Abstract
Purpose
Results are presented from 2 to 3 trials investigating oral octreotide capsules (OOC) as an alternative to injectable somatostatin receptor ligands (iSRLs) in the treatment of acromegaly.
Methods
CH-ACM-01 was an open-label trial (N = 155) and CHIASMA OPTIMAL was a double-blind placebo-controlled (DPC) trial (N = 56), both investigating OOC as maintenance therapy for patients with acromegaly who were biochemical responders receiving iSRLs.
Results
Baseline characteristics in both trials reflected those expected of patients with acromegaly responding to treatment and were similar between trials, despite differences in inclusion criteria. OOC demonstrated a consistent degree of biochemical response across trials, with 65% of patients in CH-ACM-01 maintaining response during the core period and 64% of patients in CHIASMA OPTIMAL at the end of the DPC. Mean insulin-like growth factor I (IGF-I) levels remained within inclusion criteria at the end of treatment in both trials. Of 110 patients entering the fixed-dose phase in CH-ACM-01, 80% maintained or improved acromegaly symptoms from baseline to the end of treatment. Over 85% of patients in both trials elected to continue into the extension phases. OOC were found to be well tolerated across both trials, and no dose-related adverse events were observed.
Conclusions
OOC demonstrated remarkably consistent results for biochemical response, durability of response, and preference to continue with oral treatment across these 2 complementary landmark phase 3 trials, despite differences in the design of each.
Trial registration NCT03252353 (August 2017), NCT01412424 (August 2011).
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Introduction
Acromegaly is characterized by excessive circulating levels of growth hormone (GH) and insulin-like growth factor I (IGF-I), usually resulting from a GH-secreting pituitary adenoma [1,2,3,4,5]. Treatment for acromegaly is aimed at normalizing GH and IGF-I levels, shrinking tumors, amelioration of symptoms, improving quality of life, and reducing mortality with as few side effects as possible [1, 6, 7]. Pituitary surgery is the primary therapy for most patients with acromegaly [1, 2]. For patients unwilling or unable to undergo surgery, or in patients with persistent or recurrent disease, medical therapy is indicated [2, 8, 9]. Medical therapy includes somatostatin receptor ligands (SRLs), GH receptor antagonists, and dopamine agonists in single or combination therapy [10, 11]. Long-acting injectable SRLs (iSRLs) are a cornerstone of medical treatment in acromegaly and have demonstrated efficacy in attenuating serum GH and IGF-I levels, reducing tumor size, and improving symptoms [12]. However, only 56% of patients expressed satisfaction with current injectable treatments in 1 study [13]. Patients receiving iSRLs through deep tissue injection often report injection site pain, nodules, bruising, inflammation, and scarring as well as anxiety, frustration, and loss of independence. Additionally, many patients report missing work in order to receive injections and worsening of symptoms toward the end of the dosing interval [5, 9]. The Acromegaly Treatment Satisfaction Questionnaire (Acro-TSQ) is a scale that was developed to provide a complete assessment of the disease and treatment burdens associated with acromegaly and for tracking the overall efficacy and unmet needs of new treatments for patients with acromegaly [9, 14]. In 1 analysis employing the Acro-TSQ, two-thirds of patients who were biochemically responding to iSRLs reported ongoing acromegaly symptoms, with > 80% experiencing those symptoms all the time [15]. Avoiding injections, potentially by substituting an oral formulation, was mentioned as a top preference for new acromegaly treatments among 85% of respondents [13].
To address the patient burden associated with iSRLs, an oral formulation of octreotide has been developed. Oral octreotide capsules (OOC) combine octreotide with proprietary excipients (Transient Permeability Enhancer®) to form an oily suspension of hydrophilic particles in a lipophilic medium [16, 17]. OOC are the first approved oral SRL for acromegaly in the United States and are indicated for long-term maintenance treatment in patients with acromegaly who have responded to and tolerated treatment with octreotide or lanreotide. Results of 2 complementary but distinct phase 3 multicenter trials examining the safety and efficacy of OOC have been reported. The first (CH-ACM-01) was an open-label, dose titration trial that included a large number of patients with acromegaly who were previously receiving iSRLs; the results from that trial have been reported previously [18]. The second trial, OOC-ACM-303 (CHIASMA OPTIMAL), was a randomized, double-blind, placebo-controlled (DPC) trial that served as the basis for US Food and Drug Administration approval of OOC as a long-term maintenance treatment in patients with acromegaly in whom prior treatment with SRLs has been shown to be effective and tolerated [19]. The objective of this report is to provide a more complete understanding of the safety and efficacy of OOC in patients with acromegaly, by comparing and contrasting the results obtained from the above trials with different designs.
Comparison of methods
Key differences in the 2 previously described protocols [18, 19] are summarized in Table 1. The CHIASMA OPTIMAL trial required a more stringent inclusion cutoff for IGF-I (≤ 1.0 × upper limit of normal [ULN]), and the CHIASMA OPTIMAL trial included a placebo arm. The CH-ACM-01 trial had an inclusion cutoff of IGF-I < 1.3 × ULN and was open label. Primary endpoints varied, with both reflecting the different levels of biochemical response for entry criteria, as measured by IGF-I levels, with CHIASMA OPTIMAL using an average of 2 visits compared to a single measurement for the CH-ACM-01. The timing of baseline IGF-I measurements related to last dose of iSRL varied between the 2 trials, with the baseline measurement taken within 4 weeks of the last SRL injection for CH-ACM-01, and the baseline measurements being taken between 4 and 8 weeks from the last injection based on the prior iSRL dosing interval for a given patient for CHIASMA OPTIMAL (Fig. 1; Table 1). The imputation methods also differed between the 2 trials; CH-ACM-01 used last observation carried forward (LOCF), and CHIASMA OPTIMAL trial used worst observation carried forward (WOCF), or nonresponse imputation in the analysis of the primary endpoint (i.e., any patient who did not complete the full 9 months of treatment was considered a treatment failure regardless of the reason). For assessment of acromegaly symptom-related data, the Acromegaly Index of Severity (AIS) was used for CH-ACM-01, while for CHIASMA OPTIMAL, new or worsening signs and/or symptoms of acromegaly were monitored via adverse event (AE) reporting of AEs of special interest (AESIs; such as headache, perspiration, joint pain, fatigue, and soft tissue swelling, increases in blood pressure, and increases or decreases in blood sugar).
Both trials had an optional extension phase. There were no dose restrictions for continuation into the 6-month extension period in CH-ACM-01. In CHIASMA OPTIMAL, patients could enter the open-label extension (OLE) if they completed 36 weeks on oral treatment (oral or placebo) or if they met the predefined withdrawal criteria (i.e., IGF-I ≥ 1.3 × ULN and exacerbation of acromegaly clinical signs or symptoms). Upon entering the OLE phase, the starting dose for all patients was 60 mg and was titrated based on IGF-I levels and/or signs and symptoms of acromegaly.
Results
A total of 235 individuals were screened for CH-ACM-01, of whom 80 (34%) failed screening and 155 were enrolled. For CHIASMA OPTIMAL, 119 individuals were screened; 63 (53%) failed screening and 56 of were enrolled into the trial, 28 of whom were randomized to OOC. Baseline characteristics are described in Table 2. The baseline disease characteristics of patients enrolled in both trials were very similar despite the difference in biochemical values due to varying inclusion criteria (IGF-I < 1.3 × ULN for the CH-ACM-01 trial and IGF-I ≤ 1.0 × ULN for CHIASMA OPTIMAL).
For both trials, > 80% of patients reported active acromegaly symptoms at baseline despite long-term treatment with iSRLs (injectable long-acting forms of either octreotide or lanreotide) [18, 19]. In CH-ACM-01, at baseline, 81% of patients reported ≥ 1 acromegaly symptom, 61% had ≥ 2, and 43% had ≥ 3 (Table 2). In the OOC group of CHIASMA OPTIMAL, at baseline, 82% of patients had ≥ 1 symptom, 64% had ≥ 2, and 36% had ≥ 3. For the placebo group, 86% had ≥ 1 symptom, 68% had ≥ 2, and 50% had ≥ 3 (Table 2).
Eligibility in the CH-ACM-01 trial was based on a screening visit prior to the baseline visit, and for CHIASMA OPTIMAL, baseline IGF-I values were derived as an average of the second screening value and the baseline visit. Of interest, some patients had lost biochemical response between screening and the baseline visit in both trials: 12% of patients in CH-ACM-01 and 11% of patients in CHIASMA OPTIMAL no longer had IGF-I levels below the screening cutoff, suggesting variability in IGF-I levels in patients with biochemically controlled acromegaly (Table 2).
Efficacy of OOC
Both trials demonstrated the effectiveness of OOC in all prespecified analyses. Using LOCF imputation, 65% of patients in the CH-ACM-01 trial maintained response during the core phase (response defined as IGF-I ≤ 1.3 × ULN), and 64% of patients in the OOC group of the CHIASMA OPTIMAL trial maintained response at the end of the DPC period (response defined as IGF-I ≤ 1.0 × ULN). Using the WOCF imputation, maintenance of response was 53 and 58% in the CH-ACM-01 and CHIASMA OPTIMAL trials, respectively (Table 3) [18, 19]. More than 85% (86 and 90% in the CH-ACM-01 and CHIASMA OPTIMAL trials, respectively) of the patients enrolled in the extension phases of each trial. Efficacy outcomes of the OOC treatment arms of CH-ACM-01 and CHIASMA OPTIMAL trials are summarized in Table 3. Efficacy outcome data for the CHIASMA OPTIMAL placebo group were reported previously [19].
Post hoc analysis using longitudinal IGF-I and GH measurements were used to provide a time-weighted average (TWA) that included all measurements for CH-ACM-01. TWA is an integrated measure of response over the entirety of the treatment period, which is more clinically relevant because fluctuations of IGF-I (± 30%) are common [20,21,22]. Single timepoint responder analyses have limited utility in quantifying durability of response [23, 24]. Of the patients who entered the fixed-dose period, 80% completed the core period and were responders using TWA, in comparison to 75% using endpoint analysis. Additionally, 95% of patients maintained response throughout the extension period using TWA analysis versus 85% using endpoint analysis.
Outcomes by prior injectable dose
In CH-ACM-01, patients previously treated with low-mid doses versus high doses (dosing; Table 2) of long-acting SRLs had a 71.6 and 55.6% response rate at the end of treatment, respectively, but a formal between-group comparison was not performed. In CHIASMA OPTIMAL, maintenance of response was observed in 66.7% (4/6) of patients previously receiving low doses of iSRLs and 54.5% (12/22) of patients on medium-high injected doses. The treatment effect in CHIASMA OPTIMAL was consistent irrespective of prior dose of iSRL (odds ratio, 5.4 in low dose; 5.9 in medium-high dose).
Responders during the core treatment period of CH-ACM-01 (n = 82) had final OOC doses of 40 mg (n = 48), 60 mg (n = 19), and 80 mg (n = 15). Breakdown by prior iSRL dose did not indicate a clear relationship with OOC dose in CH-ACM-01 (Fig. 2). This was not assessed in CHIASMA OPTIMAL because it is difficult to extrapolate dose correlations from CHIASMA OPTIMAL in the same manner as CH-ACM-01 owing to the limited sample size.
Acromegaly symptoms
80% of patients entering the fixed-dose phase improved or maintained acromegaly symptoms (36% maintained; 44% improved) at the end of the CH-ACM-01 trial. At the end of treatment, 80% of patients reported ≥ 1 acromegaly symptom, 56% had ≥ 2, and 38% had ≥ 3. Acromegaly symptoms were not an efficacy endpoint for the CHIASMA OPTIMAL trial; however, AESIs were observed more frequently in patients receiving placebo than those receiving OOC (92.9% vs. 53.6%), indicating the emergence of acromegaly signs and symptoms while off treatment. The most common AESIs observed were arthralgia, hyperhidrosis, fatigue, carpal tunnel syndrome, and headache.
Safety
Adverse events were consistent with the well-established AE profile of iSRLs (Table 4). In the CH-ACM-01 trial, commonly reported AEs included gastrointestinal (e.g., nausea, diarrhea, dyspepsia, abdominal pain/distension, flatulence, vomiting), neurological (e.g., headache, dizziness), and musculoskeletal events (e.g., arthralgia, back pain) [18]. In the CHIASMA OPTIMAL trial, treatment-emergent AEs with ≥ 5% incidence that were more common in the OOC group than in the placebo group were diarrhea, nausea, abdominal discomfort, vomiting, dyspepsia, blood glucose increase, sinusitis, osteoarthritis, cholelithiasis, urinary tract infection, large intestine polyp, and pain.
In both trials, the majority of events occurred within the first 3 months of treatment, with AEs decreasing over time. There were no dose-related AEs observed in the CH-ACM-01 trial. This assessment was not possible in CHIASMA OPTIMAL because of the small number of patients.
Discussion
The results of the CH-ACM-01 and CHIASMA OPTIMAL trials demonstrated consistent results in biochemical response, durability of response, and preference to continue treatment with OOC, with safety profiles that are similar to iSRLs [18, 19]. The effect of OOC was notably preserved in both open-label (CH-ACM-01) and double-blind, placebo-controlled (CHIASMA OPTIMAL) trial designs. Both phase 3 trials have yielded unique information related to OOC as a treatment for acromegaly and provide information useful for clinicians treating acromegaly. The CH-ACM-01 trial enrolled a larger cohort of 155 patients, but CHIASMA OPTIMAL’s inclusion of a placebo control provides valuable insight into events that may be disease rather than treatment related.
These complementary trials enrolled similar acromegaly populations despite differences in inclusion criteria and the known variability of IGF-I levels [21, 25, 26]. Mean IGF-I levels at the start of the core treatment phase suggest that the enrolled populations are comparable between the 2 trials—for example, the cohort is representative of acromegaly patients who were previously biochemically responding to iSRLs. Periodic fluctuations above the ULN are common on SRLs, and the small difference in inclusion criteria did not appear to alter the phenotype of the patient population across the trials. Screening failures were slightly higher in CHIASMA OPTIMAL (53%) compared to CH-ACM-01 (34%), likely due to the more conservative entry criteria of IGF-I ≤ 1.0 × ULN. The focus of the current report is comparison of active OOC treatment; thus, data from the placebo arm of CHIASMA OPTIMAL [19] have been only briefly touched upon.
Determination of the most effective dose of OOC as it relates to the prior iSRL dose was also assessed in these trials. Despite the higher rate of patients receiving mid/high iSRL doses in CHIASMA OPTIMAL and variations in dose escalation, maintenance of response was similar in the two trials. Post hoc analyses based on prior SRL dose were performed solely on patients completing the CH-ACM-01 trial as responders (n = 82). Of OOC responders previously on a high dose of iSRLs, 45% finished the core trial on the lowest tested dose of OOC (40 mg), and 69% on low-mid doses of OOC (40–60 mg). In the CHIASMA OPTIMAL trial, it is difficult to extrapolate dose correlations in the same manner due to the limited sample size. Further complicating analysis, the dose titration in CHIASMA OPTIMAL trial was driven by predefined criteria in the protocol for trial withdrawal requiring participants to have been on the maximum dose, 80 mg, for 2 consecutive visits with an IGF-I ≥ 1.3 × ULN. In this manner, the dose escalation observed in CH-ACM-01 is more representative of standard clinical practice. Wear-off timing of previous long-acting iSRLs may influence dosing of OOC, as the placebo arm of CHIASMA OPTIMAL demonstrated a median of 16 weeks of continued control after stopping SRL injections [19], suggesting that a carryover effect of long-acting iSRLs may potentially delay need for OOC dose adjustments. However, neither of these trials could provide a clear indication of OOC dose based on prior iSRL dose.
Several currently approved iSRL therapies for acromegaly report outcomes using selective analysis in completers or less rigorous methods for handling missing data [27]. The 2 trials presented here assessed OOC efficacy using rigorous and conservative approaches to account for missing data, including LOCF (CH-ACM-01) and WOCF (CHIASMA OPTIMAL) as primary endpoints. Nevertheless, both trials showed consistent and effective maintenance of biochemical response in patients with acromegaly. For CH-ACM-01, an additional post hoc TWA, which may provide a more accurate and clinically meaningful assessment, showed an even greater response as compared with end-of-treatment analysis in the fixed-dose population at the end of the extension phase [14]. Additionally, 80% of the patients entering the fixed-dose phase in CH-ACM-01 maintained or improved acromegaly symptoms from baseline to the end of treatment. This was observed despite the majority of patients demonstrating biochemical response at baseline from prior iSRLs. The reduction in symptoms at the end of the trial was possibly due to more frequent capsule dosing that could result in more consistent circulating octreotide levels, helping to reduce breakthrough symptoms that are seen with the longer dosing intervals used with iSRLs.
In both trials, the majority of patients who were fully or partially responding at baseline maintained response at the end of the trial. Importantly, a portion of patients in CH-ACM-01 who were not biochemically controlled at baseline demonstrated biochemical response by the end of the trial; the single patient in CHIASMA OPTIMAL who had an IGF-I > 1.0 × ULN at baseline, improved by the end of the trial. These data indicate that treatment with OOC can maintain biochemical control of acromegaly and may additionally help achieve control in patients who have elevated IGF-I levels while receiving iSRLs. Patients should be closely monitored to ensure long-term biochemical control, as results from these trials highlight the variability of IGF-I levels in patients with acromegaly. However, for optimal dosing and maintenance of response, it is important that patients take OOC with water ≥ 1 h before a meal or ≥ 2 h after a meal. Importantly, if biochemical control was lost while a participant was receiving OOC, reversion to their previous iSRL dose in CHIASMA OPTIMAL resulted in regain of control within 4 weeks, or 1 injection cycle [19]. Among the patients who completed the dose adjustment period of the 2 trials and were stabilized on a fixed dose of OOC, most achieved a durable response and entered the voluntary extension phase. Notably, patient-reported symptoms should be considered in dose titration decisions, as symptoms reported by health care providers and symptoms reported by patients are often not congruent, particularly in regards to frequency, severity, and pattern of symptoms [28].
OOC were found to be safe and well tolerated in both trials. The most common TEAEs were gastrointestinal, neurological, and musculoskeletal AEs, and were consistent with the known safety profile of iSRLs. Furthermore, no dose-related AEs were observed. In the CHIASMA OPTIMAL trial, approximately double the number of AESIs were observed in the placebo group, including higher rates of arthralgia, hyperhidrosis, fatigue, and peripheral swelling, mirroring the loss of biochemical control observed in these patients after withdrawal of active treatment.
Despite disease control achieved with current iSRL options, there remains an unmet need for patients with acromegaly receiving regular injections due to treatment inconvenience, injection-related pain, and complications [5, 9, 13, 28]. Many patients with acromegaly desire an alternative to injections, in the form of an oral treatment, to alleviate some of these burdens [13]. The oral octreotide formulation precludes all possibility of injection site reactions that are commonly encountered with existing iSRLs. OOC represents a safe and effective treatment option for many patients with acromegaly who require medical therapy, allowing patients who are currently responding to iSRL therapy to be safely transitioned to oral therapy if they desire, with the potential to decrease the burden and costs associated with injections.
Data availability
The datasets generated during and/or analyzed during the current trial are available from the corresponding author on reasonable request.
Change history
04 August 2021
A Correction to this paper has been published: https://doi.org/10.1007/s11102-021-01177-w
References
Katznelson L, Atkinson JL, Cook DM, Ezzat SZ, Hamrahian AH, Miller KK (2011) American Association of Clinical Endocrinologists medical guidelines for clinical practice for the diagnosis and treatment of acromegaly–2011 update. Endocr Pract 17:1–44. https://doi.org/10.4158/ep.17.s4.1
Katznelson L, Laws ER Jr, Melmed S, Molitch ME, Murad MH, Utz A, Wass JAH (2014) Acromegaly: an Endocrine Society clinical practice guideline. J Clin Endocrinol Metab 99:3933–3951. https://doi.org/10.1210/jc.2014-2700
Melmed S (2009) Acromegaly pathogenesis and treatment. J Clin Invest 119:3189–3202. https://doi.org/10.1172/jci39375
Melmed S (2020) Pituitary-tumor endocrinopathies. N Engl J Med 382:937–950. https://doi.org/10.1056/NEJMra1810772
Strasburger CJ, Karavitaki N, Störmann S, Trainer PJ, Kreitschmann-Andermahr I, Droste M, Korbonits M, Feldmann B, Zopf K, Sanderson VF, Schwicker D, Gelbaum D, Haviv A, Bidlingmaier M, Biermasz NR (2016) Patient-reported outcomes of parenteral somatostatin analogue injections in 195 patients with acromegaly. Eur J Endocrinol 174:355–362. https://doi.org/10.1530/eje-15-1042
Fleseriu M (2011) Clinical efficacy and safety results for dose escalation of somatostatin receptor ligands in patients with acromegaly: a literature review. Pituitary 14:184–193. https://doi.org/10.1007/s11102-010-0282-z
Gadelha MR, Kasuki L, Lim DST, Fleseriu M (2019) Systemic complications of acromegaly and the impact of the current treatment landscape: an update. Endocr Rev 40:268–332. https://doi.org/10.1210/er.2018-00115
Colao A, Grasso LFS, Giustina A, Melmed S, Chanson P, Pereira AM, Pivonello R (2019) Acromegaly Nat Rev Dis Primers 5:20. https://doi.org/10.1038/s41572-019-0071-6
Fleseriu M, Fogelfeld L, Gordon MB, Sisco J, Crosby RD, Ludlam WH, Haviv A, Mathias SD (2020) An evaluation of the Acromegaly Treatment Satisfaction Questionnaire (Acro-TSQ) in adult patients with acromegaly, including correlations with other patient-reported outcome measures: data from two large multicenter international studies. Pituitary 23:347–358. https://doi.org/10.1007/s11102-020-01038-y
Fleseriu M, Biller BMK, Freda PU, Gadelha MR, Giustina A, Katznelson L, Molitch ME, Samson SL, Strasburger CJ, van der Lely AJ, Melmed S (2021) A Pituitary Society update to acromegaly management guidelines. Pituitary 24:1–13
Lim DS, Fleseriu M (2017) The role of combination medical therapy in the treatment of acromegaly. Pituitary 20:136–148. https://doi.org/10.1007/s11102-016-0737-y
Carmichael JD, Bonert VS, Nuño M, Ly D, Melmed S (2014) Acromegaly clinical trial methodology impact on reported biochemical efficacy rates of somatostatin receptor ligand treatments: a meta-analysis. J Clin Endocrinol Metab 99:1825–1833. https://doi.org/10.1210/jc.2013-3757
Liu S, Adelman DT, Xu Y, Sisco J, Begelman SM, Webb SM, Badia X, Thethi TK, Fonseca V, Shi L (2018) Patient-centered assessment on disease burden, quality of life, and treatment satisfaction associated with acromegaly. J Investig Med 66:653–660. https://doi.org/10.1136/jim-2017-000570
Fleseriu M, Melmed S, Mangal B, Strasburger CJ, Biermasz NR (2016) Longitudinal assessment of response to treatment with oral octreotide capsules in patients with acromegaly: post-hoc analysis of a phase 3 trial. Endocrine Abstracts 41:GP151. https://doi.org/10.1530/endoabs.41.GP151
Fleseriu M, Molitch M, Dreval A, Biermasz NR, Gordon MB, Crosby RD, Ludlam WH, Haviv A, Gilgun-Sherki Y, Mathias SD (2021) Disease and treatment-related burden in patients with acromegaly who are biochemically controlled on injectable somatostatin receptor ligands. Front Endocrinol (Lausanne) 12:627711
Tuvia S, Atsmon J, Teichman SL, Katz S, Salama P, Pelled D, Landau I, Karmeli I, Bidlingmaier M, Strasburger CJ, Kleinberg DL, Melmed S, Mamluk R (2012) Oral octreotide absorption in human subjects: comparable pharmacokinetics to parenteral octreotide and effective growth hormone suppression. J Clin Endocrinol Metab 97:2362–2369. https://doi.org/10.1210/jc.2012-1179
Tuvia S, Pelled D, Marom K, Salama P, Levin-Arama M, Karmeli I, Idelson GH, Landau I, Mamluk R (2014) A novel suspension formulation enhances intestinal absorption of macromolecules via transient and reversible transport mechanisms. Pharm Res 31:2010–2021. https://doi.org/10.1007/s11095-014-1303-9
Melmed S, Popovic V, Bidlingmaier M, Mercado M, van der Lely AJ, Biermasz N, Bolanowski M, Coculescu M, Schopohl J, Racz K, Glaser B, Goth M, Greenman Y, Trainer P, Mezosi E, Shimon I, Giustina A, Korbonits M, Bronstein MD, Kleinberg D, Teichman S, Gliko-Kabir I, Mamluk R, Haviv A, Strasburger C (2015) Safety and efficacy of oral octreotide in acromegaly: results of a multicenter phase III trial. J Clin Endocrinol Metab 100:1699–1708. https://doi.org/10.1210/jc.2014-4113
Samson SL, Nachtigall LB, Fleseriu M, Gordon MB, Bolanowski M, Labadzhyan A, Ur E, Molitch M, Ludlam WH, Patou G, Haviv A, Biermasz N, Giustina A, Trainer PJ, Strasburger CJ, Kennedy L, Melmed S (2020) Maintenance of acromegaly control in patients switching from injectable somatostatin receptor ligands to oral octreotide. J Clin Endocrinol Metab 105:e3785–e3797. https://doi.org/10.1210/clinem/dgaa526
Erotokritou-Mulligan I, Eryl Bassett E, Cowan DA, Bartlett C, Milward P, Sartorio A, Sönksen PH, Holt RI (2010) The use of growth hormone (GH)-dependent markers in the detection of GH abuse in sport: physiological intra-individual variation of IGF-I, type 3 pro-collagen (P-III-P) and the GH-2000 detection score. Clin Endocrinol (Oxf) 72:520–526
Milani D, Carmichael JD, Welkowitz J, Ferris S, Reitz RE, Danoff A, Kleinberg DL (2004) Variability and reliability of single serum IGF-I measurements: impact on determining predictability of risk ratios in disease development. J Clin Endocrinol Metab 89:2271–2274. https://doi.org/10.1210/jc.2003-032150
Nguyen TV, Nelson AE, Howe CJ, Seibel MJ, Baxter RC, Handelsman DJ, Kazlauskas R, Ho KK (2008) Within-subject variability and analytic imprecision of insulinlike growth factor axis and collagen markers: Implications for clinical diagnosis and doping tests. Clin Chem 54:1268–1276
van Esdonk MJ, Burggraaf J, van der Graaf PH, Stevens J (2020) Model informed quantification of the feed-forward stimulation of growth hormone by growth hormone-releasing hormone. Br J Clin Pharmacol 86:1575–1584. https://doi.org/10.1111/bcp.14265
van Esdonk MJ, van Zutphen EJM, Roelfsema F, Pereira AM, van der Graaf PH, Biermasz NR, Stevens J, Burggraaf J (2018) How are growth hormone and insulin-like growth factor-1 reported as markers for drug effectiveness in clinical acromegaly research? A comprehensive methodologic review. Pituitary 21:310–322. https://doi.org/10.1007/s11102-018-0884-4
Rosario PW (2010) Normal values of serum IGF-1 in adults: results from a Brazilian population. Arquivos Brasileiros de Endocrinologia Metabologia 54:477–481
Skjaerbaek C, Frystyk J, Kaal A, Laursen T, Møller J, Weeke J, Jørgensen JO, Sandahl Christiansen J, Orskov H (2000) Circadian variation in serum free and total insulin-like growth factor (IGF)-I and IGF-II in untreated and treated acromegaly and growth hormone deficiency. Clin Endocrinol (Oxf) 52:25–33. https://doi.org/10.1046/j.1365-2265.2000.00876.x
Colao A, Bronstein MD, Freda P, Gu F, Shen CC, Gadelha M, Fleseriu M, van der Lely AJ, Farrall AJ, Hermosillo Reséndiz K, Ruffin M, Chen Y, Sheppard M (2014) Pasireotide versus octreotide in acromegaly: a head-to-head superiority study. J Clin Endocrinol Metab 99:791–799. https://doi.org/10.1210/jc.2013-2480
Geer EB, Sisco J, Adelman DT, Ludlam WH, Haviv A, Gelbaum D, Liu S, Mathias SD, Shi L (2020) Observed discordance between outcomes reported by acromegaly patients and their treating endocrinology medical provider. Pituitary 23:140–148. https://doi.org/10.1007/s11102-019-01013-2
Acknowledgements
The authors thank the trial coordinators, coinvestigators, patients, and families who participated in the trials. Medical writing assistance and revision of the manuscript under the direction of the authors was provided by PRECISIONscientia, which was supported by Chiasma, Inc.
Funding
The trial was funded by Chiasma, Inc. (Needham, MA).
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All authors have been personally and actively involved in substantial work leading to the paper and will take public responsibility for its content. The first draft of the manuscript was written by Artak Labadzhyan with editorial support, and all authors commented on previous versions of the manuscript. All authors read and approved the final manuscript.
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Conflict of interest
AL reports no conflicts of interest. LBN served as research support for Chiasma and received grant support from and served as a consultant for Ipsen. MF received a research grant to Oregon Health and Science University as principal investigator for Crinetics, Chiasma, Ionis, Novartis, Recordati and served as a scientific consultant for Crinetics, Chiasma, Ionis, Ipsen, Novartis, Pfizer, and Recordati. MBG received research support from Chiasma, Corcept, Crinetics, Ipsen, Novartis, Opico, Pfizer, Strongbridge, Teva, and Novo Nordisk and served as a scientific consultant for Chiasma and Novo Nordisk. MM received research grant to institution from Chiasma, Novartis, and Crinetics and received a consultation honorarium from Chiasma. LK served as a clinical trial principal investigator for Chiasma and Ionis and served as a consultant for Pfizer. SLS served as site principal investigator, steering chair, and consultant for Chiasma and Novartis. YG received funding in the form of a research grant from Pfizer and was compensated for serving as principal investigator of research grants to Tel Aviv-Sourasky Medical Center from Chiasma and Strongbridge Biopharma, and also received consultation fees from Tiburio and lecture fees from CTS. NB reports no conflicts of interest. MB received a research grant from Ispen and lecture fees from Ispen, Novartis, Pfizer, and Recordati, and also served as an advisory board member for Novartis, Pfizer, and Recordati. AH, WHL, GP are employees of Chiasma. CJS received consultancy fees and speaker honoraria from Chiasma, Pfizer, Ipsen, and Crinetics.
Ethical approval
This trial was performed in accordance with the principles stated in the Declaration of Helsinki. Prior to starting the trials, ethical approval was obtained for all protocols from the local Institutional Review Board or other appropriate ethics committee to confirm the trials meet national and international guidelines for research on humans.
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Labadzhyan, A., Nachtigall, L.B., Fleseriu, M. et al. Oral octreotide capsules for the treatment of acromegaly: comparison of 2 phase 3 trial results. Pituitary 24, 943–953 (2021). https://doi.org/10.1007/s11102-021-01163-2
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DOI: https://doi.org/10.1007/s11102-021-01163-2