Efficacy and safety of oral palonosetron compared with IV palonosetron administered with dexamethasone for the prevention of chemotherapy-induced nausea and vomiting (CINV) in patients with solid tumors receiving cisplatin-based highly emetogenic chemotherapy (HEC).

PURPOSE: This study aims to compare the efficacy and safety of oral palonosetron with intravenous (IV) palonosetron for the prevention of cisplatin-related chemotherapy-induced nausea and vomiting (CINV).
METHODS: A multinational, randomized, double-blind study enrolling adult chemotherapy-naive patients with malignant solid tumors scheduled to receive cisplatin-based highly emetogenic chemotherapy (HEC). Patients received oral palonosetron (0.50 mg) or IV palonosetron (0.25 mg), each with oral dexamethasone. The primary objective was to demonstrate non-inferiority in terms of patients with a complete response (CR, no emesis/no rescue medication) within the acute phase (0-24 h after chemotherapy administration).
RESULTS: Of the 743 patients randomized, 739 received study medications and 738 were included in the full analysis set. The CR rate in the acute phase was high for both groups (oral 89.4 %; IV 86.2 %). As this difference in proportions (stratum-adjusted Cochran-Mantel-Haenszel method) was 3.21 % (99 % confidence interval (CI) -2.74 to 9.17 %), non-inferiority was demonstrated (since the lower limit of the 99 % CI was closer to zero than the predefined margin of 15 %). Treatment-emergent adverse events (TEAEs) related to the study drug were rare (oral 3.2 %; IV 6.5 %). No TEAEs related to study drug leading to discontinuation were reported.
CONCLUSION: Non-inferiority of oral versus IV palonosetron was demonstrated. The CR rate in the acute phase was >86 % in both patient groups. The safety profiles were comparable.

RCT Entities:   Population Interventions Outcomes

Introduction

Cisplatin-based chemotherapy regimens are a cornerstone of curative cancer treatment for non-seminomatous germ cell tumors and a standard treatment for most advanced lung and some gastrointestinal cancers; however, chemotherapy-induced nausea and vomiting (CINV) is a major side effect [1, 2]. Currently, neurokinin 1 (NK1) and 5-hydroxytryptamine 3 (5-HT3) receptor antagonists (RAs), used in combination with steroids such as dexamethasone, are recommended to control CINV related to cisplatin-based highly emetogenic chemotherapy (HEC) [3].

Palonosetron (Aloxi®, Oncit®, Paloxi®) is a potent and selective second-generation 5-HT3 RA which has demonstrated efficacy in the management of CINV when administered both intravenously (IV) and orally [4]. Its prolonged duration of action offers significant advantages over the other 5-HT3 RAs for the prevention of CINV in patients with cancer receiving both moderately and HEC regimens [5-9]. Palonosetron has also been shown to be effective in managing CINV associated with a variety of chemotherapeutic agents across a range of indications [10-19].

Clinical studies of CINV prevention with oral and IV palonosetron doses ranging from 0.1 to 90 μg/kg have been performed. The clinical development of IV palonosetron for the prevention of CINV comprised three efficacy studies, two in moderately emetogenic CINV [20, 21] and one in highly emetogenic CINV [22], which evaluated the efficacy and safety of two palonosetron doses, 0.25 and 0.75 mg, against doses of approved comparators (ondansetron and dolasetron). The studies reported that 0.25 mg IV palonosetron was the most effective for the prevention of both moderately and highly emetogenic CINV over the study period (0–120 h).

The safety and efficacy of oral palonosetron was based on the results of a double-blind, randomized study, which evaluated the efficacy of single oral doses of 0.25, 0.50, and 0.75 mg palonosetron, versus 0.25 mg IV palonosetron, with/without the concomitant administration of dexamethasone, for the prevention of moderately emetogenic CINV. The study reported that 0.50 mg was the lowest effective oral dose of palonosetron for the prevention of moderately emetogenic CINV [4].

In this multicenter, randomized, double-blind study, we investigated the efficacy and safety of 0.50 mg oral palonosetron, compared with 0.25 mg IV palonosetron, for the prevention of CINV induced by cisplatin-based HEC in patients with malignant solid tumors.

The objective of this study was to demonstrate the efficacy of 0.50 mg oral palonosetron for the prevention of highly emetogenic CINV. Evidence of efficacy would confirm the contribution of the 0.50 mg oral palonosetron component to a netupitant/palonosetron fixed-dose combination product, developed for the prevention of nausea and vomiting induced by HEC, and the suitability of 0.50 mg oral palonosetron as an active comparator in other CINV clinical studies conducted with fixed-dose combination products.

Patients and methods

Study design

This was a phase III, multicenter (60 centers), multinational, randomized, double-blind, double-dummy, parallel group-stratified study to assess the efficacy and safety of 0.50 mg oral palonosetron in comparison with 0.25 mg IV palonosetron in patients with solid tumors receiving cisplatin-based HEC (EudraCT number: 2010-022223-29). The stratification criteria were gender (male and female) and region (USA, Latin America, Europe, Asia, and the Commonwealth of Independent States).

The trial protocol and documentation were reviewed and approved by the relevant institutional review boards, ethics committees, and health authorities. The trial was conducted in accordance with the International Conference on Harmonization Guidelines for Good Clinical Practice and applicable local regulations as well as the Declaration of Helsinki (1964, amended in 1975, 1983, 1989, 1996, and 2000). All patients provided written informed consent.

Inclusion criteria

Chemotherapy-naive male and female patients receiving a cisplatin-based HEC regimen, aged ≥18 years with histologically or cytologically confirmed malignant solid tumors and an Eastern Cooperative Oncology Group (ECOG) performance status of 0–2, were enrolled in this study. Additional inclusion criteria included adequate hepatic, renal, and hematological function.

Exclusion criteria

Patients could not receive moderately or HEC from days 2–5 following cisplatin administration, radiation therapy to the abdomen or the pelvis within 1 week prior to day 1 or between days 1 and 5, and any medication with known or potential antiemetic efficacy within 24 h prior to day 1. Additional exclusion criteria included symptomatic primary or metastatic CNS malignancy and grade ≥1 vomiting, retching, and mild nausea (as defined by the National Cancer Institute) within 24 h prior to day 1.

Patient treatment

All patients were scheduled to receive their first course of cisplatin-based cytotoxic chemotherapy administered as a single IV dose of ≥70 mg/m2 over 1–4 h on day 1, alone or in combination with other chemotherapeutic agents.

Patients were randomized to one of the following treatment groups: oral palonosetron 0.50 mg or IV palonosetron 0.25 mg. Both groups received oral dexamethasone 20 mg on day 1, followed by dexamethasone (8 mg) twice daily (bid) on days 2–4.

The use of rescue medication for the treatment of nausea/vomiting was allowed after the start of the chemotherapy administration; however, this was considered as a treatment failure. Metoclopramide tablets were provided, and the investigator was authorized to use an alternative rescue treatment at their discretion. However, the use of 5-HT3 RAs was discouraged and the use of palonosetron was not permitted.

Endpoints

The primary study objective was to demonstrate the non-inferiority of single-dose oral palonosetron 0.50 mg versus single-dose IV palonosetron 0.25 mg. The primary efficacy endpoint was the proportion of patients with a complete response (CR, defined as no emesis and no rescue medication) within 24 h (acute phase) of the start of HEC administration on day 1.

Secondary study objectives were to assess the efficacy of single-dose 0.50 mg oral palonosetron versus single-dose 0.25 mg IV palonosetron during the delayed and overall phases and to evaluate the safety and tolerability of 0.50 mg oral palonosetron versus IV palonosetron in preventing CINV. Secondary efficacy endpoints included the CR rate for the delayed (25–120 h) and overall (0–120 h) phases, the severity of nausea, the percentage of patients with complete protection (CP, defined as no vomiting, no rescue therapy, and no nausea), the percentage of patients without emesis, and the percentage of patients without rescue medication for the delayed and overall phases. Time to treatment failure (TTF), defined as the time to the first emetic episode or the administration of rescue medication, was also investigated. The impact of palonosetron on QoL using the modified Functional Living Index-Emesis (FLIE) questionnaire was also investigated [23]. Time-related efficacy assessments commenced at the time of cisplatin administration (time zero). Efficacy parameters were evaluated in the acute, delayed, and overall phases. Safety assessments included physical examination, vital signs, 12-lead electrocardiogram (ECG), laboratory analysis (hematology, blood chemistry, urinalysis), and adverse events (AEs).

AEs were coded using the Medical Dictionary for Regulatory Activities (MedDRA), version 14.0. The incidence of treatment-emergent adverse events (TEAEs) in each treatment group was assessed. Clinical laboratory data were summarized using frequency tables for values within/outside reference ranges, and shift tables were used to evaluate changes in clinical laboratory data versus baseline.

Statistical analysis

The full analysis set (FAS) comprised all patients who were randomized to treatment and received at least one chemotherapy regimen and the study medication. The FAS was used to analyze patient demographic and baseline characteristics and primary and secondary efficacy endpoints. The per-protocol (PP) population comprised all patients included in the FAS who completed the 0–24-h study period with no major protocol violations, i.e., those affecting the primary efficacy endpoint. The PP population was also used for demographic and other baseline characteristics and primary efficacy analysis. The safety population was used for all safety analyses and comprised all patients who received at least one dose of study medication and had at least one safety assessment after treatment administration.

For non-inferiority testing, calculations were based on the two-sided stratum-adjusted Cochran-Mantel-Haenszel (CMH) method for the proportion of patients with CR in the acute phase. The model included gender and region as strata. The non-inferiority of oral palonosetron would be established if the lower limit of the two-sided 99 % confidence intervals (CIs) for the difference between oral palonosetron and IV palonosetron was greater (i.e., closer to zero) than the prespecified non-inferiority margin, which was set at −15 %. For a two-sided test of difference using a type I error of 0.010, a sample size of 322 evaluable patients per treatment group was required to ensure 90 % power (nQuery Advisor, version 6.0, module PTEO1). This was revised up to 370 per treatment group in order to ensure an adequate number of evaluable patients.

For the secondary efficacy endpoints, no test for non-inferiority was performed. The comparison between treatments was performed using a CMH test including gender and region as factors. The results are presented using odds ratios (ORs), two-sided 95 % CIs for the ORs, and p values.

Results

Baseline characteristics

Between 21 June 2011 and 14 November 2012, a total of 743 patients were enrolled and randomized as 1:1 to receive oral and IV palonosetron. Of these, 739 (99.5 %) received study medications and were included in the safety population and 738 were included in the FAS. Of the 743 randomized patients, 33 (4.4 %) discontinued the study after randomization. The main reasons for discontinuation were death which was reported in 6 (1.6 %) patients in the oral palonosetron group and 11 (3.0 %) patients in the IV palonosetron group; withdrawal of consent in 2 (0.5 %) and 3 (0.8 %) patients, respectively; and loss to follow-up in 1 (0.3 %) and 3 (0.8 %) patients, respectively. Deaths observed during the study were generally due to the patient’s underlying cancer and disease progression. No deaths were considered to be due to palonosetron. In total, 710 (95.6 %) patients completed the study.

The majority of patients in the safety population were male (59.3 %) and white (86.7 %) with a mean age of 57.9 years. Overall, nearly half (46.5 %) of all the patients had lung/respiratory tract cancer. Patient baseline characteristics were generally comparable in both treatment arms and are summarized in Table 1.

Table 1

Patient baseline and disease characteristics (safety population)

	Oral palonosetron (n = 370)	IV palonosetron (n = 369)	Overall (n = 739)
Gender, n (%)
Male	219 (59.2)	217 (58.8)	436 (59.0)
Female	151 (40.8)	152 (41.2)	303 (41.0)
Ethnic origin, n (%)
White	321 (86.8)	320 (86.7)	641 (86.7)
Black	0	0	0
Asian	49 (13.2)	47 (12.7)	96 (13.0)
Hispanic	0	1 (0.3)	1 (0.1)
Other	0	1 (0.3)	1 (0.1)
Agea (years)
Mean (SD)	58.0 (9.41)	57.7 (9.92)	57.9 (9.66)
Primary cancer location, n (%)
Gastric	25 (6.8)	24 (6.5)	49 (6.6)
Head and neck	62 (16.8)	71 (19.2)	133 (18.0)
Lung/respiratory tract	174 (47.0)	170 (46.1)	344 (46.5)
Ovarian	15 (4.1)	18 (4.9)	33 (4.5)
Bladder	8 (2.2)	3 (0.8)	11 (1.5)
Other	86 (23.2)	83 (22.5)	169 (22.9)
Time since diagnosis (days)
n	370	368	738
Mean (SD)	92.7 (265.54)	66.8 (179.00)	79.8 (226.78)
Tumor extent at study entry, n (%)
Primary disease	184 (49.7)	193 (52.3)	377 (51.0)
Metastatic disease	176 (47.6)	161 (43.6)	337 (45.6)
Local recurrence	10 (2.7)	15 (4.1)	25 (3.4)

IV intravenous, SD standard deviation

aAt randomization

Efficacy

The percentage of patients (FAS) with a CR in the acute phase was 89.4 % in the oral palonosetron group and 86.2 % in the IV palonosetron group (Fig. 1). The difference in the proportions of responders (stratum-adjusted CMH method) in the FAS was 3.21 % (99 % CI −2.74 to 9.17 %) (Table 2). The non-inferiority of oral palonosetron versus IV palonosetron was demonstrated since the lower limit of the two-sided 99 % CI for the difference in proportions was greater than the predefined non-inferiority margin set at −15 %. Consistent results were obtained in the PP population with a difference in proportions between the oral and IV palonosetron groups of 3.77 % (99 % CI −3.22 to 10.76 %). The CR rates were also similar in both the delayed (76.2 vs 74.8 % for oral and IV palonosetron; OR 1.09, 95 % CI 0.77–1.5, p = 0.637) and overall (73.7 vs 70.2 % for oral and IV palonosetron; OR 1.20, 95 % CI 0.87–1.67, p = 0.269) phases (Fig. 1).

Fig. 1

Complete response rates during the acute, delayed, and overall phases (full analysis set)

Table 2

Summary of complete response in the acute, delayed, and overall phases (full analysis set)

	Oral palonosetron (n = 369)	IV palonosetron (n = 369)
Acute phase
Response, n (%)	330 (89.4)	318 (86.2)
CMH risk difference, oral vs IV palonosetron (99 % CI)	3.21 (−2.74 to 9.17)
Delayed phase
Response, n (%)	281 (76.2)	276 (74.8)
CMH odds ratio, oral vs IV palonosetron (95 % CI)	1.09 (0.77–1.52)
CMH p value	0.637
Overall phase
Response, n (%)	272 (73.7)	259 (70.2)
CMH odds ratio, oral vs IV palonosetron (95 % CI)	1.20 (0.87–1.67)
CMH p value	0.269

CI confidence interval, CMH Cochran-Mantel-Haenszel, IV intravenous

On individual study days, day 1 (0–24 h), day 2 (25–48 h), day 3 (49–72 h), day 4 (73–96 h), and day 5 (97–120 h), the percentage of responders was similar for both the oral palonosetron and IV palonosetron groups. The results were also similar for the cumulative time intervals.

There was no significant difference in the percentage of patients with no emesis in the delayed (78.9 % oral palonosetron, 77.5 % IV palonosetron; OR 1.09, 95 % CI 0.77–1.56, p = 0.625) and overall (75.6 % oral palonosetron, 73.2 % IV palonosetron; OR 1.15, 95 % CI 0.82–1.60, p = 0.430) phases.

The percentage of patients with no nausea in the acute phase was 4.6 % higher in the oral palonosetron group (80.2 vs 75.6 % in the IV group; p = 0.129), while in the delayed and overall phases, patients with no nausea in the oral and IV palonosetron groups were respectively 57.5 vs 53.4 % (p = 0.276) and 51.8 and 47.4 % (p = 0.241). No statistical differences were evidenced between palonosetron oral and IV groups on nausea data in all the acute delayed and overall study phases.

There was no significant difference between patients with no rescue medication in the acute (94.6 % oral palonosetron, 93.2 % IV palonosetron; OR 1.28, 95 % CI 0.69–2.36, p = 0.433), delayed (85.6 % oral palonosetron, 82.9 % IV palonosetron group; OR 1.27, 95 % CI 0.84–1.92, p = 0.258), and overall (84.3 % oral palonosetron, 80.8 % IV palonosetron; OR 1.32, 95 % CI 0.89–1.96, p = 0.174) phases.

Safety

No abnormal clinical test results were reported, and the analysis of ECG data indicated that any changes were at comparable interims of frequency for both treatment groups.

TEAEs were reported for approximately half of all patients in each treatment group (48.6 and 51.8 % for the oral palonosetron and IV palonosetron, respectively) (Table 3). However, TEAEs which were related to the study drug were rare (3.2 and 6.5 % for oral palonosetron and IV palonosetron, respectively) and no study drug-related TEAEs leading to discontinuation were reported (Table 3). The most frequently reported TEAEs assessed as being related to the study drugs were gastrointestinal disorders (1.6 and 3 % in the oral palonosetron group and IV palonosetron group, respectively), nervous system disorders (0.5 and 1.6 %, respectively), constipation (1.4 and 2.4 %, respectively), and headache (0.5 and 1.6 %, respectively). The most frequently reported serious TEAEs were neutropenia (1.4 and 2.4 % in the oral palonosetron group and IV palonosetron group, respectively), anemia (0.3 and 1.6 % in the oral palonosetron group and IV palonosetron group, respectively), thrombocytopenia (0.5 and 1.4 % in the oral palonosetron group and IV palonosetron group, respectively), and febrile neutropenia (0.8 and 1.1 % in the oral palonosetron group and IV palonosetron group, respectively).

Table 3

Treatment-emergent adverse events (safety population)

n (%)	Oral palonosetron (n = 370)	IV palonosetron (n = 369)	Overall (n = 739)
At least one TEAE	180 (48.6)	191 (51.8)	371 (50.2)
TEAE related to study drug	12 (3.2)	24 (6.5)	36 (4.9)
TEAE related to dexamethasone	21 (5.7)	20 (5.4)	41 (5.5)
Any related TEAE	27 (7.3)	37 (10.0)	64 (8.7)
TEAE leading to discontinuation of study drug	1 (0.3)	1 (0.3)	2 (0.3)
TEAE related to study drug leading to discontinuation	0	0	0
TEAE related to additional study drug leading to discontinuation	0	1 (0.3)	1 (0.1)
TEAE leading to death	7 (1.9)	12 (3.3)	19 (2.6)

IV intravenous, TEAE treatment-emergent adverse event

Study drug-related TEAEs qualified as serious occurred in two (0.5 %) patients in the oral palonosetron group (Table 4): abdominal pain and constipation (one patient) and diarrhea and asthenia (one patient). For both patients, the events were resolved. No patients in the IV palonosetron group had serious TEAEs assessed as being related to the study drugs.

Table 4

Serious treatment-emergent adverse events (safety population)

n (%)	Oral palonosetron (n = 370)	IV palonosetron (n = 369)	Overall (n = 739)
Serious TEAE	36 (9.7)	36 (9.8)	72 (9.7)
Serious TEAE related to study drug	2 (0.5)	0	2 (0.3)
Serious TEAE related to dexamethasone	4 (1.1)	4 (1.1)	8 (1.1)
Any serious related TEAE	5 (1.4)	4 (1.1)	9 (1.2)

IV intravenous, TEAE treatment-emergent adverse event

The death of 7 (1.9 %) patients in the oral palonosetron group and 12 (3.3 %) in the IV palonosetron group was classified as TEAEs. None of these deaths were assessed as being related to the study drugs or dexamethasone.

Discussion

The efficacy of palonosetron in controlling CINV in patients with cancer receiving treatment with a variety of chemotherapy regimens has been demonstrated previously [10-19].

In this study, we reported that in the acute phase, the majority of patients (89.4 % in the oral palonosetron group and 86.2 % in the IV palonosetron group) achieved a CR. The non-inferiority of oral palonosetron compared with IV palonosetron was thus demonstrated, as assessed by the primary efficacy endpoint (CR in the acute phase) in both the FAS and PP populations. All the planned sensitivity analyses supported the conclusion of non-inferiority of oral palonosetron compared with IV palonosetron. The two treatment groups also showed comparable CR in the delayed and overall phases, and the results of the secondary efficacy endpoints in all three phases were similar. Thus, the results of the secondary efficacy endpoints also support the demonstration of non-inferiority.

The safety of IV palonosetron has been demonstrated in several phase III clinical trials [20–22, 24–26]. The present study further supports these findings as the safety profiles of oral palonosetron and IV palonosetron were comparable and raised no new concerns.

The use of orally administered antiemetics for prophylaxis of nausea and emesis in patients receiving HEC treatment, in particular, for the control of nausea and vomiting on the first day of cisplatin treatment has been questioned [27]. This trial clearly demonstrated the non-inferiority of oral palonosetron versus IV palonosetron administration when both are used with dexamethasone. The use of oral palonosetron may be beneficial as it would allow a more convenient prophylaxis which is proven to be effective in controlling CINV caused by HEC. This may be of particular help for patients who receive treatment in an outpatient setting.

The investigators are aware that the study did not include an NK1 RA, as recommended by guidelines. However, the following of such guidelines in the clinical setting remains low and it is still important to evaluate the contribution of individual agents to CINV control [28]. In conclusion, this study demonstrated the non-inferiority of oral palonosetron versus IV palonosetron, in combination with dexamethasone, in the prevention and control of CINV in cancer patients receiving cisplatin-based HEC.