Abstract
Objective
To evaluate the emerging classes of antihyperglycemic agents that target the incretin pathway, including their therapeutic efficacy and side effect profiles, in order to help identify their place among the treatment options for patients with type 2 diabetes.Quality of evidence
MEDLINE, EMBASE, and the Cochrane Database of Systematic Reviews were searched. Most evidence is level I and II.Main message
Two classes of incretin agents are currently available: glucagonlike peptide 1 (GLP1) receptor agonists and dipeptidyl peptidase 4 (DPP4) inhibitors, both of which lower hyperglycemia considerably without increasing the risk of hypoglycemia. The GLP1 receptor agonists have a greater effect on patients' glycated hemoglobin A(1c) levels and cause sustained weight loss, whereas the DPP4 inhibitors are weight-neutral.Conclusion
The GLP1 and DPP4 incretin agents, promising and versatile antihyperglycemic agents, are finding their way into the therapeutic algorithm for treating type 2 diabetes. They can be used in patients not adequately controlled by metformin monotherapy or as initial therapy in those for whom metformin is contraindicated.Free full text
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Incretin agents in type 2 diabetes
Abstract
OBJECTIVE
To evaluate the emerging classes of antihyperglycemic agents that target the incretin pathway, including their therapeutic efficacy and side effect profiles, in order to help identify their place among the treatment options for patients with type 2 diabetes.
QUALITY OF EVIDENCE
MEDLINE, EMBASE, and the Cochrane Database of Systematic Reviews were searched. Most evidence is level I and II.
MAIN MESSAGE
Two classes of incretin agents are currently available: glucagonlike peptide 1 (GLP1) receptor agonists and dipeptidyl peptidase 4 (DPP4) inhibitors, both of which lower hyperglycemia considerably without increasing the risk of hypoglycemia. The GLP1 receptor agonists have a greater effect on patients’ glycated hemoglobin A1c levels and cause sustained weight loss, whereas the DPP4 inhibitors are weight-neutral.
CONCLUSION
The GLP1 and DPP4 incretin agents, promising and versatile antihyperglycemic agents, are finding their way into the therapeutic algorithm for treating type 2 diabetes. They can be used in patients not adequately controlled by metformin monotherapy or as initial therapy in those for whom metformin is contraindicated.
Résumé
OBJECTIF
Évaluer les nouvelles classes d’hypoglycémiants qui agissent via la voie des incrétines, y compris leur efficacité thérapeutique et leur profil d’effets indésirables, afin d’aider à établir leur place parmi les options de traitement pour les diabétiques de type 2.
QUALITÉ DES PREUVES
On a consulté MEDLINE, EMBASE et la Cochrane Database of Systematic Reviews. La plupart des preuves étaient de niveaux I et II.
PRINCIPAL MESSAGE
Il existe actuellement deux classes d’incrétines : les agonistes des récepteurs du peptide 1 apparenté au glucagon (GLP1) et les inhibiteurs de la dipeptidyl peptidase (DPP4), qui causent tous deux une réduction importante de l’hyperglycémie sans augmenter le risque d’hypoglycémie. Les agonistes des récepteurs du GLP1 ont un effet plus grand sur l’hémoglobine glycosylée A1c et entraînent une perte de poids durable, alors que les inhibiteurs de la DPP4 sont sans effet sur le poids.
CONCLUSION
Les incrétines des types GLP1 et DPP4 sont des hypoglycémiants versatiles et prometteurs qui s’intègrent progressivement à l’algorithme thérapeutique du traitement du diabète de type 2. Ils peuvent être utiles chez les patients qui ne sont pas adéquatement contrôlés avec la metformine seule ou comme traitement de première intention dans les cas où la metformine est contre-indiquée.
Diabetes is a disease of increasing consequence, affecting an estimated 285 million adults worldwide, of whom approximately 85% to 95% have type 2 diabetes (T2DM).1 Advances over the past few decades have yielded various therapeutic options.2 In the Canadian primary care setting, however, 49% of patients with T2DM failed to achieve the glycated hemoglobin (HbA1c) target levels (≤ 7%) recommended by the Canadian Diabetes Association (CDA),3 with 17% of patients at levels above 8.4%.4 Current approaches thus appear to be inadequate for many patients with T2DM.
Since 2008, Canadian physicians have had access to sitagliptin, an antihyperglycemic drug with a novel mechanism of action: increasing the activity of glucose-regulating hormones called incretins, which stimulate insulin secretion in response to high levels of blood glucose. The fact that incretins are glucose-dependent is key to their unique therapeutic potential, because this offers the possibility of controlling hyperglycemia without placing patients at risk of hypoglycemia.5
The incretin pathway (Figure 1), which represents an important aspect of normal glucose homeostasis, is not the direct target of any traditional antihyperglycemic treatments. However, various new drugs that act on this pathway have been studied extensively in late-phase trials.6 Three of these incretin agents (sitagliptin, saxagliptin, and liraglutide) are now approved in Canada, and others (already in use in Europe or the United States) could reach the Canadian market in the very near future. Here, we examine recent evidence regarding the potential of 4 of the incretin agents (sitagliptin, vildagliptin, exenatide, and liraglutide) to improve routine T2DM management in Canada, as described in the recent CDA treatment guidelines.3 Readers wishing for a broader analysis of the incretin literature, not restricted to the Canadian treatment environment, might wish to consult other relatively recent reviews, such as a series in the American Journal of Medicine in 2009.7–10
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Actions of the incretins in normal glucose homeostasis: The incretins GLP1 and GIP are peptide hormones that are released from K and L cells in the small intestine following a meal. Among other actions, the incretins stimulate release of insulin from pancreatic β cells in a glucose-dependent manner, and GLP1 suppresses glucagon release from pancreatic α cells. This has a combined effect on hyperglycemia by both increasing the uptake of glucose by tissues and decreasing the release of glucose from the liver. GLP1 also affects glucose homeostasis by delaying gastric emptying. Both GLP1 and GIP are rapidly cleaved and inactivated by DPP4, resulting in a half-life of 1–2 min. In patients with T2DM, GIP’s actions in the pancreas are impaired and GLP1 production after a meal is reduced.
DPP4—dipeptidyl peptidase 4, GIP—glucose-dependent insulinotropic polypeptide, GLP1—glucagonlike peptide 1, T2DM—type 2 diabetes.
Quality of evidence
MEDLINE, EMBASE, and the Cochrane Database of Systematic Reviews were searched. Search terms and MeSH headings used included exenatide, liraglutide, vildagliptin, and sitagliptin, in combination with the term clinical. Reference lists in selected articles were reviewed to identify additional relevant information. Randomized controlled trials, meta-analyses, and systematic reviews (level I evidence) were assessed, as were open-label trials and US Food and Drug Administration publications (level II evidence) for “real-world” experience. Level III evidence describing potential rare adverse events was also considered.
Physiologic effects of incretins
The endogenous incretins, namely glucose-dependent insulinotropic polypeptide (GIP) and glucagonlike peptide 1 (GLP1), are peptide hormones secreted from endocrine cells in the small intestine.11 In healthy individuals, both of these molecules activate insulin secretion; GLP1 also inhibits glucagon secretion and slows gastric emptying.11
A key limitation to therapeutic use of the endogenous incretins is their rapid turnover (1- to 2-minute half-lives), resulting from the action of the circulating enzyme dipeptidyl peptidase 4 (DPP4), which rapidly inactivates GIP and GLP1.11 In addition, GIP’s actions on the pancreas are blunted in patients with T2DM.12 In contrast, the action of GLP1 is essentially intact in patients with T2DM, although this hormone is produced at lower-than-normal levels following meals.12
Promising therapeutic approaches for T2DM therefore include stabilizing endogenous GLP1 using a DPP4 inhibitor (sitagliptin, vildagliptin, or saxagliptin13,14) or supplying an exogenous, more stable molecule with the action of GLP1 (the GLP1 mimetic, exenatide, or the human GLP1 analogue, liraglutide).5
Integrating incretin agents into therapeutic paradigms
As reviewed below, accumulating clinical experience for all of these therapies shows that they can effect considerable improvements in HbA1c levels, combined with sustained beneficial effects on body weight (weight loss with GLP1 receptor agonists and weight neutrality with DPP4 inhibitors). Indeed, it appears that the incretin agents discussed here are at least as effective as commonly used oral antihyperglycemics.15–19 Used in combination with oral agents, the GLP1 receptor agonists (exenatide and liraglutide) might offer glycemic control similar to that of insulin treatment, but with little or no risk of serious hypoglycemia.20–23 Incretin agents might reduce patients’ risk of diabetic complications, including possibly cardiovascular disease (CVD); trials to test this hypothesis are ongoing. Information about these ongoing trials is available from www.clinicaltrials.gov (trial numbers NCT00766857 and NCT00790205).
Key pharmacologic differences among the 4 drugs reviewed here, as well as other clinical considerations, can be found in Table 1.18,20,22–37 The clinical literature supporting the use of the various incretin agents is summarized in Table 2.15,16,18,20–28,31,32–36,38–60
Table 1.
Pharmacology and clinical considerations for the incretin agents
CONSIDERATIONS | GLP1 RECEPTOR AGONISTS | DPP4 INHIBITORS | ||
---|---|---|---|---|
EXENATIDE20,22,24–31 | LIRAGLUTIDE18,23,32–34 | VILDAGLIPTIN35,36 | SITAGLIPTIN35,37 | |
Administration | SC injection | Oral tablet | ||
Half-life, h | 2.4 | 11–15 | 2.5 | 12–14 |
Dose | 5 or 10 μg, twice daily | 0.6, 1.2, or 1.8 mg, once daily | 50 mg, twice daily | 100 mg, once daily |
Origin of active incretins following treatment | Exogenous and endogenous | Endogenous | ||
Effect on insulin level | Large increase | Moderate increase | ||
Effect on glucagon level | Moderate decrease | |||
Mean decrease in HbA1c vs placebo, % | Approximately 0.8 | 0.8–1.6 | Approximately 0.7 | 0.6–1.0 |
Postprandial hyperglycemia | Moderate decrease | Small decrease | ||
Gastric emptying | Inhibited | No clinically significant effect | ||
Body weight | Moderate decrease | Neutral | ||
Tolerability issues* | Nausea | Upper respiratory tract infection | ||
Incidence of hypoglycemia | Low rate of hypoglycemia when administered as monotherapy in patients with T2DM; risk might increase when used in combination with sulfonylureas |
DPP4—dipeptidyl peptidase 4, GLP1—glucagonlike peptide 1, HbA1c—glycated hemoglobin A1c, SC—subcutaneous, T2DM—type 2 diabetes.
Table 2.
Summary of clinical trials involving incretin agents
INCRETIN AGENT AND COMBINATION | COMPARATOR | N | DURATION, WK | MEAN CHANGE IN HBA1C, %* |
---|---|---|---|---|
Sitagliptin | ||||
![]() ![]() | Placebo | 2389 | 12–24 | −0.44 to −0.66 |
![]() ![]() | Placebo | 1437 | 24 | −0.67 to −1.90 |
![]() ![]() | Glipizide | 1172 | 52 | −0.67 |
![]() ![]() | Placebo | 441 | 24 | −0.45 |
![]() ![]() | Placebo | 353 | 24 | −0.85 |
![]() ![]() | Exenatide | 61 | 2 | NA |
Vildagliptin | ||||
![]() ![]() | Placebo | 2253 | 12–52 | −0.20 to −0.92 |
![]() ![]() | Placebo | 651 | 12–24 | −0.60 to −0.90 |
![]() ![]() | Placebo | 296 | 24 | −0.50 |
![]() ![]() | Pioglitazone | 576 | 24 | −0.88 |
![]() ![]() | Placebo | 463 | 24 | −1.00 |
![]() ![]() | Vildagliptin vs pioglitazone vs vildagliptin and pioglitazone | 607 | 24 | −1.1 |
Exenatide | ||||
![]() ![]() | Placebo | 377 | 30 | −0.86 |
![]() ![]() | Placebo | 336 | 30 | −0.8 |
![]() ![]() | Placebo | 733 | 30 | −0.75† |
![]() ![]() | Placebo | 233 | 16 | −0.89 |
![]() ![]() | Insulin glargine | 689 | 26–32 | −1.36 to −1.16 |
![]() ![]() | Biphasic insulin | 501 | 52 | −1.04 |
![]() ![]() | Placebo | 232 | 24 | −0.9 |
![]() ![]() | None | 314 | 82 | −1.1 |
![]() ![]() | Placebo | 217 | 156 | −1.0 |
Liraglutide | ||||
![]() ![]() | Glimepiride | 746 | 52 | −0.84 to −1.14 |
![]() ![]() | Placebo or glimepiride | 1091 | 26 | −1.0 |
![]() ![]() | Placebo or rosiglitazone | 1041 | 26 | −1.1 |
![]() ![]() | Placebo | 533 | 26 | −1.5 |
![]() ![]() | Insulin glargine | 581 | 26 | −1.33 |
![]() ![]() | Exenatide plus previous oral antihyperglycemics | 464 | 26 | −1.12 |
HbA1c—glycated hemoglobin A1c, LEAD—Liraglutide Effect and Action in Diabetes, NA—not applicable, TZD—thiazolidinedione.
DPP4 inhibitors: sitagliptin and vildagliptin
Oral DPP4 inhibitors increase the availability of endogenous GLP1, thus enhancing glucose-induced insulin secretion and inhibiting glucagon release. These agents have no effect on gastric emptying61,62 and do not affect body weight.35 A comprehensive meta-analysis of trials of once-daily sitagliptin (available in Canada and elsewhere) or twice-daily vildagliptin (marketed in Europe) concluded that these agents were well tolerated,35 although infections, including nasopharyngitis, upper respiratory tract infections, and urinary tract infections, were significantly increased with sitagliptin (relative risk 1.15 compared with placebo [95% confidence interval 1.02 to 1.31; P = .03]). Headache was reported for both drugs but was more common in patients taking vildagliptin.35
As monotherapy or in combination with other anti-hyperglycemic agents, DPP4 inhibitors reduced HbA1c levels to an extent similar to metformin, sulfonylureas,15 and thiazolidinediones (TZDs),16 with an average reduction of 0.6% to 0.7% compared with placebo.35 When added to insulin, vildagliptin reduced HbA1c levels by 0.6%, compared with 0.2% for placebo.56 Although long-term studies are not available comparing DPP4 inhibitors with incretin receptor agonists, a 2-week, randomized, double-blind crossover trial demonstrated significantly increased insulin secretion and tighter control of postmeal hyperglycemia with exenatide, relative to sitagliptin (P < .0001).47
GLP1 receptor agonists: exenatide and liraglutide
As peptide-based therapies, the GLP1 receptor agonists require subcutaneous administration. Thus far, exenatide has been approved for use in the United States, Europe, and elsewhere; liraglutide is now approved in the United States, Canada, and Europe. Both have been examined in multiple randomized clinical trials, in which they were used as monotherapy or as add-on therapies.
The GLP1 receptor agonists are well tolerated, and trials to date have identified no common safety concerns,18,20,22,23–28,32–34 although administration of exenatide is dose-dependently associated with nausea.29,63 Liraglutide is also associated with nausea, a side effect that does not appear to be dose dependent and which declines in frequency within 4 weeks of treatment.18,60
It has also been suggested, largely on the basis of studies in rodents, that liraglutide treatment might be associated with increased risk of C-cell adenoma or carcinoma, cancers affecting the calcitonin-producing cells of the thyroid. Indeed, mice and rats treated with liraglutide might experience acute or chronic calcitonin overexpression and C-cell hyperplasia, followed in some cases by C-cell adenoma or (at the highest doses) carcinoma. However, these effects seem to be restricted to rodents, in which normal C-cells carry functional GLP1 receptors. No calcitonin up-regulation or C-cell abnormalities have been seen in nonhuman primates treated with liraglutide. Furthermore, a calcitonin screening program, carried out in 5000 individuals, found no evidence that liraglutide stimulates human C-cells. To date, there have been no clear cases of C-cell cancers in patients receiving liraglutide.
There have been isolated reports of adverse events with these drugs, notably postmarketing reports of acute pancreatitis in patients taking exenatide. In the liraglutide development program, incidence of pancreatitis is in line with expected rates in the T2DM population.64
One potentially important distinction between the 2 agents relates to their routes of excretion. Exenatide is primarily excreted by the kidneys; although dose adjustment is not necessary for patients with moderate renal impairment (creatinine clearance 30 to 80 mL/min), it might be required for those with more severe kidney disease.65 Clearance of liraglutide, by contrast, is independent of the kidneys and the creatinine clearance rate.66
The available clinical studies offer important insights into the place of these new agents among the therapeutic options for T2DM care, as discussed below.
Exenatide
Exenatide is a synthetic version of a Gila monster salivary peptide that has 53% sequence identity with human GLP1.67 It has a half-life of 2.4 hours after subcutaneous injection in humans, with peak action achieved after 2 to 3 hours.30 Studies showed that when administered twice daily, immediately before breakfast and dinner, exenatide lowered glucose for 5 to 7 hours, predominantly affecting glycemic excursion at those meals. Postlunch hyperglycemia and fasting blood glucose levels also declined significantly (P < .05).63,68
Exenatide’s efficacy as monotherapy (5- and 10-μg twice-daily dosing) was explored in 1 study, which found that HbA1c levels declined steadily during the first 12 weeks of treatment and remained stable at 0.7% and 0.9% below baseline, respectively for the 2 different dosages.31 Patients experienced dose-dependent weight loss (2.8 and 3.1 kg, respectively) and improved systolic and diastolic blood pressure. In other studies, in which exenatide (10 μg twice daily) was combined with either metformin or a sulfonylurea, similar improvements in HbA1c levels occurred, with stable values of 0.8% to 0.9% below baseline.24,25 In the exenatide-sulfonylurea study, 41% of patients achieved HbA1c levels below 7.0%.25 Both combinations also caused progressive weight loss.24,25
Exenatide has also been studied in more complex regimens, as an add-on to metformin plus either a sulfonylurea or a TZD. In combination with metformin and a sulfonylurea, exenatide (10 μg twice daily) led to a mean placebo-adjusted reduction in HbA1c levels of 1.0%, with 34% of patients achieving HbA1c levels below 7.0% after 30 weeks.26 Again, significant weight loss of 1.6 kg occurred (P ≤ .01).26 In this multidrug regimen, patients treated with exenatide experienced changes in HbA1c levels similar to those observed in patients receiving once-daily insulin glargine20 or twice-daily biphasic insulin,22 but with weight loss instead of the weight gain associated with insulin treatments.20,22 Likewise, when combined with metformin plus a TZD, exenatide reduced HbA1c levels by an average of 0.9%, with a 1.5-kg weight reduction.27
In a longer-term, open-label extension trial of exenatide used as an add-on to sulfonylureas or metformin, patients experienced a mean reduction in HbA1c levels of 1.1% by 82 weeks, with half achieving HbA1c levels below 7.0%. Mean weight loss from baseline was 4.4 kg. Four severe cases of hypoglycemia were reported, all associated with sulfonylurea use.28 Decreased HbA1c levels and weight loss were sustained after 3 years.
In addition to the twice-daily formulation discussed above, a longer-acting exenatide formulation has been devised for once-weekly dosing. Extended-release exenatide appears to offer improved glycemic control relative to twice-daily exenatide, with similar body-weight benefits.69 More clinical findings are expected for extended-release exenatide (registered with www.clinicaltrials.gov as NCT00308139 and NCT00877890), as well as for albiglutide (registered with www.clinicaltrials.gov as NCT00849017 and NCT00838916), a novel GLP1 receptor agonist that might also offer good glycemic control with infrequent dosing.70
Liraglutide
Liraglutide is a GLP1 analogue with 97% sequence identity to the human hormone. Liraglutide contains a single amino acid substitution relative to endogenous GLP1 and is linked to a fatty acid chain, resulting in slow absorption into circulation, increased reversible albumin binding, and reduced susceptibility to DPP4. These effects extend liraglutide’s benefits, increasing its plasma half-life to 11 to 15 hours,71,72 with maximal concentration after 8 to 12 hours.73 Injected once daily, at any time of day, irrespective of meals, liraglutide reduced fasting blood glucose and glycemic excursions associated with all meals.18
Most recently, a series of 6 phase 3 studies (the Liraglutide Effect and Action in Diabetes [LEAD] studies) tested the use of liraglutide in different therapeutic regimens. The LEAD studies examined glycemic and weight effects and the safety of once-daily liraglutide (alone or in combination with other treatments), compared with placebo or active comparators.
The year-long LEAD-3 study explored liraglutide’s use as possible monotherapy; LEAD-3 patients discontinued previous oral antihyperglycemics and received either the sulfonylurea glimepiride or liraglutide, the latter at 1 of 2 doses (1.2 or 1.8 mg). The mean reduction in HbA1c levels with liraglutide was dose-dependent (−0.84% [SD 1.23%] vs −1.14% [SD 1.24%], respectively), but liraglutide at either dose was superior to glimepiride.18 Half of patients administered the higher dose of liraglutide achieved HbA1c levels below 7.0%.18 Within 16 weeks of treatment, mean body-weight reduction compared with glimepiride was 3.2 kg and 3.6 kg with liraglutide, depending on dose. Both the HbA1c levels and weight reductions were sustained throughout the 52-week study.18
In LEAD-1, LEAD-2, and LEAD-4, researchers tested the use of liraglutide combined with glimepiride, metformin, or metformin and rosiglitazone, respectively. These combination regimens reduced mean HbA1c levels by more than 1% over 26 weeks.32–34 Liraglutide had consistent beneficial effects on body weight, relative to the comparable regimen without liraglutide. For instance, in patients receiving liraglutide and metformin, mean weight was reduced by 1.8 to 2.8 kg, depending on liraglutide dose.33 In addition, as seen across the LEAD studies, treatment with liraglutide led to consistent improvements relative to baseline in systolic blood pressure.74 Further, β-cell function also increased with liraglutide treatment,75 as has been observed in studies of sitagliptin.76,77 Incidence of hypoglycemia was low with liraglutide, both in monotherapy18 and in combination regimens.
In LEAD-5, once-daily liraglutide was compared directly with insulin glargine in patients receiving concomitant metformin and glimepiride.23 Liraglutide led to significantly lower HbA1c levels compared with glargine (P = .0015). As is commonly observed following transition to insulin,78 patients starting glargine gained weight. Conversely, those administered liraglutide lost weight, with a difference of 3.5 kg at study’s end.23 These data,23 along with a similar study of exenatide versus insulin glargine in patients using metformin and a sulfonylurea,20 suggest that the GLP1 receptor agonists represent attractive alternatives to insulin treatment in patients for whom oral combination therapy does not work.
The final LEAD study, LEAD-6, offers a head-to-head comparison between the 2 GLP1 receptor agonists.60 In this study, liraglutide and exenatide both significantly reduced HbA1c levels relative to baseline. However, the extent of this reduction was significantly greater for liraglutide (P < .0001). Treatment-associated nausea declined with time for both study arms but persisted longer in patients treated with exenatide. Hypoglycemia was also less frequent in patients treated with liraglutide.
Analysis across the available LEAD studies shows a consistent improvement in HbA1c levels with liraglutide (1.0% to 1.6%), and a very low incidence of hypoglycemic episodes. In addition, liraglutide treatment was associated with sustained weight loss, systolic blood pressure reduction, and improved β-cell function.18,23,32–34
Conclusion
With accumulating data establishing the glycemic control and other benefits of the incretin agents, it is now possible to envision how these new drugs might eventually be incorporated into routine care of T2DM.
The 4 agents reviewed in Table 118,20,22–37 are similar with respect to their low risk of hypoglycemia, but some salient differences have emerged among them. The DPP4 inhibitors control glucose parameters with comparable efficacy to other antihyperglycemics, without associated weight gain or hypoglycemia.35 (The DPP4 inhibitor saxagliptin received approval from Health Canada during the final stages of revision of this review. Concomitant use of saxagliptin and metformin has been explored in patients failing metformin monotherapy14 and those naïve to pharmacologic treatment.79)
Compared with the DPP4 inhibitors, the GLP1 receptor agonists might yield greater reductions in HbA1c levels.47 Indeed, when used as part of multidrug regimens, both exenatide and liraglutide appear to be at least as effective as insulin therapy. Because insulin (unlike the incretin agents and other antihyperglycemics) has no absolute ceiling dose,3 there is no theoretical limit to its efficacy. In practice, however, insulin dosing is constrained by the danger of serious hypoglycemia, a concern that does not apply when the incretin agents are used in monotherapy. Studies in the postmarketing setting will be required to determine whether insulin or the GLP1 receptor agonists offer patients superior glycemic control in routine use.
In addition to their efficacy in controlling hyperglycemia, the GLP1 receptor agonists offer the advantage of weight loss (not seen with the DPP4 inhibitors) and they delay gastric emptying, a desirable effect for controlling postmeal glycemia, but one that can be associated with nausea in some patients. For both exenatide and liraglutide, nausea is generally transient, although it apparently persists longer in patients taking exenatide.60 Patients taking either of these agents should therefore be advised to eat small, frequent meals, particularly during the early weeks of treatment. Finally, for patients with renal impairment, the reduced clearance of exenatide could represent an additional consideration in choosing between the GLP1 receptor agonists.66
For many newly diagnosed patients, the CDA-recommended target of HbA1c levels of 7.0% or lower might be achievable within 6 months using monotherapy with sitagliptin,38 vildagliptin,48 exenatide,31 or liraglutide.18 Indeed, it appears the more ambitious target of HbA1c levels of 6.5% or lower (appropriate for certain patients, according to the CDA, to reduce risk of diabetic nephropathy) is also achievable within this time frame for at least one-third of such patients.18,31,39
The CDA stopped short of recommending this latter target for most patients, recognizing the findings from the recent ACCORD (Action to Control Cardiovascular Risk in Diabetes) study,80 which examined the effects of targeting HbA1c levels of 6.0% or lower in patients with T2DM and a history of, or risk factors for, CVD. The ACCORD study showed increased mortality among patients undergoing intensive treatment to control HbA1c levels; data from this trial also suggested that intensive control could increase risk of severe hypoglycemia, while failing to yield significant reduction in CVD outcomes. However, these findings should be compared with those in 2 other large trials—ADVANCE (Action in Diabetes and Vascular Disease: Preterax and Diamicron Modified Release Controlled Evaluation)81 and VADT (Veterans Affairs Diabetes Trial)82—in which intensive glycemic control had no evident effect on mortality. It is likely that the safety of intensive glycemic control will depend on the strategies used to achieve it.82 Using the incretin agents,18,31 it might be possible to attain a high level of glycemic control while avoiding the hypoglycemia risk seen in the ACCORD study.80
Figure 2 identifies the place of the incretin agents in treatment initiation, as described in the 2008 CDA treatment guidelines.3 These guidelines emphasize that intervention must be aggressive and rapid, using monotherapy or combination therapy with agents from different classes to achieve the target HbA1c levels within 6 to 12 months of diagnosis.3
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Initiating therapy for T2DM according to current CDA Guidelines3: CDA guidelines recommend a target of HbA1c ≤ 7.0% for most patients with T2D. Pharmacotherapy should be introduced and adjusted in a timely fashion in order to attain target HbA1c within 6–12 mo of diagnosis. To this end, patients who are not responding adequately to lifestyle changes or to metformin monotherapy should advance as quickly as possible to monotherapy or combination therapy with second-line agents, such as the incretin agents. Incretin agents should also be considered among the first-line options in treating patients for whom metformin is contraindicated or inappropriate. The choice among second-line options should be made on an individual basis. Among the factors to be considered are the patient’s need for postmeal vs basal glycemic control and the need to control the patient’s body weight. In general, insulin, sulfonylurea, and thiazolidinedione treatment can be associated with weight gain. In contrast, DPP4 inhibitors and glucosidase inhibitors are weight-neutral, and the GLP1 receptor agonists typically reduce body weight over a period of 2–12 mo.
CDA—Canadian Diabetes Association, DPP4—dipeptidyl peptidase 4, GLP1—glucagonlike peptide 1, HbA1c—glycated hemoglobin A1c, T2DM—type 2 diabetes.
Lifestyle changes represent a first, key step toward improved glycemic control in patients with moderately elevated HbA1c levels. However, the guidelines recommend that physicians wait only 2 to 3 months before introducing pharmacotherapy in patients who do not respond adequately. For most patients with T2DM, metformin is an appropriate and cost-effective first-line oral agent; it is expected that other treatments will need to be added as the disease progresses.3 Sitagliptin is approved for use as an add-on to metformin,3 and saxagliptin as an add-on to metformin or a sulfonylurea. Second-line status (after metformin monotherapy) is shared with insulin and all other oral agents,3 consistent with the consensus position of the European Association for the Study of Diabetes and the American Diabetes Association.83 Second-line status is expected to be extended to the GLP1 receptor agonists as they become available.84
Incretin agents or other second-line treatments should be introduced in a timely fashion, to avoid unnecessary delays in achieving target HbA1c levels. They might also be used as first-line treatments in patients for whom metformin is inappropriate. Recent data, notably reports demonstrating the efficacy of the GLP1 receptor agonists in monotherapy,18,31 might justify early use of incretin agents in a wider variety of patients than is recommended under the current guidelines.
The GLP1 receptor agonists offer additional benefits with respect to weight loss; however, the incretin agents are all versatile therapies that can be used effectively alone or in combination with established antihyperglycemics, helping patients achieve robust and sustainable reductions in HbA1c levels without increasing their risk of hypoglycemia.
Acknowledgments
We thank John Ashkenas, PhD, of SCRIPT in Toronto, Ont, for his editorial assistance and Novo Nordisk Canada Inc for supporting our independent work on this project.
Notes
Footnotes
This article has been peer reviewed.
Cet article a fait l’objet d’une révision par des pairs.
Contributors
Dr Ross and Dr Ekoé contributed to the literature review and to preparing the article for publication.
Competing interests
Dr Ross has received honoraria from Novo Nordisk, Eli Lilly, and Merck for continuing medical education lectures. Dr Ekoé is a member of the Novo Nordisk Advisory Board and has received honoraria for lectures from Novo Nordisk.
References
Articles from Canadian Family Physician are provided here courtesy of College of Family Physicians of Canada
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Biochemical Investigation of Inhibitory Activities of Plant-Derived Bioactive Compounds Against Carbohydrate and Glucagon-Like Peptide-1 Metabolizing Enzymes.
Dose Response, 20(2):15593258221093275, 01 Apr 2022
Cited by: 4 articles | PMID: 35574252 | PMCID: PMC9099060
Modulating the Microbiota as a Therapeutic Intervention for Type 2 Diabetes.
Front Endocrinol (Lausanne), 12:632335, 07 Apr 2021
Cited by: 40 articles | PMID: 33897618 | PMCID: PMC8060771
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Phytochemicals in Garlic Extract Inhibit Therapeutic Enzyme DPP-4 and Induce Skeletal Muscle Cell Proliferation: A Possible Mechanism of Action to Benefit the Treatment of Diabetes Mellitus.
Biomolecules, 10(2):E305, 14 Feb 2020
Cited by: 14 articles | PMID: 32075130 | PMCID: PMC7072494
Featured article: Structure moderation of gut microbiota in liraglutide-treated diabetic male rats.
Exp Biol Med (Maywood), 243(1):34-44, 24 Nov 2017
Cited by: 33 articles | PMID: 29171288 | PMCID: PMC5788162
Gut microbiota-derived short-chain fatty acids and kidney diseases.
Drug Des Devel Ther, 11:3531-3542, 11 Dec 2017
Cited by: 63 articles | PMID: 29270002 | PMCID: PMC5729884
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BioStudies: supplemental material and supporting data
Clinical Trials (Showing 6 of 6)
- (1 citation) ClinicalTrials.gov - NCT00838916
- (1 citation) ClinicalTrials.gov - NCT00766857
- (1 citation) ClinicalTrials.gov - NCT00877890
- (1 citation) ClinicalTrials.gov - NCT00790205
- (1 citation) ClinicalTrials.gov - NCT00849017
- (1 citation) ClinicalTrials.gov - NCT00308139
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