The purpose of this study was to examine the response of pancreatic beta-cells to changes in insulin sensitivity in women at high risk for type 2 diabetes. Oral glucose tolerance tests (OGTTs) and frequently sampled intravenous glucose tolerance tests (FSIGTs) were conducted on Latino women with impaired glucose tolerance and a history of gestational diabetes before and after 12 weeks of treatment with 400 mg/day troglitazone (n = 13) or placebo (n = 12). Insulin sensitivity was assessed by minimal model analysis, and beta-cell insulin release was assessed as acute insulin responses to glucose (AIRg) and tolbutamide (AIRt) during FSIGTs and as the 30-min incremental insulin response (30-min dINS) during OGTTs. Beta-cell compensation for insulin resistance was assessed as the product (disposition index) of minimal model insulin sensitivity and each of the 3 measures of beta-cell insulin release. In the placebo group, there was no significant change in insulin sensitivity or in any measure of insulin release, beta-cell compensation for insulin resistance, or glucose tolerance. Troglitazone treatment resulted in a significant increase in insulin sensitivity, as reported previously. In response, AIRg did not change significantly, so that the disposition index for AIRg increased significantly from baseline (P = 0.004) and compared with placebo (P = 0.02). AIRt (P = 0.001) and 30-min dINS (P = 0.02) fell with improved insulin sensitivity during troglitazone treatment, so that the disposition index for each of these measures of beta-cell function did not change significantly from baseline (P > 0.20) or compared with placebo (P > 0.3). Minimal model analysis revealed that 89% of the change from baseline in insulin sensitivity during troglitazone treatment was accounted for by lowered plasma insulin concentrations. Neither oral nor intravenous glucose tolerance changed significantly from baseline or compared with placebo during troglitazone treatment. The predominant response of beta-cells to improved insulin sensitivity in women at high risk for type 2 diabetes was a reduction in insulin release to maintain nearly constant glucose tolerance.

To detect and understand the changes in beta-cell function in the pathogenesis of type 2 diabetes, an accurate and precise estimation of prehepatic insulin secretion rate (ISR) is essential. There are two common methods to assess ISR, the deconvolution method (by Eaton and Polonsky)-considered the "gold standard"-and the combined model (by Vølund et al.). The deconvolution method is a 2-day method, which generally requires separate assessment of C-peptide kinetics, whereas the combined model is a single-day method that uses insulin and C-peptide data from a single test of interest. The validity of these mathematical techniques for quantification of insulin secretion have been tested in dogs, but not in humans. In the present studies, we examined the validity of both methods to recover the known infusion rates of insulin and C-peptide mimicking ISR during an oral glucose tolerance test. ISR from both the combined model and the deconvolution method were accurate, i.e., recovery of true ISR was not significantly different from 100%. Furthermore, both maximal and total ISRs from the combined model were strongly correlated to those obtained by the deconvolution method (r = 0.89 and r = 0.82, respectively). These results indicate that both approaches provide accurate assessment of prehepatic ISRs in type 2 diabetic patients and control subjects. A simplified version of the deconvolution method based on standard kinetic parameters for C-peptide (Van Cauter et al.) was compared with the 2-day deconvolution method, and a close agreement was found for the results of an oral glucose tolerance test. We also studied whether C-peptide kinetics are influenced by somatostatin infusion. The decay curves after bolus injection of exogenous biosynthetic human C-peptide, the kinetic parameters, and the metabolic clearance rate were similar whether measured during constant peripheral somatostatin infusion or without somatostatin infusion. Assessment of C-peptide kinetics can be performed without infusion of somatostatin, because the endogenous insulin concentration remains constant. Assessment of C-peptide kinetics with and without infusion of somatostatin results in nearly identical secretion rates for insulin during an oral glucose tolerance test.

Glucose toxicity (i.e., glucose-induced reduction in insulin secretion and action) may be mediated by an increased flux through the hexosamine-phosphate pathway. Glucosamine (GlcN) is widely used to accelerate the hexosamine pathway flux, independently of glucose. We tested the hypothesis that GlcN can affect insulin secretion and/or action in humans. In 10 healthy subjects, we sequentially performed an intravenous glucose (plus [2-3H]glucose) tolerance test (IVGTT) and a euglycemic insulin clamp during either a saline infusion or a low (1.6 micromol x min(-1) x kg(-1)) or high (5 micromol x min(-1) x kg(-1) [n = 5]) GlcN infusion. Beta-cell secretion, insulin (SI*-IVGTT), and glucose (SG*) action on glucose utilization during the IVGTT were measured according to minimal models of insulin secretion and action. Infusion of GlcN did not affect readily releasable insulin levels, glucose-stimulated insulin secretion (GSIS), or the time constant of secretion, but it increased both the glucose threshold of GSIS (delta approximately 0.5-0.8 mmol/l, P < 0.03-0.01) and plasma fasting glucose levels (delta approximately 0.3-0.5 mmol/l, P < 0.05-0.02). GlcN did not change glucose utilization or intracellular metabolism (glucose oxidation and glucose storage were measured by indirect calorimetry) during the clamp. However, high levels of GlcN caused a decrease in SI*-IVGTT (delta approximately 30%, P < 0.02) and in SG* (delta approximately 40%, P < 0.05). Thus, in humans, acute GlcN infusion recapitulates some metabolic features of human diabetes. It remains to be determined whether acceleration of the hexosamine pathway can cause insulin resistance at euglycemia in humans.

Insulin immunization in animal models induces T-helper (Th) 2-like antibody subclass responses to insulin and other beta-cell antigens. The aim of this study was to determine whether exposure to insulin in humans resulted in a similar subclass bias of the humoral immune response. Levels of IgG subclass antibodies to insulin (IAs), GAD, and IA-2 were measured before and after treatment with insulin in the following groups of patients: 29 patients with newly diagnosed type 1 diabetes treated with intravenous and/or subcutaneous insulin; 10 newly diagnosed patients randomized to cyclosporin A (CsA) or placebo plus subcutaneous insulin for 12 months; and 14 islet cell antibody-positive relatives receiving either intravenous and subcutaneous insulin prophylaxis or no treatment. At the onset of diabetes, the major subclass distributions of insulin autoantibodies (IAAs) were IgG1 and, to a lesser extent, IgG4. After insulin treatment in the 29 new-onset patients, IAs were initially of the IgG1 subclass. IgG4-IAs appeared later, but at 12 months, they were at higher levels than IgG1-IAs in 11 patients. Responses were higher in children compared with adults and were higher in subjects with IAAs (P < 0.001). Insulin prophylaxis in relatives showed a similar profile, with a decline in levels of IgG1-IAs after cessation of daily subcutaneous insulin. Patients treated with CsA took longer to develop IAs and showed suppressed levels of IgG4-IAs; however, their levels of high-titer IgG1-IAs persistently rebounded after completion of CsA therapy. Despite the presence of IgG4-IAs in most insulin-treated patients and relatives, a shift to IgG4-anti-GAD or IgG4-IA-2 was not found for up to 3 years after the initiation of insulin therapy. While our findings need to be correlated with T-cell cytokine responses, we suggest that the strong IgG4-IA response in insulin-treated patients is consistent with an enhancement of Th2 immunity, but there is no evidence of subsequent spreading of potentially Th2-associated IgG4 responses to other autoantigens.

To study the effect of nonesterified fatty acids (NEFAs) on uncoupling protein-2 (UCP-2) and uncoupling protein-3 (UCP-3) gene expression, a triglyceride emulsion was infused for 5 h in 14 healthy volunteers. A euglycemic-hyperinsulinemic clamp was administered concomitantly in 7 of the 14 subjects. The mRNA levels of UCP-2 and of the short (UCP-3S) and long (UCP-3L) isoforms of UCP-3 were quantified by reverse transcription-competitive polymerase chain reaction in tissue biopsies taken before and at the end of the infusion periods. Plasma NEFA concentrations increased from 362+/-52 to 989+/-157 micromol/l (P = 0.018) during triglyceride infusion. UCP-3L (8+/-1 vs. 19+/-2 amol/microg total RNA, P = 0.018) and UCP-3S (11+/-2 vs. 17+/-3 amol/microg total RNA, P = 0.027) mRNA levels increased in skeletal muscle during triglyceride infusion. UCP-3L mRNA levels were positively correlated with plasma NEFA concentrations (r = 0.53, P = 0.005) and with lipid oxidation rates (r = 0.56, P = 0.004) determined by indirect calorimetry. In contrast, the expression of UCP-2 was not affected by lipid infusion in skeletal muscle or in subcutaneous adipose tissue. During the hyperinsulinemic clamp (plasma insulin concentrations 202+/-12 pmol/l), NEFA levels (405+/-49 vs. 648+/-77 micromol/l, P = 0.063) and lipid oxidation rates (0.67+/-0.09 vs. 0.84+/-0.10 mg x kg(-1) x min(-1), P = 0.091) were not significantly increased during triglyceride infusion. Under such conditions, the induction of UCP-3L and UCP-3S mRNA expression was totally prevented (8+/-2 vs. 8+/-1 and 8 +/-2 vs. 9+/-2 amol/microg total RNA, respectively). We conclude that increased plasma NEFA levels by lipid infusion for 5 h induces the expression of UCP-3 but not UCP-2 in humans. During triglyceride infusion, physiological hyperinsulinemia appears to prevent the induction of UCP-3 mRNA levels.

Troglitazone and metformin lower glucose levels in diabetic patients without increasing plasma insulin levels. We compared the insulin sparing actions of these two agents and their effects on insulin sensitivity and insulin secretion in 20 type 2 diabetic patients. To avoid the confounding effect of improved glycemic control on insulin action and secretion, patients were first rendered euglycemic with 4 weeks of continuous subcutaneous insulin infusion (CSII) before randomization to CSII plus troglitazone (n = 10) or CSII plus metformin (n = 10); euglycemia was maintained for another 6-7 weeks. Insulin sensitivity was assessed by a hyperinsulinemic-euglycemic clamp 1) at baseline, 2) after 4 weeks of CSII, and 3) after CSII plus either troglitazone or metformin. The 24-h glucose, insulin, and C-peptide profiles were performed on the day before the second and third glucose clamps. Good glycemic control was achieved with CSII alone and was maintained with CSII plus an oral agent (mean 24-h glucose: troglitazone, 6.2+/-0.6 mmol/l; metformin, 6.2 +/-0.3 mmol/l). Insulin requirements decreased 53% with troglitazone compared with CSII alone (48+/-4 vs. 102+/-13 U/day, P < 0.001), but only 31% with metformin (76+/-13 vs. 110+/-18 U/day, P < 0.005). The 24-h C-peptide profiles were similar. Normal fasting hepatic glucose output was maintained with both agents despite lower insulin levels than on CSII alone. Insulin sensitivity did not change significantly with CSII alone or with CSII plus metformin, but improved 29% with CSII plus troglitazone (P < 0.005 vs. CSII alone) and was then 45% higher than in the CSII plus metformin patients (P < 0.005). In conclusion, metformin has no effect on insulin-stimulated glucose disposal independent of glycemic control in type 2 diabetes. Troglitazone (600 mg/day) has greater insulin-sparing effects than metformin (1,700 mg/day) in CSII-treated euglycemic patients. This is probably explained by the peripheral tissue insulin-sensitizing effects of troglitazone.

Nitric oxide (NO) appears to play a role in contraction-stimulated glucose uptake in isolated rodent skeletal muscle; however, no studies have examined this question in humans. Seven healthy men completed two 30-min bouts of supine cycling exercise at 60 +/- 2% peak pulmonary oxygen uptake (VO2 peak), separated by 90 min of rest. The NO synthase inhibitor N(G)-monomethyl-L-arginine ([L-NMMA]; total dose 5 mg/kg body weight) or saline (control) were administered via the femoral artery for the final 20 min of exercise in a randomized blinded crossover design. L-Arginine (5 mg/kg body weight) was co-infused during the final 5 min of each exercise bout. Leg blood flow (LBF) was measured by thermodilution in the femoral vein, and leg glucose uptake was calculated as the product of LBF and femoral arteriovenous (AV) glucose difference. L-NMMA infusion significantly (P < 0.05) reduced leg glucose uptake compared with control (48 +/- 12% lower at 15 min, mean +/- SE). The reduction in glucose uptake was due solely to a decrease in AV glucose difference, as there was no effect of L-NMMA infusion on LBF during exercise. Co-infusion of L-arginine restored glucose uptake during L-NMMA infusion to levels similar to control. These results indicate that NO production contributes substantially to exercise-mediated skeletal muscle glucose uptake in humans independent of skeletal muscle blood flow.

Adequate comparisons of the relative performance of different tests of beta-cell function are not available. We compared discrimination of commonly used in vivo tests of beta-cell function across a range of glucose tolerance in seven subjects with normal glucose tolerance (NGT), eight subjects with impaired glucose tolerance (IGT), and nine subjects with type 2 diabetes. In random order, each subject underwent two of each of the following tests: 1) frequently sampled 0.3-g/kg intravenous glucose tolerance test (FSIVGTT) with MinMod analysis; 2) homeostasis model assessment (HOMA) from three samples at 5-min intervals with a model incorporating immunoreactive or specific insulin measurements; and 3) continuous infusion of 180 mg x min(-1) x m(-2) glucose with model assessment (CIGMA) of three samples at 50, 55, and 60 min (1-h CIGMA) and at 110, 115, and 120 min (2-h CIGMA). The discrimination of each test was assessed by the ratio of the within-subject SD to the underlying between-subject SD, the discriminant ratio (DR). The degree to which tests measured the same physiological variable was assessed using Pearson's correlation coefficient adjusted for attenuation due to test imprecision. An unbiased line of equivalence, taking into account the imprecision of both tests, was used to compare results. Beta-cell function assessed from HOMA and beta-cell function assessed from CIGMA (CIGMA%beta) (using immunoreactive insulin) had higher DRs than first-phase intravenous glucose tolerance test-derived incremental insulin peak, area, insulin-to-glucose index, and acute insulin response to glucose from FSIVGTT-MinMod. CIGMA%beta (immunoreactive insulin) had the highest DR. FSIVGTT-derived first-phase insulin response tests correlated only moderately with HOMA and CIGMA. Using specific rather than immunoreactive insulin for HOMA and CIGMA did not improve discriminatory power. Simple tests such as HOMA and CIGMA, using immunoreactive insulin, offer better beta-cell function discrimination across subjects with NGT, IGT, and type 2 diabetes than measurements derived from FSIVGTT first-phase insulin response.

Cholesteryl ester transfer protein (CETP) transfers cholesteryl esters from HDL to VLDL and LDL. Phospholipid transfer protein (PLTP) transfers phospholipids between lipoproteins, converts HDL3 into larger and smaller particles, and is involved in pre-beta-HDL generation. We examined the effects of 24-h hyperinsulinemia (30 mU x kg(-1) x h(-1)) and 24-h Acipimox (250 mg/4 h) on plasma lipids as well as CETP and PLTP activities (measured with exogenous substrate assays) in eight healthy and eight type 2 diabetic subjects. After 24 h of insulin, plasma free fatty acids (FFAs), HDL cholesterol, and plasma apolipoprotein AI decreased in healthy subjects and type 2 diabetic patients (P < 0.05). Plasma triglycerides did not significantly change in either group. After 24 h of Acipimox, all parameters, including plasma triglycerides, decreased in both groups (P < 0.05). Insulin decreased plasma PLTP activity by 17.6% after 24 h in healthy subjects (P < 0.05) and 10.2% in diabetic patients (P < 0.05 vs. baseline; P < 0.05 vs. healthy subjects). Acipimox lowered PLTP activity by 10.3% in healthy subjects (P < 0.05) and 11.3% in diabetic patients (P < 0.05). When insulin was infused for 3 h after Acipimox, a further decrease was found only in healthy subjects. Plasma CETP activity decreased by 9.5% after 24 h of insulin in healthy subjects (P < 0.05), but not in diabetic patients. Acipimox did not decrease plasma CETP activity in either group. In healthy subjects, the PLTP responses with insulin and Acipimox were larger than the changes in CETP activity (P < 0.05). These findings suggest that there is a metabolic link between the regulation of plasma FFA and PLTP, but not CETP. The PLTP response to insulin is blunted in type 2 diabetes.

Diabetic patients have greater risk for coronary heart disease (CHD) events after coronary artery bypass graft (CABG) surgery than nondiabetic patients. The Post CABG trial studied the effects of aggressive cholesterol lowering and low-dose anticoagulation in diabetic patients compared with nondiabetic patients. A double-blind, randomized clinical trial in 1,351 patients (1-11 years after CABG), the Post CABG trial consisted of two interventions (aggressive cholesterol-lowering versus moderate lowering and low-dose warfarin versus placebo) on angiographic end points. Angiographic changes in saphenous vein graft conduits 4.3 years after entry were compared in 116 diabetic and 1,235 nondiabetic patients. Seven clinical centers participated in the trial, as well as the National Institutes of Health project office (National Heart, Lung, and Blood Institute), the coordinating center (Maryland Medical Research Institute), and the Angiogram Reading Center (University of Minnesota). Baseline characteristics of the diabetic patients differed from the nondiabetic patients in the following ways: percentage of women participants, 15 vs. 7%, P = 0.002; mean baseline weight, 87.4 vs. 82.8 kg, P = 0.006; mean BMI, 29.5 vs. 27.6 kg/m2, P = 0.0002; mean systolic blood pressure, 141.7 vs. 133.6, P < 0.0001; mean triglyceride concentrations, 2.09 vs. 1.77 mmol/l, P < 0.0001; and mean HDL cholesterol concentrations, 0.93 vs. 1.02 mmol, P = 0.0001. The percentage of clinical events was higher in diabetic than nondiabetic patients (20.6 vs. 13.4, P = 0.033) and angiographic outcomes were not different. The benefits of aggressive cholesterol lowering were comparable in diabetic and nondiabetic patients for the angiographic end points. Warfarin use was not associated with clinical or angiographic benefit. Diabetic patients in the Post CABG trial had more CHD risk factors at study entry and higher clinical event rates during the study than nondiabetic patients. The benefits of aggressive cholesterol lowering in diabetic patients were comparable to those in nondiabetic patients for both angiographic and clinical end points. The small number of diabetic patients provided limited power to detect significant differences between diabetic and nondiabetic patients or between diabetic patients in the aggressive versus moderate cholesterol treatment strategies.

We have determined the individual and combined effects of insulin and prior exercise on leg muscle protein synthesis and degradation, amino acid transport, glucose uptake, and alanine metabolism. Normal volunteers were studied in the postabsorptive state at rest and about 3 h after a heavy leg resistance exercise routine. The leg arteriovenous balance technique was used in combination with stable isotopic tracers of amino acids and biopsies of the vastus lateralis muscle. Insulin was infused into a femoral artery to increase the leg insulin concentrations to high physiologic levels without substantively affecting the whole-body level. Protein synthesis and degradation were determined as rates of intramuscular phenylalanine utilization and appearance, and muscle fractional synthetic rate (FSR) was also determined. Leg blood flow was greater after exercise than at rest (P<0.05). Insulin accelerated blood flow at rest but not after exercise (P<0.05). The rates of protein synthesis and degradation were greater during the postexercise recovery (65+/-10 and 74+/-10 nmol x min(-1) x 100 ml(-1) leg volume, respectively) than at rest (30+/-7 and 46+/-8 nmol x min(-1) x 100 ml(-1) leg volume, respectively; P<0.05). Insulin infusion increased protein synthesis at rest (51+/-4 nmol x min(-1) x 100 ml(-1) leg volume) but not during the postexercise recovery (64+/-9 nmol x min(-1) x 100 ml(-1) leg volume; P<0.05). Insulin infusion at rest did not change the rate of protein degradation (48+/-3 nmol x min(-1) 100 ml(-1) leg volume). In contrast, insulin infusion after exercise significantly decreased the rate of protein degradation (52+/-9 nmol x min(-1) x 100 ml(-1) leg volume). The insulin stimulatory effects on inward alanine transport and glucose uptake were three times greater during the postexercise recovery than at rest (P<0.05). In contrast, the insulin effects on phenylalanine, leucine, and lysine transport were similar at rest and after exercise. In conclusion, the ability of insulin to stimulate glucose uptake and alanine transport and to suppress protein degradation in skeletal muscle is increased after resistance exercise. Decreased amino acid availability may limit the stimulatory effect of insulin on muscle protein synthesis after exercise.

To test the hypothesis that glycemic thresholds for cognitive dysfunction during hypoglycemia, like those for autonomic and symptomatic responses, shift to lower plasma glucose concentrations after recent antecedent hypoglycemia in patients with type 1 diabetes mellitus (T1DM), 15 patients were studied on two occasions. Cognitive functions were assessed during morning hyperinsulinemic stepped hypoglycemic clamps (85, 75, 65, 55, and 45 mg/dl steps) after, in random sequence, nocturnal (2330-0300) hypoglycemia (48 +/- 2 mg/dl) on one occasion and nocturnal euglycemia (109 +/- 1 mg/dl) on the other. Compared with nondiabetic control subjects (n = 12), patients with T1DM had absent glucagon (P = 0.0009) and reduced epinephrine (P = 0.0010), norepinephrine (P = 0.0001), and neurogenic symptom (P = 0.0480) responses to hypoglycemia; the epinephrine (P = 0.0460) and neurogenic symptom (P = 0.0480) responses were reduced further after nocturnal hypoglycemia. After nocturnal hypoglycemia, in contrast to nocturnal euglycemia, there was less deterioration of cognitive function overall (P = 0.0065) during hypoglycemia based on analysis of the sum of standardized scores (z-scores). There was relative preservation of measures of pattern recognition and memory (the delayed non-match to sample task, P = 0.0371) and of attention (the Stroop arrow-word task, P = 0.0395), but not of measures of information processing (the paced serial addition task) or declarative memory (the delayed paragraph recall task), after nocturnal hypoglycemia. Thus, glycemic thresholds for hypoglycemic cognitive dysfunction, like those for autonomic and symptomatic responses to hypoglycemia, shift to lower plasma glucose concentrations after recent antecedent hypoglycemia in patients with T1DM.

To define the mechanism of insulin's anticatabolic action, the effects of three different dosages of insulin (0.25, 0.5, and 1.0 mU x kg(-1) x min(-1)) versus saline on protein dynamics across splanchnic and skeletal muscle (leg) beds were determined using stable isotopes of phenylalanine, tyrosine, and leucine in 24 healthy subjects. After an overnight fast, protein breakdown in muscle exceeded protein synthesis, causing a net release of amino acids from muscle bed, while in the splanchnic bed protein synthesis exceeded protein breakdown, resulting in a net uptake of these amino acids. Insulin decreased (P < 0.003) muscle protein breakdown in a dose-dependent manner with no effect on muscle protein synthesis, thus decreasing the net amino acid release from the muscle bed. In contrast, insulin decreased protein synthesis (P < 0.03) in the splanchnic region with no effect on protein breakdown, thereby decreasing the net uptake of the amino acids. In addition, insulin also decreased (P < 0.001) leucine nitrogen flux substantially more than leucine carbon flux, indicating increased leucine transamination (an important biochemical process for nitrogen transfer between amino acids and across the organs), in a dose-dependent manner, with the magnitude of effect being greater on skeletal muscle than on the splanchnic bed. In conclusion, muscle is in a catabolic state in human subjects after an overnight fast and provides amino acids for synthesis of essential proteins in the splanchnic bed. Insulin achieves amino acid balance across splanchnic and skeletal muscle beds through its differential effects on protein dynamics in these tissue beds.

Stimulation of beta3-adrenoceptors by selective agonists improves insulin action and stimulates energy metabolism in various rodent models of obesity and type 2 diabetes. Whether selective beta3-adrenoceptor stimulation exerts metabolic actions in humans remains to be proven. The effects of a highly selective beta3-adrenoceptor agonist on insulin action, energy metabolism, and body composition were assessed in 14 healthy young lean male volunteers (age 22.5 +/- 3.3 years, 15 +/- 5% body fat [mean +/- SD]) randomly assigned to 8 weeks of treatment with either 1,500 mg/day of CL 316,243 (n = 10) or placebo (n = 4). Insulin-mediated glucose disposal (IMGD), nonoxidative glucose disposal (NOGD), oxidative glucose disposal (OGD) (indirect calorimetry), and splanchnic glucose output (SGO; beta3-[H3]glucose) were determined during a 100-min hyperinsulinemic-euglycemic glucose clamp (40 mU x m(-2) x min(-1)) before and after 4 and 8 weeks of treatment. The 24-h energy expenditure (24-EE), 24-h respiratory quotient (24-RQ), and the oxidation rates of fat and carbohydrate were determined in a respiratory chamber before and after 8 weeks. After 4 weeks, treatment with CL 316,243 increased IMGD (+45%, P < 0.01) in a plasma concentration-dependent manner (r = 0.76, P < 0.02). This effect was due to an 82% increase in NOGD (P < 0.01), while OGD and SGO remained unchanged. The effects on insulin action were markedly diminished after 8 weeks; this was significantly related to an unexpected decline in the plasma concentrations of CL 316,243 (-36%, P = 0.08). At this time, 24-RQ was lowered (P < 0.001), corresponding to a 23% increase in fat oxidation (P < 0.01) and a 17% decrease in carbohydrate oxidation (P = 0.05). The 24-EE after 8 weeks did not differ from baseline, and there was no change in body weight or body composition. Plasma concentrations of glucose, insulin, and leptin were unaffected by treatment, while free fatty acid concentrations increased by 41% (P < 0.05), again linearly with the achieved plasma concentration of CL 316,243 (r = 0.67, P < 0.05). Treatment with CL 316,243 had no effect on heart rate or blood pressure and caused no cases of tremors. We conclude that treatment of lean male subjects with CL 316,243 increases insulin action and fat oxidation, both in a plasma concentration-dependent manner. This is the first study to demonstrate unequivocal metabolic effects of a highly selective beta3-adrenoceptor agonist in humans.

We examined whether the ACE gene insertion/deletion (I/D) polymorphism modulates renal disease progression in IDDM and how ACE inhibitors influence this relationship. The EURODIAB Controlled Trial of Lisinopril in IDDM is a multicenter randomized placebo-controlled trial in 530 nonhypertensive, mainly normoalbuminuric IDDM patients aged 20-59 years. Albumin excretion rate (AER) was measured every 6 months for 2 years. Genotype distribution was 15% II, 58% ID, and 27% DD. Between genotypes, there were no differences in baseline characteristics or in changes in blood pressure and glycemic control throughout the trial. There was a significant interaction between the II and DD genotype groups and treatment on change in AER (P = 0.05). Patients with the II genotype showed the fastest rate of AER progression on placebo but had an enhanced response to lisinopril. AER at 2 years (adjusted for baseline AER) was 51.3% lower on lisinopril than placebo in the II genotype patients (95% CI, 15.7 to 71.8; P = 0.01), 14.8% in the ID group (-7.8 to 32.7; P = 0.2), and 7.7% in the DD group (-36.6 to 37.6; P = 0.7). Absolute differences in AER between placebo and lisinopril at 2 years were 8.1, 1.7, and 0.8 microg/min in the II, ID, and DD groups, respectively. The significant beneficial effect of lisinopril on AER in the II group persisted when adjusted for center, blood pressure, and glycemic control, and also for diastolic blood pressure at 1 month into the study. Progression from normoalbuminuria to microalbuminuria (lisinopril versus placebo) was 0.27 (0.03-2.26; P = 0.2) in the II group, and 1.30 (0.33-5.17; P = 0.7) in the DD group (P = 0.6 for interaction). Knowledge of ACE genotype may be of value in determining the likely impact of ACE inhibitor treatment.

On the basis of the positive outcome of animal experiments, several large placebo-controlled trials are underway and aiming for the first time at the prevention of an immune-mediated disease, type 1 diabetes. The first of these trials, The Deutsche Nicotinamide Intervention Study (DENIS), evaluated the clinical efficacy of high doses of nicotinamide in children at high risk for IDDM. Nicotinamide has been shown to protect beta-cells from inflammatory insults and to improve residual beta-cell function in patients after onset of IDDM. Individuals at high risk for developing IDDM within 3 years were identified by screening the siblings (age 3-12 years) of patients with IDDM for the presence of high titer (> or =20 Juvenile Diabetes Foundation [JDF] U) islet cell antibodies. Probands (n = 55) were randomized into placebo and nicotinamide (slow release, 1.2 g x m(-2) x day(-1)) receiving groups and followed prospectively in a controlled clinical trial using a sequential design. Rates of diabetes onset were similar in both groups throughout the observation period (maximum 3.8 years, median 2.1 years). This sequential design provides a 10% probability of a type II error against a reduction of the cumulative diabetes incidence at 3 years from 30 to 6% by nicotinamide. The trial was terminated when the second sequential interim analysis after the eleventh case of diabetes showed that the trial had failed to detect a reduction of the cumulative diabetes incidence at 3 years from 30 to 6% (P = 0.97). The group receiving nicotinamide exhibited decreased first-phase insulin secretion in response to intravenous glucose (P = 0.03). No other side effects were observed. We conclude that in this subgroup of diabetes-prone individuals at very high risk and with an assumed rapid disease progression, nicotinamide treatment did not cause a major decrease or delay of diabetes development. However, the data do not exclude the possibility of a less strong, but potentially meaningful, risk reduction in this cohort, or a major clinical effect of nicotinamide in individuals with less risk of progression to IDDM than studied here.

The objective of the study was to examine the potential differential effect of insulin and acipimox (both of which reduce free fatty acid [FFA] availability) on VLDL apolipoprotein (apo) B metabolism. We studied eight healthy men (age 40 +/- 4 years, BMI 25.8 +/- 0.9 kg/m2, plasma triglycerides 1.30 +/- 0.12 mmol/l) after an overnight fast (control study, n = 8), during inhibition of lipolysis with an antilipolytic agent, acipimox (n = 8), and under 8.5-h euglycemic-hyperinsulinemic conditions (n = 5). Plasma FFAs were similarly suppressed in the acipimox and insulin studies (approximately 70% suppression). 2H3-leucine was used to trace apo B kinetics in VLDL1 and VLDL2 subclasses (Svedberg flotation rates: 60-400 and 20-60), and a non-steady-state multicompartmental model was used to derive the kinetic constants. The mean rate of VLDL1 apo B production was 708 +/- 106 mg/day at the beginning and 602 +/- 140 mg/day at the end of the control study. Production of the lipoprotein decreased to 248 +/- 93 mg/day during the insulin study (P < 0.05 vs. control study) and to 375 +/- 92 mg/day (NS) during the acipimox study. Mean VLDL2 apo B production was significantly increased during the acipimox study (399 +/- 42 vs. 236 +/- 27 mg/day, acipimox vs. control, P < 0.05) but not during the insulin study (332 +/- 51 mg/day, NS). The fractional catabolic rates of VLDL1 and VLDL2 apo B were similar in all three studies. We conclude that acute lowering of FFAs does not change the overall production rate of VLDL particles, but there is a shift toward production of smaller and denser VLDL2 particles, and, thus, the amount of total VLDL particles secreted remained constant. Insulin acutely suppresses the total production rate of VLDL apo B by decreasing the production of large triglyceride-rich VLDL1 particles. Based on these findings, we postulate that insulin has a direct suppressive effect on the production of VLDL apo B in the liver, independent of the availability of FFAs.

Circulating soluble E-selectin, intercellular adhesion molecule-1 (ICAM-1), and vascular adhesion molecule-1 (VCAM-1) concentrations were evaluated in 93 nonobese essential hypertensive patients, of whom 16 had impaired glucose tolerance and hyperlipidemia (group I); 25 had impaired glucose tolerance (group II); 28 had hyperlipidemia (group III); and 24 had no metabolic abnormalities (group IV). A group of 22 healthy volunteers served as a control group. All groups were without clinical or ultrasound evidence of vascular lesion and were matched for age, sex, and BMI. Endothelial soluble adhesion molecules were measured at baseline, during an oral glucose tolerance test, and after 12 weeks of either enalapril or placebo treatments. Plasma soluble E-selectin, ICAM-1, and VCAM-1 were higher (P < 0.05) in group I and II than in the other groups (group I: E-selectin, 96.1+/-27.1; ICAM-1, 304.0+/-102.1; VCAM-1, 626.1+/-156.2 microg/l. Group II: E-selectin, 88.0+/-18.0; ICAM-1, 268.0+/-84.1; VCAM-1, 594.1+/-140.9 microg/I. Group III: E-selectin, 70.1+/-18.1; ICAM-1, 195.1+/-68.0; VCAM-1, 495.9+/-110.1 microg/l. Group IV: E-selectin, 65.1+/-16.1; ICAM-1, 168.1+/-64.0; VCAM-1, 472.1+/-108.2 microg/l). Soluble adhesins levels were not higher than normal in groups III and IV. Plasma soluble ICAM-1 concentrations increased in group I after glucose administration and were directly correlated with 2-h insulin levels (r=0.648, P=0.007). Compared with placebo, 12 weeks of enalapril treatment significantly (P < 0.0001) reduced soluble E-selectin, ICAM-1, and VCAM-1. Decrements of soluble adhesins were not dependent on enalapril-related blood pressure changes. Therefore, an early endothelial activation was present in essential hypertensive patients with impaired glucose tolerance, regardless of the presence of hyperlipidemia. ACE inhibition counteracted such endothelial activation.

Picotamide both inhibits thromboxane synthetase and acts as a thromboxane antagonist at the receptor level. We investigated the long-term effect of picotamide on urinary albumin excretion (UAE) at rest and induced by exercise in 30 type 2 diabetic patients who were normotensive and had microalbuminuria while at rest. The subjects of our study had a mean age of 52.5 +/- 1.6 years, BMI of 28.5 +/- 0.7 kg/m2, diabetes duration of 9.1 +/- 1.8 years, and HbA1c of 7.0 +/- 0.8%. The study was a randomized double-blind placebo-controlled trial. The patients were randomly allocated to receive for 1 year either picotamide, 300 mg, 3 tablets/day, or placebo, 3 tablets/day. The patients were asked to visit our outpatient clinic after 1, 3, 6, 9, and 12 months of treatment. At all times, blood pressure, microalbuminuria at rest, blood glucose, serum creatinine, serum picotamide, and creatinine clearance were measured; at baseline and after 6 and 12 months, all patients underwent submaximal physical exercise. After 6 months of picotamide, baseline and exercise-induced microalbuminuria were significantly decreased (up to one-third) as compared with the baseline and placebo level, with no further drops at month 12 of picotamide treatment. On placebo treatment, UAE at rest and after exercise was slightly increased compared with baseline values. The effects of picotamide occurred without significant side effects or changes in either blood pressure levels or glycometabolic control. Our study is the first long-term intervention trial in type 2 diabetes showing that an antithromboxane agent is able to decrease microalbuminuria, which in this disease is a dual marker of macro- and microangiopathy. Our findings suggest an important role for thromboxane in the pathophysiology of microalbuminuria in diabetes; moreover, we hypothesize that antithromboxane agents may have a place in the treatment/prevention of both macro- and microvascular complications in type 2 diabetic patients.

Troglitazone, an oral antidiabetic agent with antioxidant properties, has previously been shown to increase the resistance of LDL to oxidation in vitro and in vivo in healthy volunteers. In a randomized, placebo-controlled, parallel-group study in 29 patients with NIDDM, we tested the effect of troglitazone (200 mg once daily) on the resistance of LDL to oxidation and on circulating levels of preformed lipid hydroperoxides and the adhesion molecule E-selectin. Resistance of LDL to oxidation was assessed by measuring 1) fluorescence development induced by copper treatment (lag phase), and 2) amount of thiobarbituric acid-reactive substances (TBARS) generated by incubation with umbilical vein endothelial cells. At 8 weeks, the lag phase was increased by 23% (P < 0.01 by analysis of covariance [ANCOVA]) in the patients receiving troglitazone (n = 18) compared with the group receiving placebo (n = 11). At the same time, TBARS were 3.63 +/- 0.10 nmol/l (vs. 5.32 +/- 0.10 nmol/l in the placebo group, P = 0.009), LDL hydroperoxide concentration was reduced from 1.48 +/- 0.03 to 1.19 +/- 0.03 ng/mg (no change in the placebo group, P < 0.01), and plasma E-selectin levels decreased from 56.5 +/- 2.33 to 43.7 +/- 1.77 microg/l (no change in the placebo group, P < 0.01). In NIDDM, troglitazone may slow down the development of atherosclerosis by modifying LDL-related atherogenic events.