Introduction
Acromegaly is a rare disorder that, in the large majority of cases, is caused by hypersecretion of growth hormone (GH) from a benign somatotroph pituitary adenoma, which leads to elevated insulin-like growth factor 1 (IGF-1) secretion [
1‐
3]. Excessive GH and IGF-1 levels (>1 ng/mL and >age and sex-normalized IGF-1 levels above the upper limit of normal, respectively) are associated with multisystemic comorbidities, including congestive heart failure, sleep apnea, arthritis, impaired glucose tolerance, insulin resistance, and diabetes mellitus, as well as an elevated risk of mortality [
1,
2,
4]. Treatment that achieves and maintains biochemical control is associated with the improvement of some key comorbidities and leads to normalization of life expectancy [
1,
2,
5]. Additionally, sustained reductions in pituitary tumor volume and signs and symptoms of disease are important goals in the treatment of acromegaly [
1,
2]. Transsphenoidal surgery is the first-line treatment for acromegaly [
2,
3,
6]. Because approximately 75 % of GH-secreting tumors are macroadenomas that invade the cavernous sinus or extend into the suprasellar region [
7], most patients will not achieve complete remission from surgery alone and, therefore, will need pharmacological intervention [
2].
Somatostatin receptor types 2 and 5 (sst
2 and sst
5) are each expressed in approximately 90 % of GH-secreting pituitary adenomas and have been useful for tumor-targeted pharmacotherapy with first-generation somatostatin analogs [SSAs; octreotide long-acting release (LAR) and lanreotide Autogel (ATG)] [
8‐
13]. Pasireotide LAR is a second-generation, multireceptor-targeted SSA that is approved by the US Food and Drug Administration, the European Medicines Agency, and several South American countries for the treatment of patients with acromegaly who have had an inadequate response to surgery and/or for whom surgery is not an option [
14‐
17]. Compared with octreotide LAR and lanreotide ATG, which bind with highest affinity to sst
2, pasireotide has higher binding affinity for sst
5 [
14,
18,
19]. In a large, randomized, 12-month, Phase 3 trial (C2305 study) in medically naive patients with acromegaly, pasireotide LAR demonstrated superior biochemical control (composite end point of age-normalized IGF-1 and GH <2.5 ng/mL) in comparison with octreotide LAR (31.3 vs. 19.2 %;
P = 0.007) [
20]. Similar results were obtained in the 12-month crossover extension phase of the C2305 trial, in which 17.3 % (95 % confidence interval, 9.8–27.3) of patients with acromegaly who had not achieved biochemical control with octreotide LAR achieved biochemical control with pasireotide LAR [
21]. In a separate, large, randomized, 24-week, Phase 3 trial (C2402 study) in patients with inadequately controlled acromegaly, treatment with two different doses of pasireotide LAR resulted in significantly higher rates of biochemical control than did continued treatment with either octreotide LAR or lanreotide ATG (15 % of patients treated with pasireotide LAR 40 mg and 20 % of those treated with pasireotide LAR 60 mg vs. 0 % of those continuing treatment with octreotide LAR or lanreotide ATG;
P = 0.0006 for pasireotide LAR 40 mg group,
P < 0.0001 for pasireotide LAR 60 mg group) [
22].
In both of these large Phase 3 trials, treatment with pasireotide LAR was associated with higher rates of hyperglycemia-related adverse events (AEs) than were other SSAs [
20,
22]. In the C2305 trial, the rate of hyperglycemia-related AEs was 57.3 % in patients treated with pasireotide LAR and 21.7 % in patients treated with octreotide LAR [
20]. Grade 3/4 hyperglycemia-related AEs were reported in 9.0 % of patients treated with pasireotide LAR and in 1.7 % of those treated with octreotide LAR. AEs related to elevations in blood glucose were the most common causes of discontinuation in the pasireotide LAR group. In the C2402 trial, hyperglycemia-related AEs were reported in 67 % of patients treated with pasireotide LAR 40 mg, in 61 % of those treated with pasireotide LAR 60 mg, and in 30 % of those who continued treatment with active control [
22]. In those patients with normal glycemic levels at baseline, 30 % of patients treated with pasireotide LAR 40 mg developed hyperglycemia compared with 48 % of patients treated with pasireotide LAR 60 mg and 15 % of patients treated with the active control [
23]. In contrast, in patients with hyperglycemia at baseline, 52 % maintained elevated glycemic levels after 24 months of treatment with pasireotide LAR 40 mg, compared with 71 % of patients treated with pasireotide LAR 60 mg and 42 % of patients treated with the active control. Here we present safety data from an expanded-treatment protocol that evaluated pasireotide LAR in a clinical practice-based setting, with a focus on the reported incidence of hyperglycemia-related AEs.
Materials and methods
Patients
Patients were eligible for inclusion in the study if they met the following inclusion criteria: age ≥18 years; confirmed diagnosis of acromegaly that was caused by a GH-producing pituitary tumor, with circulating age and sex-adjusted IGF-1 levels >1.3 × the upper limit of normal and random GH concentrations >1 µg/mL within 30 days of screening; not controlled by, not eligible for, or refused pituitary surgery; and had Karnofsky performance status scores of >60. A washout period of ≥8 weeks (days −63 to 0) was required before the screening assessment for patients who were receiving medical therapy for acromegaly.
Key exclusion criteria included concomitant treatment with SSAs, GH-receptor antagonists, or dopamine agonists, unless concomitant treatment was discontinued and the washout period was completed before the screening assessment; compression of the optic chiasm that caused any visual field defect for which surgical intervention was indicated; signs or symptoms of tumor compression for which surgical intervention was required; major surgery/surgical therapy of any type within 4 weeks of screening; radiotherapy of the pituitary gland within 4 weeks before screening or failure to recover from side effects of radiotherapy; history of hypothyroidism that was inadequately treated with thyroid hormone replacement therapy; or diabetes with poorly controlled blood glucose, as evidenced by glycated hemoglobin (HbA1c) >8 % at screening.
Study design
ACCESS was designed as an open-label, uncontrolled, single-arm, multicenter, expanded-treatment protocol to provide access to pasireotide LAR to patients with acromegaly for whom medical therapy was appropriate pending regulatory approval. After a screening period, which may have included a 4–8-week washout period for patients previously treated with medical therapy, eligible patients were administered pasireotide LAR 40 mg intramuscularly starting at visit 2 (baseline/week 0) every 28 days (±2 days) until either a discontinuation occurred or pasireotide LAR became both commercially available and reimbursable. Patients were to be transitioned to commercial pasireotide LAR as quickly as possible (not exceeding 6 months after commercial availability) and to have end-of-treatment evaluations on the day of the final dose of the study. For patients who discontinued treatment, follow-up evaluations were performed 28 days after the last administration of study drug.
At the study investigator’s discretion, the dose of pasireotide LAR could be increased to 60 mg for patients with age and sex-adjusted IGF-1 levels greater than the upper limit of normal after the third injection of pasireotide LAR 40 mg. Stepwise dose reductions from 60 to 40 mg and from 40 to 20 mg were permitted for tolerability (e.g., grade ≥ 3 AE or laboratory change directly attributable to pasireotide LAR).
The study was conducted in accordance with the ethical principles of the Declaration of Helsinki and implemented and reported in accordance with the International Conference on Harmonisation Harmonised Tripartite Guideline for Good Clinical Practice. The study protocol and informed consent forms were approved by the institutional review board, independent ethics committee, and/or research ethics board of each study site. All patients provided written informed consent to participate in the trial (ClinicalTrials.gov identifier: NCT01995734).
Outcomes
The primary objective was to document the safety of pasireotide LAR in patients with acromegaly by determining the proportion of patients with treatment-emergent grade ≥3 or serious AEs. Efficacy data were not collected centrally for this study. Secondary end points included the incidence of AEs; abnormalities in laboratory, vital signs, or electrocardiographic (ECG) results; and changes from baseline in laboratory values, ECG results, and vital signs. Investigators were responsible for evaluating IGF-1 and GH every 3 months to determine whether dose modifications were needed; however, the data were not collected by the sponsor.
Treatment assessments
The severity of AEs was described as mild (grade 1), moderate (grade 2), severe (grade 3), or life-threatening (grade 4) according to the Common Terminology Criteria for Adverse Events (CTCAE) [
24]. The CTCAE is a set of criteria used for the standardized grading of AEs. Notably, hyperglycemia is defined and graded by the CTCAE according to fasting plasma glucose (FPG) level as follows: grade 1, greater than the upper limit of normal to 160 mg/dL; grade 2, >160–250 mg/dL; grade 3, >250–500 mg/dL; and grade 4, >500 mg/dL. Serious AEs included those that were fatal or life-threatening; resulted in persistent or significant disability; were associated with a congenital anomaly or birth defect; jeopardized the patient; or may have required medical or surgical intervention, required inpatient hospitalization, or prolonged an existing hospitalization. Laboratory values were regularly monitored, including hematologic and blood chemistry parameters (including FPG), liver function parameters, coagulation parameters, HbA
1c, free thyroxine, thyroid-stimulating hormone, serum cortisol, plasma adrenocorticotropic hormone, and urinary parameters. A standard 12-lead ECG was performed for each patient at screening, at baseline (before and 30 min after the first injection), 21 days after each injection for the first 3 months, and every 3 months thereafter during the study. Gallbladder ultrasonography was performed at baseline, at month 6, and at the end of treatment.
Statistical analyses
Demographic and other baseline data (including disease characteristics) were summarized for the complete cohort, which included all patients who received ≥1 dose of pasireotide LAR. All safety analyses were based on data from patients who received ≥1 dose of pasireotide LAR and had ≥1 postbaseline safety assessment. No sample size calculation was performed. Primary safety data were analyzed with descriptive statistics. Categorical data are represented as frequencies and percentages. For continuous data, means, standard deviations (SDs), medians, minimums, and maximums were estimated.
Discussion
Phase 3 studies evaluating the efficacy and safety of pasireotide LAR in patients with acromegaly have demonstrated higher rates of hyperglycemia-related AEs in patients treated with pasireotide LAR than in patients treated with octreotide LAR or lanreotide ATG [
20,
22]. The ACCESS study was designed as an expanded-treatment protocol that would permit assessment of the safety of pasireotide LAR in patients with acromegaly within a practice-based setting before the drug became commercially available. The mean duration of treatment was 37.6 weeks, with a mean of 9.8 injections of pasireotide LAR. Our analysis demonstrated a low rate of grade ≥3 or serious treatment-emergent AEs (the primary end point of the study), which occurred in 25.0 % of patients, and only 11.4 % of patients discontinued treatment because of AEs, but 45.5 % experienced hyperglycemia-related AEs. A total of four patients (9.1 %) discontinued treatment with pasireotide LAR because of hyperglycemia-related AEs. Among patients who were treated with antidiabetic therapy, most (66.7 %) initiated only first-line antidiabetic medications (e.g., metformin, sitagliptin). These results suggest that hyperglycemia-related AEs associated with pasireotide LAR may be manageable with standard antidiabetic medication. Of note, <50 % of patients initiated antidiabetic therapy after starting treatment with pasireotide LAR.
In the patients treated with pasireotide LAR for at least 3 months (
n = 42), elevations in HbA
1c and FPG to diabetic levels (HbA
1c >6.4 %, FPG >99 mg/dL) were observed in 40 % (
n = 17) and 93 % (
n = 39) of patients, respectively, which is consistent with previous findings [
20,
22]. Similarly, in patients who completed ≥15 months of the study (
n = 10), diabetic HbA
1c levels (>6.4 %) were reported in 40 % (
n = 4). Most patients treated with pasireotide LAR, regardless of glucose tolerance at baseline, experience elevated glucose levels within the first 2 to 3 months [
14], which typically stabilize thereafter [
26]. Therefore, since the majority of patients in the ACCESS study (98 %) received ≥3 doses of pasireotide LAR, the study observation period was likely long enough to allow for appropriate treatment decisions for the management of hyperglycemia related to pasireotide LAR.
Treatment-emergent elevated glucose levels, hyperglycemia, and type 2 diabetes were reported in 23 (
n = 10), 23 (
n = 10), and 14 % (
n = 6) of patients, respectively. However, it should be noted that there is no technical difference between these categories of AEs, except that they are reported differently depending on whether the AE was detected as a change in a laboratory value or was reported by the clinician. To avoid any possibility of inaccurate reporting of the data, the results herein are described exactly as they were recorded in the study (i.e., a distinction was made between “elevated glucose levels” and “hyperglycemia”), similar to the published report of the C2402 study data [
22].
The optimal management of hyperglycemia associated with pasireotide LAR in patients with acromegaly is currently being investigated [
27,
28]. Of the patients in the ACCESS trial who initiated a new antidiabetic medication, metformin, insulin, glimepiride, and sitagliptin were the drugs most commonly administered. A mechanistic study in healthy volunteers showed that hyperglycemia associated with pasireotide subcutaneous (SC) is associated with decreases in insulin secretion but little change in insulin sensitivity [
29]. These findings are consistent with the data presented here, which show a reduction in fasting insulin levels after initiation of pasireotide LAR. In another study of healthy volunteers, treatment with the biguanide metformin was shown to have minimal effects on hyperglycemia associated with pasireotide SC exposure after an oral-glucose-tolerance test, whereas the dipeptidyl peptidase-4 inhibitor vildagliptin and the glucagon-like peptide-1 receptor agonist liraglutide were the most effective at restoring glucose to normal levels [
30]. However, a reduction in insulin sensitivity is associated with uncontrolled acromegaly [
31]; therefore, it has been suggested that initiating antidiabetic medications that improve insulin sensitivity, such as metformin, may also be an effective strategy for managing pasireotide LAR-associated hyperglycemia in patients with acromegaly [
32]. A post hoc analysis of patients enrolled in the C2305 trial showed that mean HbA
1c levels after 12 months of treatment with pasireotide LAR were 6.6, 6.7 and 7.2 % in patients whose hyperglycemia was managed with metformin alone, metformin plus other oral antidiabetic medications, and insulin with or without other oral antidiabetic, respectively [
27]. These data suggest that metformin may be an effective component in pharmacological control of hyperglycemia associated with pasireotide LAR in selected patients.
This analysis of the ACCESS study provides the first assessment of the safety of pasireotide LAR in a practice-based clinical setting and reflects actual management patterns in a broader population of patients with acromegaly. Limitations of this analysis include an overall small number of patients enrolled in ACCESS who had long durations of time in the trial because of late enrollment in the study, and the lack of specific information regarding doses of concomitant antidiabetic medications.
ACCESS was designed as a safety study, and efficacy data were not recorded as part of the trial design; therefore, correlations between safety and treatment outcomes could not be evaluated. However, previous Phase 3 studies have investigated the efficacy of pasireotide LAR [
20,
22]. The study of 358 medically naive patients with acromegaly demonstrated that pasireotide LAR provided biochemical control superior to that of octreotide LAR [
20]. Subsequently, a study of 198 patients with inadequately controlled acromegaly showed that treatment with pasireotide LAR resulted in significantly higher rates of biochemical control than did continued treatment with other SSAs [
22]. Although efficacy data support the use of pasireotide LAR in the treatment of acromegaly, particularly for patients who fail multimodal treatment, the adverse effects of pasireotide LAR on glycemic levels need to be taken into account when choosing a treatment strategy [
33]. The results reported here provide evidence to support the manageable safety profile of pasireotide LAR in patients with acromegaly, which is critical to assessing the overall clinical benefit of treatment with pasireotide LAR.
Acknowledgments
We would like the thank Ghulam Warsi for assistance with the study. Support for this study was provided by Novartis Pharmaceuticals Corporation. Medical editorial assistance was provided by MedThink SciCom (Raleigh, NC) and was sponsored by Novartis Pharmaceuticals Corporation.