1 Department of Internal Medicine, University of Michigan, Ann Arbor, Michigan
2 Novo Nordisk A/S, Bagsvaerd, Denmark
3 Novo Nordisk Pharmaceuticals, Inc., Princeton, New Jersey
4 Institute of Gerontology, University of Michigan, Ann Arbor, Michigan
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ABSTRACT |
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Glucagon-like peptide 1 (GLP-1) is a hormone that stimulates insulin secretion and simultaneously decreases glucagon secretion (1,2). The insulinotropic effect is glucose dependent. Because GLP-1 stimulates insulin secretion primarily at elevated glucose levels, it is possible that GLP-1 therapy of type 2 diabetes might present a low risk of hypoglycemia (3). GLP-1 might also decrease hepatic glucose production indirectly (4), delay gastric emptying, and suppress appetite in type 2 diabetic patients (5). This array of effects gives GLP-1 the potential to be an efficacious and safe glucose-lowering agent for type 2 diabetes. In addition, GLP-1 has been shown to stimulate the differentiation of islet progenitor cells into insulin-producing cells and may be important for ß-cell neogenesis (6).
Short-term (12-h) infusion of GLP-1 as well as 6-week continuous subcutaneous infusion of GLP-1 has been shown to significantly improve insulin secretion in type 2 diabetic patients (7,8). However, native GLP-1 has a very short half-life because of its rapid degradation by dipeptidyl peptidase IV and, thus, is unlikely to be used as a therapeutic drug in diabetes treatment. NN2211 is an acylated derivative of GLP-1 with full agonistic activity at the GLP-1 receptor in vitro (9). NN2211 is slowly degraded because of a combination of albumin binding, metabolic stability, and gradual release from the injection site. Pharmacokinetic profiles in healthy volunteers and type 2 diabetic subjects have shown that NN2211 is suitable for once-daily injection (1012). NN2211, in a single dose of 10 µg/kg, has been found to effectively reduce fasting and postprandial hyperglycemia, delay gastric emptying, and suppress prandial glucagon secretion in type 2 diabetic patients (12).
In the present study, we assessed the effect of a single subcutaneous injection of NN2211 on ß-cell sensitivity to glucose using a graded glucose infusion protocol in a group of adults with type 2 diabetes. The trial was a randomized, double-blind, placebo-controlled crossover trial. The degree of improvement of ß-cell function was also assessed by comparison with a control group of healthy volunteers of similar age who did not receive the drug.
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RESEARCH DESIGN AND METHODS |
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A graded glucose infusion protocol was initiated at 08:00 the following day. The aim of this procedure was to assess insulin secretion in response to gradually raising plasma glucose levels from 5 to 12 mmol/l over 3 h. Subjects were studied in the supine position. The antecubital intravenous catheter was used for insulin and glucose infusions. The second intravenous catheter in a dorsal hand/wrist vein of the contralateral arm was placed into a warming box heated to 60°C to obtain arterialized blood samples for glucose and insulin. After an initial baseline sample was taken, a small intravenous dose of insulin (0.0070.014 units/kg) was administered to lower the glucose level to
5 mmol/l. The insulin was allowed to decay (20 min after bolus insulin), after which samples were drawn at 5-min intervals for 15 min to define baseline levels of glucose, insulin, and C-peptide. An intravenous infusion of 20% dextrose was then started. Every 5 min, samples were drawn for determination of insulin, C-peptide, and glucose. For each of the 5-min samples, plasma glucose was measured using a Beckman glucose analyzer (Beckman, Palo Alto, CA), and the glucose infusion rate was adjusted accordingly to gradually raise plasma glucose levels from 5 to 12 mmol/l over 3 h. Periodic additional blood samples were drawn for glucagon and NN2211 concentrations.
Normal control subjects.
Healthy subjects (n = 10; 5 men, 5 women) who did not receive the trial medication also underwent the graded glucose infusion protocol to provide reference data on ß-cell function. All control subjects met ADA criteria for normal glucose tolerance with a fasting plasma glucose ≤6.1 mmol/l and 2-h plasma glucose <7.8 mmol/l, as determined with an oral glucose tolerance test. Subjects were selected to approximate the demographic characteristics of the diabetic patients. As shown in Table 1, the diabetic and control subjects were well matched except for BMI, which was higher in diabetic subjects. The control subjects were admitted to the GCRC the morning after an overnight fast. The graded glucose infusion protocol was carried out as described for the diabetic patients, except control subjects did not receive the overnight insulin infusion or the trial medication.
Assays.
Plasma glucose was measured immediately at bedside with a Beckman glucose analyzer using the glucose oxidase technique. HbA1c was measured by high-performance liquid chromatography, with a normal range of 3.86.4%. All other blood samples were centrifuged and serum was stored at -20°C until analysis. Serum insulin was quantified using a highly specific and sensitive two-site enzyme-linked immunosorbent assay (ELISA) with an interassay coefficient of variation of 3% (DAKO Diagnostics, Cambridgeshire, U.K.). C-peptide was measured by a two-site monoclonal-based ELISA with an interassay coefficient of variation (in triplicate) of 3% (DAKO Diagnostics). Glucagon was assessed by radioimmunoassay (GL-32K; Linco Research, St. Charles, MO.). NN2211 concentrations were analyzed by ELISA using a capture monoclonal antibody against GLP-1/NN2211 and a detection monoclonal antibody specific for the NH2-terminal portion of GLP-1/NN2211. Before pharmacokinetic analysis, the samples were incubated at 37°C to remove endogenous GLP-1, as NN2211 is stable with incubation. The mean accuracy (recovery) of the NN2211 assay has been reported as 102% (range 93113%) (11).
Statistical analysis.
The primary objective of the efficacy analysis was to compare the effects of NN2211 versus placebo on ß-cell responsiveness to graded glucose infusion as assessed by the insulin secretion rate (ISR) area under the curve (AUC) over the 40- to 220-min time interval of graded glucose infusion studies. The ISR during the graded glucose infusion protocol was derived by deconvolution of peripheral C-peptide concentrations and previously determined C-peptide kinetics (13,14). The total ISR over the 40- to 220-min time interval was estimated for each subject by calculating the AUC using the trapezoidal rule.
The secondary objectives of the efficacy analysis were to compare NN2211 with placebo with respect to the following: 1) slope of the ISR versus plasma glucose level for each subject (estimated by a regression model of ISR on plasma glucose level), 2) glucagon AUC over the 40- to 220-min time interval (calculated in a similar way to that of ISR AUC), and 3) insulin clearance (mean ISR divided by mean insulin concentration).
Adverse events were recorded on the treatment days. All efficacy end points for NN2211 versus placebo were analyzed using an ANOVA model for the crossover design. Two-sided tests were performed with P = 0.05 as the level of significance. Results for diabetic subjects are given as NN2211 versus placebo.
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RESULTS |
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Insulin secretion.
As shown in Fig. 3, the ISR increased substantially with NN2211 administration compared with placebo during the graded glucose infusion studies over the glucose range 612 mmol/l, and was similar to values in healthy control subjects who did not receive the drug. The effects of NN2211 in enhancing insulin secretory response became evident after 4060 min of glucose infusion, when the plasma glucose levels reached 67 mmol/l. The drug effect was increasingly apparent as plasma glucose levels increased further to 12 mmol/l, thus displaying the glucose-dependent action of NN2211. As summarized in Fig. 4, ß-cell sensitivity to glucose as assessed by the ISR AUC was increased by 70% with NN2211 treatment (1,130 ± 150 vs. 668 ± 106 pmol/kg; P < 0.001). The ISR AUC with NN2211 in diabetic subjects was similar to values in healthy control subjects who did not receive the drug (1,206 ± 99). The ISR AUC was an estimate of the total amount of insulin secreted per kilogram of body weight over the 40- to 220-min time interval of the graded glucose infusion studies. The effect of NN2211 on the slope of ISR versus plasma glucose level is summarized in Fig. 5. The slope of ISR versus plasma glucose level increased by
133% with NN2211 (1.26 ± 0.36 vs. 0.54 ± 0.18 pmol · l[min-1] · mmol-1 · kg-1]; P < 0.014). The slope of ISR versus plasma glucose level with NN2211 in diabetic subjects was comparable to the value in healthy control subjects (1.44 ± 0.18).
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Other measures.
As shown in Fig. 6, glucagon levels were similar with NN2211 and placebo administration in the fasting state and did not change over time in the diabetic subjects. The glucagon AUC remained unchanged with NN2211 compared with placebo (14,665 ± 1,350 vs. 15,761 ± 1,788 pg · min-1 · ml-1; P = 0.24). Plasma glucagon levels were higher in the fasting state and during graded glucose infusion studies in diabetic subjects compared with control subjects, although the glucagon AUC was not significantly different (11,827 ± 768 pg · ml-1 in healthy control subjects; P = 0.11). Insulin clearance (mean ISR divided by mean insulin concentration) was similar with NN2211 and placebo (0.06 ± 0.01 vs. 0.05 ± 0.01 l · min-1 · kg-1; P = 0.35). The pharmacokinetic profile of NN2211 was evaluated by 10-point profiles for up to 17 h after dosing. The AUC of NN2211 plasma concentration from 0 to 17 h was 70,742 ± 19,256 pmol/l, the Cmax of NN2211 was 5,884 ± 1,778 pmol/l, and the Tmax of NN2211 was 13.1 ± 2.8 h. The t1/2 was not determined because of the limited duration of postdosing profiling and because this parameter has been reported in previous studies with NN2211 in healthy (t1/2 = 1115 h) and diabetic subjects (t1/2 = 10.0 ± 3.5 h) (1012).
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DISCUSSION |
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Continuous infusion of GLP-1 for 12 h has been shown to improve basal and stimulated ß-cell function, as assessed by hyperglycemic clamp and arginine stimulation in type 2 diabetic patients (7). A 6-week continuous subcutaneous infusion of GLP-1 (compared with saline infusion) has been shown to significantly improve insulin secretion, as assessed by the hyperglycemic clamp method in 10 type 2 diabetic subjects, and also to decrease fasting glucose, HbA1c, and fructosamine levels (8). In a recent study, GLP-1 infusion also increased insulin secretory response to graded glucose infusion in a dosage-dependent manner in type 2 diabetic and healthy control subjects (15). However, the rapid degradation of GLP-1 and the need for continuous infusion prevent the hormones broader clinical use. In contrast, NN2211 is a slowly degraded GLP-1 analog that has been found to be suitable for once-daily dosing.
In the present study, a single dose of NN2211 (compared with placebo) significantly increased insulin and C-peptide levels and substantially improved the overall insulin secretory response to a controlled, gradual increase of glucose levels over a physiological range during the glucose infusion protocol in type 2 diabetic subjects. NN2211 was administered the night before study days to achieve maximum concentration of the drug during the graded glucose infusion protocol the following morning. One advantage of this study was the careful matching of glucose levels over time, which allowed quantitative comparisons of insulin secretion with placebo versus with NN2211, and also comparison with a nondiabetic control group over the same glucose range. In addition, insulin secretion was assessed in response to physiological postprandial glucose levels, which contrasts with the high nonphysiological glucose levels achieved with the hyperglycemic clamp method.
The effects of NN2211 in enhancing the insulin secretory response became evident after 4060 min of glucose infusion when the plasma glucose levels reached 67 mmol/l. The drug effect was increasingly apparent as plasma glucose levels increased further to 12 mmol/l. The glucose level dependency of the effect of NN2211 on insulin secretion agrees with findings of GLP-1 studies in normal (6,17) and diabetic subjects (3). The lack of effect of NN2211 on insulin secretion at euglycemia indicates that this drug might not lead to inappropriate insulin secretion, which could limit the risk of hypoglycemia in type 2 diabetic patients. Administration of subcutaneous GLP-1 and intravenous glucose has been shown to induce reactive hypoglycemia in healthy volunteers, but not in type 2 diabetic subjects (18). However, long-term clinical intervention studies are needed to test this hypothesis.
The insulin and C-peptide levels and insulin secretory response achieved with NN2211 in diabetic subjects were remarkably similar to those of healthy control subjects with normal glucose tolerance who did not receive the drug. The restoration of insulin secretion dynamics has not been observed with oral hypoglycemic agents in type 2 diabetic patients (19,20). Thus, the dramatic improvement of insulin responses during graded hyperglycemia after NN2211 is encouraging. However, this comparison does not take into account the likely greater insulin resistance in diabetic subjects, given their higher BMI, increased fasting insulin levels, and decreased glucose infusion rates needed to achieve similar glucose and insulin levels during study. At a comparable level of insulin resistance, individuals with normal ß-cells would likely secrete much more insulin in response to a challenge. Thus, despite the dramatic improvement of insulin secretion in the diabetic subjects after NN2211, it is likely that their ß-cell function remained impaired.
Impairment of islet sensitivity to glucose is an early abnormality of ß-cell function, as demonstrated in studies of families with maturity-onset diabetes of the young. Subjects who have glucokinase mutations with elevated fasting and postprandial glucose levels were found to have similar first-phase insulin response to intravenous glucose tolerance testing compared with nondiabetic control subjects (21). However, insulin secretion rates were 61% lower with graded glucose infusion studies in which glucose infusion rates were increased in a stepwise fashion. Our subjects with relatively well-controlled type 2 diabetes also had a very poor insulin secretion response to graded glucose infusion (see placebo values in Figs. 35 compared with those of nondiabetic control subjects).
In a previous study, a single injection of NN2211 was found to reduce fasting and postprandial hyperglycemia, suppress prandial glucagon secretion, and delay gastric emptying in type 2 diabetic patients (12). This study also evaluated insulin secretion in response to a standard meal. Postprandial insulin secretion was only slightly and insignificantly increased with NN2211; however, the interpretation of these findings is difficult as postprandial glucose levels were also substantially reduced with NN2211 compared with placebo. In contrast, in the current study, the insulin secretory response increased dramatically with NN2211 compared with placebo when patients were studied while glucose levels were carefully matched.
A limitation of this study was its short duration, in that the effect of only a single injection of NN2211 was tested. Clearly, a longer-term study is needed to define the effectiveness of NN2211 in enhancing insulin secretion in type 2 diabetic patients. Another limitation was the overall good glycemic control of the patients studied. The presence of residual ß-cell function in these patients may have contributed to the observed dramatic effect of NN2211 (although ß-cell function was grossly impaired in the absence of NN2211). The effectiveness of NN2211 on insulin secretion in patients with poorly controlled type 2 diabetes needs to be assessed. All of the diabetic subjects in the current study were treated with oral monotherapy, except one subject who was treated through diet. A possible carryover effect of sulfonylurea treatment on insulin secretion should have been limited by discontinuation of these agents 1 week before the studies. In addition, the metformin used by four subjects and the -glucosidase inhibitor used by one subject were withheld 1 day before the studies; however, these agents are not known to have direct effects on ß-cell function. In the current study, effects on fasting hyperglycemia could not be assessed, as diabetic subjects received an overnight insulin infusion to achieve comparable glucose levels before initiation of graded glucose infusion studies. We observed similar glucagon levels with intravenous glucose stimulation with NN2211 and placebo, in contrast to the meal-related suppression of glucagon levels seen with NN2211 (12) and GLP-1 (2). Because hyperglycemia tends to suppress glucagon secretion, the current protocol was not well suited to testing for a possible suppressive effect of NN2211 on glucagon secretion. In addition, because this study did not compare the effects of GLP-1 and NN2211, it cannot be concluded that NN2211 will be as efficacious as GLP-1 in all circumstances.
In summary, during controlled, matched hyperglycemia in patients with well-controlled type 2 diabetes, a single dose of NN2211 (compared with placebo) increased insulin and C-peptide levels and dramatically improved insulin secretory response to glucose, as assessed by the increased ISR AUC and the increased slope of ISR versus plasma glucose level. NN2211 was well tolerated, without evidence of hypoglycemia or significant side effects, and the pharmacokinetic properties should allow convenient once-daily dosing.
We conclude that acute administration of the long-acting GLP-1 derivative, NN2211, restores ß-cell responsiveness to physiological hyperglycemia in patients with type 2 diabetes. NN2211 has been shown to have the potential beneficial effects of improving insulin secretion, decreasing fasting and postprandial hyperglycemia, decreasing prandial glucagon secretion, and delaying gastric emptying. Long-term studies are needed to elucidate the full therapeutic potential of NN2211.
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ACKNOWLEDGMENTS |
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We would like to thank the study participants for their cooperation and commitment and the University of Michigan GCRC nurses and staff for their assistance.
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FOOTNOTES |
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Address correspondence and reprint requests to Jeffrey B. Halter, MD, University of Michigan, 1111 CCGC Bldg., 1500 East Medical Center Dr., Ann Arbor, MI 48109-0926. E-mail: jhalter{at}umich.edu
Received for publication October 29, 2002 and accepted in revised form April 8, 2003
ADA, American Diabetes Association; AUC, area under the curve; ELISA, enzyme-linked immunosorbent assay; GCRC, General Clinical Research Center; GLP-1, glucagon-like peptide 1; ISR, insulin secretion rate
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REFERENCES |
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