Pharmacology, efficacy and safety of liraglutide in the management of type 2 diabetes

Joshua J Neumiller; Travis E Sonnett; Lindy D Wood; Stephen M Setter; R Keith Campbell

. 2010 Jul 14;3:215–226.

Pharmacology, efficacy and safety of liraglutide in the management of type 2 diabetes

Joshua J Neumiller ^1,^✉, Travis E Sonnett ², Lindy D Wood ¹, Stephen M Setter ¹, R Keith Campbell ²

PMCID: PMC3047975 PMID: 21437090

Abstract

Liraglutide is a glucagon-like peptide-1 analog with pharmacokinetic properties suitable for once-daily administration approved by the Food and Drug Administration for the treatment of patients with type 2 diabetes. Clinical trial data from large, controlled studies demonstrate the safety and efficacy of liraglutide in terms of hemoglobin A_1c (HbA_1c) reduction, reductions in body weight, and the drug’s low risk for hypoglycemic events when used as monotherapy. Liraglutide has been studied as monotherapy and in combination with metformin, glimepiride, and rosiglitazone for the treatment of type 2 diabetes. Additionally, comparative data with insulin glargine and exenatide therapy are available from Phase III trials. Once-daily administration may provide a therapeutic advantage for liraglutide over twice-daily exenatide, with similar improvements in HbA_1c and body weight observed when liraglutide was compared with exenatide. The glucose-dependent mechanism of insulin release with incretin analog therapy holds potential clinical significance in the management of postprandial hyperglycemic excursions, with minimal risk of hypoglycemia when used with non-secretagogue medications. Data to date on patient-reported outcomes with liraglutide treatment are encouraging. The most common adverse events associated with liraglutide therapy are dose-dependent nausea, vomiting, and diarrhea. Diligent postmarketing surveillance to elucidate the risk of pancreatitis and medullary thyroid carcinoma in a heterogeneous population are likely warranted.

Keywords: incretin analog, incretin effect, liraglutide, diabetes

Introduction

The burden of diabetes continues to grow, both globally to more than 220 million people worldwide with diabetes¹ and in the US, where more than 23.6 million people have the disease.² Although numerous interventions and medications exist to treat diabetes, less than half of adults in the US with diabetes are able to reach the target glycosylated hemoglobin A_1c (HbA_1c) level, as set by the American Diabetes Association (ADA), of less than 7% for most patients.³^,⁴ Attaining and maintaining glycemic control in type 2 diabetes mellitus (T2DM) is complicated by disease progression and continued β-cell deterioration.⁵ Benefits of intensive glucose control include a reduction in microvascular complications, as well as the so-called “legacy effect”. This effect refers to the results of a 10-year follow-up study to the United Kingdom Prospective Diabetes Study, which found that intensive glucose control in newly diagnosed T2DM patients provided long-term benefits on cardiovascular outcomes and mortality, even if intensive control was not sustained in the long term.⁶ Considering these findings, and that 18% of patients developed a diabetes-related complication within 6 years of diagnosis in the United Kingdom Prospective Diabetes Study,⁷ it is clear that glycemic control starting at the time of T2DM diagnosis is important.

While lifestyle modifications, including diet and exercise, were once the initial treatment for patients with T2DM, it is now recognized that these interventions are insufficient for most patients, and pharmacotherapy should not be delayed.⁸ Thus, the initial management of a patient presenting with T2DM consists of both lifestyle modification and medication, most specifically metformin, as recommended by the ADA.⁹ While monotherapy may suffice in the short term, most patients will need polypharmacy to achieve and sustain glycemic control.⁵ The ADA recommends initial combination therapy in newly diagnosed patients with an HbA_1c of >8.5%,⁹ while a consensus panel for the American Association of Clinical Endocrinologists (AACE) and the American College of Endocrinology (ACE) is even more aggressive, recommending dual therapy for patients with an HbA_1c between 7.6% and 9%, and triple therapy or insulin for those with an initial HbA_1c of >9%.⁸

Because the choice of initial therapy and adjunctive therapy for intensification is increasingly individualized to the patient, agents that were once viewed solely as add-on therapy are now being considered much earlier in the course of treatment. Glucagon-like peptide-1 (GLP-1) agonists and dipeptidyl peptidase-4 (DPP-4) inhibitors are examples of such agents. The AACE/ACE diabetes algorithm recommends monotherapy for patients with an initial HbA_1c of 6.5%–7.5%.⁸ While metformin is the preferred initial agent, GLP-1 receptor agonists, DPP-4 inhibitors, thiazolidinediones, and alpha-glucosidase inhibitors are included as alternatives.⁸ For patients requiring dual or triple therapy, the AACE/ACE preferentially recommends the addition of a GLP-1 agonist or a DPP-4 inhibitor, citing their efficacy and safety profiles, over thiazolidinediones or sulfonylureas.⁸ Following initial treatment with metformin, the ADA, in contrast, recommends intensification with either basal insulin or a sulfonylurea (both Tier 1, or well validated therapies), pioglitazone or a GLP-1 agonist (both Tier 2, or less well validated therapies).⁹ Not only have such treatment algorithms changed in recent years to recommend GLP-1 agonists earlier, but package labeling is also changing to expand their use. Exenatide, the GLP-1 agonist approved by the Food and Drug Administration (FDA) in 2005 for combination therapy, received an indication for monotherapy in 2009.¹⁰

This relatively new class of GLP-1 agonists has gained increasing use for a variety of reasons. Agents which mimic the incretin system, such as GLP-1 agonists, have a low incidence of hypoglycemia, often cause weight loss, and may preserve β-cells or even stimulate their proliferation.¹¹^,¹² In addition to the approval of exenatide, liraglutide was approved by the FDA in January 2010.¹³ This paper will provide an overview of liraglutide and attempt to compare this new incretin analog with exenatide in terms of efficacy, safety, and utility in the treatment of patients with T2DM.

Methods

A MEDLINE search (1966 – February 2010) was conducted with the key words “liraglutide” and “incretin therapies” for clinical trials and pertinent review articles published in English. References of identified articles were searched for additional relevant sources. Abstracts from the ADA and European Association for the Study of Diabetes annual meetings presented in 2006, 2007, 2008, and 2009 were also searched for relevant data. English language articles pertinent to the pharmacology, pharmacokinetics, efficacy, safety, and patient-related outcomes of liraglutide treatment were reviewed. Six Phase III clinical trials from the Liraglutide Effects and Action in Diabetes (LEAD) program have been published. Reports on patient-reported outcomes and quality of life measures have also been published and are discussed herein.

Pharmacology

A role for an intestinal mediator of insulin secretion was initially conceived by the observation that the oral intake of glucose resulted in a greater insulin response when compared with intravenous glucose administration.¹⁴^,¹⁵ This “incretin effect” is now known to be due to the stimulation of insulin release by the oral intake of nutrients which results in insulin secretion above and beyond the insulin release induced by increased blood glucose concentrations alone. The incretin effect is now recognized as being responsible for approximately 60% of the insulin response to a given meal.¹⁶ Of clinical significance, the incretin effect has been shown to be greatly impaired in patients with T2DM.¹⁷ The incretin effect is primarily attributed to 2 insulinotropic gut hormones, ie, GLP-1 and glucose-dependent insulinotropic polypeptide (GIP). GLP-1 is a 30-amino acid peptide released from L-cells of the intestine in response to a meal,¹⁸ and GIP is released by duodenal cells of the proximal small bowel.¹⁹ GLP-1 secretion is known to be deficient in patients with T2DM,²⁰^,²¹ and GLP-1 infusion has been shown experimentally to lower glucose levels via enhanced glucose-dependent insulin secretion in subjects with T2DM.²²^–²⁴ Further study with GLP-1 in subjects with T2DM has demonstrated beneficial effects of GLP-1 on decreasing inappropriate glucagon secretion,²⁵^,²⁶ slowing of gastric emptying,²⁷^,²⁸ and increased satiety and decreased food intake.²⁹

While GLP-1 has demonstrated clinical utility in the management of patients with T2DM, endogenous GLP-1 is rapidly degraded by the enzyme DPP-4, resulting in a GLP-1 half-life of approximately 1–2 minutes.³⁰ The development of DPP-4 resistant GLP-1 analogs has been one strategy by which to utilize the beneficial effects of GLP-1 in patients with T2DM. Liraglutide is the newest incretin analog currently available in the US, which is approved for once-daily administration.¹³ In vitro studies indicate that liraglutide retains affinity for GLP-1 receptors despite these structural modifications.³¹ The addition of the C16 acyl chain allows for noncovalent binding to albumin, both hindering DPP-4 access to the molecule and contributing to a prolonged half- life and duration of action.³²

Pharmacokinetics

The structure of liraglutide makes it kinetically unique when compared with the related compound exenatide; liraglutide incorporates a palmitate side chain at position 26 using a γ-glutamic acid spacer.³³^,³⁴ This change allows for 99% albumin binding when compared with natural GLP-1, allowing liraglutide to escape glomerular filtration and extend its duration of action. Liraglutide is detected in the urine and feces as metabolites, and is hepatically metabolized and eliminated via the liver and kidneys.

The pharmacokinetic profile of liraglutide makes it a desirable agent for the treatment of T2DM, given the extended time to maximum plasma concentration (T_max) and half-life (t_1/2). In an initial study performed by Elbrond et al, 72 healthy male subjects received 8 consecutive subcutaneous doses (1.25–20.0 μg/kg per dose) of liraglutide.³⁵ Results from this study reported a T_max of 9–12 hours after dosing, and a plasma t_1/2 of elimination of 11–15 hours.³⁵ In a study of 30 healthy male subjects receiving 5 consecutive subcutaneous doses (1.25–12.5 μg/kg per dose) of liraglutide, the reported T_max was 10–14 hours, while the plasma t_1/2 of elimination was 11–13 hours.³⁴ Further kinetic studies were performed utilizing liraglutide in a multi-day fashion with different administration times. One study was performed in 11 subjects with T2DM, administering 10 μg/kg subcutaneously once daily at bedtime for 1 day.³⁶ The T_max was found to be 10–14 hours, consistent with previous studies, while the plasma t_1/2 was found to be 6–14 hours. A second study was performed with liraglutide, administering 6 μg/kg subcutaneously every morning over a 7-day period in 13 T2DM subjects.³⁷ Study results reported a T_max of 7.1–13.1 hours, and a steady-state plasma t_1/2 of 17.9 hours.

Liraglutide was also examined in clinical trials to determine if normal dosing pharmacokinetics would be impacted in both renally and hepatically impaired subjects. Jacobsen et al performed a study in 30 subjects, comprising 24 with varying degrees of renal impairment and 6 healthy subjects, in which 0.75 mg of liraglutide was administered subcutaneously, with 72-hour follow-up blood sampling.³⁸ Results from this study found that liraglutide did not adversely impact serum creatinine in mild-to-severe renal impairment, and was not associated with an increased risk of adverse events in this study population. A meta-analysis was performed examining the Phase III LEAD studies, looking at the impact of liraglutide on serum creatinine levels.³⁹ When compared with normal subjects, no significant change in serum creatinine occurred with either 1.2 mg daily or 1.8 mg daily dosing; this is considered to be due to the modification of liraglutide’s chemical structure when compared with natural GLP-1. Liraglutide was also evaluated in 24 subjects with mild, moderate, severe, or no hepatic impairment.⁴⁰ Subjects were administered 0.75 mg of liraglutide as a single dose, and were evaluated after a 72-hour period to determine if hepatic impairment influenced liraglutide’s kinetic and safety profile. After both renal and hepatic evaluations, it was concluded by the researchers that no hepatic or renal dosing adjustments are necessary with liraglutide.

When compared with exenatide, there are several differences that may be advantageous when considering the use of liraglutide. Exenatide was directly compared with liraglutide in the LEAD-6 trial to determine the efficacy and safety of each agent.⁴¹ Subjects were administered either 1.8 mg/day of liraglutide (202 subjects) or 10 μg twice daily of exenatide (187 subjects) for a period of 26 weeks. It was found that liraglutide maintained steady-state plasma levels 24 hours after administration, while exenatide peaked and returned to baseline plasma levels 10–12 hours following administration. Liraglutide was also found to have minimal impact on renal function due to its chemical structure, while exenatide is primarily eliminated through the kidney, and is not recommended for use in severe renal impairment or end-stage renal disease.¹

Clinical trials

The LEAD program comprises 6 randomized, controlled, double-blind Phase III clinical studies in participants with T2DM inadequately controlled with lifestyle and dietary interventions or oral antidiabetic therapies. Table 1 provides a summary of select efficacy endpoints reported from the six LEAD studies discussed individually below.⁴²^–⁴⁷

Table 1.

Select efficacy outcomes from the Liraglutide Effects and Action in Diabetes (LEAD) trials

	Pts	Treatment		Treatment period (weeks)	HbA_1C Change (%)	Achievement of HbA_1C < 7% (%)	FPG change (mg/dL)	PPG change (mg/dL)	BW change (kg)
	Pts	Background	Intervention	Treatment period (weeks)	HbA_1C Change (%)	Achievement of HbA_1C < 7% (%)	FPG change (mg/dL)	PPG change (mg/dL)	BW change (kg)
LEAD-1⁴²	1041	Glim 2–4 mg/day	Lir 0.6 mg/day	26	−0.6^a	24^a	−13.0^a	−32.4^a	+0.7^b
			Lir 1.2 mg/day		−1.08^a,^b	35^a,^c	−28.3^a,^e	−45.0^a,^f	+0.3^b
			Lir 1.8 mg/day		−1.13^a,^b	42^a,^d	−28.6^a,^e	−48.6^a,^g	−0.2^b
			Ros 4 mg/day		−0.44^a	22	−15.8	−32.4	+2.1
LEAD-2⁴³	1091	Met 1 g twice daily	Placebo		+0.23	8	+18.2	−7.2^f	−0.1
			Lir 0.6 mg/day	26	−0.7^a	28.0ⁱ	−19.8^a	−30.6^j	−1.8^b
			Lir 1.2 mg/day		−1.0^a,^h	35.3ⁱ	−28.8^a	−41.4^j	−2.6^b,^k
			Lir 1.8 mg/day		−1.0^a,^h	42.4ⁱ	−30.6^a	−46.8^j	−2.8^b,^k
			Glim 4 mg/day		−1.0^a	36.3	−23.4^a	−45.0^j	+1.0
			Placebo		+0.1	10.8	+7.2	−10.8	−1.5
LEAD-3⁴⁴	746	Diet/exercise	Lir 1.2 mg/day	52	−0.84^l	42.8^m	−15.1ⁿ	−30.8	−2.1^b
		50% maximum dose of OAD monotherapy	Lir 1.8 mg/day		−1.14^b	50.9^b	−25.6^b	−37.4^o	−2.5^b
		50% maximum dose of OAD monotherapy	Glim 8 mg/day		−0.51	27.8	−5.2	−24.5	+1.1
LEAD-4⁴⁵	533	Met 1 g twice daily	Lir 1.2 mg/day	26	−1.48^a	57.5^a	−40^a	−47^j	−1.0^p
		Ros 8 mg/day	Lir 1.8 mg/day		−1.48^a	53.7^a	−44^a	−49^j	−2.0^p
			Placebo		−0.54	28.1	−8	−14	+0.6
LEAD-5⁴⁶	581	Met 1 g twice daily	Lir 1.8 mg/day	26	−1.33^a,^b	53.1^a,^q	−27.9^a	−32.6^a	−1.8^a,^b
		Glim 4 mg/day	Insulin glargine		−1.09	45.8	−32.2	−29.0	+1.6
			Placebo		−0.24	15.5	+9.5	−0.5	−0.4
LEAD-6⁴¹	464	Met	Lir 1.8 mg/day	26	−1.12^b	54^r	−29.0^b	NR^s	−3.2
		SU	Exen 10 μg bid		−0.79	43	−10.8	NR	−2.9

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Notes: P ≤ 0.0001 versus placebo;

P < 0.0001 versus comparator;

P = 0.0005 versus comparator;

P < 0.0001 versus comparator;

P <0.01 versus comparator;

P = 0.043 versus comparator;

P = 0.0022 versus comparator;

noninferior to active comparator;

ⁱ

P < 0.02 versus placebo;

P < 0.001 versus placebo;

P ≤ 0.01 versus placebo;

P = 0.0014 versus comparator;

P = 0.0007 versus comparator;

ⁿ

P = 0.027 versus comparator;

P = 0.0038 versus comparator;

P < 0.05 versus placebo;

P = 0.0139 versus comparator;

P = 0.0015 versus comparator;

Average reduction reported to be significantly greater for exenatide when compared with liraglutide.

Abbreviations: HbA_1c, hemoglobin HbA_1c; BW, body weight; Exen, exenatide; FPG, fasting plasma glucose; Glim, glimepiride; Lir, liraglutide; NR, not reported; OAD, oral antidiabetic drug; PPG, postprandial glucose; Pts, participants randomized; Ros, rosiglitazone; SU, sulfonylurea.

Liraglutide versus rosiglitazone as add-on to baseline glimepiride

LEAD-1 was a 26-week, randomized, double-dummy trial in 1041 patients with T2DM. The objective of the study was to compare the addition of liraglutide to glimepiride therapy with glimepiride monotherapy or the addition of rosiglitazone to baseline glimepiride.⁴² Participants had a mean baseline HbA_1c of 8.4% and a mean age of 56.1 years. Participants received liraglutide 0.6 mg/day, 1.2 mg/day, or 1.8 mg/day in combination with glimepiride, placebo plus glimepiride (2–4 mg/day), or rosiglitazone 4 mg/day plus glimepiride. Mean HbA_1c was reduced by −1.08% and −1.13% with liraglutide 1.2 mg and 1.8 mg, respectively. Participants receiving rosiglitazone experienced a mean HbA_1c reduction of −0.44%, and glimepiride monotherapy resulted in a mean HbA_1c increase of 0.23% (P < 0.0001). Of those treated with liraglutide 1.2 mg plus glimepiride, 22% reached an HbA_1c less than 6.5%, with 21% reaching an HbA_1c less than 6.5% with liraglutide 1.8 mg plus glimepiride. In contrast, 4% of those on glimepiride monotherapy and 10% of subjects treated with rosiglitazone plus glimepiride reached an HbA_1c below 6.5% (P < 0.0003).

Liraglutide versus glimepiride as add-on to baseline metformin

LEAD-2 was a randomized, double-blind study that enrolled 1091 participants with T2DM.⁴³ Participants had a mean baseline HbA_1c of 8.4%. Participants received liraglutide 0.6 mg, 1.2 mg, or 1.8 mg once daily added to metformin 1 g twice daily, placebo plus metformin, or glimepiride 4 mg/ day added to metformin. Mean HbA_1c reductions of −0.7%, −1.0%, and −1.0% were observed with liraglutide 0.6 mg, 1.2 mg, and 1.8 mg in combination with metformin, respectively. Those receiving metformin monotherapy experienced a mean HbA_1c increase of 0.1%, with a decrease of −1.0% seen in those receiving glimepiride plus metformin (P < 0.05 versus liraglutide plus metformin versus placebo plus metformin). Weight loss was achieved in all participants receiving liraglutide, compared with a 1.0 kg weight gain observed in those receiving glimepiride (P < 0.0001 for all liraglutide doses when compared with glimepiride). The percentage of patients achieving an HbA_1c less than 6.5% was 11.3% in the liraglutide 0.6 mg plus metformin group, 19.8% in the liraglutide1.2 mg plus metformin group, and 24.6% in the liraglutide 1.8 mg plus metformin group, compared with 4.2% of those treated with placebo plus metformin, and 22.2% of those treated with glimepiride plus metformin (P < 0.02 for all liraglutide doses when compared with placebo).

Liraglutide versus glimepiride as monotherapy

The LEAD-3 study enrolled 746 patients with T2DM and a mean baseline HbA_1c of 8.2%.⁴⁴ This Phase III, double-blind, parallel-treatment study involved a head-to-head comparison of monotherapy with 1.2 mg/day or 1.8 mg/day of liraglutide or glimepiride 8 mg/day. Any previous oral antidiabetic drugs (up to half the maximal dose) were discontinued at randomization prior to study drug initiation. At 52 weeks of therapy, mean HbA_1c reductions from baseline of −0.84% (P = 0.0014 versus glimepiride) and −1.4% (P < 0.0001 versus glimepiride) were seen with liraglutide 1.2 mg and 1.8 mg, compared with a reduction of −0.51% for glimepiride. Twenty-seven percent of patients on liraglutide 1.8 mg and 16% of patients on glimepiride attained an HbA_1c less than 6.5%. Decreases in body weight observed were −2.1 kg and −2.5 kg for liraglutide 1.2 mg and 1.8 mg, respectively (P = 0.0001 versus glimepiride for both doses). In contrast, participants receiving glimepiride experienced an average weight gain of 1.1 kg.

Liraglutide as add-on to baseline metformin and rosiglitazone

LEAD-4 was a 26-week, placebo-controlled trial enrolling 533 patients with T2DM and a mean baseline HbA_1c of 8.3%.⁴⁵ LEAD-4 assessed the effect of adding liraglutide 1.2 mg or 1.8 mg to baseline metformin 1 g twice daily plus rosiglitazone 8 mg/day. Liraglutide addition resulted in mean HbA_1c reductions of −1.48% for both liraglutide doses compared with −0.54% observed with the addition of placebo (P = 0.0001). An HbA_1c less than 6.5% was achieved in 35% and 37% of patients receiving liraglutide 1.2 mg and 1.8 mg, respectively. Liraglutide 1.2 mg and 1.8 mg treatment resulted in reductions in fasting plasma glucose (−40 mg/dL and −43 mg/dL, respectively) and postprandial glucose levels (−49 mg/dL and −47 mg/dL, respectively). Patients receiving placebo experienced a mean increase in body weight of 0.6 kg compared with a mean weight loss of −1.0 kg and −2.0 kg for liraglutide 1.2 and 1.8 mg (P < 0.05 versus placebo for both liraglutide doses).

Liraglutide versus glargine as add-on to baseline metformin and glimepiride

LEAD-5 aimed to compare liraglutide with insulin glargine as add-on therapy to metformin and glimepiride.⁴⁶ LEAD-5 enrolled a total of 581 patients with T2DM with a mean baseline HbA_1c of 8.2%. Participants received liraglutide 1.8 mg/day, liraglutide placebo, or insulin glargine in addition to metformin 1 g twice daily and glimepiride (2–4 mg/day) for a duration of 26 weeks. The dose of insulin glargine was individually titrated according to a patient-driven algorithm, with a mean dose of 24 units per day reported at the end of the trial in the insulin glargine arm. Mean HbA_1c values were decreased −1.33%, −0.24%, and −1.09% with the addition of liraglutide, placebo, and insulin glargine, respectively (P < 0.05 for liraglutide versus placebo and insulin glargine). An HbA_1c below 6.5% was achieved in 37.1% of patients treated with liraglutide, 10.9% of those treated with placebo (P < 0.0001 versus liraglutide), and 23.6% of patients in the insulin glargine group (P = 0.0001 versus liraglutide). A mean body weight reduction of −1.81 kg was reported in the liraglutide group (P < 0.0001 versus glargine; P = 0.0001 versus placebo), with a mean weight loss of −0.42 kg in the placebo group, and a 1.62 kg weight gain seen in the insulin glargine group.

Liraglutide versus exenatide as add-on to baseline metformin and/or a sulfonylurea

LEAD-6 was a 26-week trial in 464 patients inadequately treated with metformin and/or a sulfonylurea with a mean baseline HbA_1c of 8.2%.⁴¹ This trial aimed to compare liraglutide 1.8 mg/day to exenatide 10 μg twice daily as add-on therapy. HbA_1c reductions of −1.12% for liraglutide and −0.79% for exenatide were observed (P < 0.0001). A target HbA_1c less than 6.5% was achieved in 35% of those treated with liraglutide versus 21% for patients receiving exenatide (P < 0.0001). Changes in body weight were similar in both groups with no statistical differences in weight change between the liraglutide and exenatide treatment groups. Weight reductions of −3.2 kg and −2.9 kg for liraglutide and exenatide were observed, respectively.

Additional clinical endpoints

Clinical studies with liraglutide have also demonstrated potential benefits of therapy on β-cell function and the cardiovascular system. One study utilized a graded glucose protocol to assess the effects of a single liraglutide dose of 7.5 μg/kg on insulin secretion.⁴⁷ Insulin secretion increased with elevation in blood glucose in all groups, however liraglutide treatment resulted in a more pronounced insulin response which was similar to that observed in healthy control subjects. Other clinical studies have shown improvements in glucose-induced insulin secretion, β-cell sensitivity, and suppression of 24-hour glucagon secretion following 1 week of therapy,³⁷ and sustained β-cell sensitivity to glucose over 12 weeks of therapy.⁴⁸ Regarding the effects of liraglutide treatment on cardiovascular health, statistically significant decreases in systolic blood pressure, ranging from 2 to 7.9 mmHg, have been observed in clinical trials.⁴³^,⁴⁴^,⁴⁹ The mechanism resulting in the observed reduction in systolic blood pressure is unknown, but appears unrelated to concomitant weight loss.⁵⁰ Early data additionally indicates liraglutide treatment may also decrease cardiovascular markers such as PAI-1 and BNP, but the clinical implications, either positive or detrimental, of these findings are unknown.

Safety and tolerability

Hypoglycemia

Of paramount importance in any newly approved drug used to treat T2DM is the likelihood of hypoglycemia, when used as mono-, dual-, or even as part of a triple-therapy regimen. In the LEAD trials, a minor hypoglycemic event was defined as a plasma glucose concentration of <56 mg/dL that was resolved with self-treatment, and a major hypoglycemic event was defined as a hypoglycemic event requiring third party assistance. Note that in LEAD-1, self-treatment was the sole criteria used to classify a hypoglycemic event as minor.⁴² As expected, trials utilizing combination sulfonylurea therapy resulted in the highest incidence of hypoglycemia. LEAD-1 involved patients on concurrent sulfonylurea therapy (glimepiride).⁴² In this trial, the percentage of patients experiencing minor hypoglycemia was reported as glimepiride monotherapy (placebo) 2.6%, 0.17 events/subject-year; liraglutide 0.6 mg, 5.2%, 0.17 events/subject-year; liraglutide 1.2 mg 9.2%, 0.51 events/subject-year; liraglutide 1.8mg, 8.1%, 0.47 events/subject-year; and rosiglitazone 4.3%, 0.12 events/subject-year. Table 2 provides a summary of adverse event findings from the LEAD program. Furthermore, in the 1.8 mg liraglutide plus glimepiride cohort, one major hypoglycemic event occurred.⁴²

Table 2.

Adverse drug event rates in Liraglutide Effects and Action in Diabetes (LEAD) trials

Study	Drug	Patients experiencing minor hypoglycemia (%)	Major hypoglycemic events (n)	Nausea (%)	Vomiting (%)	GI events (%)	Pancreatitis (number of subjects)	Pulse rate (bpm)	Liraglutide antibody formation (%)
LEAD-1⁴²	Liraglutide 0.6 mg	5.2	0	NR	NR	NR	1	+2–4^a ^b	9–13^a
	Liraglutide 1.2 mg	9.2^c,^d	0	10.5	4.4	NR	0
	Liraglutide 1.8 mg	8.1^e	1	NR	NR	NR	0
	Rosiglitazone 4 mg	4.3	0	NR	NR	NR	0	+1	NA
	Placebo	2.6	0	1.8	NR	NR	0	−1	NA
LEAD-2⁴³	Liraglutide 0.6 mg	3^a ^f	0	11	5–7^a	35	0	+2–3^a ^g	NR
	Liraglutide 1.2 mg			16		40	1		NR
	Liraglutide 1.8 mg			19		44	0		NR
	Glimepiride 4 mg	17	0	NR	1	17	1	+1	NA
	Placebo	3	0	NR	1	17	0	+1	NA
LEAD-3⁴⁴	Liraglutide 1.2 mg	12^f	0	27.5^f	9.3	49	1	+3.2^h	NR
	Liraglutide 1.8 mg	8^f	0	29.3^f	12.4	51	1	+1.6	NR
	Glimepiride 8 mg	24	0	8.5	3.6	26	0	+0.4	NA
LEAD-4⁴⁵	Liraglutide 1.2 mg	9.0	0	29	7	45	0	+2	4.1
	Liraglutide 1.8 mg	7.9ⁱ	0	40	17	56	0	+3	6.7
	Placebo	5.1	0	NR	NR	19	0	−0.5	0
LEAD-5⁴⁶	Liraglutide 1.8 mg	27.5	5	13.9	6.5	NR	0	+2.62	9.8
	Insulin glargine	28.9	0	1.3	0.4	NR	0	+0.08	NA
	Placebo	16.7	0	3.5	3.5	NR	0	+0.93	NA
LEAD-6⁴¹	Liraglutide 1.8 mg	26^j	0	25.5	6.0	45.5	1	+3.28^k	NR
	Exenatide 10 μg bid	34	2	28.0	9.9	42.7	0	+0.69	NA

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Notes: Reported composite for all liraglutide doses tested;

P ≤ 0.002 versus placebo;

P = 0.0024 versus comparator;

P = 0.048 versus placebo;

P = 0.0065 versus comparator;

P < 0.001 versus comparator;

P < 0.03 for 0.6 mg and 1.2 mg liraglutide groups versus comparator;

P = 0.0027 versus comparator;

ⁱ

P = 0.004 versus placebo;

P = 0.0131 versus comparator;

P = 0.0012 versus comparator.

Abbreviations: bid, twice daily; bpm, beats per minute; GI, gastrointestinal; NA, not applicable; NR, not reported.

In LEAD-2, the percentage of patients experiencing minor hypoglycemia was low in the placebo and liraglutide cohorts, roughly 3%, while 17% of subjects receiving glimepiride reported an incidence of minor hypoglycemia.⁴³ Major hypoglycemic events did not occur in LEAD-2. There were a low percentage of patients reporting minor hypoglycemic events in LEAD-3, with 8% of the subjects in the liraglutide 1.8 mg group (0.25 events per year) and 12% of subjects in the 1.2 mg group experiencing minor hypoglycemic events (0.3 events per year).⁴⁴ Twenty-four percent of subjects in the glimepiride group reported minor hypoglycemic events while no major hypoglycemic events occurred in any of the groups in this 52-week trial.

Minor hypoglycemia was reported in LEAD-4 at rates of 9%, 7.9%, and 5.1% of subjects in the 1.2 mg liraglutide, 1.8 mg liraglutide, and placebo groups, respectively.⁴⁵ No major hypoglycemic events were reported. In LEAD-5, 27.4% of the patients receiving liraglutide experienced at least 1 episode of minor hypoglycemia (1.2 events/subject/year), while 28.9% (1.3 events/subject/year) and 16.7% (1.0 events/subject/year) experienced minor hypoglycemia in the insulin glargine and placebo groups, respectively.⁴⁶ In the liraglutide group, 5 subjects reported a major hypoglycemic episode, with no major hypoglycemic events reported in the other two cohorts.

In the open-label 26-week trial known as LEAD-6, minor hypoglycemia occurred in 26% and 34% of the liraglutide and exenatide groups, respectively; correlating to event rates of 1.9 (liraglutide) and 2.6 (exenatide) events per subject per year.⁴¹ Two cases of major hypoglycemia occurred in subjects exposed to exenatide and a sulfonylurea.

Gastrointestinal adverse events

In the LEAD-1 trial, incomplete data were provided for all arms of the study in regard to gastrointestinal (GI) side effects.⁴² The most complete data reveal that nausea was highest in the liraglutide 1.2 mg cohort (10.5%) compared with an event rate of 1.8% in the placebo group. Additionally, 4.4% and 7.9% of those in the 1.2 mg liraglutide group experienced vomiting and diarrhea, respectively.

The LEAD-2 trial involved subjects on a wide range of oral therapies that included metformin, sulfonylureas, repaglinide, or some combination of these listed medications.⁴³ GI adverse events were pronounced in this trial, with 35% of the subjects in the 0.6 mg liraglutide group experiencing GI side effects, including nausea, vomiting, and diarrhea, with 40% and 44% experiencing these GI-related adverse events in the 1.2 mg and 1.8 mg groups, respectively. This is in comparison with 17% of the placebo-treated group reporting GI-associated adverse events. Five percent (36 subjects) of those receiving any dose of liraglutide withdrew from the study due to GI-related adverse events.

In LEAD-3, nausea occurred in 27.5%, 29.3%, and 8.5% of participants in the 1.2 mg liraglutide, 1.8 mg liraglutide, and glimepiride groups, respectively.⁴⁴ Vomiting occurred in 3.6% of subjects receiving glimepiride, while this side effect occurred in 9.3% and 12.4% of those receiving 1.2 mg and 1.8 mg of liraglutide, respectively. Diarrhea was reported by 15.5%, 18.7%, and 8.9% of participants in the 1.2 mg liraglutide, 1.8 mg liraglutide, and glimepiride groups, respectively. A total of 6 participants (1.2%) receiving liraglutide withdrew from the study due to vomiting, while a total of 17 participants (3.4%) receiving liraglutide withdrew for any GI-related complaint. In the 26-week study known as LEAD-4, 29% of subjects receiving 1.2 mg liraglutide experienced nausea while 40% of subjects in the 1.8 mg liraglutide group reported this adverse event.⁴⁵ Vomiting was reported by 7% and 17% of subjects in the 1.2 mg and 1.8 mg liraglutide groups, respectively. When all GI adverse events were grouped (nausea, vomiting, diarrhea), 19% of those receiving placebo and 45% and 56% of those receiving 1.2 mg and 1.8 mg of liraglutide, respectively, reported GI-related complaints. GI adverse events contributed to 5 withdrawals (3% of participants) in the liraglutide 1.2 mg group and 19 (10.7% of participants) in the liraglutide 1.8 mg group.

Nausea occurred in 13.9% of those receiving liraglutide, 3.5% in placebo arm, and 1.3% of participants in the insulin glargine group in LEAD-5.⁴⁶ In this trial, diarrhea was reported in 10%, 5.3%, and 1.3% in the liraglutide, placebo, and insulin glargine groups, respectively. Vomiting occurred in 6.5%, 3.5%, and 0.4% in the liraglutide, placebo, and insulin glargine groups, respectively. Dyspepsia was also reported in this trial, with 6.5%, 0.9%, and 1.7% of subjects in the liraglutide, placebo, and insulin glargine groups, respectively, experiencing this GI-related adverse event. Four subjects in LEAD-5 receiving liraglutide withdrew from the study due to GI-related adverse events. LEAD-6 reported similar rates of GI-related adverse events between the liraglutide and exenatide groups.⁴¹ Overall, GI adverse events occurred in 45.5% and 42.7% of liraglutide- and exenatide-treated subjects, respectively, with nausea being the most frequently reported event. Nausea tended to resolve over time with both therapies, however, with 2.5% of the liraglutide group reporting nausea at week 26 compared with 15.8% of those receiving exenatide therapy.⁴¹ Vomiting occurred in 6.0% and 9.9% of the liraglutide and exenatide groups, respectively.

From the above data it can be seen that nausea is a frequent adverse event in subjects receiving liraglutide. However, nausea was most pronounced in the first 4 weeks of therapy, with symptoms generally dissipating over the remainder of the study period in all trials.

Pulse rate

The effects of liraglutide on pulse rate ranged from an increase of 2–4 beats per minute (bpm) in subjects receiving liraglutide (P ≤ 0.002 versus placebo; P < 0.01 versus rosiglitazone), with pulse increasing by a mean 1 bpm in subjects receiving rosiglitazone, and pulse decreasing by a mean 1 bpm in the placebo group.⁴² In the LEAD-2 trial, pulse rates increased by a mean 2–3 bpm in those receiving liraglutide, compared with a 1 bpm increase in the glimepiride and placebo groups.⁴³ The mean pulse rate in LEAD-3 increased by 0.4, 3.2, and 1.6 bpm for the glimepiride group and the 1.2 mg and 1.8 mg liraglutide groups, respectively.⁴⁴ Pulse rate increased by 2 bpm in subjects receiving liraglutide in LEAD-4, with mean pulse rates increasing by 3 bpm in those receiving liraglutide 1.8 mg.⁴⁵ Pulse rate increased by a mean of 2.62 bpm in those subjects receiving liraglutide in LEAD-5, while increases of 0.08 bpm and 0.93 bpm were experienced by those in the insulin glargine and placebo groups, respectively.⁴⁶ In LEAD-6, heart rates increased by a mean of 3.28 bpm in the liraglutide group compared with 0.69 bpm in the exenatide group.⁴¹

Pancreatitis

Pancreatitis has been reported in clinical trials with liraglutide. In LEAD-1, one subject receiving liraglutide 0.6 mg developed pancreatitis but successfully completed the trial.⁴² Two subjects withdrew from the LEAD-2 study after developing pancreatitis, 1 receiving liraglutide and 1 receiving glimepiride.⁴³ 1 participant in each of the liraglutide groups in LEAD-3 developed pancreatitis, with one completing the trial.⁴⁴ No cases of pancreatitis were reported in the 26-week LEAD-4 or LEAD-5 trials.⁴⁵^,⁴⁶ Likewise, no cases of acute pancreatitis were reported in LEAD-6; however 1 case of mild pancreatitis occurred in a subject receiving liraglutide who subsequently completed the 26-week trial.⁴¹

Anti-liraglutide antibodies

In LEAD-1, 9%–13% of subjects exposed to liraglutide during the 26-week trial developed anti-liraglutide antibodies. ⁴² The LEAD-2 and LEAD-3 trials did not measure the development of liraglutide antibody formation. In LEAD-4, 6 subjects in the liraglutide 1.2 mg group and 9 subjects in the liraglutide 1.8 mg group developed antibodies.⁴⁵ In LEAD-5, 23 subjects (9.8%) of subjects developed antiliraglutide antibodies during the 26-week study.⁴⁶ Because the LEAD-6 trial involves an extension phase where subjects may continue to take liraglutide, antibody determination will be completed once the trial is complete and after an appropriate washout period; these data are not currently available.⁴¹ While the clinical impact of anti-liraglutide antibodies is unknown at this time, further study of this phenomenon is warranted.

Additional safety considerations

Study withdrawal rates due to adverse drug events and event rates for serious adverse events reported in the six LEAD trials are summarized in Table 3. Interestingly, injection-related adverse events such as injection site rash, were not reported in any of the LEAD trials. In addition to the adverse drug events discussed above, peripheral edema was reported in the LEAD-4 trial, likely due to participants also receiving concomitant rosiglitazone.⁴⁵ In this trial, peripheral edema occurred in 5.1%, 1.7%, and 8.0% of the subjects in the 1.2 mg liraglutide, 1.8 mg liraglutide, and placebo groups, respectively. The LEAD studies indicate liraglutide to be generally safe, however the development of rare adverse events is of concern until patients at heightened risk for developing events such as pancreatitis can be identified. The safety and tolerability of liraglutide can only truly be assessed with robust Phase IV post-marketing data involving long-term treatment with this novel therapy.

Table 3.

Clinical study withdrawal and serious adverse event rates in Liraglutide Effects and Action in Diabetes (LEAD) trials

Study	Drug	Discontinuation due to ADE^a (%)	Serious adverse events^b
LEAD-1⁴²	Liraglutide 0.6 mg	20	3%
	Liraglutide 1.2 mg	34	4%
	Liraglutide 1.8 mg	43	5%
	Rosiglitazone 4 mg	19	3%
	Placebo	19	3%
LEAD-2⁴³	Liraglutide 0.6 mg	32	NR
	Liraglutide 1.2 mg	52	NR
	Liraglutide 1.8 mg	57	NR
	Glimepiride 4 mg	23.5	NR
	Placebo	4	NR
LEAD-3⁴⁴	Liraglutide 1.2 mg	28	16 subjects/18 events
	Liraglutide 1.8 mg	24	8 subjects/9 events
	Glimepiride 8 mg	16	13 subjects/17 events
LEAD-4⁴⁵	Liraglutide 1.2 mg	44	8 subjects/8 events
	Liraglutide 1.8 mg	60	7 subjects/10 events
	Placebo	10.7	12 subjects/13 events
LEAD-5⁴⁶	Liraglutide 1.8 mg	48	NR
	Insulin glargine	38.5	NR
	Placebo	5.5	NR
LEAD-6⁴¹	Liraglutide 1.8 mg	70	5.1%
	Exenatide 10 μg bid	69	2.6%

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Notes: Percentage of the total number of subject dropouts who withdrew due to an adverse drug event;

Reported either as a percentage of study subjects or number of subjects and number of events.

Abbreviations: ADE, adverse drug event; NR, not reported.

An additional theoretical concern raised in the liraglutide prescribing information is a warning regarding the observation of dose-dependent and treatment-duration-dependent thyroid C-cell tumors witnessed at clinically relevant exposures in rats and mice.¹³ During clinical trials with liraglutide, calcitonin, a biomarker for the detection of medullary thyroid cancer, was monitored routinely.⁵¹ During the LEAD program, increases in calcitonin levels did occur in a slightly higher percentage of patients treated with liraglutide when compared with controls, however, calcitonin levels remained within normal ranges.⁵¹ Ultimately, while it is unknown if this is clinically relevant in humans, liraglutide is contraindicated in patients with a personal or family history of medullary thyroid carcinoma, and in patients with multiple endocrine neoplasia syndrome type 1.¹³ The FDA has requested the establishment of a cancer registry to monitor the annual incidence of medullary thyroid cancer over the next 15 years.⁵¹

Administration

Liraglutide was approved in July of 2009 by the European Commission for marketing consideration to all 27 European Union members.⁵² Liraglutide is administered as a subcutaneous injection for once-daily treatment of T2DM, as an adjunct therapy in combination with metformin, a sulfonylurea, or metformin plus a sulfonylurea or thiazolidinedione. ⁵³ The approved dosing for use in Europe is an initial dose of 0.6 mg daily for one week, with a recommended titration to 1.2 mg daily after the first week. The maximum recommended daily dose is 1.8 mg for patients who are not well controlled and who can tolerate the higher titrated dose, although doses as high as 2 mg daily have been used in clinical trials.⁵⁴ The LEAD studies found that titrating liraglutide by 0.6 mg weekly improved the tolerability and reduced the occurrence of GI adverse events.⁴³ Injection site reactions are another concern, and should be monitored for during liraglutide initiation.¹³ Liraglutide received FDA approval for use in the US in January 2010 as an adjunct to diet and exercise to improve glycemic control in adults with T2DM.¹³ Similar to Europe, in the US liraglutide is recommended at a starting dose of 0.6 mg daily for the first week, followed by an upward titration to 1.2 mg daily.¹³ For those patients not achieving the desired glycemic control at the 1.2 mg dose, the dose can likewise be increased to 1.8 mg. As per the prescribing information, it is also recommended that a reduction in the dose of pre-existing insulin secretagogue medications be considered when initiating liraglutide to minimize the risk of treatment-emergent hypoglycemia.¹³ Liraglutide is available commercially in the US as a simple pen capable of administering 0.6, 1.2, and 1.8 mg doses.

Patient-specific considerations

A common problem among T2DM patients is the issue of weight management. Elevated body weight or obesity, and an increased risk of cardiovascular-related complications often increase the medical burden and medication load of the patient.⁵⁵ The patient is often prescribed a medication regimen that is counterproductive to weight loss, which decreases treatment satisfaction due to resulting weight gain. Newer GLP-1 agonists, such as exenatide and liraglutide, are associated with weight reduction in healthy and diabetic subjects.⁴¹ A comparative trial of exenatide and liraglutide in T2DM subjects concluded that both exenatide and liraglutide were associated with a significant reduction in body weight when compared with baseline (−2.87 kg and −3.24 kg, respectively).⁴¹ In the LEAD-3 trial, weight loss was reported in both the 1.2 mg and 1.8 mg liraglutide monotherapy groups, with an average loss of −2 kg and −2.5 kg, respectively (P < 0.0001).⁴⁴ Reported weight loss occurred during the first 16 weeks, but was sustained throughout the remaining 36 weeks of treatment. After completion of a second 52-week open-label study period, weight reductions of −2.1 kg and −2.7 kg for both the 1.2 mg and 1.8 mg liraglutide study groups, respectively, were significant when compared with those receiving glimepiride (P < 0.0001).⁴⁴ In all LEAD studies completed, liraglutide 1.8 mg daily was associated with reported weight reductions of −0.2 kg to −3.24 kg over a period of at least 6 months.⁴¹^–⁴⁶ Of additional interest, an analysis of patients from LEAD-1 and LEAD-2 reported that weight reductions in patients receiving liraglutide were primarily due to reductions in fat mass rather than lean tissue mass.⁵⁶ Finally, a trial enrolling healthy, nondiabetic patients with a mean baseline BMI of 30–40kg/m² compared the weight effects of liraglutide at doses of 1.2, 1.8, 2.4, and 3 mg daily, versus orlistat 120 mg three times daily or placebo.⁵⁷ Weight loss in liraglutide subjects was −4.8 kg in the 1.2 mg group (P = 0.003), −5.5 kg in the 1.8 mg group (P < 0.0001), −6.3 kg in the 2.4 mg group (P < 0.0001), and −7.2 kg in the 3.0 mg group (P < 0.0001) when compared with baseline.

Quality of life was another indicator of treatment outcome that was evaluated in select clinical trials. Astrup et al found that mean physical function improved in the liraglutide 3.0 mg group by a score of 6.8 (P = 0.001) when compared with placebo, and by 6.0 when compared with the orlistat treatment group (P = 0.006).⁵⁷ Mean self-esteem also increased in the 3.0 mg daily group by a score of 9.6 when compared with placebo (P = 0.0001), and by 6.2 when compared with the orlistat treatment group (P = 0.04). Patient-reported outcomes were also investigated in the LEAD-3 trial. Compared with glimepiride, the liraglutide 1.8 mg cohort reported a mean decrease in BMI that was associated with improvements in both weight image and weight concern (P < 0.0001).⁴⁴ Decreases in weight concern were associated with increases in overall quality of life, general perception of their health (both P < 0.0001), and mental/emotional health (P = 0.002). Finally, in LEAD-6, subjects were assessed for treatment satisfaction using the Diabetes Treatment Satisfaction Questionnaire. ⁴¹ Overall treatment satisfaction was reported to be significantly higher in the liraglutide group when compared with the exenatide group (P = 0.0004).

Future studies regarding adherence and continued impact on patient quality of life would be of value to the clinical community, with the unique kinetic parameters of liraglutide, as well as its positive impact on weight, lending merit to liraglutide as a viable option for the treatment of T2DM.

Discussion

The pharmacokinetic profile of liraglutide is amenable to once-daily dosing, thus creating a potential advantage when compared with twice-daily exenatide. Drug regimen simplicity is an important clinical consideration, particularly in patients receiving multiple medications for the treatment of T2DM and related comorbidities. Patients often present with resistance to the initiation of an injectable agent, however the potential for weight loss with the incretin mimetics and incretin analogs can be a motivator for some patients. The most recent consensus algorithm released by the ADA and the European Association for the Study of Diabetes lists GLP-1 analogs as a treatment option for consideration as a Tier 2 agent, or “less well-validated therapy”, in T2DM patients.⁹ The consensus guideline recommends consideration of GLP-1 agonist therapy in selected clinical situations. One situation in which GLP-1 agonist therapy could be considered is if weight loss is a major consideration and the patient’s HbA_1c level is close to target (<8.0%).⁹ The guideline warns, however, that GLP-1 agonist therapy is not indicated for all patients and should be used with caution in those with a history of significant GI disease, such as a diagnosis of gastroparesis, due to a possible exacerbation of such conditions with incretin mimetic therapy.⁹ Because postprandial hyperglycemia affects HbA_1c to a greater degree than fasting hyperglycemia, the closer a patient is to their HbA_1c goal, GLP-1 agonists, such as liraglutide, provide a viable treatment option to target postprandial glucose excursions due to their glucose-dependent effects on insulin secretion.

Conclusion

Clinical trial data from large, controlled studies demonstrate the efficacy and safety of liraglutide in terms of HbA_1c reduction, beneficial effects on body weight, and a low risk for hypoglycemic events when used as monotherapy. Liraglutide is relatively well tolerated, with dose-dependent nausea, vomiting, and diarrhea being the most commonly reported adverse events observed in clinical trials. Clinical trial data in humans indicate that liraglutide may have a role in the treatment of T2DM patients as monotherapy early in the disease process, as well as in combination with metformin, glimepiride, and rosiglitazone in patients inadequately controlled on oral antidiabetic drugs. Comparative data with exenatide twice-daily indicate a potential therapeutic advantage for liraglutide in terms of ease of use, with similar improvements in HbA_1c and body weight seen when comparing these two agents. Data are currently not available comparing liraglutide with once-weekly exenatide currently under Phase III study, however. Questions do remain regarding the safety of this agent in terms of risk of pancreatitis and medullary thyroid carcinoma. While the risk of such events is assumed to be small, vigorous postmarketing surveillance and reporting is warranted to identify patients that may be at increased risk for experiencing such events.

Footnotes

Disclosure

The authors report no conflicts of interest in relation to the content or production of this article.

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PERMALINK

Pharmacology, efficacy and safety of liraglutide in the management of type 2 diabetes

Joshua J Neumiller

Travis E Sonnett

Lindy D Wood

Stephen M Setter

R Keith Campbell

Abstract

Introduction

Methods

Pharmacology

Pharmacokinetics

Clinical trials

Table 1.

Liraglutide versus rosiglitazone as add-on to baseline glimepiride

Liraglutide versus glimepiride as add-on to baseline metformin

Liraglutide versus glimepiride as monotherapy

Liraglutide as add-on to baseline metformin and rosiglitazone

Liraglutide versus glargine as add-on to baseline metformin and glimepiride

Liraglutide versus exenatide as add-on to baseline metformin and/or a sulfonylurea

Additional clinical endpoints

Safety and tolerability

Hypoglycemia

Table 2.

Gastrointestinal adverse events

Pulse rate

Pancreatitis

Anti-liraglutide antibodies

Additional safety considerations

Table 3.

Administration

Patient-specific considerations

Discussion

Conclusion

Footnotes

References

ACTIONS

PERMALINK

RESOURCES

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