Liraglutide vs insulin glargine and placebo in combination with metformin and sulfonylurea therapy in type 2 diabetes mellitus (LEAD-5 met+SU): a randomised controlled trial

This 26 week randomised, parallel-group, placebo-controlled study (with liraglutide placebo and open-label insulin glargine arms) was carried out in adult patients with type 2 diabetes.

The 581 randomised patients in this multicentre (107 sites), multinational (17 countries) trial were 18–80 years old, with type 2 diabetes treated with oral glucose-lowering drugs (OGLAs) (94–95% combination therapy) (Table 1) for at least 3 months before screening. General inclusion criteria included: HbA_1c level of 7.5–10% if on OGLA monotherapy or 7–10% if on OGLA combination therapy, and BMI ≤ 45kg/m². Patients were excluded if they: had used insulin within 3 months prior to the trial (except for short-term treatment for intercurrent illness); had impaired hepatic or renal function, clinically significant cardiovascular disease, proliferative retinopathy or maculopathy, hypertension (≥180/100 mmHg) or cancer; were pregnant; experienced recurrent hypoglycaemia or hypoglycaemia unawareness; were seropositive for hepatitis B antigen or hepatitis C antibody; or used any drugs except for OGLAs that could affect blood glucose levels. The trial was conducted in accordance with the Declaration of Helsinki and ICH Good Clinical Practice. Written informed consent was obtained from patients prior to commencement of the trial, and protocols and consent forms were approved by the local health authorities, the local independent ethics committees and institutional review boards (Electronic supplementary material [ESM]).

Randomisation (using a telephone or web-based randomisation system) followed a 6 week run-in period during which participants were placed on a standard combination therapy with metformin and glimepiride: forced metformin and glimepiride dose escalation over 3 weeks followed by a 3 week maintenance period. Participants already on 2 g metformin and sulfonylurea therapy could proceed directly to the maintenance regimen at the discretion of the investigator. During the dose-escalation period, doses of metformin and glimepiride were increased by up to 2 g/day and 4 mg/day, respectively.

Patients were randomised if they met the inclusion criteria, had received glimepiride (4 mg) and metformin (2 g) treatment for at least 3 weeks and had a fasting plasma glucose (FPG) between 7.5 and 12.8 mmol/l after the 6 week run-in. All patients were stratified at randomisation based on their previous therapy (OGLA monotherapy or combination therapy).

Patients were randomly allocated to three interventions (2:1:2) to receive: once-daily liraglutide (blinded); once-daily liraglutide placebo (blinded) or once-daily insulin glargine (open-labelled; sanofi-aventis, Paris, France), all in combination with metformin and glimepiride (open-labelled). Liraglutide and liraglutide placebo were supplied by Novo Nordisk A/S (Bagsvaerd, Denmark). Investigators, participants and study monitors were blinded to the treatment status of the liraglutide and placebo groups at all times.

The 1.8 mg liraglutide dose selected for this study was based on previously completed phase 2 dose-range-finding studies [9]. After randomisation, patients in the liraglutide group underwent a 2 week dose escalation, starting at 0.6 mg once daily with weekly increments of 0.6 mg, reaching a final daily dose of 1.8 mg by the end of the second week; daily placebo injections were matched for volume. After the 2 week dose-escalation period the liraglutide dose was fixed for 24 weeks. Trial medication was administered by subcutaneous injection in the abdomen, thigh or upper arm using a pre-filled pen device (with a NovoFine 30G disposable needle; Novo Nordisk). The injection could be administered at any time of the day. Participants were encouraged to inject liraglutide during the same overall time period on a day-to-day basis.

Reduction of glimepiride dose from 4 mg to 2 mg was allowed after randomisation if necessitated by adverse events (AEs) or hypoglycaemia.

As in similar previous studies [10, 11], insulin glargine (100 IU/ml injected once daily with OptiSet; sanofi-aventis) was titrated by patients following instruction by the investigator according to a specific and widely adopted dosing algorithm for insulin glargine based on fasting concentration of blood glucose (adapted from A Trial comparing Lantus Algorithms to achieve Normal blood glucose Targets in patients with Uncontrolled blood Sugar [AT-LANTUS]) [11]. The starting dose of insulin glargine was numerically equivalent to the highest FPG value in mmol/l over the previous 7 days (e.g. if the FPG measure was 10 mmol/l, the initial glargine dose would be 10 IU). This facilitated ease of initiation in this patient-driven titration. During the first 8 weeks of treatment, the dose was titrated twice weekly by the participant, based on self-measured FPG, aiming for a target value of FPG ≤ 5.5 mmol/l. After 8 weeks of treatment, the frequency of monitoring and titration was at the investigator’s discretion, but at minimum the insulin glargine dose was adjusted at the 12 and 18 week visits. The investigator reviewed the doses and these could be changed at his/her discretion. The injection could be administered at any time of the day, but the selected time of the day remained the same throughout the trial.

Participants eligible for randomisation were assigned to liraglutide, liraglutide placebo or insulin glargine in a 2:1:2 randomisation pattern. At screening, all participants were given a 6 digit participant number. At randomisation, eligible participants were allocated to one of the three treatment groups using a telephone- or web-based randomisation system. Participants were stratified by whether they were treated with monotherapy or combination therapy for their diabetes at screening. A block size of five was defined for both groups. The blinded electronic-sealed codes were accessible to the investigators, affiliate and international product safety personnel or any other relevant party who might have had a need for breaking the treatment code; for example, for safety or regulatory purposes. Break of the code was performed through the telephone- or web-based randomisation system via an emergency code-break call. Novo Nordisk trial personnel, international product safety personnel, and the investigator received a notification generated by the interactive voice response system/interactive web response system via an emergency code-break call.

The primary efficacy outcome measure was change in whole blood HbA_1c after 26 weeks of treatment. The secondary outcome measures included changes in bodyweight, waist circumference, FPG, eight point plasma glucose (PG) profiles, beta cell function (proinsulin to C-peptide ratio) and BP.

HbA_1c was measured (at baseline and at weeks 12, 18 and 26) using high-performance liquid chromatography according to an assay certified by the National Glycohemoglobin Standardization Program (NGSP). Self-measurement of PG from capillary samples was performed using a Medisense Precision Xtra/MediSense Optimum glucose meter (Abbott, Maidenhead, UK) that used test strips calibrated to plasma values. Insulin and C-peptide were measured in serum using a chemiluminescence immunoassay. Proinsulin was measured in serum using an enzyme-linked immunosorbent assay. Glucagon was measured by RIA in aprotinin-treated plasma.

Safety assessments included hypoglycaemic episodes based on symptoms and PG (<3.1 mmol/l). Episodes requiring third-party medical assistance were classified as major. Liraglutide antibodies were measured by radioprecipitation assay using ¹²⁵I-labelled liraglutide tracer and polyethylene glycol precipitation. Vital signs, ECG, calcitonin and biochemical and haematology measures were recorded. All AEs, either observed by the investigator or reported spontaneously by the participants, were recorded by the investigator. The participants were asked at each post-screening visit or contact with the site if they had had any AEs (including changes in concomitant illness or new illnesses) since the last evaluation. The participant was asked: ‘Have you experienced any problems since the last contact?’

The trial comprised a 2 week screening period followed by a 3 week dose-escalation period, a 3 week maintenance period and then a 26 week treatment period. The follow-up period was 1 week. In total the participants attended nine visits at the site and had two telephone contacts (week 1 and 4 post-randomisation) during the trial duration of a maximum of 36 weeks. At screening, the participants were assigned a unique participant number. Inclusion and exclusion criteria were reviewed prior to randomisation. The randomisation criteria were reviewed at the randomisation visit. At each visit, information was collected and/or procedures performed according to the protocol. Patients recorded information in diaries between the visits to be reviewed at each visit. Week 26 was the end-of-trial visit for completers, who also attended a follow-up visit (week 27). Participants with a confirmed FPG reading >13.3 mmol/l at week 8 or thereafter and no intercurrent treatable illness were withdrawn from the study.

The data were analysed for the intent-to-treat population, defined as patients who were exposed to at least one dose of trial product(s) after randomisation. For the primary endpoint, HbA_1c, the statistical analysis was also performed without the last observation carried forward on the per-protocol population (participants completing the study without significant protocol violations) (ESM Table 1). Each endpoint was analysed using an analysis of covariance (ANCOVA) model with treatment, pre-treatment and country as fixed effects and baseline as the covariate. Missing baseline values were not imputed; that is, participants without a baseline value were excluded from the primary analysis. Post-baseline missing values were replaced using last observation carried forward. Sample size calculations were based on predicted HbA_1c and bodyweight after 26 weeks of treatment.

The study was powered against the primary endpoint change in HbA_1c. The non-inferiority margin against glargine was set to 0.4% and the difference to detect superiority against placebo was set to 0.5%. In addition the study was powered to detect a 3% difference in weight. The combined power was greater than 85%.

For superiority and non-inferiority of liraglutide vs comparators, hierarchical tests were conducted. The primary endpoint was the change from baseline in HbA_1c after 26 weeks of treatment. A sequential testing procedure was employed to protect the overall type 1 error rate. First, superiority of liraglutide to that of placebo had to be declared, then non-inferiority against glargine was tested and, if declared, superiority was tested. Finally, a test for superiority of insulin glargine vs placebo was performed.

The proportion of participants achieving HbA_1c targets (American Diabetes Association [ADA] target: <7% [12]; American Association of Clinical Endocrinologists [AACE] target ≤6.5% [13]) was compared between treatments using a logistic regression model with treatment as fixed effect and baseline HbA_1c as a covariate. Hypoglycaemic episodes were analysed using a generalised linear model including treatment and country as fixed effects. Other safety data were compared by descriptive statistics. Values are expressed as means ± SD unless otherwise noted; significance was set at p < 0.05. For the primary analysis (non-inferiority/superiority) the level of significance was 2.5% (one-sided test) and 5% (two-sided test).