Fixed ratio dosing of pramlintide with regular insulin before a standard meal in patients with type 1 diabetes.

Amylin is co-secreted with insulin and is therefore lacking in patients with type 1 diabetes. Replacement with fixed ratio co-administration of insulin and the amylin analogue pramlintide may be superior to separate dosing. This concept was evaluated in a ratio-finding study. Patients with type 1 diabetes were enrolled in a randomized, single-masked, standard breakfast crossover study using regular human insulin injected simultaneously with pramlintide 6, 9 or 12 mcg/unit insulin or placebo. Insulin dosage was reduced by 30% from patients' usual estimates. Plasma glucose, glucagon and pramlintide and adverse events were assessed. All ratios reduced 0-3-h glucose and glucagon increments by >50%. No hypoglycaemia occurred. Adverse events were infrequent and generally mild. All pramlintide/insulin ratios markedly and safely reduced glycaemic excursions and suppressed glucagon secretion in the immediate postprandial state. Further study using one of these ratios to explore the efficacy and safety of longer-term meal-time and basal hormone replacement is warranted.

Pharmacometrics and the transition to model-based development.

As the transition to model-based drug development continues, pharmacometric analysis will have an increasingly important role across the entire life cycle of drug discovery, development, regulatory approval, and commercialization. For this reason, pharmacometrics can--and should--have an integrating function in the transformation to model-based development. This essay describes an approach for formalizing the pharmacometrics process using the disciplines encompassed by enterprise engineering.

Mechanism of the postreceptor defect in insulin action in human obesity. Decrease in glucose transport system activity.

We have studied insulin-stimulated 3-O-methyl glucose transport by isolated adipocytes prepared from 10 normal and 11 obese individuals. The results demonstrated that the insulin-glucose transport dose-response curves were shifted to the right in cells from the obese patients, and that the magnitude of this rightward shift was significantly correlated to the reduction in adipocyte insulin receptors in individual subjects (r = 0.48, P less than 0.01). In three obese patients a rightward shift in the dose-response curve could be demonstrated and there was no decrease in maximal insulin effect. This corresponded to in vivo glucose clamp results showing only a rightward shift in the insulin dose-response curve for overall glucose disposal in these three subjects (1980. J. Clin. Invest. 65: 1272-1284). In the remaining eight obese patients, the in vitro glucose transport studies showed not only a rightward shift in the dose-response curves but also a marked decrease in basal and maximally insulin-stimulated rates of transport, indicating a postreceptor defect in insulin action. Again, this was consistent with the in vivo glucose clamp studies demonstrating a marked postreceptor defect in these individuals. In conclusion, these results indicate that the mechanism of the postreceptor defect in insulin action, which exists in many obese patients, is related to a decrease in the activity of the glucose transport effector system.

Mechanisms of insulin resistance in human obesity: evidence for receptor and postreceptor defects.

UNLABELLED: To assess the mechanisms of the insulin resistance in human obesity, we have determined, using a modification of the euglycemic glucose clamp technique, the shape of the in vivo insulin-glucose disposal dose-response curves in 7 control and 13 obese human subjects. Each subject had at least three euglycemic studies performed at insulin infusion rates of 15, 40, 120, 240, or 1,200 mU/M2/min. The glucose disposal rate was decreased in all obese subjects compared with controls (101 +/- 16 vs. 186 +/- 16 mg/M2/min) during the 40 mU/M2/min insulin infusion. The mean dose-response curve for the obese subjects was displaced to the right, i.e., the half-maximally effective insulin concentration was 270 +/- 27 microU/ml for the obese compared with 130 +/- 10 microU/ml for controls. In nine of the obese subjects, the dose-response curves were shifted to the right, and maximal glucose disposal rates (at a maximally effective insulin concentration) were markedly decreased, indicating both a receptor and a postreceptor defect. On the other hand, four obese patients had right-shifted dose-response curves but reached normal maximal glucose disposal rates, consistent with decreased insulin receptors as the only abnormality. When the individual data were analyzed, it was found that the lease hyperinsulinemic, least insulin-resistant patients displayed only the receptor defect, whereas those with the greatest hyperinsulinemia exhibited the largest post-receptor defect, suggesting a continuous spectrum of defects as one advances from mild to severe insulin resistance. When insulin's ability to suppress hepatic glucose output was assessed, hyperinsulinemia produced total suppresssion in all subjects. The dose-response curve for the obese subjects was shifted to the right, indicating a defect in insulin receptors. Insulin binding to isolated adipocytes obtained from the obese subjects was decreased, and a highly significant inverse linear relationship was demonstrated between insulin binding and the serum insulin concentration required for halfmaximal stimulation of glucose disposal. IN CONCLUSION: (a) decreased cellular insulin receptors contribute to the insulin resistance associated with human obesity in all subjects; (b) in the least hyperinsulinemic, insulin-resistant patients, decreased insulin receptors are the sole defect, whereas in the more hyperinsulinemic, insulin-resistant patients, the insulin resistance is the result of a combination of receptor and postreceptor abnormalities; (c) all obese patients were insensitive to insulin's suppressive effects on hepatic glucose output; this was entirely the result of decreased insulin receptors; no postreceptor defect in this insulin effect was demonstrated.

Mechanisms of insulin resistance in aging.

We have studied 17 elderly and 27 non-elderly, nonobese subjects (mean age 69+/-1 and 37+/-2 yr, respectively) to assess the mechanisms responsible for the abnormal carbohydrate tolerance associated with aging. Serum glucose and insulin levels were significantly elevated in the elderly subjects compared with the nonelderly subjects during a 75-g oral glucose tolerance test, suggesting an insulin resistant state. Peripheral insulin sensitivity was assessed in both groups using the euglycemic glucose clamp technique during an insulin infusion rate of 40 mU/m(2) per min. Similar steady-state serum insulin levels led to a peripheral glucose disposal rate of 151+/-17 mg/m(2) per min in the elderly compared with a value of 247+/-12 mg/m(2) per min in the nonelderly, thus documenting the presence of insulin resistance in the elderly subjects. Insulin binding to isolated adipocytes and monocytes was similar in the elderly and nonelderly groups (2.34+/-0.33 vs. 2.62+/-0.24% and 5.04+/-1.10 vs. 5.12+/-1.07%), respectively. Thus, insulin resistance in the presence of normal insulin binding suggests the presence of a postreceptor defect in insulin action. This was confirmed by performing additional euglycemic clamp studies using infusion rates of 15 and 1,200 mU/m(2) per min to assess the contours of the dose-response relationship. These studies revealed a 39 and 25% decrease in the glucose disposal rate in the elderly subjects, respectively. The results confirm the presence of a postreceptor defect as well as a rightward shift in the dose-response curve. Insulin's ability to suppress hepatic glucose output was less in the elderly subjects during the 15 mU/m(2) per min insulin infusion (77+/-5 vs. 89+/-4% suppression), but hepatic glucose output was fully and equally suppressed in both groups during the 40 and 1,200 mU/m(2) per min infusion. Finally, a significant inverse relationship was observed between the degree of glucose intolerance in the individual elderly subjects, as reflected by the 2-h serum glucose level during the oral glucose tolerance test, and the degree of peripheral insulin resistance as assessed by the glucose disposal rate during the 40 mU/m(2) per min insulin infusion (r = 0.59, P < 0.01).We conclude that carbohydrate intolerance develops as part of the aging process. This carbohydrate intolerance appears to be the consequence of peripheral insulin resistance caused by a postreceptor defect in target tissue insulin action, which causes both a decrease in the maximal rate of peripheral glucose disposal and a rightward shift in the insulin action dose-response curve. In elderly subjects, the severity of the abnormality in carbohydrate tolerance is directly correlated to the degree of peripheral insulin resistance.

Influence of hyperglycemia on insulin's in vivo effects in type II diabetes.

The present study was designed to quantitate the interaction between the decrease in target tissue insulin action seen in subjects with Type II diabetes and the mass action effect of glucose exerted via the prevailing hyperglycemic state. To this end, euglycemic glucose clamp studies were performed in 26 control subjects using insulin infusion rates of 15, 40, 120, 240, and 1,200 mU/M2 per min and in 10 Type II diabetic subjects using insulin infusion rates of 120 and 1,200 mU/M2 per min. The results of these euglycemic studies indicated that insulin-stimulated peripheral glucose disposal was decreased in the Type II diabetics due to a combined receptor (rightward shift in the dose-response curve) and postreceptor defect in insulin action (decreased maximal response), whereas the decrease in insulin-mediated suppression of hepatic glucose output (HGO) was consistent with a defect in insulin binding (rightward shift in dose-response curve). Hyperglycemic glucose clamp studies were also performed in the Type II diabetics at their respective fasting serum glucose levels (mean [+/- SE] 280 +/- 17 mg/dl) employing insulin infusion rates of 15, 40, 120, and 1,200 mU/M2 per min. In the presence of their basal level of hyperglycemia, the noninsulin-dependent diabetes mellitus (NIDDM) subjects exhibited rates of overall glucose disposal that were similar to those observed in control subjects studied at euglycemia at similar steady state insulin concentrations. This suggests that in Type II diabetics, the mass action effect of glucose partially compensates for the marked decrease in insulin-stimulated glucose uptake observed under euglycemic conditions. However, even in the presence of hyperglycemia, insulin levels below 100 microU/ml had little effect and maximally effective insulin levels increased peripheral glucose disposal only 2.8-fold (142 +/- 7-413 +/- 47 mg/M2 per min) above basal in the Type II diabetics, compared with a sixfold increase (75 +/- 4-419 +/- 34 mg/M2 per min) in the control subjects studied at euglycemia. Thus, the severe insulin resistance that is a characteristic feature of NIDDM remains apparent. Basal HGO was elevated in the NIDDM subjects (157 +/- 6 vs. 76 +/- 4 mg/M2 per min for controls) and a high degree of correlation was found between the basal rate of HGO and the fasting glucose level (r = 0.80, P less than 0.01). The presence of hyperglycemia augmented insulin-mediated suppression of HGO, but did not restore it to normal. We concluded that: (a) in the presence of basal hyperglycemia, physiologic insulin levels exerts a diminished effect to suppress HGO and stimulate peripheral glucose disposal in NIDDM; (b) basal HGO is elevated in untreated Type II diabetics, and this may serve to maintain the level of hyperglycemia required to compensate for the decrease in peripheral insulin action; and (c) fasting hyperglycemia exerts a suppressive effect on HGO but does not completely compensate for the decrease in hepatic insulin action in Type II diabetics.

Rates of noninsulin-mediated glucose uptake are elevated in type II diabetic subjects.

Although insulin is extremely potent in regulating glucose transport in insulin-sensitive tissues, all tissues are capable of taking up glucose by facilitated diffusion by means of a noninsulin-mediated glucose uptake (NIMGU) system. Several reports have estimated that in the postabsorptive state the majority of glucose disposal occurs via a NIMGU mechanism. However, these estimates have been either derived or extrapolated in normal humans. In the present study we have directly measured NIMGU rates in 11 normal (C) and 7 Type II noninsulin-dependent diabetic subjects (NIDDM; mean +/- SE fasting serum glucose, 249 +/- 24 mg/dl). To accomplish this, the serum glucose was clamped at a desired level during a period of insulin deficiency induced by a somatostatin infusion (SRIF, 550 micrograms/h). With a concomitant [3-3H]glucose infusion, we could isotopically quantitate glucose disposal rates (Rd) during basal (basal insulin present) and insulin-deficient (SRIF) conditions. With this approach we found that (a) basal Rd was greater in NIDDM than in C, 274 +/- 31 vs. 150 +/- 7 mg/min, due to elevated hepatic glucose output, (b) NIMGU composes 75 +/- 5% of basal Rd in C and 71 +/- 4% in NIDDM, (c) NIDDMS have absolute basal NIMGU rates that are twice that of C (195 +/- 23 vs. 113 +/- 8 mg/min, P less than 0.05), (d) when C were studied under conditions of insulin deficiency (SRIF infusion) and at a serum glucose level comparable to that of the NIDDM group (250 mg/dl), their rates of NIMGU were the same as that of the NIDDM group (186 +/- 19 vs. 195 +/- 23 mg/min; NS). We conclude that (a) in the postabsorptive state, NIMGU is the major pathway for glucose disposal for both C and NIDDM; (b) for a given glucose level the efficiency of NIMGU (NIMGU divided by serum glucose level) is equal in C and NIDDM, but since basal Rd is elevated in NIDDMs their absolute basal rates of NIMGU are higher; and (c) elevated basal rates of NIMGU in NIDDM may play a role in the pathogenesis of the late complications of diabetes.

Insulin receptors in isolated human adipocytes. Characterization by photoaffinity labeling and evidence for internalization and cellular processing.

We photolabeled and characterized insulin receptors in isolated adipocytes from normal human subjects and then studied the cellular fate of the labeled insulin-receptor complexes at physiologic temperatures. The biologically active photosensitive insulin derivative, B2(2-nitro-4-azidophenylacetyl)des-PheB1-insulin (NAPA-DP-insulin) was used to photoaffinity label the insulin receptors, and the specifically labeled cellular proteins were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and autoradiography. At saturating concentrations, the binding of 125I-NAPA-DP-insulin to the isolated adipocytes at 16 degrees C was rapid (half-maximal in approximately 1 min and maximal in approximately 10 min) and approximately 25% of the specifically bound ligand was covalently linked to the cells by a 3-min exposure to long-wave (366 nm) ultraviolet light. Analysis of the photolabeled cellular proteins by PAGE in the absence of disulfide reductants revealed the specific labeling of a major protein band of Mr 330,000 and two less intense bands of Mr 295,000 and 260,000. Upon reduction of disulfide bonds with dithiothreitol, all three unreduced forms of the insulin receptor were converted into a major labeled Mr-125,000 band and a less intensely labeled Mr-90,000 band. The labeling of the Mr-125,000 receptor subunit was saturable and native porcine insulin effectively inhibited (half-maximal inhibition at 12 ng/ml) the photolabeling of this binding subunit by NAPA-DP insulin. When intact adipocytes photolabeled at 16 degrees C (a temperature that inhibits endocytosis) were immediately trypsinized, all of the labeled receptor bands were converted into small molecular weight tryptic fragments, indicating that at 16 degrees C all of the labeled insulin-receptor complexes remained on the cell surface. However, when the photolabeled cells were further incubated at 37 degrees C and then trypsinized, a proportion of the labeled receptors became trypsin insensitive, indicating that this fraction has been translocated to the cell interior and thus was inaccessible to the trypsin in the incubation medium. The intracellular translocation of the labeled receptors was observed within 2 min, became half-maximal by 10 min, and maximal by approximately 30 min of incubation at 37 degrees C. Cellular processing of the internalized insulin-receptor complexes also occurred, since incubation at 37 degrees C (but not 16 degrees C) resulted in the generation of a Mr-115,000 component from the labeled receptors. Inclusion of chloroquine, a drug with lysosomotropic properties, in the incubation media caused a time-dependent increase (maximal increase of 50% above control by 2 h at 37 degrees C) in the intracellular pool of labeled receptors. In contrast to these findings in human adipocytes, no appreciable internalization of insulin-receptor complexes and no chloroquine effect was observed in cultures human IM-9 lymphocytes during a 1-h incubation at 37 degrees C. We concluded that in isolated human adipocytes: (a) the subunit structure of insulin receptors is the same as that reported for several other tissues, (b) insulin-receptor complexes are rapidly internalized and processed at physiologic temperatures, and (c) the cellular processing of insulin-receptor complexes occurs at one or more chloroquine-sensitive intracellular site(s).

Receptor and postreceptor defects contribute to the insulin resistance in noninsulin-dependent diabetes mellitus.

We have assessed the mechanisms involved in the pathogenesis of the insulin resistance associated with impaired glucose tolerance and Type II diabetes mellitus by exploring, by means of the euglycemic glucose-clamp technique, the in vivo dose-response relationship between serum insulin and the overall rate of glucose disposal in 14 control subjects; 8 subjects with impaired glucose tolerance, and 23 subjects with Type II diabetes. Each subject had at least three studies performed on separate days at insulin infusion rates of 40, 120, 240, 1,200, or 1,800 mU/M2 per min. In the subjects with impaired glucose tolerance, the dose-response curve was shifted to the right (half-maximally effective insulin level 240 vs. 135 microunits/ml for controls), but the maximal rate of glucose disposal remained normal. In patients with Type II diabetes mellitus, the dose-response curve was also shifted to the right, but in addition, there was a posal. This pattern was seen both in the 13 nonobese and the 10 obese diabetic subjects. Among these patients, an inverse linear relationship exists (r = -0.72) so that the higher the fasting glucose level, the lower the maximal glucose disposal rate. Basal rates of hepatic glucose output were 74 +/- 4, 82 +/- 7, 139 +/- 24, and 125 +/- 16 mg/M2 per min for the control subjects, subjects with impaired glucose tolerance, nonobese Type II diabetic subjects, and obese Type II diabetic subjects, respectively. Higher serum insulin levels were required to suppress hepatic glucose output in the subjects with impaired glucose tolerance and Type II diabetics, compared with controls, but hepatic glucose output could be totally suppressed in each study group. We conclude that the mechanisms of insulin resistance in patients with impaired glucose tolerance and in patients with Type II noninsulin-dependent diabetes are complex, and result from heterogeneous causes. (a) In the patients with the mildest disorders of carbohydrate homeostasis (patients with impaired glucose tolerance) the insulin resistance can be accounted for solely on the basis of decreased insulin receptors. (b) In patients with fasting hyperglycemia, insulin resistance is due to both decreased insulin receptors and postreceptor defect in the glucose mechanisms. (c) As the hyperglycemia worsens, the postreceptor defect in peripheral glucose disposal emerges and progressively increases. And (d) no postreceptor defect was detected in any of the patient groups when insulin's ability to suppress hepatic glucose output was measured.

Effects of insulin infusion on human skeletal muscle pyruvate dehydrogenase, phosphofructokinase, and glycogen synthase. Evidence for their role in oxidative and nonoxidative glucose metabolism.

To determine whether activation by insulin of glycogen synthase (GS), phosphofructokinase (PFK), or pyruvate dehydrogenase (PDH) in skeletal muscle regulates intracellular glucose metabolism, subjects were studied basally and during euglycemic insulin infusions of 12, 30, and 240 mU/m2 X min. Glucose disposal, oxidative and nonoxidative glucose metabolism were determined. GS, PFK, and PDH were assayed in skeletal muscle under each condition. Glucose disposal rates were 2.37 +/- 0.11, 3.15 +/- 0.19, 6.71 +/- 0.44, and 11.7 +/- 1.73 mg/kg X min; glucose oxidation rates were 1.96 +/- 0.18, 2.81 +/- 0.28, 4.43 +/- 0.32, and 5.22 +/- 0.52. Nonoxidative glucose metabolism was 0.39 +/- 0.13, 0.34 +/- 0.26, 2.28 +/- 0.40, and 6.52 +/- 1.21 mg/kg X min. Both the proportion of active GS and the proportion of active PDH were increased by hyperinsulinemia. PFK activity was unaffected. Activation of GS was correlated with nonoxidative glucose metabolism, while activation of PDH was correlated with glucose oxidation. Sensitivity to insulin of GS was similar to that of nonoxidative glucose metabolism, while the sensitivity to insulin of PDH was similar to that of glucose oxidation. Therefore, the activation of these enzymes in muscle may regulate nonoxidative and oxidative glucose metabolism.

Decreased activation of skeletal muscle glycogen synthase by mixed-meal ingestion in NIDDM.

Glycogen synthase (GS) catalyzes the formation of glycogen in human skeletal muscle, the tissue responsible for disposal of a significant portion of an oral carbohydrate load. Non-insulin-dependent diabetes mellitus (NIDDM) is characterized by fasting and postprandial hyperglycemia in conjunction with reduced rates of insulin-stimulated glucose disposal and storage in peripheral tissues, including muscle. Our objectives in this study were to determine whether ingestion of a mixed meal activates GS in control nondiabetic subjects and whether meal-related GS activation is reduced in NIDDM. To accomplish this, mixed formula meals were administered to 11 NIDDM and 9 age- and weight-matched nondiabetic control subjects. Plasma glucose and insulin values were measured before and for 90 min after meal ingestion. Skeletal muscle biopsies were performed just before and 90 min after meal ingestion for measurement of GS activity. Compared with control subjects, NIDDM subjects had significantly higher postprandial hyperglycemia and reduced postprandial hyperinsulinemia. GS was activated by meal ingestion in control subjects to a significantly greater extent than in NIDDM subjects. In NIDDM subjects, activation of GS was inversely correlated with fasting plasma glucose (r = .69, P less than .05). Therefore, NIDDM is characterized by reduced activation of a key step in the process of muscle glycogen repletion after a meal. Reduced activation of GS by a mixed meal in NIDDM may contribute to the reduced glucose disposal after a meal, thus contributing to the hyperglycemia observed in these subjects.

Day-long integrated serum insulin and C-peptide profiles in patients with NIDDM. Correlation with urinary C-peptide excretion.

To determine whether non-insulin-dependent diabetes mellitus (NIDDM) is characterized by day-long hypoinsulinemia, we measured 24-h serum profiles for glucose, insulin, and C-peptide by use of a constant-rate blood-withdrawal technique in diabetic and control subjects fed isocaloric meals. When only lean subjects were considered, diabetic subjects (relative body weight 0.99 +/- 0.3) and control subjects (relative body weight 0.95 +/- 0.03) had similar 24-h integrated serum insulin concentrations (13.4 +/- 2.5 vs. 16.1 +/- 2.0 microU/ml, P NS) due to the offsetting effects of increased basal levels and decreased postprandial responses in NIDDM. In contrast, both basal and meal-stimulated insulin levels were decreased in obese NIDDM subjects (relative body weight 1.39 +/- 0.07) compared with obese control subjects (relative body weight 1.60 +/- 0.08), resulting in a 61% reduction in the 24-h integrated insulin value (18.7 +/- 1.5 vs. 48.4 +/- 13.7 microU/ml). Thus, the capacity to increase 24-h integrated serum insulin as a function of relative body weight was impaired in NIDDM subjects (r = 0.27, P NS) compared with control subjects (r = .70, P less than .01). In contrast, 24-h integrated C-peptide was decreased (P less than .01) in both lean (0.92 +/- 0.13 pM/ml) and obese (1.52 +/- 0.19 pM/ml) NIDDM patients compared with the respective control groups (1.50 +/- 0.13 and 3.03 +/- 0.44 pM/ml). The molar ratio of 24-h integrated C-peptide to insulin was diminished in lean but not obese NIDDM compared with control subjects. A 3-wk period of intensive insulin therapy led to normalization of the mean 24-h integrated insulin (but not integrated serum C-peptide) value in NIDDM compared with a control group that had an identical mean relative body weight. The 24-h urinary C-peptide measured on the same day as the serum profile was correlated (P less than .01) with both the 24-h integrated serum insulin (r = .69) and C-peptide (r = .67) concentrations in control subjects but not in NIDDM subjects (r = .20 and .04, respectively, P NS). Additionally, the urinary clearance of C-peptide was increased in NIDDM (38.1 +/- 7.8 vs. 20.4 +/- 1.7 ml/min in control subjects, P less than .05) and varied with treatment status (26.0 +/- 4.6 ml/min after insulin therapy).(ABSTRACT TRUNCATED AT 400 WORDS)

The metabolic clearance of insulin and the feedback inhibition of insulin secretion are altered with aging.

Elevated basal and stimulated insulin levels have been previously demonstrated in elderly human subjects. To see whether these elevated insulin levels are due to alterations in either the metabolic clearance rate (MCR) for insulin or the feedback inhibition of insulin secretion, we have studied 14 elderly and 19 nonelderly subjects, mean age 70 +/- 2 and 35 +/- 2 yr, respectively. Fasting serum insulin and C-peptide levels were elevated in the elderly compared with the nonelderly, 17 +/- 2 versus 11 +/- 1 microU/ml, P less than 0.01 and 0.95 +/- 0.12 versus 0.47 +/- 0.07 pmol/ml, P less than 0.001. Euglycemic hyperinsulinemia created by insulin infusion rates of 15, 40, and 1200 mU/m2/min with glucose held constant resulted in steady-state serum insulin levels of 65 +/- 4, 109 +/- 8, and 11,316 +/- 890 versus 34 +/- 2, 96 +/- 5, and 11,083 +/- 1079 microU/ml in the elderly and nonelderly subjects, respectively. The MCR of insulin was decreased by 46% in the elderly compared with the nonelderly (10.1 +/- 0.7 versus 18.7 +/- 1.4 ml/kg/min) at the insulin infusion rate of 15 mU/m2/min with no difference observed between the two groups at the higher insulin infusions. Steady-state suppression of C-peptide by exogenous insulin was similar, 73 +/- 2% versus 72 +/- 2% and 70 +/- 3% versus 64 +/- 5% in the nonelderly and elderly groups during the 15 and 40 mU/m2/min insulin infusions, respectively. However, 50% suppression was achieved within 30 min in the nonelderly group compared with 70 min in the elderly group during the low-dose infusion.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of hyperglucagonemia in maintenance of increased rates of hepatic glucose output in type II diabetics.

Elevated rates of basal hepatic glucose output (bHGO) are significantly correlated with the fasting serum glucose (FSG) level in subjects with non-insulin-dependent diabetes mellitus (NIDDM). This observation suggests that bHGO is a major determinant of the severity of the diabetic state in these subjects. In addition, basal glucagon levels (bGL) are higher in these diabetics than in control subjects, despite the concurrent basal hyperglycemia and hyperinsulinemia, two factors known to suppress glucagon secretion. Although bGL is responsible for sustaining two-thirds of bHGO in normal humans, its role in sustaining elevated rates of bHGO in NIDDM has not been previously defined. To this end, we have studied 13 normal and 10 NIDDM subjects; mean FSG levels were 90 +/- 2 and 262 +/- 21 mg/dl, respectively (P less than .001). The mean fasting serum insulin and glucagon levels were higher in the diabetics than in the controls: 17 +/- 2 vs. 9 +/- 1 microU/ml (P less than .01) and 208 +/- 37 vs. 104 +/- 15 pg/ml (P less than .01), respectively. On separate days, HGO was assessed isotopically (with 3-[3H]glucose) in the basal state and during infusion of somatostatin (SRIF) (600 micrograms/h) alone and in conjunction with replacement infusions of glucose and insulin. The results demonstrate that bHGO is higher in diabetics than in controls (145 +/- 12 vs. 89 +/- 3 mg X m-2 X min-1, P less than .01); during infusion of SRIF alone, HGO was suppressed by 25% (P less than .05) and 34% (P less than .05) of the basal value in controls and diabetics, respectively; when the studies were repeated with glucose levels held constant at or near the FSG level by the glucose-clamp technique, the pattern and degree of HGO suppression was similar to that obtained by infusion of SRIF alone; during isolated glucagon deficiency (SRIF + insulin, 5 mU X m-2 min-1, with serum glucose maintained at basal level), HGO was suppressed by 71 +/- 8% of the basal value in controls (P less than .001) and by 58 +/- 7% in diabetics (P less than .001); and when isolated glucagon deficiency with similar hyperglycemia was created in control subjects, HGO was suppressed by 87% of the basal value.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of insulin treatment on insulin secretion and insulin action in type II diabetes mellitus.

We have studied the effects of 3 wk of continuous subcutaneous insulin infusion (CSII) on endogenous insulin secretion and action in a group of 14 type II diabetic subjects with a mean (+/-SEM) fasting glucose level of 286 +/- 17 mg/dl. Normal basal and postprandial glucose levels were achieved during insulin therapy at the expense of marked peripheral hyperinsulinemia. During the week of posttreatment evaluation, the subjects maintained a mean fasting glucose level of 155 +/- 11 mg/dl off insulin therapy, indicating a persistent improvement in carbohydrate homeostasis. Adipocyte insulin binding and in vivo insulin dose-response curves for glucose disposal using the euglycemic clamp technique were measured before and after therapy to assess the effect on receptor and postreceptor insulin action. Adipocyte insulin binding did not change. The insulin dose-response curve for overall glucose disposal remained right-shifted compared with age-matched controls, but the mean maximal glucose disposal rate increased by 74% from 160 +/- 14 to 278 +/- 18 mg/m2/min (P less than 0.0005). The effect of insulin treatment on basal hepatic glucose output was also assessed; the mean rate was initially elevated at 159 +/- 8 mg/m2/min but fell to 90 +/- 5 mg/m2/min in the posttreatment period (P less than 0.001), a value similar to that in control subjects. Endogenous insulin secretion was assessed in detail and found to be improved after exogenous insulin therapy. Mean 24-h integrated serum insulin and C-peptide concentrations were increased from 21,377 +/- 2766 to 35,584 +/- 4549 microU/ml/min (P less than 0.01) and from 1653 +/- 215 to 2112 +/- 188 pmol/ml/min (P less than 0.05), respectively, despite lower glycemia. Second-phase insulin response to an intravenous (i.v.) glucose challenge was enhanced from 170 +/- 53 to 1022 +/- 376 microU/ml/min (P less than 0.025), although first-phase response remained minimal. Finally, the mean insulin and C-peptide responses to an i.v. glucagon pulse were unchanged in the posttreatment period, but when glucose levels were increased by exogenous glucose infusion to approximate the levels observed before therapy and the glucagon pulse repeated, responses were markedly enhanced. Simple and multivariate correlation analysis showed that only measures of basal hepatic glucose output and the magnitude of the postbinding defect in the untreated state could be related to the respective fasting glucose levels in individual subjects.(ABSTRACT TRUNCATED AT 400 WORDS)

Metabolic consequences of very-low-calorie diet therapy in obese non-insulin-dependent diabetic and nondiabetic subjects.

To determine the effects of very-low-calorie diets on the metabolic abnormalities of diabetes and obesity, we have studied 10 obese, non-insulin-dependent diabetic (NIDDM) and 5 obese, nondiabetic subjects for 36 days on a metabolic ward during consumption of a liquid diet of 300 kcal/day with 30 g of protein. Rapid improvement occurred in the glycemic indices of the diabetic subjects, with mean (+/- SEM) fasting plasma glucose falling from 291 +/- 21 to 95 +/- 6 mg/dl (P less than 0.001) and total glycosylated hemoglobin from 13.1 +/- 0.7% to 8.8 +/- 0.3% (P less than 0.001) (normal reference range 5.5-8.5%). Lipid elevations were normalized with plasma triglycerides reduced to less than 100 mg/dl and total plasma cholesterol to less than 150 mg/dl in both groups. Hormonal and substrate responses were also comparable between groups with reductions in insulin and triiodothyronine and moderate elevations in blood and urinary ketoacid levels without a corresponding rise in free fatty acids. Electrolyte balance for sodium, potassium, calcium, and phosphorus was initially negative but approached equilibrium by completion of the study. Magnesium, in contrast, remained in positive balance in both groups throughout. Total nitrogen loss varied widely among all subjects, ranging from 70 to 367 g, and showed a strong positive correlation with initial lean body mass (N = 0.83, P less than 0.001) and total weight loss (N = 0.87, P less than 0.001). The nondiabetic group, which had a significantly greater initial body weight and lean body mass than the diabetic group, also had a significantly greater weight loss of 450 +/- 31 g/day compared with 308 +/- 19 g/day (P less than 0.01) in the diabetic subjects. The composition of the weight lost at completion was similar in both groups and ranged from 21.6% to 31.3% water, 3.9% to 7.8% protein, and 60.9% to 74.5% fat. The contribution of both water and protein progressively decreased and fat increased, resulting in unchanged caloric requirements during the diet. This study demonstrates that short-term treatment with a very-low-calorie diet in both obese diabetic and nondiabetic subjects results in: safe and effective weight loss associated with the normalization of elevated glucose and lipid levels, a large individual variability in total nitrogen loss determined principally by the initial lean body mass, and progressive increments in the contribution of fat to weight loss with stable caloric requirements and no evidence of a hypometabolic response.

In vivo deactivation of peripheral, hepatic, and pancreatic insulin action in man.

The in vivo deactivation of insulin action has been studied in 10 lean, nondiabetic subjects using a modification of the euglycemic glucose clamp technique. Following cessation of 40- and 120-mU/m2/min insulin infusions, the serum insulin levels fell to one-half their initial values (mean +/- SE) of 126 +/- 7 and 350 +/- 14 microunits/ml in 7 +/- 1 and 8 +/- 1 min, respectively. The mean incremental glucose disposal rates (IGDR) fell more slowly following discontinuation of the 40- and 120-mU/m2/min insulin infusions, so that the time required for the IGDRs to fall to one-half their initial values (D50 IGDR) were were 42 +/- 5 and 78 +/- 1 min, respectively. Mean hepatic glucose output was totally suppressed during the 40- and 120-mU/m2/min insulin infusions, remained completely suppressed following cessation of the infusions for 50 and 80 mi, and subsequently returned to basal levels. The times required for the HGOs to return to one-half their basal levels (R50 HGO) were 59 +/- 8 and 119 +/- 6 min, respectively. The times required for insulin action to decrease to one-half the initial values in the periphery (D50 IGDR) and in the liver (R50 HGO) were correlated with the preceding steady-state glucose disposal rates in individual subjects (r = 0.75, P less than 0.001 and r = 0.58, P less than 0.05, respectively). The suppression of endogenous insulin secretion by exogenous insulin infusions was also studied in 4 subjects during a total of 5 euglycemic glucose clamps; the mean basal serum C-peptide level was 0.67 +/- 0.24 pmol/ml before administration of the exogenous insulin, fell to 0.34 +/- 0.17 pmol/ml during the steady-state phase of the study, and remained suppressed throughout the duration of the deactivation phase of the glucose clamp. Residual pancreatic insulin secretory capacity was demonstrated by a rise in the serum C-peptide level to 1.77 +/- 0.50 pmol/ml at 120 min following a standardized meal given at the conclusion of the deactivation phase of the glucose clamp. These results demonstrate that the deactivation of insulin action in the periphery, liver, and pancreas lags behind the disappearance of insulin from the plasma. The mechanisms responsible for this lag in in vivo deactivation are not known for certain, but may include slower clearance of insulin form tissue compartments than form the plasma, the necessity for the target tissues to generate specific deactivation signals, or a slow rate of decay of saturable steps in the cellular activation process.

Effect of a high carbohydrate diet on insulin binding to adipocytes and on insulin action in vivo in man.

We studied the effects of short-term (5 days) and long-term (2 wk) high carbohydrate (75%) feedings on insulin binding to isolated adipocytes and insulin sensitivity in vivo in normal subjects. Ingestion of the high carbohydrate diet led to daylong hyperinsulinemia in both short- and long-term groups. Insulin binding to isolated adipocytes was decreased in both groups; in the short-term groups this decrease in insulin binding was caused by a decrease in the receptor affinity, whereas in the long-term group it was caused by a decrease in receptor number. On the other hand, despite this decrease in insulin binding, total in vivo insulin sensitivity was markedly improved in both groups. In conclusion, (1) the short-term adaptive response of the insulin receptor is a decrease in binding affinity whereas the long-term response is a decrease in receptor number, (2) sustained and chronic hyperinsulinemia can lead to a decrease in the number of cellular insulin receptors, (3) high carbohydrate diets lead to a general increase in insulin's ability to promote glucose removal from plasma, and (4) the paradox of enhanced insulin sensitivity in the face of decreased insulin binding can be explained if high carbohydrate diets also lead to an increase in the activity of steps in glucose metabolism distal to the insulin receptor.

The acute and chronic effects of sulfonylurea therapy in type II diabetic subjects.

Although sulfonylurea agents have been used in the clinical management of type II diabetes (non-insulin-dependent diabetes mellitus, NIDDM) for over two decades, the mechanisms responsible for their hypoglycemic action remain controversial. We have quantitated glycemic control, endogenous insulin secretion in response to mixed meals, adipocyte insulin binding, insulin-mediated peripheral glucose disposal, and basal hepatic glucose output in 17 type II diabetic subjects before and after 3 mo of therapy with the second-generation, sulfonylurea compound glyburide in an attempt to identify the factors responsible for the clinical response to the drug. In addition, 9 subjects were treated for an additional 15 mo to see if the response to the drug changed with time. The mean fasting serum glucose level fell from an initial value of 264 +/- 17 mg/dl to 178 +/- 16 mg/dl after 3 mo of drug therapy. Endogenous insulin secretion increased in all subjects, but the increase was most marked in those subjects who continued to exhibit fasting hyperglycemia (fasting serum glucose greater than 175 mg/dl) after 3 mo of therapy. Adipocyte insulin binding was unchanged after 3 mo of therapy, while the maximal rate of peripheral glucose disposal was increased by 23%, indicating enhancement of peripheral insulin action at a postreceptor site(s). Basal hepatic glucose output showed a significant correlation with the fasting serum glucose level both before and after therapy (r = 0.86, P less than 0.001) and fell from 141 +/- 12 mg/m2/min before therapy to 107 +/- 11 mg/m2/min after 3 mo of therapy.(ABSTRACT TRUNCATED AT 250 WORDS)

In vivo deactivation of proinsulin action on glucose disposal and hepatic glucose production in normal man.

We have studied the deactivation of the in vivo actions of insulin and biosynthetic human proinsulin (recombinant DNA) to stimulate the glucose disposal rate (GDR) and to inhibit hepatic glucose output (HGO) in man. Twelve healthy, lean, young subjects were studied using a modification of the euglycemic glucose clamp technique. Subjects received 4-h infusions on separate occasions of insulin (15 mU/m2/min equivalent to 0.54 microgram/m2/min) or proinsulin (2.75 micrograms/m2/min), achieving steady-state serum levels of 32 +/- 3 microU/ml (equivalent to 0.23 +/- 0.02 pmol/ml) and 3.7 +/- 0.2 pmol/ml, respectively. Suppression of HGO was similar (83-84%) with proinsulin and insulin, but stimulation of GDR above basal was greater with insulin (3.41 +/- 0.43 versus 1.98 +/- 0.28 mg/kg/min, P less than 0.001). Following cessation of the hormone infusions, serum proinsulin concentration fell in a biphasic fashion with half-times of 25 and 146 min for the two phases. Serum half-disappearance time for insulin was 5 min. Deactivation of the hormone's effects to stimulate GDR was 50% complete by 35 min after insulin and 71 min after proinsulin. In contrast, 50% of the recovery times for the effect on suppression of HGO were 55 min after insulin and 188 min after proinsulin. Serum glucagon levels did not differ significantly after the insulin and proinsulin infusions. In summary: (1) Deactivation of proinsulin and insulin's effects to suppress HGO proceeds more slowly than deactivation of their effects to stimulate GDR; and (2) There is a markedly prolonged and disproportionately delayed deactivation of proinsulin's effects on suppression of HGO. This later finding may prove of therapeutic value in the treatment of diabetes mellitus.