose alone, was unchanged after egg white ingestion, and was greatest after ingestion of gelatin. The free fatty acid concentration decrease was 4- to 8-fold greater after the ingestion of protein with glucose compared with ingestion of glucose alone.     

Effects of glucose, galactose, and lactose ingestion on the plasma glucose and insulin response in persons with non-insulin-dependent diabetes mellitus

Galactose usually is ingested as lactose, which is composed of equimolar amounts of glucose and galactose. The contribution of galactose to the increase in glucose and insulin levels following ingestion of equimolar amounts of galactose and glucose, or lactose, has not been reported in people with non-insulin-dependent diabetes mellitus (NIDDM). Therefore, we studied the effects of galactose ingestion alone, as well as with glucose either independently or in the form of lactose, in subjects with untreated NIDDM. Eight male subjects with untreated NIDDM ingested 25 g glucose, 25 g galactose with or without 25 g glucose, or 50 g lactose as a breakfast meal in random sequence. They also received 50 g glucose on two occasions as a reference. Water only was given as a control meal. Plasma galactose, glucose, glucagon, α-amino nitrogen (AAN), nonesterified fatty acids (NEFA), and serum insulin and C-peptide concentrations were determined over a 5-hour period. The integrated area responses were quantified over the 5-hour period using the water control as a baseline. Following ingestion of 25 g galactose, the maximal increase in plasma galactose concentration was 1 mmol/L. The mean maximal increases in plasma galactose concentration following ingestion of 25 g galactose + 25 g glucose or following 50-g lactose meals were similar and were only 12% of that following ingestion of galactose alone (P < .05). The mean galactose area response over the water control for the 25-g galactose meal was 0.95 ± 0.31 mmol · h/L. That following ingestion of 25 g glucose + 25 g galactose or following the 50-g lactose meal was 0.17 ± 0.07 and 0.13 ± 0.05 mmol · h/L, respectively. Following ingestion of 25-g or 50-g glucose meals, the galactose area responses increased only slightly. The mean glucose area response following the 50-g glucose meals was 14.8 ± 2.5 mmol · h/L. Glucose area responses following ingestion of 25 g galactose, 25 g glucose, 25 g glucose + 25 g galactose, and 50 g lactose were 11%, 49%, 54%, and 60% of that observed following ingestion of 50 g glucose, respectively. The mean insulin area response following ingestion of the 50-g glucose meals was 965 ± 162 pmol · h/L. The insulin area responses observed with 25 g galactose, 25 g glucose, 25 g glucose + 25 g galactose, and 50 g lactose were 24%, 51%, 81%, and 85% of that observed with the 50-g glucose meals, respectively. The C-peptide data confirmed the insulin data. The glucagon concentration was unchanged after galactose ingestion and decreased after glucose ingestion. However, the decrease in the glucagon area response observed with 25 g galactose + 25 g glucose or 50 g lactose was less than that with ingestion of 25 g glucose alone. The latter suggests inhibition of the glucagon response to glucose by the added galactose. In conclusion, ingested galactose results in only a modest increase in plasma glucose concentration. The glucose area responses to galactose and glucose are additive. Oral galactose is a relatively potent insulin secretagogue, and the insulin response is also additive to that following glucose ingestion. Ingestion of glucose with galactose markedly reduces the increase in plasma galactose concentration. The mechanism of this effect remains to be defined.     

The metabolic response to various doses of fructose in type II diabetic subjects.

Eight men with untreated type II diabetes were given 480 mL water containing 15 g, 25 g, 35 g, and 50 g fructose orally, in random sequence. The same subjects were given the same volume of water as a control. They also were given 50 g glucose on two occasions for comparative purposes. Plasma glucose, urea nitrogen, and glucagon, and serum insulin, C-peptide, alpha-amino-nitrogen (AAN), nonesterified fatty acids (NEFA), and triglycerides were determined over the subsequent 5-hour period. The area responses to each dose of fructose were calculated and compared with the water control. The integrated glucose area dose-response was curvilinear, with little increase in glucose until 50 g fructose was ingested. With the 50-g dose, the area response was 25% of the response to 50 g glucose. The insulin response also was curvilinear, but the curve was opposite to that of the glucose curve. Even the smallest dose of fructose resulted in a relatively large increase in insulin, and a near-maximal response occurred with 35 g. The area response to 50 g fructose was 39% of that to 50 g glucose. The C-peptide data were similar to the insulin data. The AAN area response to fructose ingestion was negative. However, the response was progressively less negative with increasing doses. The glucagon area response was positive, but a dose-response relationship was not apparent. The glucagon area response was negative after glucose ingestion, as expected. The urea nitrogen area response was negative, but again, a dose-response relationship to fructose ingestion was not present.(ABSTRACT TRUNCATED AT 250 WORDS)     

Insulin sensitivity predicts glycemia after a protein load

Protein ingestion results in small but distinct changes in plasma glucose and insulin. We hypothesized that the glycemic and/or insulin response to protein might be related to the degree of insulin sensitivity. Our aim was to determine the relationships between insulin sensitivity (assessed by euglycemic-hyperinsulinemic clamp) and postprandial glucose, insulin, C-peptide, and glucagon responses to a 75-g protein meal and a 75-g glucose load. Sixteen lean healthy Caucasian subjects (mean +/- SD age, 25 +/- 6 years; body mass index [BMI], 23.1 +/- 1.7 kg/m2) participated in the study. After the protein meal, the mean plasma glucose declined gradually below fasting levels to a nadir of -0.36 +/- 0.46 mmol/L from 60 to 120 minutes, showing wide intraindividual variation. Insulin sensitivity (M value) was 1.1 to 3.9 mmol/L/m2 min in the subjects and correlated inversely with the plasma glucose response to the protein meal (r = -.58, P = .03), ie, the most insulin-sensitive subjects showed the greatest decline in plasma glucose. In contrast, there was no correlation between insulin sensitivity and the insulin or glucagon response to the protein load, or between the M value and the metabolic responses (glucose, insulin, C-peptide, and glucagon) to the glucose load. Our study suggests that the net effect of insulin and glucagon secretion on postprandial glucose levels after a protein meal might depend on the individual's degree of insulin sensitivity. Gluconeogenesis in the liver may be less susceptible to inhibition by insulin in the more highly resistant subjects, thereby counteracting a decline in plasma glucose.     

The metabolic response to ingestion of proline with and without glucose

Ingested protein results in an increase in circulating insulin and glucagon concentrations and no change, or a slight decrease, in circulating glucose. In subjects with type 2 diabetes, when protein is ingested with glucose, insulin is further increased and the glucose rise is less than when glucose is ingested alone. Presumably these effects are due to the amino acids present in the proteins. The effects of individual amino acids, ingested in physiologic amounts, with or without glucose, have not been determined. Therefore, we have begun a systematic study of the response to ingested amino acids. Eight young, non-obese, subjects (4 men, 4 women) ingested 1 mmol proline/kg lean body mass, 25 g glucose, 25 g glucose + 1 mmol proline/kg lean body mass or water only on 4 separate occasions at 8 am. Blood was obtained before and after ingestion of the test meal over the following 150 minutes. Proline ingestion resulted in a 13-fold increase in the plasma proline concentration. This was decreased by 50% when glucose was ingested with proline. Proline alone had little effect on glucose, insulin, or glucagon concentrations. However, ingestion of proline with glucose resulted in a 23% attenuation of the glucose area response and no change in insulin response compared with the response to that of glucose alone. A glucose-stimulated decrease in glucagon was further facilitated by proline. Ingested proline is readily absorbed. It reduces the glucose-induced increase in glucose concentration in the presence of an unchanged insulin and a decreased glucagon response.     

Leucine, when ingested with glucose, synergistically stimulates insulin secretion and lowers blood glucose

Our laboratory is interested in the metabolic effects of ingested proteins. As part of this research, we currently are investigating the metabolic effects of ingested individual amino acids. The objective of the current study was to determine whether leucine stimulates insulin and/or glucagon secretion and whether, when it is ingested with glucose, it modifies the glucose, insulin, or glucagon response. Thirteen healthy subjects (6 men and 7 women) were studied on 4 different occasions. Subjects were admitted to the special diagnostic and treatment unit after a 12-hour fast. They received test meals at 8:00 am. On the first occasion, they received water only. Thereafter, they received 25 g glucose or 1 mmol/kg lean body mass leucine or 1 mmol/kg lean body mass leucine plus 25 g glucose in random order. Serum leucine, glucose, insulin, glucagon, and α-amino nitrogen concentrations were measured at various times during a 2.5-hour period after ingestion of the test meal. The amount of leucine provided was equivalent to that present in a high-protein meal, that is, that approximately present in a 350-g steak. After leucine ingestion, the leucine concentration increased 7-fold; and the α-amino nitrogen concentration increased by 16%. Ingested leucine did not affect the serum glucose concentration. When leucine was ingested with glucose, it reduced the 2.5-hour glucose area response by 50%. Leucine, when ingested alone, increased the serum insulin area response modestly. However, it increased the insulin area response to glucose by an additional 66%; that is, it almost doubled the response. Ingested leucine stimulated an increase in glucagon. Ingested glucose decreased it. When ingested together, the net effect was essentially no change in glucagon area. In summary, leucine at a dose equivalent to that present in a high-protein meal, had little effect on serum glucose or insulin concentrations but did increase the glucagon concentration. When leucine was ingested with glucose, it attenuated the serum glucose response and strongly stimulated additional insulin secretion. Leucine also attenuated the decrease in glucagon expected when glucose alone is ingested. The data suggest that a rise in glucose concentration is necessary for leucine to stimulate significant insulin secretion. This in turn reduces the glucose response to ingested glucose.     

Glucose intolerance in thyrotoxicosis roles of insulin, glucagon and somatostatin

The responses in plasma glucose, insulin, C-peptide, glucagon and somatostatin to an oral glucose load were studied in 10 thyrotoxic patients and 10 matched euthyroid controls. The thyrotoxic patients had higher mean fasting plasma glucose (P less than 0.05) and responded to oral glucose with an earlier peak at 30 min which was higher than the corresponding glucose level in the controls (P less than 0.05). Impaired glucose tolerance was found in 3 patients. Fasting insulin and C-peptide levels were normal in the thyrotoxic patients when corrected for the higher glucose levels. Following glucose ingestion, there was no significant difference between the areas under the insulin or C-peptide curves in patients and controls, but Seltzer's insulinogenic index was reduced in the patients (P less than 0.01) suggesting an impaired pancreatic B-cell response to oral glucose. Mean basal glucagon was normal in the thyrotoxic patients. However, while in the controls plasma glucagon became suppressed following glucose ingestion (P less than 0.0001), no significant suppression was found in the patients. In the thyrotoxic patients, mean basal somatostatin was normal, but the area under the somatostatin curve following glucose ingestion was significantly increased (P less than 0.02). Our findings suggest that decreased glucagon suppression and impaired insulin response after glucose ingestion are involved in glucose intolerance in thyrotoxicosis. Enhanced somatostatin responses to oral glucose in thyrotoxicosis may have contributed to the observed impairment in pancreatic B-cell responsiveness.     

Infusion of synthetic human C-peptide does not affect plasma glucose, serum insulin, or plasma glucagon in healthy subjects

We studied six healthy male subjects to determine whether a four-hour infusion of synthetic human C-peptide sufficient to achieve mean (+/- SD) peripheral plasma concentrations of 1.3 +/- 0.7 pmol/mL affected plasma glucose, serum insulin, or plasma glucagon. Subjects were studied in a fasting state and following an oral glucose load during four-hour 0.9% NaCl (control) and C-peptide (mean dose: 70 nmol) infusions. No differences were observed between saline and C-peptide infusions for mean values of fasting plasma glucose (94 +/- 6 v 87 +/- 5 mg/dL), serum insulin (3 +/- 1 v 2 +/- 1 microU/mL), or plasma glucagon (124 +/- 65 v 112 +/- 70 pg/dL). Following oral glucose ingestion no differences were detected between saline and C-peptide infusions for mean peak values of plasma glucose (168 +/- 18 v 168 +/- 31) and serum insulin (59 +/- 6 v 57 +/- 21) or mean nadir values of plasma glucagon (80 +/- 73 v 75 +/- 70). There was a slight delay in the insulin rise following oral glucose on the C-peptide infusion day, but differences between mean values for individual sampling times were not statistically significantly different.     

A high concentration of circulating insulin suppresses the glucagon response to hypoglycemia in normal man.

In an attempt to clarify whether circulating insulin per se exerts an inhibitory effect on the hormonal responses to hypoglycemia, with special emphasis on glucagon secretion, nine healthy volunteers were exposed to low dose (244 pmol/kg.h) and high dose (1034 pmol/kg.h) iv insulin infusions for 3 h on two separate occasions. A close to identical arterial hypoglycemia of about 3.4 mmo/L was obtained in both tests by glucose clamping during the high dose test. The corresponding glucose concentration in the venous blood was significantly lower in the high dose test (2.5 +/- 0.1 vs. 3.0 +/- 0.1 mmol/L; P less than 0.01), while the plasma free insulin level was 4 times higher in the high dose test (897 +/- 50 vs. 208 +/- 14 pmol/L). Plasma glucagon was elevated in both experiments, but its rise was reduced during the high dose test after 1 h, yielding an incremental area under the glucagon curve that was significantly smaller than that obtained during the low dose test (213 +/- 70 vs. 348 +/- 81 ng/L.h; P less than 0.05). The plasma adrenaline, noradrenaline, GH, C-peptide, pancreatic polypeptide, and somatostatin profiles were similar in the two tests. We conclude that an inhibitory effect of circulating insulin on the glucagon response to hypoglycemia can be demonstrated in normal man during an infusion of insulin yielding a plasma concentration of about 900 pmol/L. The responses of other hormones studied are not significantly influenced by the circulating insulin level.     

Lack of effect of high-dose biosynthetic human C-peptide on pancreatic hormone release in normal subjects

We studied the effect of high doses of biosynthetic human C-peptide on pancreatic hormone secretion in response to oral (75 g) and intravenous [( IV] 0.33 g/kg of D50%) glucose on normal volunteers. The infusion of human C-peptide at a rate of 360 ng/kg/min body weight, increased the plasma C-peptide concentration from a basal level of 0.32 +/- 0.04 pmol/mL to 38.5 +/- 1.8 pmol/ml. Overall, C-peptide had no significant effect on the serum levels of glucose, insulin, proinsulin, glucagon, and pancreatic polypeptide, either under basal conditions or following IV and oral glucose administration. However, small decreases in glucose and insulin concentrations that were not statistically significant were seen during the first hour after C-peptide infusion. The results of the present studies are therefore consistent with the conclusion that even supraphysiologic plasma concentrations of infused C-peptide do not affect basal insulin secretion or overall insulin secretory responses to oral or IV glucose. However, we cannot definitively exclude a small reduction in insulin secretion in the first hour after oral glucose ingestion.     

Effects of size,time of day and sequence of meal ingestion on carbohydrate tolerance in normal subjects

The effects of size, time of day and sequence of meal ingestion were determined in healthy subjects using a Latin square design. Plasma glucose, insulin and gastric inhibitory polypeptide, but not glucagon, were correlated with meal size. Plasma glucose, but not insulin, gastric inhibitory polypeptide or glucagon, were greater later in the day. The progressive decline in carbohydrate tolerance from 08.00 to 18.00 h was associated with impaired insulin secretion estimated by C-peptide, and with impaired insulin action.     

Carbohydrate metabolism in pregnancy. XIV. Relationships between circulating glucagon,insulin, glucose and amino acids in response to a “mixed meal” in late pregnancy

Gestational influences upon the changes in circulating glucose, amino acids, insulin, and glucagon after the ingestion of a “mixed meal” containing carbohydrate (50 g), protein (25 g), and fat (10 g) were examined. Nine subjects were tested during weeks 30–40 of gestation and again 6–8 wk postpartum. The “mixed meal” elicited greater and more prolonged increases in plasma glucose antepartum, whereas the increments in total serum amino acids were blunted at all time points. In the face of greater glycemic but lesser aminogenic stimulation, the integrated increase in plasma insulin was 60% greater antepartum than post partum, whereas the increment in glucagon was not significantly altered. Thus, integrated insulin/glucagon response was increased during antepartum studies. The insulin preponderance following alimentary challenge with mixed nutrients would suggest that the anabolism of ingested amino acids is “facilitated” during late human pregnancy.     

C-peptide and glucagon profiles in minority children with type 2 diabetes mellitus

The present study was conducted to determine the extent of insulin deficiency and glucagon excess in the hyperglycemia of type 2 diabetes in children. The incidence of type 2 diabetes mellitus in children and adolescents has increased substantially over the past several years. Because insulin and glucagon action both regulate blood glucose concentration, we studied their responses to mixed meals in children with type 2 diabetes. Subjects were 24 patients with type 2 diabetes compared with 24 controls, aged 9--20 yr (predominantly African-Americans), matched for body mass index and sexual maturation. All of those with diabetes were negative for antibodies to glutamic acid decarboxylase. Plasma glucose, glucagon, and serum C-peptide concentrations were measured at 0, 30, 60, 90, and 120 min after a mixed liquid meal (Sustacal) ingestion (7 mL/kg body weight; maximum, 360 mL). The area under the curve (AUC) was calculated by trapezoidal estimation. The incremental C-peptide (Delta CP) in response to the mixed meal was calculated (peak -- fasting C-peptide). The plasma glucose AUC was significantly greater in patients than in controls (mean +/- SEM, 1231 +/- 138 vs. 591 +/- 13 mmol/L x min; P < 0.001). The Delta CP was significantly lower in those with diabetes than in controls (1168 +/- 162 vs. 1814 +/- 222 pmol/L; P < 0.02). Glucagon responses did not differ between the two groups. Hyperglycemia is known to inhibit glucagon secretion. Therefore, our patients with substantial hyperglycemia would be expected to have decreased glucagon responses compared with controls and are thus relatively hyperglucagonemic. Patients were divided into poorly and well controlled subgroups (glycosylated hemoglobin A(1c), > or =7.2% and <7.2%, respectively). There were no significant differences in the Delta CP and glucagon responses between these two subgroups. We next analyzed the data in terms of duration of diabetes (long term, > or =1 yr; short term, <1 yr). The CP was significantly lower in long- vs. short-term patients (768 +/- 232 vs. 1407 +/- 199 pmol/L; P < 0.05). The plasma glucagon AUC was significantly higher in the long- vs. short-term patients (9029 +/- 976 vs. 6074 +/- 291 ng/L x min; P < 0.001). Hemoglobin A(1c) did not differ between long- vs. short-term patients. Our results indicate that relative hypoinsulinemia and hyperglucagonemia represent the pancreatic beta- and alpha-cell dysfunctions in children with type 2 diabetes. The severity of both beta- and alpha-cell dysfunctions appears to be determined by the duration of diabetes.     

The thermogenic and metabolic effects of protein hydrolysate with or without a carbohydrate load in healthy male subjects

High-protein diets are beneficial in weight maintenance because of their satiating and thermogenic effects. These effects may be partly mediated by the hormonal effects of proteins. This study investigated the effect of soy protein hydrolysate (SPH) with and without a carbohydrate pre- and afterload on energy metabolism and hormonal secretion in 8 healthy nonobese subjects. In an additional trial, pea protein hydrolysate was compared to SPH, both with a carbohydrate afterload. The study had a single-blind crossover design. In all cases, 0.4 g protein and/or carbohydrate per kilogram of body weight was tested. Diet-induced thermogenesis (DIT) was measured by ventilated hood measurements, and postprandial blood samples were drawn over 3 hours. Soy protein hydrolysate consumption induced a higher DIT than a carbohydrate (CHO) load. Both conditions induced similar insulin responses. Soy protein hydrolysate induced a glucagon, but no glucose, response; whereas CHO induced a glucose, but no glucagon, response. Soy protein hydrolysate with a CHO pre- or afterload induced similar DIT and insulin responses. No glucose response was found when SPH preceded the CHO load. Total glucagon responses were similar with CHO as pre- and afterload, but time courses were different. Pea protein hydrolysate with a CHO afterload induced both higher insulin and glucagon responses (area under the curve) than SPH with CHO afterload, but DIT was similar in both conditions. In conclusion, this study shows that the larger DIT after protein than after CHO may be related to the glucagon response that is induced by protein but not by CHO; that the protein-induced DIT and glucagon response are not influenced by a CHO pre- or afterload; and that protein ingestion can fully prevent the plasma glucose increase associated with CHO when CHOs are ingested after proteins.     

Secretion and hepatic extraction of insulin after weight loss in obese noninsulin-dependent diabetes mellitus

We assessed the effects of weight loss on pancreatic secretion and hepatic extraction of insulin in 11 obese subjects with noninsulin-dependent diabetes mellitus. Weight loss of 15.4 +/- 2.0 kg (mean +/- SE) resulted in decreased fasting insulin [20.2 +/- 2.5 to 9.8 +/- 2.5 microU/mL (145 +/- 18 to 70 +/- 18 pmol/L); P less than 0.02] and C-peptide (850 +/- 80 to 630 +/- 110 pmol/L; P less than 0.05) levels. The plasma glucose response to oral glucose and iv glucagon was improved with unchanged peripheral insulin levels. When plasma glucose levels were matched to those before weight loss, peripheral serum insulin and plasma C-peptide responses to iv glucagon were increased and similar to those in obese nondiabetic subjects studied at euglycemia. The total insulin response (area under the curve) to iv glucagon was reduced 30% (P less than 0.005), while the total C-peptide response area did not change after weight loss. At matched hyperglycemia, the total response area was enhanced 72% for insulin (P less than 0.002) and 64% for C-peptide (P less than 0.001). Incremental (above basal) response areas after weight loss did not change for insulin, but increased 66% for C-peptide (P less than 0.05). The incremental areas were augmented nearly 2-fold (196%) for insulin (P less than 0.01) and 1.7-fold (173%) for C-peptide (P less than 0.01) when assessed at matched hyperglycemia. Both basal (7.3 +/- 0.5 to 14.1 +/- 1.8; P less than 0.01) and total stimulated (6.1 +/- 0.4 to 8.8 +/- 1.4; P less than 0.05) C-peptide to insulin molar ratios increased after weight loss. We conclude that after weight loss in noninsulin-dependent diabetes mellitus, 1) insulin secretion is decreased in the basal state but increased after stimulation; 2) changes in insulin secretion are reflected by peripheral levels of C-peptide but not insulin, due in part to enhanced hepatic insulin extraction; and 3) at matched levels of hyperglycemia insulin secretion is markedly increased and similar to that in obese nondiabetic subjects studied at euglycemia.     

Metabolic and endocrine responses to a standard mixed meal. A physiologic study

Summary In order to study endocrine and metabolic responses to normal food ingestion, 8 ‘healthy’ subjects received a standard mixed meal which reflected the composition of Western diet (CHO 47%, protein 23%, fat 26%, alcohol 4%), in 20 min. Before and after the meal, in each subject glucose, lactate, FFA, insulin, C-peptide, glucagon and HGH were determined. The results showed that glycemic and insulinemic responses were not very different from those observed after the classical oral glucose tolerance test. Plasma FFA and blood lactate decreased progressively after the meal. Plasma glucagon and HGH showed opposite changes: pancreatic glucagon rose and HGH slightly declined after composite food ingestion. Supported by C.N.R. grant No. 76.01321.04 115.1187.     

Comparison of the pattern of postprandial carbohydrate metabolism after ingestion of a glucose drink or a mixed meal

To determine whether the postprandial pattern of carbohydrate metabolism differs after ingestion of an identical amount of glucose as either a drink or as a part of a mixed meal, normal subjects were studied on two occasions. On both occasions, hepatic and extrahepatic glucose metabolism were assessed using the dual isotope and forearm catheterization techniques as well as indirect calorimetry. Plasma glucose, insulin, and C-peptide concentrations and rate of systemic entry of ingested glucose all were lower (P less than 0.05) during the first 15 min after the mixed meal than after the glucose drink. The integrated C-peptide response was greater (P less than 0.05) after the mixed meal, whereas the integrated suppression of glucagon was greater (P less than 0.05) after the glucose drink. Despite these differences in circulating hormone concentrations, after the first 15 min, the rates of systemic entry of ingested glucose, endogenous glucose release, incorporation of carbon dioxide into glucose, and glucose and lipid oxidation as well as nonoxidative glucose storage were virtually the same after the mixed meal and the glucose drink. We conclude that the pattern of postprandial carbohydrate metabolism after ingestion of a glucose meal is remarkably similar to that after ingestion of a more traditional mixed meal. These data suggest that insights regarding the pattern of postprandial carbohydrate metabolism derived from previous studies employing only a glucose drink are likely to pertain to those observed when healthy individuals ingest a meal that contains protein and fat.     

Pancreatic beta-cell function in cirrhotic patients with and without overt diabetes. C-peptide response to glucagon and to meal

To study the role of pancreatic beta-cell function in glucose intolerance and frank diabetes that sometimes develops in cirrhosis, the C-peptide response to a bolus IV injection of 1 mg of glucagon was measured in nine controls and in two groups of patients with cirrhosis. The first group comprised nine subjects with normal or high-normal fasting plasma glucose and no glycosuria; five of them had impaired glucose tolerance. The second group consisted of eight cirrhotics in whom frank diabetes had developed six to 48 months after the diagnosis of cirrhosis. They were characterized by fasting plasma glucose greater than 140 mg/dL and permanent glycosuria. No differences in the degree of liver impairment or portal-systemic shunting were observed between the two groups. Plasma glucose response to glucagon was similarly reduced in cirrhotic subjects. Basal C-peptide was high normal in patients with cirrhosis, and significantly increased in nondiabetic subjects. By contrast peak C-peptide levels and total C-peptide responses to glucagon were low normal in cirrhotics and significantly reduced in patients with cirrhosis and diabetes. In 14 patients the C-peptide response to a standard meal was also measured. It was significantly reduced in patients with cirrhosis and diabetes (six cases), as compared to cirrhotic subjects without diabetes. Peak C-peptide after IV glucagon significantly correlated with peak C-peptide after the meal (r = .927), or total C-peptide response to meal (r = .871). Impaired insulin secretion may add to insulin resistance in patients with liver cirrhosis, leading to the development of frank diabetes, characterized by fasting hyperglycemia and glycosuria.     

Glyburide enhances the responsiveness of the beta-cell to glucose but does not correct the abnormal patterns of insulin secretion in noninsulin-dependent diabetes mellitus

Eleven patients with noninsulin-dependent diabetes mellitus were studied before and after 6-10 weeks of glyburide therapy. Patients were studied during a 24-h period on a mixed diet comprising 30 Cal/kg divided into three meals. The following day a hyperglycemic clamp study was performed, with glucose levels clamped at 300 mg/dL (16.7 mmol/L) for a 3-h period. Insulin secretion rates were calculated by deconvolution of peripheral C-peptide concentrations using individual C-peptide clearance kinetics derived after bolus injection of biosynthetic human C-peptide. After 6-10 weeks on glyburide, the identical studies were repeated. In response to glyburide, the fasting plasma glucose level decreased from 12.3 +/- 1.2 to 6.8 +/- 0.9 mmol/L. Although the mean glucose over the 24 h of the meal study decreased from 12.7 +/- 1.4 to 10.8 +/- 1.2 mmol/L, postprandial hyperglycemia persisted on therapy, and after breakfast, glucose levels exceeded 10 mmol/L and did not return to fasting levels for the remainder of the day. Fasting serum insulin, plasma C-peptide, and the insulin secretion rate were not different before (152 +/- 48 pmol/L, 0.82 +/- 0.16 pmol/mL, and 196 +/- 34 pmol/min, respectively) and after (186 +/- 28 pmol/L, 0.91 +/- 0.11 pmol/mL, and 216 +/- 23 pmol/min, respectively) glyburide treatment despite lowering of the glucose level. However, average insulin and C-peptide concentrations over the 24-h period increased from 366 +/- 97 pmol/L and 1.35 +/- 0.19 pmol/mL to 434 +/- 76 pmol/L and 1.65 +/- 0.15 pmol/mL, respectively. The total amount of insulin secreted over the 24-h period rose from 447 +/- 58 nmol before therapy to 561 +/- 55 nmol while receiving glyburide. Insulin secretion was demonstrated to be pulsatile in all subjects, with periodicity ranging from 2-2.5 h. The number of insulin secretory pulses was not altered by glyburide, whereas pulse amplitude was enhanced after lunch and dinner, suggesting that the increased insulin secretion is characterized by increased amplitude of the individual pulses. In response to a hyperglycemic clamp at 300 mg/dL (16.7 mmol/L), insulin secretion rose more than 2-fold, from 47 +/- 9 nmol over the 3-h period before treatment to 103 +/- 21 nmol after glyburide therapy. We conclude that the predominant mechanism of action of glyburide in patients receiving therapy for 6-10 weeks is to increase the responsiveness of the beta-cell to glucose.(ABSTRACT TRUNCATED AT 400 WORDS)