The potential role of valsartan + AHU377 (LCZ696) in the treatment of heart failure

Current treatments for non-insulin dependent diabetes mellitus (NIDDM) remain far from ideal. The universal finding of islet dysfunction characterised by the absence of first phase insulin secretion, even prior to the level of hyperglycaemia diagnostic of NIDDM, challenges the rationale for treatments that only enhance insulin action. To date, however, the sulfonylureas are the only insulin secretagogues available and even the most rapid acting of these fail to restore early insulin release in response to meals. Four novel non-sulfonylurea insulin secretagogues are in advanced clinical development: A-4166, KAD-1229, BTS 67 582 and repaglinide. These promising new agents control prandial hyperglycaemia by augmenting the early insulin response to meals. Preclinical and early clinical data suggest that their potencies vary considerably, as do their pharmacokinetics and, importantly, their pharmacodynamics. The two shortest-acting compounds, A-4166 and KAD-1229, will be developed to be taken prior to each main meal, while the slower, longer duration agents, repaglinide and BTS 67 582, may be developed to be taken twice daily. With a sufficiently rapid onset and short duration of action, the new non-sulfonylurea insulin secretagogues may improve or even restore the impairment of early insulin secretion without inducing the prolonged hyperinsulinaemia characteristic of sulfonylureas. Treatment with these new agents will immediately improve prandial glucose control and with continued treatment these agents are expected to improve the overall metabolic state. Furthermore, a short-acting secretagogue will have minimal propensity to elicit prolonged or delayed hypoglycaemia and it is expected that by minimising chronic hyperinsulinaemia the weight gain that accompanies sulfonylurea treatment will be avoided. In summary, the new non-sulfonylurea insulin secretagogues will make an important contribution to the limited and inadequate armamentarium currently available for the treatment of NIDDM, and their use in combination with insulin sensitising agents may provide, for the first time, an approximation to ideal metabolic control in NIDDM.     

New non-sulfonylurea insulin secretagogues

Current treatments for non-insulin dependent diabetes mellitus (NIDDM) remain far from ideal. The universal finding of islet dysfunction characterised by the absence of first phase insulin secretion, even prior to the level of hyperglycaemia diagnostic of NIDDM, challenges the rationale for treatments that only enhance insulin action. To date, however, the sulfonylureas are the only insulin secretagogues available and even the most rapid acting of these fail to restore early insulin release in response to meals. Four novel non-sulfonylurea insulin secretagogues are in advanced clinical development: A-4166, KAD-1229, BTS 67 582 and repaglinide. These promising new agents control prandial hyperglycaemia by augmenting the early insulin response to meals. Preclinical and early clinical data suggest that their potencies vary considerably, as do their pharmacokinetics and, importantly, their pharmacodynamics. The two shortest-acting compounds, A-4166 and KAD-1229, will be developed to be taken prior to each main meal, while the slower, longer duration agents, repaglinide and BTS 67 582, may be developed to be taken twice daily. With a sufficiently rapid onset and short duration of action, the new non-sulfonylurea insulin secretagogues may improve or even restore the impairment of early insulin secretion without inducing the prolonged hyperinsulinaemia characteristic of sulfonylureas. Treatment with these new agents will immediately improve prandial glucose control and with continued treatment these agents are expected to improve the overall metabolic state. Furthermore, a short-acting secretagogue will have minimal propensity to elicit prolonged or delayed hypoglycaemia and it is expected that by minimising chronic hyperinsulinaemia the weight gain that accompanies sulfonylurea treatment will be avoided. In summary, the new non-sulfonylurea insulin secretagogues will make an important contribution to the limited and inadequate armamentarium currently available for the treatment of NIDDM, and their use in combination with insulin sensitising agents may provide, for the first time, an approximation to ideal metabolic control in NIDDM.     

Study of the insulinotropic effect of the novel antihyperglycemic agent KAD-1229 using HIT T15 cells,a hamster's insulinoma cell line

The insulinotropic effect of (+)-monocalcium bis [(2S)-2-benzyl-3-(cis-hexahydro-2-isoindolinyl-carbonyl)propionate] dihydrate (CAS 145375-43-5, KAD-1229) was assessed by comparing it with those of glibenclamide (CAS 10238-21-8), nateglinide (CAS 105816-04-4), and repaglinide (CAS 135062-02-1) using HIT T15 cells, a hamster insulinoma cell line. Although their potencies were different, KAD-1229, glibenclamide, nateglinide, and repaglinide all concentration-dependently and significantly induced insulin release from these cells. Further, each agent displaced the binding of 3H-glibenclamide to the cell membrane and inhibited 86Rb+ efflux from the cells. These results indicate that KAD-1229, glibenclamide, nateglinide, and repaglinide each exert their insulinotropic effect by binding to the glibenclamide binding sites (sulfonylurea receptors) on pancreatic beta-cells and closing K+ channels. Diazoxide, a K+ channel opener, and nitrendipine, a Ca2+ blocker, suppressed the insulin release induced by KAD-1229 or glibenclamide. These results demonstrate that the insulinotropic actions of KAD-1229 and glibenclamide involve similar underlying pathways.     

Effect of KAD-1229, a nonsulfonylurea hypoglycemic agent, on plasma glucose and insulin in streptozotocin-induced diabetic dogs

Hypoglycemic agents with a rapid onset and short duration of action should be useful for controlling postprandial hyperglycemia. Our aim was to establish a diabetes mellitus model in dogs, and then during an oral glucose tolerance test to compare the hypoglycemic effect and insulinotropic action of KAD-1229, a new hypoglycemic agent, with that of gliclazide, a conventional sulfonylurea. In this model, KAD-1229 reduced the increase in plasma glucose level without producing hypoglycemia. Gliclazide had a weaker effect on reduction of the glucose increase and caused hypoglycemia via a significantly raised insulin secretion in the late phase. A rapid insulinotropic action of KAD-1229 was clearly observed in the portal venous blood. The results suggest that in type 2 diabetes caused by, at least, insulin deficiency, KAD-1229 may improve impaired insulin secretion in the early phase and attenuate hyperglycemia without causing a sustained hypoglycemia.     

Alterations of insulin secretion following long-term manipulation of ATP-sensitive potassium channels by diazoxide and nateglinide

Previous studies have shown that prolonged exposure to drugs, which act via blocking KATP channels, can desensitize the insulinotropic effects of drugs and nutrients acting via KATP channels. In this study, effects of prolonged exposure to diazoxide, a KATP channel opener, on beta cell function were examined using clonal BRIN-BD11 cells. The findings were compared to the long-term effects of KATP channel blockers nateglinide and tolbutamide. Following 18 h exposure to 200 microM diazoxide, the amounts of insulin secreted in response to glucose, amino acids and insulinotropic drugs were increased. Secretory responsiveness to a variety of agents acting via KATP channels was retained following prolonged diazoxide exposure. In contrast, 18 h exposure to 100 microM nateglinide significantly attenuated the insulin secretory responses to tolbutamide, nateglinide and BTS 67 582. Glucose- and L-alanine-stimulated insulin release were unaffected by prolonged nateglinide exposure, however responsiveness to L-leucine and L-arginine was diminished. Prolonged exposure to nateglinide had no effect on forskolin- and PMA-stimulated insulin release, and the overall pattern of desensitization was similar to that induced by 100 microM tolbutamide. We conclude that in contrast to chronic long-term KATP channel blockade, long-term diazoxide treatment is not harmful to KATP channel mediated insulin secretion and may have beneficial protective effects on beta cell function.     

Induced desensitization of the insulinotropic effects of antidiabetic drugs, BTS 67 582 and tolbutamide

Acute and chronic mechanisms of action of novel insulinotropic antidiabetic drug, BTS 67 582 (1, 1-dimethyl-2-(2-morpholinophenyl)guanidine fumarate), were examined in the stable cultured BRIN-BD11 cell line. BTS 67 582 (100 - 400 microM) stimulated a concentration-dependent increase (P<0.01) in insulin release at both non-stimulatory (1.1 mM) and stimulatory (8. 4 mM) glucose. Long-term exposure (3 - 18 h) to 100 microM BTS 67 582 in culture time-dependently decreased subsequent responsiveness to acute challenge with 200 microM BTS 67 582 or 200 microM tolbutamide at 12 - 18 h (P<0.001). Similarly 3 - 18 h culture with the sulphonylurea, tolbutamide (100 microM), also effectively suppressed subsequent insulinotropic responses to both BTS 67 582 and tolbutamide. Culture with 100 microM BTS 67 582 or 100 microM tolbutamide did not affect basal insulin secretion, cellular insulin content, or cell viability and exerted no influence on the secretory responsiveness to 200 microM of the imidazoline, efaroxan. While 18 h BTS 67 582 culture did not affect the insulin-releasing actions (P<0.001) of 16.7 mM glucose, 10 mM arginine, 30 mM KCl, 25 microM forskolin or 10 nM phorbol-12-myristate 13-acetate (PMA), significant inhibition (P<0.001) of the insulinotropic effects of 10 mM 2-ketoisocaproic acid (KIC) and 10 mM alanine were observed. These data suggest that BTS 67 582 shares a common signalling pathway to sulphonylurea but not imidazoline drugs. Desensitization of drug action may provide an important approach to dissect sites of action of novel and established insulinotropic antidiabetic agents.     

Insulinotropic action of (2S)-2-benzyl-3-(cis-hexahydro-2-isoindolinyl-carbonyl) propionate I. Secretory and cationic aspects

• 1.1. Sodium (2S)-2-benzyl-3-(cis-hexahydro-2-isoindolinylcarbonyl) propionate (KAD-1229) is a newly introduced non-sulphonylurea insulinotropic agent.
• 2.2. It failed to affect insulin release by rat islets incubated in the absence of D-glucose, slightly increased insulin output at 2.8 mM D-glucose and markedly enhanced secretion at 6.0 and 11.1 mM D-glucose. At the latter hexose concentration, the threshold concentration for the insulinotropic action of KAD-1229 was below 0.1 μM and a close-to-maximal response recorded with 1.0 μM KAD-1229. Even at 16.7 mM D-glucose, KAD-1229 (10 μM) still augmented insulin output.
• 3.3. At 6.0 mM D-glucose, KAD-1229 (0.1–1.0 μM) caused a concentration-related increase in ⁴⁵Ca uptake. This coincided, in prelabelled islets, with a rapid and dual change in ⁸⁶Rb outflow and dramatic increase in ⁴⁵Ca outflow.
• 4.4. KAD-1229 also increased insulin release evoked by 2-ketoisocaproate (10 mM), albeit to a lesser extent than observed at a D-glucose concentration of comparable insulinotropic efficiency. ¹⁴C-labelled KAD-1229 was poorly oxidized by the islets.
• 5.5. These findings support the view that the mode of action of KAD-1229 displays analogy with that of hypoglycemic sulphonylurea.

     

Interaction of nateglinide with K(ATP) channel in beta-cells underlies its unique insulinotropic action

Nateglinide is a novel insulinotropic agent for the treatment of type 2 diabetes. It is a D-phenylalanine derivative, chemically distinct from repaglinide and sulphonylureas (glyburide or glimepiride). Although each agent is known to stimulate insulin release via the signaling cascade initiated by closure of ATP-dependent K+ (K(ATP)) channels in pancreatic beta-cells, the pharmacological effect of nateglinide is reportedly fast-acting, short-lasting, sensitive to ambient glucose and more resistant to metabolic inhibition. The aim of the present study was to elucidate the molecular mechanism(s) underlying the distinct properties of the insulinotropic action of nateglinide. By using the patch-clamp methods, we comparatively characterized the potency and kinetics of the effect of these agents on K(ATP) channels in rat beta-cells at normal vs. elevated glucose and under physiological condition vs. experimentally induced metabolic inhibition. Our results demonstrated that the mode of the action of nateglinide on K(ATP) current was unique in (a) glucose dependency; (b) increased potency and efficacy under ATP depletion and uncoupling of mitochondrial oxidative phosphorylation than physiological condition; (c) substantially more rapid onset and offset kinetics. The data provide mechanistic rationale for the unique in vivo and ex vivo activity profile of nateglinide and may contribute to reduced hypoglycemic potential associated with excessive insulin secretion.     

Clinical pharmacokinetics of nateglinide: a rapidly-absorbed, short-acting insulinotropic agent

The prevalence and medical and economic impact of type 2 diabetes mellitus is increasing in Western societies. New agents have been developed that act primarily to reduce postprandial glucose excursions, which may be of particular significance now that postprandial glucose excursions are known to be correlated with cardiovascular morbidity and mortality. Nateglinide is a phenylalanine derivative that blocks K+ channels in pancreatic beta-cells, facilitating insulin secretion. Nateglinide sensitises beta-cells to ambient glucose, reducing the glucose concentration needed to stimulate insulin secretion. The pharmacokinetics of nateglinide are characterised by rapid absorption and elimination, with good (73%) bioavailability. Nateglinide is more rapidly absorbed when given 0-30 minutes prior to meal ingestion than if given during the meal. Nateglinide is extensively metabolised, primarily by cytochrome P450 2C9, and eliminated primarily by the kidney. Nateglinide pharmacokinetics are linear over the dose range 60-240 mg. No significant pharmacokinetic alterations occur in renally impaired patients, in the elderly, or in mildly hepatically impaired patients. Nateglinide administered prior to meals stimulates rapid, short-lived insulin secretion in a dose-dependent manner, thus decreasing mealtime plasma glucose excursions. Its effects on insulin secretion are synergistic with those of a meal. With increasing nateglinide doses, the risk of hypoglycaemia also increases, but its incidence is low. Even if a meal is missed, and the patient skips the dose of nateglinide (as recommended in the event of a missed meal), the incidence of subsequent hypoglycaemia remains low compared with long-acting agents. The postprandial insulinotropic effects of nateglinide are more rapid than those of repaglinide and more rapid and greater than those of glibenclamide (glyburide), while producing less prolonged insulin exposure and less risk of delayed hypoglycaemia. Further investigation is required to determine if nateglinide inhibition of postprandial glucose excursions will help to prevent diabetic complications or preserve pancreatic beta-cell function.     

Effect of a non-sulphonylurea hypoglycaemic agent, KAD-1229 on hormone secretion in the isolated perfused pancreas of the rat.

1. We examined the cooperative effect of a newly synthesized oral hypoglycaemic agent, KAD-1229 with glucose on insulin, glucagon and somatostatin secretion in the isolated perfused pancreas of the rat. 2. KAD-1229 stimulated concentration-dependently the first phase of insulin secretion without the second phase in the presence of 2.8 mM glucose, while it stimulated both the first and the second phase of insulin release in the presence of 5.6 mM glucose. It was confirmed that the first phase of insulin release is depolarization-induced release with no other additional signal transduction. 3. KAD-1229 also enhanced insulin release evoked by 16.7 mM glucose, a concentration known to inhibit the ATP-sensitive K+ current completely. 4. A low concentration (2.8 mM) of glucose stimulated somatostatin release transiently, while a higher concentration (16.7 mM) of glucose exerted a sustained stimulation. KAD-1229 stimulated somatostatin secretion in a concentration-dependent manner irrespective of glucose concentrations. 5. When glucagon release was stimulated with 2.8 mM glucose, KAD-1229 inhibited this hypoglycaemia-induced glucagon secretion. 6. When pancreata from rats pretreated with streptozotocin (STZ) 60 mg kg-1 were perfused, the basal secretion of glucagon was markedly elevated, and the glucagon response to the low glucose was abolished. Further, the insulin and somatostatin responses to KAD-1229 were largely attenuated. KAD-1229 showed transient enhancement followed by inhibition of the glucagon release from the STZ-pretreated rat pancreas. 7. We conclude that KAD-1229 stimulates insulin and somatostatin release, while it inhibits glucagon release following transient stimulation.     

那格列奈与格列吡嗪治疗2型糖尿病疗效比较

目的:探讨那格列奈治疗2型糖尿病的疗效。方法:2型糖尿病患者62例,随机分为两组。那格列奈组30例,格列吡嗪组32例,两组年龄、性别匹配具有可比性,疗程均为12周。观察两组空腹血糖、餐后2h血糖、胰岛素、糖化血红蛋白等变化及不良反应。结果:两组治疗后空腹血糖、餐后2h血糖和糖化血红蛋白(HbAIC)均明显下降,差异有显著性(P<0.01);两药降低空腹血糖幅度无统计学意义,而对餐后2h血糖的疗效那格列奈高于格列吡嗪(P<0.01),那格列奈降低HbAIC疗效优于格列吡嗪(P<0.05),那格列奈能刺激胰岛素分泌,口服后2h血浆胰岛素浓度高于格列吡嗪。结论:那格列奈和格列吡嗪对空腹血糖均有显著性下降,那格列奈控制餐后高血糖和降低HbAIC明显优于格列吡嗪。     

Nateglinide: A structurally novel,short-acting,hypoglycemic agent

Nateglinide is a short-acting, pancreatic, beta-cell-selective, K(ATP) potassium channel blocker that improves overall glycemic control in type 2 diabetes. Although nateglinide's mechanism of action is related to that of sulphonyl-ureas and repaglinide, important differences do exist. Nateglinide binds rapidly to the sulfonylurea SUR1 receptor with a relatively low affinity, and it dissociates from it extremely rapidly in a manner of seconds. This rapid association and dissociation gives nateglinide a unique "fast on-fast off" effect. Thus, nateglinide has a rapid onset and short duration of action stimulating insulin secretion in vivo and providing good control of postprandial hyperglycemia when taken immediately prior to meals. The rapid action of nateglinide on the beta cells stimulates and restores the normal physiological first and early phase of insulin secretion, consequently reducing postprandial hyperglycemia. This hypoglycemic effect of nateglinide leads to improved glycemic control, while the short duration avoids delayed hyperinsulinemia and hypoglycemia after meals. Nateglinide is not a sulfonylurea, but it shares the mechanism of action of commonly used oral hypoglycemic agents such as glibenclamide and glipizide. Like the recently introduced, short-acting agent, repaglinide, it does not incorporate a sulfonylurea moiety. However, nateglinide's effects on insulin secretion and glycemic control differ significantly from the sulfonylureas and repaglinide in that it preferentially stimulates acute phase insulin, better controls postprandial glucose excursions and spikes, and causes less hyperinsulinemia and hypoglycemia. Compounds with such a profile should not only achieve improved overall glucose control, but also reduce the risk of vascular complications which is the most important feature of nateglinide. Clinical studies with nateglinide have confirmed that it acts rapidly and both restores insulin release and attenuates the postprandial glucose spike. Nateglinide is both effective and well tolerated in the treatment of type 2 diabetes. The reported overall profile of adverse effects appears to be superior to that of other K(ATP) potassium channel blockers, the glucose modulator metformin and PPARgamma agonists such as troglitazone. Clinical comparisons of these agents have shown nateglinide to be more effective in attenuating postprandial glucose than any other oral hypoglycemic agent, and that treatment with both nateglinide and metformin provides additive effects that afford improved control of plasma glucose levels. The administration regimen for nateglinide, immediately prior to meals, also facilitates patient compliance. (c) 2001 Prous Science. All rights reserved.     

The effects of mitiglinide (KAD-1229), a new anti-diabetic drug, on ATP-sensitive K+ channels and insulin secretion: comparison with the sulfonylureas and nateglinide.

Mitiglinide (KAD-1229), a new anti-diabetic drug, is thought to stimulate insulin secretion by closing the ATP-sensitive K+ (K(ATP)) channels in pancreatic beta-cells. However, its selectivity for the various K(ATP) channels is not known. In this study, we examined the effects of mitiglinide on various cloned K(ATP) channels (Kir6.2/SUR1, Kir6.2/SUR2A, and Kir6.2/SUR2B) reconstituted in COS-1 cells, and compared them to another meglitinide-related compound, nateglinide. Patch-clamp analysis using inside-out recording configuration showed that mitiglinide inhibits the Kir6.2/SUR1 channel currents in a dose-dependent manner (IC50 value, 100 nM) but does not significantly inhibit either Kir6.2/SUR2A or Kir6.2/SUR2B channel currents even at high doses (more than 10 microM). Nateglinide inhibits Kir6.2/SUR1 and Kir6.2/SUR2B channels at 100 nM, and inhibits Kir6.2/SUR2A channels at high concentrations (1 microM). Binding experiments on mitiglinide, nateglinide, and repaglinide to SUR1 expressed in COS-1 cells revealed that they inhibit the binding of [3H]glibenclamide to SUR1 (IC50 values: mitiglinide, 280 nM; nateglinide, 8 microM; repaglinide, 1.6 microM), suggesting that they all share a glibenclamide binding site. The insulin responses to glucose, mitiglinide, tolbutamide, and glibenclamide in MIN6 cells after chronic mitiglinide, nateglinide, or repaglinide treatment were comparable to those after chronic tolbutamide and glibenclamide treatment. These results indicate that, similar to the sulfonylureas, mitiglinide is highly specific to the Kir6.2/SUR1 complex, i.e., the pancreatic beta-cell K(ATP) channel, and suggest that mitiglinide may be a clinically useful anti-diabetic drug.     

symbol: see text] Nateglinide and [symbol: see text] repaglinide for type 2 diabetes?

[symbol: see text] Nateglinide (Starlix-Novartis) and [symbol: see text] repaglinide (NovoNorm-Novo Nordisk) are two of a new class of orally active antidiabetic drugs, the meglitinides. They have a rapid-onset and short-lasting stimulating effect on insulin secretion. Both are licensed for combination therapy with metformin in patients with type 2 diabetes mellitus who are inadequately controlled by maximally tolerated doses of metformin alone. In addition, repaglinide is licensed for use as monotherapy in patients with type 2 diabetes whose hyperglycaemia can no longer be controlled satisfactorily by diet, weight reduction and exercise. Here we discuss whether repaglinide and nateglinide offer worthwhile advantages in the management of patients with type 2 diabetes.     

Recent developments and emerging therapies for type 2 diabetes mellitus

Most patients with type 2 (non-insulin-dependent) diabetes mellitus require pharmacotherapy, initially as monotherapy and subsequently in combination, as adjuncts to diet and exercise. Exogenous insulin is ultimately required in a substantial proportion, reflecting the progressive natural history of the disease. Sulphonylureas and biguanides have been employed for over 4 decades as oral antidiabetic agents, but they have a limited capacity to provide long term glycaemic control and can cause serious adverse effects. Thus, more efficacious and tolerable antidiabetic agents are required. Recent years have witnessed the introduction of agents with novel modes of action, that is, the alpha-glucosidase inhibitors acarbose and miglitol (which reduce postprandial hyperglycaemia) and the first of the thiazolidinedione insulinsensitising drugs--troglitazone and rosiglitazone. Although the former has been withdrawn in some countries due to adverse effects, another 'glitazone' pioglitazone is expected to be approved in the near future. Other recently introduced drugs include glimepiride and the meglitinide insulin secretagogue, repaglinide. Attention is also focusing increasingly on combination therapy using insulin together with sulphonylureas, metformin or troglitazone. Rapid-acting insulin analogues are now being used as alternatives to conventional insulins; their role in the management of type 2 diabetes mellitus is presently uncertain but reports of a reduced frequency of hypoglycaemia are encouraging. The development of new drugs aims to counter the principal metabolic defects of the disorder, respectively, relative insulin deficiency and insulin resistance. Novel classes of rapid-acting secretagogues under evaluation include the morphilinoguanide BTS 67582 and the meglitinides mitiglinide (KAD 1229) and senaglinide (A-4166). Succinate ester derivatives represent a potential novel approach to improving beta-cell function through enhancement of insulin biosynthesis and secretion. Enhancement of nutrient-induced insulin secretion is a mechanism with several putative targets within the beta-cell; potentiators of insulin secretion include glucagon-like peptide-1 and its analogues, phosphodiesterase inhibitors and the imidazoline derivative PMS 812 (S 21663). The amylin agonist pramlintide slows gastric emptying and suppression of glucagon secretion. Non-thiazolidinedione insulin-sensitising agents include the gamma-receptor agonist G 1262570X (GG 570) and D-chiro-inositol. Insulin analogues with prolonged action and inhaled insulin preparations are also under investigation. Insulin-mimetic agents include organic vanadium compounds. Whether newer agents will offer clinically relevant efficacy and tolerability advantages over existing therapies remains to be determined.     

Stimulation of insulin secretion in clonal BRIN-BD11 cells by the imidazoline derivatives KU14r and RX801080

The imidazoline derivatives KU14R and RX801080 have each been reported to antagonize imidazoline-stimulated insulin secretion. This study investigated the effects of a range of concentrations of both KU14R and RX801080 on insulin secretion from the clonal pancreatic beta cell line, BRIN-BD11. In the presence of a stimulatory (8.4 m m) glucose concentration, both KU14R (50-200 microm;P< 0.01 to P< 0.001) and RX801080 (50-200 microm;P< 0.01 to P< 0.001) were found to dose-dependently stimulate insulin secretion. The imidazoline efaroxan (200 microm) stimulated insulin secretion (P< 0.001) from BRIN-BD11 cells. This insulinotropic effect was significantly augmented by KU14R (100-200 microm;P< 0.01 to P< 0.001) and RX801080 (200 microm;P< 0.05). Insulin secretion from BRIN-BD11 cells was also stimulated by the novel guanidine derivative BTS 67 582 (200 microm;P< 0.001). This secretagogue action was augmented both by KU14R (25-200 microm;P< 0.001) and by RX801080 (25-200 microm;P< 0.05 to P< 0.001). It is concluded that, rather than acting as antagonists of imidazoline-induced insulin secretion, the imidazoline derivatives KU14R and RX801080 are themselves potent insulinotropic agents.     

Repaglinide: a review of its use in type 2 diabetes mellitus

Oral repaglinide (GlucoNorm?; NovoNorm?; Prandin?; Surepost?) is a rapid-acting insulin secretagogue that lowers postprandial glucose (PPG) excursions by targeting early-phase insulin release, with reductions in PPG considered to be important in reducing long-term cardiovascular complications of diabetes mellitus. Repaglinide, a carbamoylbenzoic acid derivative, is chemically related to the meglitinide class of insulin secretagogues, but unrelated to the sulfonylurea insulin secretagogues. Meglitinides, including repaglinide, have a distinct binding site at the β-cell membrane, which differs from that of sulfonylureas, and corresponds to greater insulinotropic effects with repaglinide than with glibenclamide and/or glimepiride and a more rapid onset of action in in vitro and in vivo studies. This article reviews the clinical efficacy and tolerability of oral repaglinide in the treatment of patients with type 2 diabetes and provides an overview of its pharmacological properties. In well designed clinical trials of up to 52 weeks' duration and in the clinical practice setting, recommended dosages of repaglinide (0.5-4?mg three times daily up to 30?minutes prior to a meal) provided effective glycaemic control and were generally well tolerated in treatment-naive or -experienced adult patients with type 2 diabetes, including elderly patients and those with renal impairment. Furthermore, as monotherapy or in combination with other oral antihyperglycaemic drugs, repaglinide was at least as effective as other oral antihyperglycaemic drugs at improving or maintaining glycaemic control, with a tolerability profile that was generally similar to that of sulfonylurea drugs and nateglinide. Thus, repaglinide remains an effective option for the management of patients with type 2 diabetes.     

Drug-drug and food-drug pharmacokinetic interactions with new insulinotropic agents repaglinide and nateglinide

This review describes the current knowledge on drug-drug and food-drug interactions with repaglinide and nateglinide. These two meglitinide derivatives, commonly called glinides, have been developed for improving insulin secretion of patients with type 2 diabetes mellitus. They are increasingly used either in monotherapy or in combination with other oral antihyperglycaemic agents for the treatment of type 2 diabetes. Compared with sulfonylureas, glinides have been shown to (i) provide a better control of postprandial hyperglycaemia, (ii) overcome some adverse effects, such as hypoglycaemia, and (iii) have a more favourable safety profile, especially in patients with renal failure.The meal-related timing of administration of glinides and the potential influence of food and meal composition on their bioavailability may be important. In addition, some food components (e.g. grapefruit juice) may cause pharmacokinetic interactions. Because glinides are metabolised via cytochrome P450 (CYP) 3A4 isoenzyme, they are indeed exposed to pharmacokinetic interactions. In addition to CYP3A4, repaglinide is metabolised via CYP2C8, while nateglinide metabolism also involves CYP2C9. Furthermore, both compounds and their metabolites may undergo specialised transport/uptake in the intestine, another source of pharmacokinetic interactions. Clinically relevant drug-drug interactions are those that occur when glinides are administered together with other glucose-lowering agents or compounds widely coadministered to diabetic patients (e.g. lipid-lowering agents), with drugs that are known to induce (risk of lower glinide plasma levels and thus of deterioration of glucose control) or inhibit (risk of higher glinide plasma levels leading to hypoglycaemia) CYP isoenzymes concerned in their metabolism, or with drugs that have a narrow efficacy : toxicity ratio.Pharmacokinetic interactions reported in the literature appear to be more frequent and more important with repaglinide than with nateglinide. Rifampicin (rifampin) reduced repaglinide area under the plasma concentration-time curve (AUC) by 32-85% while it reduced nateglinide AUC by almost 25%. Reported increases in AUCs with coadministration of drugs inhibiting CYP isoenzymes never exceeded 80% for repaglinide (except with ciclosporin and with gemfibrozil) and 50% for nateglinide. Ciclosporin more than doubled repaglinide AUC (+144%), a finding that should raise caution when using these two drugs in combination. The most impressive pharmacokinetic interaction was reported with combined administration of gemfibrozil (a strong CYP2C8 inhibitor) and repaglinide (8-fold increase in repaglinide AUC). Although no studies have been performed in patients with type 2 diabetes, the latter combination should be avoided in clinical practice.     

那格列奈和瑞格列奈在2型糖尿病中对胰岛素的作用

目的:对比那格列奈、瑞格列奈合并二甲双胍用药治疗2型糖尿病12周后胰岛素快速分泌相和B细胞分泌胰岛素功能的改变.方法:61个经4周单用二甲双胍后病例随机分入那格列奈组和瑞格列奈组进行12周药物治疗.在0周和12周检测空腹血糖(FPG)、餐后2 h血糖(2 h PG)、糖化血红蛋白(HbA1C)、空腹胰岛素(FIN)及餐后1 h胰岛素(1 h IN)水平,并比较治疗前后胰岛素分泌相改变程度及HOMA-IR模型中B细胞功能指数(HOMA-IS)的变化.结果:(1)两组FPG、2 h PG及HbA1C均较治疗前有显著下降,P＜0.05,组间比较差异无显著性.(2)以1 h IN与空腹胰岛素FIN比值作为评估胰岛素分泌改变程度指标,两组12周其比值均高于治疗前,P＜0.05,但组间比较无差异;治疗后两组HOMA-IS显著高于治疗前,P＜0.05,治疗后两组之间无差异.(3)影响1 h IN /FIN及HOMA-IS的主要因素为糖尿病病史.结论:那格列奈和瑞格列奈与二甲双胍联合治疗2型糖尿病在降糖、促进胰岛素快速分泌和改善B细胞分泌功能均有显著作用.病史的长短是决定胰岛素快相分泌及胰岛B功能的重要因素.     

Investigation of the effects of BTS 67 582, a novel antidiabetic agent,in the beagle dog

BTS 67 582 stimulates insulin release and causes dose‐dependent glucose‐lowering activity in the conscious beagle dog. Plasma glucose levels were lowered within 1 h and were maximally reduced by 53.2± 2.7% 2–3 h after oral dosing with 90 μmol/kg BTS 67 582 (equivalent to 22.5 mg/kg as the free base). A dose of BTS 67 582 causing a 25% (ED₂₅) reduction of plasma glucose was calculated as 24.7 μmol/kg. No effect on the urinary excretion of glucose was observed (except for a marginal increase at the highest dose tested, 90 μmol/kg BTS 67 582). Insulin‐stimulated glucose disposal is, therefore, the most likely cause of the glucose‐lowering effect of BTS 67 582. BTS 67 582 significantly increased urine flow by 1.9‐ and 2.2‐fold and sodium excretion by 2.8‐ and 2.9‐fold by BTS 67 582 at 30 and 90 μmol/kg, respectively, without increased potassium excretion. In separate studies, increases in the urinary clearance of both creatinine and p‐aminohippuric acid were observed with BTS 67 582 at 90 μmol/kg, indicating that changes in glomerular filtration rate and renal blood flow, respectively, may have contributed to this diuretic effect. BTS 67 582 had no effect on blood pressure or heart rate. In conclusion, in the conscious beagle dog BTS 67 582 stimulates insulin secretion, causes dose‐dependent lowering in plasma glucose, and also possesses mild eukalemic diuretic properties. Drug Dev. Res. 47:137–143, 1999. © 1999 Wiley‐Liss, Inc.