Nonprogression of subclinical beta-cell dysfunction among first-degree relatives of IDDM patients. 5-yr follow-up of the Seattle Family Study

It is unknown among first-degree relatives of individuals with insulin-dependent diabetes mellitus (IDDM) whether the disease process occurs in relatively few but always progresses to clinical IDDM or whether subclinical disease is more common but remains nonprogressive in many cases. Islet cell antibodies (ICAs) were found in 21 of 724 (2.9%) first-degree relatives during screening in the greater Seattle area between 1983 and 1988. Measures of beta-cell function (glucose disappearance rate [Kg], fasting insulin, acute insulin response to intravenous arginine [AIRarg], acute insulin response to intravenous glucose [AIRgluc], slope of glucose potentiation of AIRarg) and insulin sensitivity were obtained. Twenty individuals, 9 ICA+ relatives and 11 ICA- relatives, were evaluated prospectively. When expressed in relation to the expected AIRgluc based on each subject's sensitivity index, AIRgluc in 18 of 20 relatives fell below 100%, indicating inappropriately low insulin secretion (subclinical beta-cell dysfunction). After a median follow-up of 42 mo, 10 of 11 ICA- relatives remained ICA-. None showed deteriorating beta-cell dysfunction, and none developed diabetes. Five ICA+ relatives showed persistent immunologic positivity. beta-Cell function remained remarkably stable in all except 2 relatives. One was a 15-yr-old boy who developed IDDM shortly after screening and before evaluation of beta-cell function could be carried out. The other was an 18-yr-old monozygotic twin who developed IDDM after 27 mo. Both of these individuals had ICAs of 80 Juvenile Diabetes Foundation U and had been discordant for less than 5 yr.(ABSTRACT TRUNCATED AT 250 WORDS)     

Consequences on beta-cell function and reserve after long-term pancreas transplantation

beta-Cell replacement in diabetes using pancreatic islets or beta-cell surrogates is a research area undergoing intense scrutiny. Once this approach is demonstrated to be reproducibly successful, the next major issue will be the length of time that success will be sustained. Whole and segmental pancreas transplants are now successful for up to two decades. Study of these grafts can provide insight into and predictions about beta-cell function and reserve when islet transplantation becomes a routine. The studies described herein investigated 102 human whole and segmental transplant recipients and control subjects to address the following five questions. 1) Is the usual reciprocal relationship between the acute insulin response to intravenous glucose (AIR(gluc)) and the level of fasting plasma glucose (FPG) maintained in pancreas transplant recipients? 2) Do recipients who have no AIR(gluc) have an acute insulin response to intravenous arginine (AIR(arg))? 3) Do recipients of whole pancreata from cadaveric donors have twice the amount of insulin secretory reserve as that found in recipients of 50% segmental grafts from living, related donors? 4) What clinically accessible measure of insulin secretion best correlates with glucose potentiation of arginine-induced insulin secretion (GPAIS)? 5) Do successful pancreas transplant recipients evince time-dependent declines in beta-cell function and glycemic regulation when studied long term and longitudinally? The results demonstrate that 1) the normal relationship between AIR(gluc) and fasting glucose levels is maintained despite systemic venous drainage of allografts and consequent hyperinsulinemia; 2) AIR(gluc) and AIR(arg) decrease in parallel as fasting glucose levels rise, although AIR(arg) is still present after AIR(gluc) disappears; 3) AIR(arg) and AIR(gluc) are strongly predictive of beta-cell mass; 4) AIR(arg) and AIR(gluc) are strongly predictive of insulin secretory reserve; and 5) transplant recipients who have successfully maintained normoglycemia for an average of 10 years and up to 22 years nonetheless experience time-related declines in beta-cell function.     

Normoglycemia and preserved insulin secretory reserve in diabetic patients 10-18 years after pancreas transplantation.

Pancreas transplantation is a controversial form of therapy for type I diabetes. A major obstacle to acceptance of this procedure for many physicians is the lack of demonstrable long-term success. We performed these studies to assess the hypothesis that successful pancreas transplantation is efficacious in normalizing endogenous insulin secretion and glycemia in the long term (1-2 decades). Sixteen patients with a history of diabetic complications who had undergone a transplant 10-18 years earlier involving either a whole or a segment of pancreas were recruited for measurements of fasting plasma glucose, HbA1c, intravenous glucose tolerance, and insulin secretory reserve. All patients were taking immunosuppressive drugs, but none was using insulin or other hypoglycemic agents. All recipients had normal levels of fasting blood glucose, intravenous glucose tolerance, and HbA1c, and 15 of 16 stated that their quality of life had improved after transplantation. They had intact acute insulin responses to intravenous pulses of glucose and to arginine and insulin secretory reserve. Glucose potentiation of arginine-induced insulin secretion, the measure of insulin secretory reserve, correlated significantly (r = 0.095, P < 0.001) with the acute insulin response to intravenous glucose, rendering the latter a much simpler and valid measure of functional beta-cell mass. We conclude that successful pancreas transplants are efficacious for periods as long as 1-2 decades in returning euglycemia to type 1 diabetic patients by restoring endogenous insulin secretion and insulin secretory reserve. Thus, concern about long-term deterioration, as distinct from rejection, should not be a major obstacle when deciding whether to recommend pancreas transplantation.     

Prevention of diabetes for up to 13 years by autoislet transplantation after pancreatectomy for chronic pancreatitis

Patients with chronic pancreatitis who undergo total pancreas resection inevitably become diabetic unless their islets are autotransplanted to prevent diabetes. We studied patients who underwent this procedure to assess its long-term efficacy in providing stable glucose regulation. Six patients were followed for up to 13 (6.2 +/- 1.7) years after intrahepatic islet autotransplantation. From 290,000 to 678,000 islets were transplanted and no patients received drugs to control glucose levels postoperatively. Islet function was assessed by measurements of fasting plasma glucose (FPG), intravenous glucose disappearance rate (KG), HbA1c, insulin responses to intravenous glucose and to arginine, and insulin secretory reserve. Patients were studied two to four times each to obtain longitudinal data. Five of six patients remained free of insulin treatment and maintained FPG <126 mg/dl and HbA1c levels <6.5%. As a group, they maintained stable insulin secretory reserve, but insulin responses to glucose tended to decrease over time in three patients. KG values correlated significantly with the number of islets originally transplanted. These data indicate that intrahepatic autoislet transplantation can successfully maintain stable beta-cell function and normal levels of blood glucose and HbA1c for up to 13 years after total pancreatectomy as treatment for chronic painful pancreatitis. This usually overlooked procedure of intrahepatic islet transplantation designed to prevent diabetes in patients undergoing pancreatectomy for chronic pancreatitis should be considered more often.     

Relationship between diabetes and obesity 9 to 18 years after hemipancreatectomy and transplantation in donors and recipients

BACKGROUND: Healthy human volunteers occasionally elect to undergo surgical removal of the distal half of their pancreas for donation to a relative with type 1 diabetes. This provides the unusual opportunity to study segments of the same pancreas in two markedly different environments, i.e., the normal one of the donor and the unusual one of the ectopically transplanted recipient who is receiving immunosuppressant drugs that can diminish insulin secretion and cause insulin resistance. METHODS: We studied eight donor/recipient pairs 9 to 18 years after the original surgery to assess the hypothesis that beta-cell mass is the primary determinant of glucose homeostasis. We measured levels of fasting glucose and hemoglobin A1c, intravenous glucose disappearance rates, acute insulin and C-peptide responses, and beta-cell secretory reserve. RESULTS: Comparisons of the mean data between the two groups revealed no significant differences in fasting plasma glucose, hemoglobin A1c, fasting insulin or C-peptide, acute insulin or C-peptide responses to arginine and to glucose, or beta-cell secretory reserve. Eight patients were obese; this subgroup contained all patients who developed mild diabetes (four donors and two recipients). CONCLUSION: The within-pairs metabolic outcomes support the primacy of pancreatic mass in determining glucose homeostasis, but the discordancy within pairs for developing postoperative diabetes implicates variables, especially obesity, as important secondary determinants in the risk of developing diabetes in donors and recipients. Our data suggest that obesity should be a contraindication to donation of pancreatic segments and that donors should assiduously avoid becoming obese.     

Early Metabolic Markers That Anticipate Loss of Insulin Independence in Type 1 Diabetic Islet Allograft Recipients

The objective of this study was to identify predictors of insulin independence and to establish the best clinical tools to follow patients after pancreatic islet transplantation (PIT). Sequential metabolic responses to intravenous (I.V.) glucose (I.V. glucose tolerance test [IVGTT]), arginine and glucose‐potentiated arginine (glucose‐potentiated arginine‐induced insulin secretion [GPAIS]) were obtained from 30 patients. We determined the correlation between transplanted islet mass and islet engraftment and tested the ability of each assay to predict return to exogenous insulin therapy. We found transplanted islet mass within an average of 16 709 islet equivalents per kg body weight (IEQ/kg BW; range between 6602 and 29 614 IEQ/kg BW) to be a poor predictor of insulin independence at 1 year, having a poor correlation between transplanted islet mass and islet engraftment. Acute insulin response to IVGTT (AIR_GLU) and GPAIS (AIR_max) were the most accurate methods to determine suboptimal islet mass engraftment. AIR_GLU performed 3 months after transplant also proved to be a robust early metabolic marker to predict return to insulin therapy and its value was positively correlated with duration of insulin independence. In conclusion, AIR_GLU is an early metabolic assay capable of anticipating loss of insulin independence at 1 year in T1D patients undergoing PIT and constitutes a valuable, simple and reliable method to follow patients after transplant.     

Accurate measurement of endogenous insulin secretion does not require separate assessment of C-peptide kinetics

The implication of beta-cell failure as an early defect in type 2 diabetes exacerbates the need for accurate but facile assessment of islet cell secretory rate, particularly in large group studies in which individual assessment of C-peptide kinetics is impractical. This study was designed to examine whether it is possible to obtain accurate secretory rates from the extended combined model, which provides insulin and C-peptide kinetics from plasma measurements of the two peptides. Equimolar intraportal infusions of insulin and C-peptide that are designed to simulate insulin secretion rates during both oral and intravenous glucose tolerance tests were used to generate plasma insulin and C-peptide data in conscious dogs that were examined under clamped glucose conditions. The plasma peptide kinetics were analyzed using the extended combined model to generate estimates of prehepatic insulin secretion that were then compared with the known intraportal infusion rates. The extended combined model was able to reproduce the known intraportal infusion profiles. The model-predicted rates were similar to those calculated with methods that require separate assessment of C-peptide kinetics. Simulation results supported lesser clearance of insulin during rapid changes of portal insulin (as measured by an intravenous glucose tolerance test) versus slow changes in portal insulin (as measured by an oral glucose tolerance test). The extended combined model accurately calculates prehepatic insulin appearance. It may be possible to apply this approach to large studies of beta-cell function designed to identify changes in islet function in subjects at risk for diabetes. Such an approach could strengthen epidemiological and genetic studies of the pathogenesis of diabetes.     

The relationship of insulin production to glucose metabolism in severe sepsis

Basal glucose metabolism was evaluated in eight stable, infected patients by measuring hepatic glucose production rates in relation to stress endocrine profile and by comparing these data to five injured, noninfected patients. All patients exhibited normal total-body oxygen consumptions and cardiac indices. Fasting basal insulin values were similar in both groups (6 microU/cc) despite a significantly higher plasma glucose level in septic patients (106 +/- 14 mg/dL) compared to nonseptic patients (88 +/- 10 mg/dL). Septic patients exhibited splanchnic glucose production and calculated glucose clearance rates, 53% and 34% higher, than injured nonseptic patients, respectively. In addition, septic patients exhibited a decreased pancreatic insulin secretory response to an intravenous glucose tolerance test as evidenced by a significantly depressed peak insulin value (17 microU/cc) relative to injured patients (77 microU/cc). These findings indicate that insulin suppression is evident in sepsis even in the absence of shock and suggest that sepsis-related basal hyperglycemia does not appear to be associated with peripheral insulin resistance.     

Acute insulin responses to glucose and arginine as predictors of beta-cell secretory capacity in human islet transplantation

Islet transplantation for type 1 diabetes can enable the achievement of near-normal glycemic control without severe hypoglycemic episodes. How much an islet (beta-cell) graft may be contributing to glycemic control can be quantified by stimulatory tests of insulin (or C-peptide) secretion. Glucose-potentiation of arginine-induced insulin secretion provides a measure of functional beta-cell mass, the beta-cell secretory capacity, as either AIR(pot) or AIR(max), but requires conduct of a hyperglycemic clamp. We sought to determine whether acute insulin responses to intravenous glucose (AIR(glu)) or arginine (AIR(arg)) could predict beta-cell secretory capacity in islet recipients. AIR(arg) was a better predictor of both AIR(pot) and AIR(max) (n=10, r2=0.98, P<0.0001 and n=7, r2=0.97, P<0.0001) than was AIR(glu) (n=9, r2=0.78, P=0.002 and n=6, r2=0.76, P=0.02). Also, the measures of beta-cell secretory capacity were highly correlated (n=7, r2=0.98, P<0.0001). These results support the use of AIR(arg) as a surrogate indicator of beta-cell secretory capacity in islet transplantation.     

The effect of pancreatic polypeptide infusion on glucose tolerance and insulin response in longitudinally studied pancreatitis-induced diabetes

Glucose intolerance is often associated with pancreatitis. Pancreatitis-induced diabetes represents a different clinical syndrome than type I and type II diabetes mellitus. Patients with pancreatitis-induced diabetes may be extremely sensitive to exogenous insulin, rarely develop ketoacidosis, and rarely exhibit classic diabetic complications, such as retinopathy, nephropathy, or accelerated vasculopathy. Pancreatic polypeptide (PP) deficiency has been implicated in the defect of glucose homeostasis found after pancreatitis. This study evaluated intravenous and oral glucose tolerance and insulin response to glucose loading, in the setting of pancreatitis, with and without short-term PP replacement. Dogs (n = 7) underwent pancreatic duct ligation (PDL) and were studied with and without PP infusion (2 micrograms/kg/hr) before PDL and at 1 week, 6 weeks, and 4 months after PDL by means of intravenous and oral glucose tolerance tests. Basal and bombesin-stimulated PP levels at 4 months after PDL were subnormal, verifying PP deficiency in these animals with pancreatitis. PP levels during PP infusion reproduced normal postcibal levels, averaging 897 +/- 40 pg/ml. Glucose tolerance, expressed as the glucose decay constant for the intravenous glucose tolerance tests and as the integrated glucose response for the oral glucose tolerance tests, deteriorated over time and was not improved by acute PP replacement. The integrated insulin response to glucose was not affected by PP. The acute infusion of PP at a dose that reproduces normal postprandial PP levels fails to improve glucose tolerance or augment insulin release in this model of pancreatitis-induced diabetes.     

Beta-cell function and insulin sensitivity in nondiabetic HLA-identical siblings of insulin-dependent diabetics

Insulin secretion and insulin sensitivity were compared in 12 HLA-identical siblings of insulin-dependent diabetics and nondiabetic controls. Only the maximum acute insulin response to intravenous arginine was lower in the siblings than in the matched controls (P less than .05); other measures of insulin secretion, including the acute insulin response to glucose or arginine, the second-phase insulin response to glucose, and the slope of glucose potentiation, were not significantly different. Insulin sensitivity, derived from an intravenous glucose tolerance test with a minimal-modeling technique, was lower in the siblings (P less than .01). In a large group of nondiabetic controls of various adiposity, insulin secretion and insulin sensitivity were inversely related. In view of the difference in insulin sensitivity between siblings and matched controls, a direct comparison of beta-cell function tests may be inappropriate, and the measures of insulin secretion were compared with those of nondiabetics when adjusted for differences in insulin sensitivity. This analysis revealed that all measures of insulin secretion were significantly lower in the siblings. We conclude that HLA-identical siblings of insulin-dependent diabetics show evidence of both insulin resistance and impaired beta-cell function and that analysis of beta-cell function in relation to insulin sensitivity shows a greater frequency of beta-cell secretory abnormalities than previously appreciated.     

In vitro and in vivo studies of a naturally occurring variant of the human p85alpha regulatory subunit of the phosphoinositide 3-kinase: inhibition of protein kinase B and relationships with type 2 diabetes, insulin secretion, glucose disappearance constant, and insulin sensitivity

In humans, the Met326Ile missense variant of the p85alpha regulatory subunit of the phosphoinositide 3-kinase (PI3K) has been associated with either significant reductions in glucose effectiveness and intravenous glucose tolerance in Caucasians or a significantly higher insulin secretory response in Pima Indians. In the present study, we genotyped 1,190 Caucasian males to evaluate the impact in vivo of the Met326Ile variant of the p85alpha subunit of PI3K on the acute insulin response, intravenous glucose tolerance, insulin-mediated glucose uptake, and the prevalence of type 2 diabetes after 20 years of follow-up. We also expressed the variant in vitro to evaluate the impact on insulin-stimulated activation of protein kinase B (PKB). The Met326Ile variant of p85alpha was not associated with type 2 diabetes or with alterations in insulin secretion, insulin sensitivity, or intravenous glucose tolerance in vivo. Expressed in vitro, the Ile326 and the Met326 variant acted equally as a dominant-negative and prevented (60-70% inhibition) insulin-mediated activation of PKB by inhibiting the phosphorylation of PKB at Thr308. We conclude that the Met326Ile variant of the p85alpha regulatory subunit of PI3K is likely to be as functionally normal in vivo as in vitro.     

An islet cell carcinoma containing glucagon and insulin. Chronic glucagon excess and glucose homeostasis.

Described here is a patient who had an islet cell carcinoma containing both glucagon (glucagonoma) and insulin (insulinoma). Complete removal of the tumor was possible. Immunoreactive glucagon (IRG) could be extracted from all parts of the tumor (approximately 50 mug./gm.) and was shown to be fully bioactive. Immunoreactive insulin (IRI) could be extracted only from one section of the tumor (approximately 30 mug./gm.). The clinical and biochemical manifestations of the disease were dermatitis, diabetes, weight loss, anemia, hypoaminoacidemia, and hyperketonemia. The diabetes was characterized by low or normal fasting blood glucose concentrations and by impaired glucose tolerance (Kg = 0.4). After complete removal of the tumor, the dermatitis cleared, the catabolic state changed into an anabolic state, blood amino acid concentrations increased, and blood ketone-body concentrations decreased. Fasting blood glucose concentrations, however, rose above 200 mg./dl., and glucose tolerance declined further (Kg = 0.15). Hourly blood sampling for 24 hours, intravenous and oral glucose tolerance tests, intravenous arginine and tolbutamide tolerance tests with serial determinations of IRG, IRI, and blood glucose were performed preoperatively and again two weeks and two months postoperatively. The results of these studies demonstrated marked abnormalities in the stimulation and suppression of glucagon and insulin release. In addition, they failed to demonstrate a glycemic effect on the chronically elevated glucagon concentrations in this patient, while identifying insulin as the dominant factor determining blood glucose homeostasis.     

Effects of cyclosporin on insulin and C-peptide secretion in healthy beagles

Plasma glucose, C-peptide, and insulin responses to intravenous glucose (intravenous glucose tolerance test [IVGTT], 0.5 g/kg), glucagon (1 mg i.v.), and oral glucose (oral glucose tolerance test [OGTT], 1 g/kg) were assessed in six normal beagles before, during, and 1 and 4 mo after the administration of cyclosporin A (CsA) in doses previously shown to be required for uniform prevention of canine islet-allograft rejection (20 mg/kg; mean trough radioimmunoassay serum levels greater than or equal to 500 ng/ml). Insulin secretion in response to intravenous glucose and glucagon was significantly inhibited during the administration of CsA (areas under insulin-response curves, pmol.min-1.L-1; IVGTT, pre-CsA, 11,127 +/- 1285; during CsA, 5954 +/- 1147, P less than .05; glucagon tolerance test, pre-CsA, 18,617 +/- 2807; during CsA, 4401 +/- 486, P less than .05 vs. pretreatment levels). These secretory defects persisted 4 mo after CsA was discontinued (IVGTT, 4358 +/- 659; glucagon tolerance test, 10,567 +/- 2479, P less than .05). C-peptide responses paralleled these changes. Plasma glucose disposal in response to these secretagogues, however, returned to normal 1 mo after discontinuation of CsA. In contrast to the findings for IVGTT and glucagon, insulin-response curves to OGTT were not statistically different during CsA administration. We conclude that, although glucose disappearance rates are normal after discontinuation of the CsA administration, CsA causes irreversible impairment in islet secretory responses detectable with IVGTT and glucagon but not with OGTT. These results suggest that short-term CsA in doses required to prevent islet-allograft rejection in dogs can result in permanent loss of functionally competent beta-cells.     

Carbohydrate metabolism and pancreatic islet-cell function in thalassemia major.

To investigate the development of diabetes mellitus in patients with thalassemia major, plasma glucose and immunoreactive insulin (IRI) levels following oral glucose and intravenous tolbutamide and glucose disappearance rates following intravenous insulin were measured in 10 patients before and during five years on a high transfusion program (HTP). Plasma immunoreactive glucagon (IRG) levels following oral glucose, intravenous insulin, and arginine were measured during the sixth year. Serial percutaneous liver biopsies were performed on seven patients. The oral glucose tolerance tests (OGAT) and mean peak IRI levels were normal in nine of 10 patients before HTP. After HTP was begun a progressive deterioration of OGTT occurred despite normal IRI levels. Following tolbutamide, the mean per cent fall in plasma glucose in the patients before HTP was significantly less than in controls (p less than 0.01) and similar to that of controls during five years of HTP in spite of higher than normal peak IRI levels. Of seven survivors after six years of HTP, three had normal OGTT and four had chemical diabetes; mean peak IRI levels were normal, but fasting IRG levels were significantly higher than in controls (p less than 0.05). In all seven patients, plasma IRG failed to increase following insulin-induced hypoglycemia and was significantly higher than in controls after arginine (p less than 0.01); after oral glucose, plasma IRG fell significantly below that of fasting only in the patients with chemical diabetes (p less than 0.03). Following intravenous insulin, the mean per cent fall in glucose before and during HTP was significantly less than in controls (p less than 0.01). Hemosiderosis and cirrhosis were present in all biopsied patients. Four patients died; two had chemical and two had nonketotic insulin-dependent diabetes. These data suggest that diabetes mellitus occurs frequently in patients with thalassemia on HTP and that insulin resistance and hyperglucagonemia, possibly due to cirrhosis, are important etiologic factors.     

Insulin release in impaired glucose tolerance: oral minimal model predicts normal sensitivity to glucose but defective response times

The availability of quantitative indexes describing beta-cell function in normal life conditions is important for the characterization of impaired mechanisms of insulin secretion in pathophysiological states. Recently, an oral C-peptide minimal model has been proposed and applied to subjects with normal glucose tolerance (NGT) during graded up-and-down glucose infusion protocols (40-min periods at 4, 8, 16, 8, 4, and 0 mg.kg(-1).min(-1)) and oral glucose tolerance tests. These tests are characterized by slow glucose and C-peptide dynamics, which reproduce prandial conditions. In view of the importance of beta-cell dysfunction in the pathogenesis of type 2 diabetes, our aim was to test and use the oral minimal model in subjects with impaired glucose tolerance (IGT) to identify deranged mechanisms of beta-cell function. Plasma C-peptide and glucose data from graded up-and-down glucose infusions were analyzed in nine NGT and four IGT subjects using the classic deconvolution approach and the oral minimal model, and indexes of beta-cell function were derived. An index of insulin sensitivity was also obtained for each subject from minimal model analysis of glucose and insulin levels achieved during the test. Both deconvolution and minimal model analyses revealed that individuals with IGT have a relative defect in the ability to secrete enough insulin to adequately compensate for insulin resistance. Additionally, minimal model analysis suggests that insulin secretory defect in IGT arises from delays in the timing of the beta-cell response to glucose.     

Impaired beta-cell function, incretin effect, and glucagon suppression in patients with type 1 diabetes who have normal fasting glucose

We have recently described a novel phenotype in a group of subjects with type 1 diabetes that is manifested by glucose >11.1 mmol/l 120 min after an oral glucose load, but with normal fasting glucose levels. We now describe the metabolic characteristics of these subjects by comparing parameters of islet hormone secretion and glucose disposal in these subjects to age-matched nondiabetic control subjects. The patients with type 1 diabetes had fasting glucose, insulin, and glucagon values similar to those of control subjects. Additionally, the insulin secretory response to intravenous arginine at euglycemia was similar in the control and diabetic groups (264 +/- 33.5 and 193 +/- 61.3 pmol/l; P = 0.3). However, marked differences in beta-cell function were found in response to hyperglycemia. Specifically, the first-phase insulin response was lower in diabetic subjects (329.1 +/- 39.6 vs. 91.3 +/- 34.1 pmol/l; P < 0.001), as was the slope of glucose potentiation of the insulin response to arginine (102 +/- 18.7 vs. 30.2 +/- 6.1 pmol/l per mmol/l; P = 0.005) and the maximum insulin response to arginine (2,524 +/- 413 vs. 629 +/- 159 pmol/l; P = 0.001). Although plasma levels of glucagon-like peptide (GLP)-1 and gastric inhibitory peptide (GIP) did not differ between control and diabetic subjects, the incretin effect was lower in the diabetic patients (70.3 +/- 5.4 vs. 52.1 +/- 5.9%; P = 0.03). Finally, there was a lack of suppression of glucagon in the patients after both oral and intravenous glucose administration, which may have contributed to their postprandial hyperglycemia. Glucose effectiveness did not differ between patients and control subjects, nor did insulin sensitivity, although there was a tendency for the patients to be insulin resistant (9.18 +/- 1.59 vs. 5.22 +/- 1.17 pmol.(-1).min(-1); P = 0.08). These data characterize a novel group of subjects with type 1 diabetes manifested solely by hyperglycemia following an oral glucose load in whom islet function is normal at euglycemia, but who have marked defects in both alpha- and beta-cell secretion at hyperglycemia. This pattern of abnormalities may be characteristic of islet dysfunction early in the development of type 1 diabetes.     

Comparison of tests of beta-cell function across a range of glucose tolerance from normal to diabetes.

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.     

Longitudinal compensation for fat-induced insulin resistance includes reduced insulin clearance and enhanced beta-cell response

Central adiposity is highly correlated with insulin resistance, which is an important risk factor for type 2 diabetes and other chronic diseases. However, in normal individuals, central adiposity can be tolerated for many years without development of impaired glucose tolerance or diabetes. Here we examine longitudinally the mechanisms by which glucose tolerance can be maintained in the face of substantial insulin resistance. Normal dogs were fed a diet enriched with moderate amounts of fat (2 g x kg(-1) x day(-1)), similar to that seen in modern "cafeteria" diets, and the time course of metabolic changes in these animals was examined over 12 weeks. Trunk adiposity as assessed by magnetic resonance imaging increased from 12 to 19%, but body weight remained unchanged. Insulin sensitivity (SI) as determined by frequently sampled intravenous glucose tolerance tests was measured over a 12-week period. SI decreased 35% by week 1 and remained impaired for the entire 12 weeks. Intravenous glucose tolerance was reduced transiently for 1 week, recovered to baseline, and then again began to decline after 8 weeks. First-phase insulin response began to increase after week 2, peaked by week 6 (190% of basal), and then declined. The increase in insulin response was due partially to enhanced beta-cell function (22%) but due also to an approximately 50% reduction in insulin clearance. This compensation by insulin clearance was also confirmed with insulin clamps performed in fat-fed versus control dogs. The present study confirms the ability of the normal individual to compensate for fat-induced insulin resistance by enhanced insulin response, such that the product of insulin sensitivity x secretion is little changed. However, the compensation is due as much to reduced insulin clearance as increased beta-cell sensitivity to glucose. Reduced hepatic extraction of insulin may be the first line of defense providing a higher proportion of secreted insulin to the periphery and sparing the beta-cells during compensation for the insulin-resistant state.     

Functional alteration of islet cells after jejunal or ileal resection in dogs.

Functional alteration of the islet cells was investigated in dogs after the resection of different parts of the small intestine. Three weeks after jejunal or ileal resection, when the dogs might still have been in a catabolic state, insulin and pancreatic glucagon release in response to intravenously infused glucose and arginine was reduced. Three months after jejunal resection, both intravenous glucose tolerance and insulinogenic index in the intravenous glucose tolerance test were significantly below the preoperative values (P less than 0.001, P less than 0.05), while pancreatic glucagon release in response to arginine infusion release. This functional alteration three months after jejunal resection was similar to that seen in diabetes mellitus. On the other hand, three months after ileal resection, insulin and pancreatic glucagon release was almost normal. We conclude that the jejunum plays a more important role in the enteroinsular system than the ileum and that prolonged interruption of this enteroinsular axis can cause insular disorder and what could hypothetically be called enterogenic chemical diabetes, in view of the altered glucose tolerance test and the alteration in insulin secretory response.