CENTER FOR DRUG EVALUATION AND
RESEARCH

APPLI CA I 0N NUMBER:

2057180rig13000

SUMMARY REVIEW

Division Director Review

Division Director Review

 

 

 

 

 

Date (electronic stamp)

From Donna Griebel, MD

Subject Division Director Slunmaiy Review
NDA NDA 205 7 1 8

Applicant Name Helsiim Healthcare SA

 

Date of Submission

September 26, 2013
Received: September 27, 201 3

 

 

 

PDUFA Goal Date September 27, 2014

Proprietary Name Akynzeo

Established (U SAN) Name netupitant and palonosetron

Dosage Forms Strength capsule/ netupitant 300 mg and palonosetron 0.5 mg

 

Proposed Indication(s)

Prevention of acute and delayed nausea and vomiting
associated with initial and repeat com'ses of cancer
chemotherapy, including highly emetogenic
chemotherapy

 

 

Action:

 

Approval

 

 

Material Reviewed/Consulted
0ND Action Package, including:

Names of discipline reviewers

 

Medical Of?cer Review

Nancy Snow, Ruyi He, MD

 

Statistical Review

Yeh-Fong Chen, PhD/Freda ooner, 

 

CMC

Raymond Frankewich, PhD/Hitesh Shroff, PhD/Nina
Ni, 

 

ONDQA Biophaimaceutics

Assadollah Nony, PhD/Tapash Ghosh, PhD/Richard
Lostritto, 

 

Phannacology Toxicology Review

Ke Zhang, PhD/David Joseph, 

 

Clinical Pharmacology Review

Dilara appar, PhD/Insook Kim, PhD/Sue-Chih Lee,

ingyu Yu, PhD/Nitin Mehrotra, 

 

 

 

 

 

 

 

DTL Review Ruyi He, MD

PMHS Erica Radden, MD/Hari Cheryl Sachs, MD/Lynne Yao,

MHT MD
Carrie eresa, Phaim D, MPH/Jeanine Best, MSN, RN,
PNP/Lynne Yao, MD

081 Susan Liebenthal, MD

SS Katherine Bonson, Silvia Calderon, PhD/Michael
Klein, 

0ND=0$ce of New Drugs

of Scienti?c Evaluation
PMHS=Pediatric and Maternal Health Sta?
Maternal Health Team
CDTIFCross-Discipljne Team Leader
CSS=Controlled Substance Sta?

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Reference ID: 3635819

 

 

Division Director Review

 

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Division Director Review

1. Introduction

The applicant has submitted an NDA for an oral ?xed combination product that consists of
two antiemetics, the 5HT3 inhibitor palonosetron 0.5 mg (which has been previously approved
in the US as a single agent, but never marketed in the US) and an inhibitor netupitant
300 mg (which is a new molecular entity). There are multiple 5HT3 inhibitors approved for
prevention of chemotherapy induced nausea and vomiting (C INV). This class (5HT3
inhibitor) is generally associated with ef?cacy in the ?st 24 hours after chemotherapy, the
?acute phase?. There is currently only one approved inhibitor in the US, Emend,
which has been approved in both oral and intravenous (IV) dosage forms. inhibition is
are particularly important for prevention of nausea and vomiting dlu'ing the delayed phase. The
delayed phase is generally de?ned as the time period between 24 and 120 hours post
chemotherapy.

Akynzeo is a single capsule that contains: 3 smaller tablets (100 mg each) of netupitant and a
single capsule of palonosetron 0.5 mg. In order to address the combination rule, the applicant
submitted 3 major ef?cacy trials, each designed to demonstrate the contribution of each
component to overall product ef?cacy. The applicant intended the development plan to address
ef?cacy for prevention of CINV in both moderately emetogenic chemotherapy (MEC) and
highly emetogenic chemotherapy (HEC), in both the acute and delayed phases. The
development plan was subject to multiple meetings between the applicant and FDA.
Discussions were complicated by the approved indication for oral palonosetron and the
sponsor?s desire to use we
These negotiations are summarized

in Section 2 Backgrormd of this review.

The Akynzeo development plan was based on the regulatory approach to INV drug
development used for previously approved antiemetics. Late in its development, the FDA
raised the issue that future product labeling could be impacted by ASCO 2011 guideline1
changes in the emetogenicity category NIEC to I-IEC) for anthracyclines (including
doxorubicin, epinlbicin, idarubicin and dalmorubicin) administered in combination with
cyclophosphamide. The chemotherapy administered in the single trial conducted to
support Akynzeo?s approval for a MEC indication em?olled women receiving anthracycline

plus cyclophosphamide chemotherapy.

All disciplines have recommended approval, and I concur with their recommendations. My
review will focus on major review issues.

 

Basch E. Prestrud A. Hesketh P. et a1. Antiemetics: American Society of Clinical Oncology Clinical Practice
Guideline Update. JCO. 2011. Vol 29:4189-4198.

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2. Background
Please refer to the Clinical and CDTL reviews for a comprehensive summary of the regulatory
history. In this section, I will cover:
1) The general approach that has been utilized to establish effectiveness of
antiemetics for CINV
2) The labeled indications that have been granted to reflect trial outcomes
3) Considerations regarding the impact of changes in emetogenicity designation
for anthracycline plus cyclophosphamide combination chemotherapy (from
MEC to HEC) on antiemetic indications for CINV.
4) The previously documented evidence base for the effectiveness of oral
palonosetron, which impacted the clinical development plan design, given the
need to address the Combination Rule.
After presenting this information for context, I will summarize the key discussions between
FDA and the sponsor regarding the Akynzeo clinical development plan.
Regulatory issues related to the general approach to antiemetic drug development.
Antiemetic drug development for CINV has generally included clinical trials dedicated to
studying effectiveness of the proposed product in the setting of HEC (usually, cisplatin-based
chemotherapy) and trials dedicated to the setting of MEC (most recently, these trials have
enrolled patients who were treated with anthracycline and cyclophosphamide chemotherapy).
The indications have evolved to stating the product prevents chemotherapy induced nausea and
vomiting in MEC and/or HEC, depending on the outcome of the trials in each of these two
settings. A summary of this MEC/HEC labeling history follows below. The reader is also
referred to Dr. J. Korvick’s October 2005 review supporting the approval of Emend for MEC,
as it provides a more detailed summary of this history.
The first 5HT3 inhibitor, intravenous ondansetron, was approved in January 1991, with a
very general indication statement, “Prevention of nausea and vomiting associated with initial
and repeat courses of emetogenic cancer chemotherapy,” which did not contain the MEC/HEC
terminology, even though studies were conducted in the settings of cisplatin and
cyclophosphamide 500 mg to 600 mg/m2. There was also no reference to “MEC” and “HEC”
in the ondansetron Clinical Studies section. However, the oral ondansetron label, approved in
December 1992, did contain specific indication statements regarding HEC and MEC.
Although the labeled indication from the 1993 approval of IV granisetron was general, with a
qualifier, “Prevention of nausea and or vomiting associated with emetogenic cancer therapy,
including high dose cisplatin,” the Clinical Studies section includes cisplatin studies and a
subsection called “moderately emetogenic chemotherapy study” that specifically describes
MEC as carboplatin, cisplatin 20-50 mg/m2 and cyclophosphamide >600mg/m2.
Oral dolasetron was approved in September 1997 with the indication, “prevention of nausea
and vomiting associated with moderately emetogenic cancer chemotherapy.” The clinical
development program for the oral dosage form focused on MEC chemotherapy regimens. The

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chemotherapy in one trial was cyclophosphamide and/or doxorubicin. The chemotherapy in
the second trial was not described in the label. Intravenous dolasetron was also approved in
September 1997 with the indication “prevention of nausea and vomiting associated with
initial and repeat courses of emetogenic cancer chemotherapy, including high dose cisplatin.”
The NDA also included a single MEC study. The Clinical Studies section includes a header
“Cyclophosphamide Based Chemotherapy” and describes the study as primarily enrolling
women receiving “moderately emetogenic chemotherapy such as cyclophosphamide based
regimens.”
Intravenous palonosetron was approved in July 2003, with indications specifically identifying
HEC and MEC. Approximately half of the patients in the MEC trial were treated with
doxorubicin and approximately 10% with epirubicin. Oral palonosetron was approved in
August 2008, with an indication limited to MEC. Approximately half of the patients in the
trial were treated with doxorubicin and another 10% with epirubicin. Due to its long half-life,
the clinical development plan included evaluation in both the acute and delayed phases post
chemotherapy. The intravenous palonosetron indication refers to efficacy in both the delayed
and acute phases post MEC chemotherapy. However, in the setting of HEC, it is only
approved for the acute phase. In contrast, oral palonosetron does not carry an indication for
the delayed phase. The results of secondary analysis of delayed phase in the noninferiority
trial that supported the approval of oral palonosetron for MEC did not demonstrate that oral
palonosetron (0.5mg) was noninferior to IV palonosetron (0.25mg).
Aprepitant, which was approved in March 2003, is the only approved NK-1 inhibitor. The
indication was “prevention of acute and delayed nausea and vomiting associated with initial
and repeat courses of highly emetogenic cancer chemotherapy, including high-dose cisplatin.”
Patients in both clinical trials received cisplatin based chemotherapy (>50 mg/m2). Approval
of a MEC indication occurred in October 2005, “prevention of nausea and vomiting
associated with initial and repeat courses of moderately emetogenic cancer chemotherapy.”
The label describes a single MEC trial that enrolled almost exclusively women, who were
treated with anthracycline plus cyclophosphamide combination regimens. The approval of
aprepitant constituted the first references to “acute” and “delayed” “phases”, although the
ondansetron label’s Clinical Studies section refers to multi-day dosing and its Dosage and
Administration instructions for MEC state that treatment should continue with BID dosing “for
1-2 days after completion of chemotherapy.”
Initially, drug development plans for products intended to prevent delayed nausea and
vomiting utilized a primary endpoint of overall phase, which encompasses the full 0-120 hour
period, with secondary endpoints for each component, acute phase (first 24 hours) and delayed
phase (25-120 hours). The Division has transitioned to recommending that delayed phase is
the appropriate primary endpoint period for a product intended to prevent delayed nausea and
vomiting.
This history is summarized in the table below.

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Table 1. Summary of CINV Indications Granted for Various 5-HT3 Inhibitor and NK-1 Inhibitors

5HT3
Zofran
(ondansetron)

Dosage form

HEC/MEC
HEC and MEC

Anzemet
(dolasetron)

IV and PO

IV

IV = “Prevention of
[CINV], including high
dose cisplatin”
PO = MEC
“Prevention of [CINV],
including high dose
cisplatin”
Clinical Studies Section
includes a MEC trial.
HEC

PO

MEC
MEC

Acute and Delayed
Acute

HEC
MEC

Acute and Delayed
“prevention of nausea and
vomiting” Clinical Studies
Section refers to “overall phase,
0-120 hours”. Individual
analyses for acute, delayed not
statistically significant in one of
two MEC studies.

Kytril
(granisetron)

Aloxi
(palonosetron)
NK1
Emend

PO and IV

Acute/Delayed
Acute
Plus: Day 2 and 3 dosing
instructions for MEC only.
acute based on Clinical Studies
Section says first 24 hours
acute based on Clinical Studies
Section says 24 hours.

Acute

Impact of changes in emetogenicity designation for anthracycline plus cyclophosphamide
from MEC to HEC on indications for antiemetics for CINV.
Given the changes in the designation of anthracycline plus cyclophosphamide regimens to
“HEC” and the enrollment limited to patients receiving anthracycline plus cyclophosphamide
chemotherapy in Akynzeo’s dedicated “MEC” trial, the Division considered whether it is
appropriate to approve a general CINV indication if a product has only shown efficacy in a
development program limited to HEC chemotherapy trials. It seemed reasonable to assume
that a product that is effective in HEC would be effective in MEC. The approval history of
antiemetics was evaluated to identify examples of products in which efficacy could only be
established in the setting of HEC, i.e., the product specifically failed in MEC trials while at the
same time “winning” in HEC.
The product labels of Emend (NK-1 inhibitor) and various 5HT3 inhibitors, including Zofran,
Aloxi (palonosetron), Anzemet (dolasetron) and Kytril (granisetron) were reviewed and only
two products were identified with an indication limited to MEC, i.e., oral dolasetron and oral

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Aloxi. Each of those products was only studied in the MEC setting. The review was further
complicated by the fact that there are limitations in the HEC/MEC indications related to
specific periods of prevention of CINV, i.e., acute vs. delayed phases, based on whether the
phase was studied and whether efficacy was established. This issue was relevant to two
products, palonosetron and Emend.
The IV palonosetron indication refers to efficacy in both the delayed and acute phases post
MEC chemotherapy. However, in the setting of HEC, it is only approved for the acute phase.
In contrast, oral palonosetron, which does not carry a HEC indication, has a MEC indication
limited to the acute phase. Therefore, for IV palonosetron, efficacy in MEC was actually
broader than in HEC (including delayed phase).
Emend carries an indication for both the acute and delayed phases of HEC, but only general
wording regarding MEC, i.e., no specific reference to acute and delayed phases for MEC. At
the time of initial approval, the primary endpoint for the only MEC study was “overall phase”,
i.e., the full 0-120 hours post chemotherapy (approximate N= 430 per arm). However, the
numerically favorable trends in each secondary endpoint, the acute and delayed phases, were
not statistically significant. The individual acute and delayed phase efficacy analyses were
statistically significant in the HEC trial. This resulted in the initial differential labeling
between HEC and MEC. However, a subsequent study submitted for review post-approval
also evaluated Emend in MEC (approximate N=430 per arm), and that second study showed
statistically significant improvements in efficacy relative to the control in each of the analyses,
acute and delayed phases; the indication was not revised to reflect this.
After considering the trials that supported the specific indications that appeared limited to
MEC, the Division concluded we lack persuasive evidence that a product that is effective in
HEC would not also be expected to be effective in the setting of MEC. It should be noted that
even though the anthracyline/cyclophosphamide (AC) combination was changed from MEC to
HEC in the Guidelines, the information provided to support the change suggests that this
regimen is not as emetogenic as cisplatin chemotherapy. The lower limit for inclusion in the
HEC category is causing vomiting in 90% of patients not treated with antiemetic prophylaxis.
However, as stated in the ASCO Guidelines, (www.asco.org/guidelines/antiemetics) the
Update Committee changed the emetogenicity category for AC after considering placebo
controlled data which indicated 85% of patient treated with AC would be expected to vomit in
the absence of antiemetic prophylaxis.
It is of key importance for an antiemetic development program to establish whether a new
product is effective in the setting of cisplatin chemotherapy, and it seems reasonable to expect
that a product that has been shown to be effective for CINV HEC, should be effective for
CINV MEC. The Division concluded that the early more general (historic) approach to CINV
labeling that utilized a general statement combined with a qualifier such as, “indicated for the
prevention of nausea and vomiting associated with cancer chemotherapy, including, but not
limited to, highly emetogenic chemotherapy” would be appropriate if a product has been
shown to be effective in the setting of cisplatin based chemotherapy. If the product has not
been studied in the setting of cisplatin based chemotherapy, or the product failed to
demonstrate effectiveness in that setting but was effective in the setting of less emetogenic

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drugs, the labeled indication would then need to clearly specify the setting in which it has been
shown to be effective, and a limitation of use that states the product has not been studied or
was not effective in the setting of cisplatin based chemotherapy could be considered. The
latter would be important if the clinical trials supporting approval were limited to AC
regimens. Similarly, if the product is only effective in non-anthracycline/cyclophosphamide
and non-HEC chemotherapy, the product label would need to specify that information.
The differences in delayed phase efficacy observed in the IV palonosetron trials between the
MEC and HEC settings should be considered in assessing future development plans that might
(b) (4)
propose
. The
differences observed in delayed phase efficacy of IV palonosetron between the HEC (cisplatin)
and MEC trials (which primarily enrolled women with breast cancer and the most common
chemotherapy regimen studied was likely AC) suggest that these regimens should be studied
separately in order to clearly define the full extent of efficacy in the setting of cisplatin
chemotherapy.
An additional consideration regarding the Guidelines and labeling relates to the concomitant
antiemetic medications administered in the clinical trials supporting product approval. Emend
was the first and only product to mention in the Dosage and Administration section that the
product should be administered with a 5-HT3 antagonist and a corticosteroid. The Emend
label gives specific instructions for dexamethasone dosing on Days 1 and Days 2-4 post
chemotherapy in the setting of “HEC”. The MEC dexamethasone instructions state it should
be administered on Day 1 only (how it was administered in the clinical trials). Similar
dexamethasone schedules were utilized in the trials submitted to support this NDA. The ASCO
Guidelines state that for HEC, an NK-1 inhibitor should be administered with a 5HT3 on day 1
only and with dexamethasone on days 1-3 or Days 1-4. For MEC, the Guidelines do not
recommend use of an NK-1 inhibitor. Instead they recommend palonosetron (due to its long
half-life) combined with dexamethasone administered Days 1-3, a dexamethasone regimen
that does not appear in approved product labels.
Impact of oral/IV palonosetron labeled indications on Akynzeo’s clinical development
plan. The proposed combination product combines the NK-1 inhibitor netupitant with the
applicant’s 5HT3 inhibitor, oral palonosetron. Because the proposed fixed combination
contained a product that had been previously approved for specific CINV indications, the
established efficacy of oral palonostron had to be considered in determining the trials
necessary to support the approval of a product that combines it with a new NK-1 inhibitor.
The applicant proposed to develop the combination product for both HEC and MEC
indications, and both acute and delayed phases in each of HEC and MEC. The previously
approved NK-1 inhibitor, Emend, was approved based on add-on studies in combination with
a 5HT-3 inhibitor (and dexamethasone).
There were two major issues to address in designing a development plan with this scope of
indications for a fixed combination that included oral palonosetron 0.5 mg: 1) oral
palonosetron is not indicated for HEC, so the contribution of oral palonosetron to prevention
of CINV in the HEC setting would need to be established, and 2) questions were raised
regarding whether it would be necessary to establish the role of palonosetron for even the

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acute MEC setting in the presence of the NK-1, in light of evidence from Emend trials that
NK-1 inhibition increased acute phase response. Additional complexities arose from the
(b) (4)
sponsor’s desire to
in studies designed
(b) (4)
to establish the contribution of netupitant. The difference in palonosetron doses
was anticipated to diminish the ability to delineate
the contribution of each product to the combination. The summary of the interactions between
the sponsor and FDA regarding the clinical development plan follows below.
Summary of communication between FDA and sponsor regarding the Akynzeo clinical
development plan.
At the April 5, 2006, pre-IND meeting, the sponsor asked for comment on whether their
plan to not include a netupitant alone arm in their phase 2 dose finding study ( netupitant
added on to oral palonosetron 0.5 mg in the setting of HEC) would fall short of adequately
addressing the Combination Rule. They had concerns that an NK-1 alone arm may be
inadequate treatment in the setting of HEC. The Division agreed to the plan. (Note: this refers
to Study NETU-07-07, ultimately the key trial submitted to support the HEC indication.)
The sponsor also asked whether it would be adequate to establish noninferiority of oral 0.5 mg
(b) (4)
palonosetron
in the setting of MEC to support its use in
combination with netupitant in both MEC and HEC settings. The Agency response was
limited to saying that it would depend on the data from the noninferiority study, and the
HEC/MEC issue was not addressed. FDA ultimately raised this issue as a concern at the End
of phase 2 meeting.
In the July 20, 2009 End of Phase 2 meeting, the sponsor proposed the following studies to
support Akynzeo approval for acute and delayed CINV in HEC and MEC:
For HEC:
1) Study NETU-07-07 (phase 2 dose finding study of netupitant added
to oral palonosetron 0.50 mg, which is not approved for HEC)
(b) (4)

For MEC:

1) NETU-08-18: superiority trial comparing oral palonosetron 0.5 mg
(b)
(b) (4)
plus netupitant combination versus (4) palonosetron
(the
different palonosetron doses raised issues for interpreting netupitant’s
contribution to treatment effect).

The meeting minutes reflect that the FDA stated that “more work will be needed for the
HEC indication since oral palonosetron is not approved for this indication”.
The sponsor asked FDA to confirm that an individual netupitant monotherapy study is not
needed to fulfill the Combination Rule requirement. The meeting minutes state, “FDA
confirmed that the sponsor’s phase 2 study confirmed that netupitant was effective for the
proposed indication.” However, the Division had not yet reviewed the data and the results
would need to be confirmed in NDA review.
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The sponsor specifically asked about their plan to bridge the phase 2 study NETU-07-07
“combination test articles” to the phase 3 fixed-dose combination capsule, which would be
further bridged to the to-be-marketed fixed-dose combination capsule. FDA stated that for
the in vivo bioavailability study intended to bridge the phase 2 and 3 trials, the sponsor’s plan
(b) (4)
(b) (4)
to
the BE criteria for Cmax based on
would be an NDA
review issue. The FDA described the requirements for successfully bridging the phase 3 and
to-be-marketed formulations, as outlined in the SUPAC guidance. FDA stated that the
manufacturing site change determination (regarding “Level”) is made on a case by case
basis”, and FDA lacked adequate information to agree with the sponsor’s proposal that the
(b)
(b)
manufacturing site change was a Level (4) and the equipment equivalency was a Level (4) (See
Section 3 CMC/Biopharmaceutics of this review.)
The Division told the sponsor that the multi-cycle trial would need to be longer than the
proposed 3 cycles, given that netupitant and its metabolites had been detected in dog
myocardium. The sponsor agreed not to put an upper limit on cycle numbers and agreed to
include additional cardiovascular safety monitoring in the clinical trials, e.g. troponin levels.
Note that in this meeting, the Division agreed that the general design of the proposed MEC
study NETU-08-18 was adequate to support approval for MEC, provided the combination
(b)
demonstrated superiority to (4) palonosetron. The difference in palonosetron doses was raised
as a significant concern. The Division agreed to a primary endpoint of overall phase (0-120
hours), with the acute and delayed phases as secondary endpoints, in part because the
approved NK-1 Emend was approved based on superiority in the overall phase.
(b) (4)

Also on October 12, 2009, a SPA request was submitted for a MEC study, NETU-08-18.
(b) (4)
The sponsor proposed

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(b) (4)

. The Division issued

a SPA No Agreement letter for this request on November 27, 2009.
1. Similar concerns were expressed regarding the different doses of palonosetron in
the two arms. The Division recommended an oral palonosetron control arm.
2. The Division noted that palonosetron is only approved for the acute phase of MEC,
and that the eventual product labeling would need to state that the contribution of
the palonosetron to the fixed combination in MEC is for the acute phase (0-24
hours). The proposed trial would not establish efficacy of palonosetron in the
delayed and overall phases.
3. The above cardiovascular safety monitoring recommendations were repeated.
On January 22, 2010, the FDA and sponsor met to discuss the SPA no agreement letters. The
sponsor proposed the following revised clinical development program:
(b) (4)

NETU 10-10 (New HEC study proposal: Noninferiority trial of 0.5 mg oral
palonosetron compared to 0.25 mg IV palonosetron in the setting of
HEC, with primary endpoint Complete Response in the acute phase)
The sponsor proposed that this study would establish the contribution of
the oral palonosetron to the combination with netupitant.
NETU-07-07 (HEC dose finding trial already completed)
NETU-08-18 (MEC trial proposed in the MEC SPA request)
In this meeting:
1. The Division stated it would review the development plan with the Office of
Medical Policy (OMP).
2. Regarding the proposed palonosetron (IV vs. oral) HEC noninferiority study
(NETU-10-10),
a. Division stated this trial might serve as an appropriate alternative to adding
oral palonosetron arms (third study arm) to other trials to establish the
contribution of oral palonosetron to the combination.
b. Division indicated the proposed 15% noninferiority margin might be
accepted, as it had been accepted with past applications; however, further
internal discussion was required. FDA pointed out that the prior
palonosetron approval based on a noninferiority assessment utilized an
adjusted confidence interval due to reliance on a single study. The sponsor
stated the adjustment in that trial was due to testing multiple palonosetron
doses. FDA reiterated its confidence interval adjustment recommendation.
c. Division expressed concern about whether a HEC study could be conducted
without including an NK-1 inhibitor.

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 Division Director Review

4. FDA stated, ?We agree that the study design isolates the effect of
netupitant. However, we will need to review the ?nal study results and statistical
analysis plan for NETU-O7-O7 before we can provide comment on whether 300 mg
of netupitant was superior in the overall, acute, and delayed phases of INV-HEC 

5. Regarding MEC study the division reiterated its recommendation for
an oral palonosetron control arm, but stated it would review this with 0MP.

6. The Division agreed with a proposal to eliminate 12-horu' troponin samples.

These issues were subsequently discussed with leadership from 0MP, and the Division
followed OMPs recommendations. This included requiring the applicant to establish the role
of oral palonosetron in treatment of HEC which could be done by performing a noninferiority
trial comparing oral palonosetron to IV palonosetron. In addition, the Division wouldn?t
require an only arm to establish the additional contribution of the 5HT3 to prevention of
nausea and vomiting. 0MP leadership also encouraged the Division and applicant to consider
the phase 2 dose ?nding trial NETU 07-07 an adequate and well controlled trial that had the
potential for providing substantial evidence of netupitant?s effectiveness in HEC, a second
HEC study wouldn?t be necessary.

A letter dated March 8, 2010 conveyed the advice from the 0MP meeting:

1. ?Trials and NETU-O7-07 will be acceptable to support the proposed
?xed-dose combination capsule for the prevention of acute and delayed INV -HEC 
provided that we are able, after our review of the trial data, to con?rm the outcome you
have reported for NETU-07-07, and if the outcome of is also positive.
Trial (m4) does not appear to be necessary.

2. Trial NETU-08-18, which proposes 

is not acceptable to support the ?xed-dose combination capsule for the
prevention of acute and delayed INV-MEC . For trial NETU-08-18 to support the
proposed indication, the protocol should be revised to include an active comparator
arm of 0.5 mg oral alonosetron This arm can either be a third arm or replace the
proposed arm. Additionally, the primary endpoint can be tested either as
a co-primary endpoint consisting of acute and delayed phases, or tested hierarchically
with the delayed phase ?rst followed by acute and overall phases, to control Type I
error.?

(5) (4)

if NETU-07-O7
was found non-supportive, presuming was success?il in establishing
noninferiority. The Agency replied in a letter on March 17, 2010: ?We have concerns
regarding reliance on 

The sponsor responded with a follow-up question regarding whether

If you have concerns that NETU-07-07 may not be supportive, we again
recommend that that 0M4)

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On March 30, 2010, another SPA request was submitted for the MEC protocol for study
NETU-08-18. A SPA No Agreement was issued on May 14, 2010. Although the sponsor
had (No, the FDA couldn?t
agree with speci?c aspects of the statistical analysis plan, including a proposal to 

The Agency



couldn?t agree,

On May 4, 2010, a SPA request was submitted for the sponsor?s new palonosetron
noninferiority trial which compared oral palonosetron 0.5 mg with IV
palonosetron 0.25 mg in HEC. A SPA no agreement letter was issued on June 18, 2010.
The Agency agreed on some aspects of the proposed protocol and disagreed on others.

1. FDA agreed with the primary endpoint of complete response in the ?st 24 horu's.

2. FDA agreed with a 15% noninferiority margin ?based on past usage?; however, it
recommended type I error should be controlled at a two-sided 1% level, for the
results to be considered robust.

3. Sponsor asked for reassurance that the noninferiority study in combination with the
phase 2 dose ?nding study would adequately support approval for
HEC, in light of the NETU-07-07 population. The sponsor stated: ?Completed
single cycle study was entirely conducted in Russia and the Ukraine
and therefore there will be no US patients treated with the combination in the HEC
setting in the planned NDA. If is successful and if FDA ?nds the
ef?cacy analyses in ongoing review of the NETU-07-07 study report to be
acceptable, study NETU-07-07 is planned to serve as the sole pivotal trial for
pruposes of supporting HEC ef?cacy and (in with MEC study
NETU-08-18 in the planned NDA). NETU-07-07 demonstrated statistical
superiority of the combination 300/05 mg dose group versus oral palonosetron 0.5
mg alone in the overall acute (p=0.007) and delayed (p=0.018) phases.?
FDA replied NETU-07-07 will be acceptable as the sole ef?cacy trial in acute and
delayed INV-HEC provided the reviews of NETU-07-07 and PALO-10-01
conclude the data support ef?cacy and there are suf?cient data beyond cycle 4.

4. Sponsor asked about the ability to label for ef?cacy of repeat cycles in HEC, given
that NETU-07-07 was not a repeat dose study. FDA stated, ?With regards to repeat
cycles, from an ef?cacy standpoint, this labeling in HEC will rely on the
observation in the MEC study. From a safety standpoint, the repeat cycle labeling
claim will need to be obtained from HEC and/or MEC 

A meeting was held July 15, 2010 to discuss the SPA no agreement letter issued for MEC
study NETU-08-18. The sponsor clari?ed that although most patients would be expected to
be treated a maximum of 4 cycles, there would be no treatment limit and some patients would
receive more than 4 cycles. In addition, they proposed a new repeat cycle trial that would
em?oll both HEC and MEC patients receiving rmlimited consecutive repeat cycles, NETU- 10-
29. The Division stated it expected to review more than 100 patients who had been treated

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with at least 6 cycles of the combination, for the purposes of safety evaluation, ideally in the
setting of a control arm.
Subsequently, two SPA requests were submitted on September 21, 2010, for:
1) MEC trial NETU-08-18 comparing the combination to oral palonosetron
2) HEC noninferiority study of palonosetron oral vs. IV
The Agency issued SPA agreement letters to each request on November 3, 2010. FDA
agreed the repeat cycle efficacy demonstrated in NETU-08-18 could support labeling repeat
cycle efficacy in both MEC and HEC. FDA agreed to the 15% noninferiority margin for the
HEC palonosetron trial, based on the sponsor’s plan to use a 99% confidence interval.
Establishing noninferiority margins in CINV antiemetic clinical development has been
difficult due to the paucity of placebo-controlled information. In addition, the responder
definitions in available placebo controlled trials are not consistent with the definition the
Division now considers relevant. The IV palonosetron label indicates the adult acute phase
CINV indication for HEC and MEC hinged on noninferiority analyses utilizing a -15% lower
bound of the confidence interval for the difference in response between palonosetron and the
comparator, utilizing a 2-sided 97.5% confidence interval. The lower bound exceeded -10 in
all three trials; in one MEC trial (ondansetron control) it exceeded zero. (Both MEC trials
enrolled 70-80% females receiving breast cancer chemotherapy, suggesting AC was the
“MEC” regimen.) The following table is reproduced from the IV palonosetron label:

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Table 2: Intravenous palonosetron noninferiority analyses

The Statistical Reviewer for the IV palonosetron NDA summarized the applicant’s metaanalysis supporting their proposed noninferiority margin. She identified 4 key trials that
compared ondansetron to placebo, which are summarized in the table below. The difference in
response rates for ondansetron vs. placebo ranged from 47-70% for MEC. The HEC trial
difference was 14% and was exceeded by lowest bound of the confidence interval for the
comparison of IV palonosetron to ondansetron or dolasetron.

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Table 3: Summary of placebo controlled 5HT3 inhibitor efficacy data

Table 7. Response rates in comparative trials

Study Active Response Response Difference Emeto-
treatment in placebo in active in rates genicity

Beck et al, Ondansetron 15/81 52/79 47% Moderate

1993 . 

Cubeddu Ondansetron 0/10 7/ 10 70% Moderate

et al, 1990 

Cubeddu Ondansetron 0/14 2/14 14% High

et al, 1990 

Cubeddu Ondansetron 9/73 47/7 1 54% Moderate

et al, 1994 

She also considered the placebo response rates from individual studies in the meta-analysis,
which ranged 0-50%, with a mean of 17 and standard deviation of 16. For HEC, the placebo
mean was 7 with a standard deviation of 10. She summarized her evaluation of the historical
data in the context of the palonosetron ef?cacy results as follows: . . .an examination and
meta-analysis of results ??om the anti-emetic literattu'e was carried out. In the few studies
where ondansetron or dolasetron was directly compared to placebo, the active treatment
reliably out-performed placebo to a greater extent than the difference between treatments in
the trials in this application. magnitude of the differences formd or modeled in the
meta-analysis also was large enough to justify a conclusion of noninferiority of palonosetron
in the current trials.?

The noninferiority margin of -15% utilized in the IV palonosetron application has been
selected by sponsors of other 5HT3 antagonist development plans for their noninferiority
analyses. (See reviews of the granisetron patch for review discussions regarding challenges
posed by establishing a noninferiority margin. In that review, the con?dence intervals arormd
the complete responses observed were also examined relative to the maximum placebo
response that may be expected.)

In another letter dated November 19, 2010, the Agency responded to questions regarding the
Akynzeo repeat coru'se safety study NETU-10-29. The Agency recommended strati?ed
randomization by chemotherapy type and strongly recommended making ?every
effort to em?oll patients who are receiving repeat dose anthracycline containing therapy? to
provide repeated dose safety data in the setting of cardiotoxic chemotherapy.

In the April 16, 2013 pre?NDA meeting, FDA noted that NETU 08-18, the sole MEC
ef?cacy trial, utilized AC chemotherapy and discussed the reclassi?cation of AC regimens to
HEC with the sponsor. FDA stated that if Aknyzeo was approved, the indication would
describe the regimens actually studied in the program. The Division stated it is moving
beyond and classi?cations. FDA also advised the sponsor that its iustifg?gtion

for
would be a revrew rssue. FDA noted that it there were Iew patients 

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renal impairment in the clinical dataset, a post marketing study to assess pharmacokinetics in
renally impaired subjects would be considered.

3. CMC/Biopharmaceutics
The CMC reviewers determined the applicant had provided sufficient information to assure the
identity, strength, purity and quality of the drug product. The Office of Compliance made a
recommendation of “Acceptable” for the manufacturing facilities. The reviewers ultimately
concurred with final labeling after revision. The CMC and Biopharmaceutics reviewers have
recommended approval, and I concur.
The fixed combination product is composed of:
 Three intermediate netupitant tablets (100 mg each)
(b) (4)
 One intermediate palonosetron
capsule (0.5mg)
 One size 0 hard gelatin capsule consisting of a white body with black imprint “HE1”
and a caramel cap.
A certificate from the capsule manufacturer confirmed the gelatin in the capsule meets the
(b) (4)
recommendations of the FDA
Guidance.
The CMC reviewers identified 4 excipients present in the final dosage form that were not
listed in the FDA inactive ingredient database for further evaluation by both the CMC and the
Pharmacology/Toxicology reviewers. Ultimately, they determined that two of the excipients
were in fact in the database and the amount present in the drug product is far lower than the
maximum amount cited in the Database (see addendum reviews). They determined there was
no safety issue associated with the levels present of either of the two remaining excipients,
based on a number of data sources, including the Joint FAO/WHO Expert Committee on Food
Additives, the European Food Safety Authority Scientific Panel on Food Additives,
Flavorings, Processing Aids and Materials in Contact with Food published findings of safety
of sucrose esters of fatty acids, a CFR citation for sodium stearyl fumarate listing it as an
entitled Food Additive Permitted for Direct Addition to Food for Human Consumption.
The capsule formulation for netupitant changed between phases 1 and 2. The reviewer
stated that the phase 2 capsule formulation “was the basis of the tablet formulation proposed
for commercialization and was used in the pivotal Phase 3 trials.” The clinical and
registration batch manufacturing sites differed, and the applicant provided a “tabular
comparison of equipment used at the different sites and a detailed comparison of processing
parameters during the manufacturing of INT clinical and registration batches,” in
accordance with the Q8(R2) Pharmaceutical Development, Manufacturing Process
Development guidance. In addition, a bioequivalence study
was performed to establish
(b) (4)
equivalence between the tablet product made by
and the tablet made by HPB.
The study was reviewed by the ONDQA Biopharmaceutics reviewers. (See below.)
Regarding the finished drug product specification impurities, the CMC reviewer noted that
the elemental impurity level acceptance criteria were appropriately set and were less than
allowed by USP <232>.
Regarding the impurities identified for netupitant, the CMC reviewer noted that(b)the
drug
(4)
substance specification listed two process impurities,
and one

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degradation product. but none of the other identi?ed degradation products
were speci?ed The CMC reviewer noted

that for the latter 3 degradatron products, which were not speci?ed 111 the ?nished drug
product speci?cation none were identi?ed above through 24 months of storage
which justi?ed not monitoring these 3. The degradatron product M) was
observed 111 the drug product under forced stress conditions and was as the main
degradation product to be observed dru?ing stability. The MC reviewer noted that the limit
set for mwwas justi?ed in accordance with ICHQ3A, based on the maximum
dailv dose ot'netuprtant. Ames testing for two speci?ed impurities, 0914)

revealed no evidence of mutagenic effect. The netupitant drug substance was
subjected to in vivo and in vitro testing, including Ames test, mouse tests and
micronucleus test in rat bone marrow. The Ames test concluded no evidence of mutagenic
effect. The mouse cell mutation assay and rat test were negative.
Additionally, a deductive estimate of risk from existing knowledge (DEREK) assessment
was performed on all the potential impru'ities structurally related to netrrpitant and no
genotoxic alert structure was formd. Based on these assessments, the reviewers determined
that the impru?ity limits based on IC Q3B were acceptable.

Regarding the impurities for the palonosetron component of the drug product, the CMC
reviewer noted that the limit for the speci?ed impurity was based on the
quali?cation threshold in IC Q3B for a drug with a maxrmum darly dose of <10 mg, and
that it is the same limit for the crurentlv marketed Aloxi Capsules which rs an identical?)
palonosetr on dose.

. The MC revrewer noted that srnce these 3 are process
rmpurrtres they do not need to be speci?ed impurities in the Akynzeo drug product
speci?cation, in accordance with IC Q3B. An additional ('degradation product of
palonosetr on was identi?ed 1n this submission, ,and it rs not momtor ed 111
Akynzeo or in the Aloxi capsule marketed product. The MC reviewer stated 1n his review,
?Since it is not monitored in either the drug substance or in Aloxi capsules, it appears that it
has not been observed in any signi?cant amount in the drug substance or drug product on
stability.? To further evaluate this, he noted that this impru?ity would be detected as ?Single
Unspeci?ed Impurities? in the srunmary results, and examination of those results revealed
that ?no impurity above LOQ was detected after 24 months storage.? Because it does not
appear in signi?cant amormts on stability, the MC reviewers determined that the
applicant?s decision to not treat it as a speci?ed impurity was justi?ed.

ONDQA Biopharmaceutics. The applicant submitted two bioequivalence studies to
provide a bridge between the late phase 1 formulation, phase 3 formulation and the to-be
marketed formulation.

Study NETU-O9-07 provided an adequate bridge between the late phase 1/ 2 formulations
and the phase 3 formulation, both manufactru'ed at atalent Philadelphia. The initial study
product consisted of two netupitant capsules, each containing 150 mg plus a palonosetron
0.5 mg softgel. The subsequent product for phase 3 was the ?xed combination capsule
containing 300 mg netrrpitant plus palonosetron 0.5 mg. The reviewers agreed
bioequivalence was established in this study.

Study NETU-11-02 provided an adequate bridge between two phase 3 products from two
different manufacturing facilities (?xed combination capsule used in development and
manufactru?ed in vs. commercial site ?xed combination product
manufactured by HBP in Ireland), between the two manufacturing sites. Bioequivalence

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was established. Dissolution data were also submitted to support bridging. The reviewers
found these data further supported bioequivalence. The OSI inspection found the clinical
and analytical sites for study NETU11-02 to be satisfactory.
The reviewers also evaluated the dissolution methods and acceptance criteria proposed for
both the intermediate and finished fixed combination products.
The Biopharmaceutics reviewers recommended approval. They agreed that the applicant
would submit dissolution data from the first five batches of the product following approval
as a post approval supplement, and the FDA would reevaluate the netupitant dissolution
acceptance criteria.

4. Nonclinical Pharmacology/Toxicology
The Pharmacology/Toxicology reviewers have recommended approval, and I concur. Their
labeling recommendations were incorporated, including their recommendation that Akynzeo
should have labeling consistent with Pregnancy Category C, based on the netupitant
component of this fixed combination product. An increased incidence of external and skeletal
abnormalities in rabbit fetuses was observed following daily administration of netupitant in
rabbits at 10 mg/kg/day and higher (0.2 times the human AUC at the recommended single
human dose with each cycle of chemotherapy) during the period of organogenesis.
Abnormalities included positional abnormalities in the limbs and paws, and fused sternebrae.
Reduction in fetal rabbit weight occurred at 30 mg/kg/day. Maternal toxicity in rabbits (i.e.,
loss of bodyweight during the treatment period) was also observed at 30 mg/kg/day. The
PMHS Maternal Health Team concurred. The reviewers confirmed that the Aloxi product
label Section 8.1 Pregnancy Category B remains appropriate.
Netupitant alone was tested in oral toxicity studies of up to 26 weeks in rats and 9
months in dogs. Daily dosing was studied. Netupitant induced phospholipidosis (in liver,
lung, and lymphoid tissues) at doses of 10 mg/kg/day or higher in both rats and dogs. The
calculated animal to human AUC multiples for netupitant, based on the AUC values
associated with exposures to 10 mg/kg/day in both rats and dogs, ranged from 0.4 to 1.8.
Oral toxicity studies with the combination of netupitant and palonosetron were performed in
rats and dogs for up to 13 weeks. The combination did not produce any additional toxicity as
compared with either drug alone. In the one month dog study of netupitant with a 4 week
recovery period, phospholipidosis accompanied by inflammation was seen beginning at 15
mg/kg/day (focal liver necrosis was noted in one dog at the 50 mg/kg/day dose). In a dog
study of similar duration and recovery period, in which netupitant was combined with
palonosetron, hepatic hypertrophy was noted but no necrosis.
The Pharmacology/Toxicology reviewers stated that the “clinical significance of
phospholipidosis in these studies is not clear.” They noted that animals were dosed daily and
human dosing is anticipated to be no more frequent than a dose every 3 weeks, based on the
usual scheduling of chemotherapy cycles. The netupitant median half-life in humans
(specifically, cancer patients) is 88 hours, so the exposure per 3 week cycle in humans is
longer than 24 hours, but is definitely not the daily exposure over multiple weeks that
occurred in the animal studies. The available pharmacology/toxicology review of Emend, the
currently approved NK-1 inhibitor, does not suggest phospholipidosis is a class effect.

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However, in a consult review from Division of Cardiorenal Products’ (DCRP) QT
Interdisciplinary review team (submitted to IND 73493 on January 26, 2010), a DCRP
pharmacologist stated that since another member of the drug class (casopitant) had
myocardial necrosis and phospholipidosis observed in nonclinical studies, and hypotension,
bradycardia, QT prolongation in nonclinical studies, she raised concern there could be a class
effect. She also referred to documented “accumulation” of netupitant and its metabolite in dog
myocardium, however, the study was not designed in a way that can identify “accumulation”.
It appears that she is referring to an increase in myocardial drug levels with increasing dose.
On September 22, 2014, Dr. Jacobs provided her review of this issue in a written memo,
which stated that there is no evidence of histologic cardiac effects for Akynzeo in any animal
study. She concluded that phospholipidosis affecting the heart would be detected by light
microscopy and that given the differences in the molecules (netupitant vs. casopitant), a
different toxicity profile “is not unexpected”. She stated no further nonclinical cardiac studies
of netupitant are necessary at this time.
The nonclinical finding of phospholipidosis was considered in evaluating the clinical safety
data. See Section 8 Safety of this review; there was no clear safety signal detected associated
with netupitant exposure. I further inquired about FDA’s experience with how
phospholipidosis in nonclinical studies translates into clinical significance in humans. The
reviewers stated that Dr. A. Jacobs, the Associate Director in OND IO, concurred that
phospholipidosis is a nonspecific finding of uncertain significance. In Dr. Jacobs’ September
22, 2014 memo, she stated, “Phospholipidosis commonly occurs with cationic amphophilic
drugs of which there are more than 50. Phospholipidosis is not necessarily associated with
adverse effects, even when the phospholipidosis persists, and even in the brain.” In addition,
the reviewer noted that “minimal liver necrosis” in a background of phospholipidosis was
detected in only one animal study (oral dosing x 13 weeks in rats), with a margin of 3.4-fold
relative to human plasma exposure at the recommended dose. The reviewer noted that there
was no liver necrosis noted in the combination studies in animals.
The reviewers confirmed that netupitant did not show mutagenic activity in the Ames test or
the in mouse lymphoma cell mutation assay. Netupitant did not significantly increase the
frequency of micronucleated polychromatic erythrocytes in bone marrow in the in vivo rat
micronucleus test. Based on the treatment setting, i.e., intermittent dosing in patients
receiving cancer chemotherapy, it was determined a carcinogenicity study should not be
required. The decision was based on Executive CAC recommendation/comment.
Palonosetron has been subject to a carcinogenicity evaluation. It was positive for clastogenic
effects in the Chinese hamster ovarian (CHO) cell chromosomal aberration test. The
description of the results of the 104-week carcinogenicity study in mice can be found in the
Aloxi product label and will be included in the AKYNZEO label. Palonosetron produced
increased incidences of adrenal benign pheochromocytoma and combined benign/malignant
pheochromocytoma, increased incidences of pancreatic Islet cell adenoma and combined
adenoma/carcinoma and pituitary adenoma in male rats. In female rats, it produced
hepatocellular adenoma and carcinoma and increased the incidences of thyroid C-cell
adenoma and combined adenoma and carcinoma.
See Section 10 Pediatrics of this review for a summary of the Pharmacology/Toxicology
reviewers’ recommendations regarding PREA PMRs.

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The Pharmacology/Toxicology and CMC reviewers worked in conjunction to assure that the
excipients present in the drug product were adequately qualified, and specifications were
appropriate for human safety. The Pharmacology/Toxicology reviewers determined that the
excipients identified by CMC for their review were present in amounts that provided
reasonable assurance of safety (see Section 3 CMC/Biopharmaceutics). The reviewers entered
an addendum review to clarify an error regarding two excipients initially identified as not
being present in the FDA Inactive Ingredient Search for Approved Drug Products data base.

5.

Clinical Pharmacology

I concur with the Clinical Pharmacology reviewers that there are no outstanding Clinical
Pharmacology issues that preclude approval.
An apomorphine challenge study in humans suggested that netupitant plasma concentrations
>300 ng/mL were necessary to reduce vomiting relative to placebo. (See Table 4 below for
Cmax concentrations of netupitant in healthy subjects.) In the dose finding study, Study 07-07
(key study submitted to support netupitant’s efficacy in a setting of cisplatin chemotherapy),
there was no significant dose-response relationship for achievement of CR in the delayed
phase among the 3 netupitant doses evaluated: 100, 200 and 300 mg. A concentration-response
relationship could not be explored because PK was not evaluated in the study.
The median elimination half-life of netupitant in patients with cancer was 88 hours, and 50%
and 75% of a radiolabeled netupitant dose was recovered from urine and feces over 120 hours
and 336 hours (2 weeks). The majority was recovered in feces (70.7% vs 4% in urine). The
fraction of an oral netupitant dose excreted unchanged in urine was <1%. For this reason no
dedicated renal impairment study was conducted. The product label will state in Section 8.7
Renal Impairment:
No dosage adjustment for AKYNZEO is necessary in patients with mild to moderate renal
impairment. The pharmacokinetics and safety of netupitant has not been studied in
patients with severe renal impairment, although severe renal impairment did not
substantially affect pharmacokinetics of palonosetron. The pharmacokinetics for
netupitant and palonosetron was not studied in patients with end-stage renal disease
requiring hemodialysis. Avoid use of AKYNZEO in patients with severe renal
impairment or end-stage renal disease.
The impact of hepatic impairment on netupitant pharmacokinetics was adequately evaluated to
support labeling in patients with mild or moderate hepatic impairment. Mean Cmax increased
approximately 30% in both groups, while mean AUC0-∞ increased 56% in mild impairment
and 107% in moderate. There were only 2 patients with severe hepatic impairment studied and
the Cmax varied widely between them (63% increase and 463% increase relative to healthy
subjects). The product label will state in Section 8.6 Hepatic Impairment:
No dosage adjustment for AKYNZEO is necessary for patients with mild to moderate
hepatic impairment (Child-Pugh score 5 to 8). Limited data are available with

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AKYNZEO in patients with severe hepatic impairment (Child-Pugh score >9)/ Avoid
use of AKYNZEO in patients with severe hepatic impairment.
Population PK analyses in cancer patients found that Cmax of netupitant was 35% higher in
females than males, but the AUCs were similar. Age did not influence the PK of either
netupitant or palonosetron. In dedicated PK studies, the AUC and Cmax of netupitant
increased by 25% and 36% in the elderly vs. younger adults. The AUC and Cmax of
palonosetron were 37% and 10% higher in the elderly vs. younger subjects.
Table 4 Comparison of Netupitant Systemic Exposure between younger and older subjects after a single
AYNZEO dose

Drug interactions. Neither of the components of this fixed combination product impacted the
PK of the other component, i.e., netupitant did not change the PK of palonosetron and
palonosetron did not change the PK of netupitant. In vitro studies suggested that in vivo drug
interactions are possible for CYP3A4 enzyme via inhibitory effects of netupitant and its M1
metabolite, while it is unlikely for other CYP enzymes studied in vitro. Netupitant is a P-gp
and BCRP transporter inhibitor. Palonosetron has been previously shown in in vitro studies
not to have an impact on these CYP’s; however, the effect of palonosetron on CYP2C19 has
not been evaluated. There will be a PMC to evaluate netupitant’s potential as a P-gp substrate
(see below).
With respect to drug interaction clinical studies, I will focus only on the impact of the product
on the pharmacokinetics of specific co-administered chemotherapy agents and dexamethasone
(drugs metabolized primarily by CYP3A4). Dexamethasone is used concomitantly with NK-1
and 5HT3 inhibitors as part of the antiemetic regimen. Co-administration of Akynzeo and
docetaxel resulted in 49% higher mean Cmax and 35% higher AUC of docetaxel. Etoposide’s
AUC0-t was approximately 21% higher, and the Cmax was not changed. The AUC of
cyclophosphamide increased 21% and Cmax was not changed. These data are summarized in
the table below, which is reproduced from the Clinical Pharmacology review.

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Table5. Docetaxel, Etoposide and Cyclophosphamide Plasma Exposure in Co-administration with Akynzeo
(netupitant + palonosetron) or Palonosetron Alone (Reference)

The clinical meaningfulness of these PK changes was explored by the Clinical reviewers. The
docetaxel interaction resulted in the largest changes in chemotherapeutic agent exposure. The
Clinical Pharmacology reviewers noted that the changes in docetaxel were consistent with
netupitant’s classification as a moderate inhibitor of CYP3A4, and the docetaxel product label
states that docetaxel dose adjustment is necessary only with co-administration of strong
CYP3A4 inhibitors. Co-administration with ketoconazole, a strong CYP3A4 inhibitor,
(b) (4)
increases docetaxel AUC 120% (2.2 fold). The docetaxel product label says
Comparing this to the netupitant
interaction data, the magnitude of increase in Cmax observed in the netupitant study was greater
than that observed in the ketoconazole study, however, the impact on docetaxel AUC was
markedly greater with ketoconazole compared to netupitant. The Clinical Pharmacology
reviewers pointed out that the Drug Drug Interaction Guidance states that designation of
inhibition, i.e., strong vs. moderate vs. weak, is based on AUC or CL, not Cmax.
The clinical trial safety data were explored for evidence that the drug interaction between
docetaxel and netupitant impacted safety. The patient numbers are too small to draw definitive
conclusions; however, no clear impact on safety was identified. Forty-nine patients were
identified who were treated with AKYNZEO and docetaxel. Of those, 19/49 were in a trial
that compared Akynzeo to palonosetron (Study 08-18). The remaining 30 were treated in
Study 10-29, which compared Akynzeo to aprepitant + palonosetron. In Study 08-18, 19
patients and 13 patients received docetaxel chemotherapy in the Akynzeo and the palonosetron
arms, respectively. A numerically higher rate of SAEs was observed in patients receiving
palonosetron alone (39%, 5/13) than in the Akynzeo treated patients, (21%, 4/19). In Study
10-29 (comparison of Akynzeo to aprepitant/palonosetron), 5/30 (17%) Akynzeo patients
treated with docetaxel had an SAE, compared to 1/5 (20%) of patients in the aprepitant plus

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palonosetron arm. The aprepitant label states it is also a moderate CYP3A4 inhibitor, however,
it states ?oral aprepitant did not in?uence the phannacokinetics of docetaxel.?

The reviewers also requested analyses of cytopenias based on whether a patient treated with
docetaxel was exposed to netupitant. There was no clear evidence of a meaningful impact of
the drug interaction, no persuasive evidence that netupitant resulted in a higher rate of
high grade neutropenia or thrombocytopenia when co-administered with docetaxel. Although
the rates of Grade 3 and 4 neutropenia were numerically higher in the netupitant group, sample
size is too small to support meaningful conclusions. See the tables below, which summarize
the hematology data for the docetaxel subgroups in Study 08-18 and Study 10-29.

Table 6: Study NETU-08-18 Hematology Grade 3 or 4 changes During Cycle 1 in the Docetaxel treated

 

 

 

 

Subgroup
FDC PALO Alone
(N=l9) (N=l3)
Parameter 11 11 
Leukocytes: VVBC decreased
Number of patients with result 19 13
Any severe grade 9 (47-4) 4 (30-8)
Grade 3 1 (5-3) 2 (15-4)
Grade 4 8 (411) 2 (15-4)
Neutrophils: neutrophil count
decreased
Number ot?patients with result 19 13
Any severe grade I 1 (57-9) 5 (38-5)
Grade 3 4 (21.1) 1 (7.7)
Grade 4 7 (36-8) 4 (30.8)
Hemoglobin: anemia
Number ot?patients with result 19 13
Any severe grade 0 0
Platelets: platelet count decreased
Number of patients with result 19 13
Any severe grade 0 0
Grade 3 0 0
Grade 4 0 0
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Table 7: Study Hematology Grade 3 or 4 changes During Cycle 1 in the Docetaxel treated

 

 

 

Subgroup
DC Aprepitant/Palo

Parameter 
Leukocytes: VVBC decreased
Number ofpatients with result 30 5
Any severe grade 5 16.7) 1 (20.0)
Grade 3 4 (13.3) 1 (20.0)
Grade 4 1 (3-3) 0
Neutrophils: neutrophil count
decreased
Number of patients with result 30 5
Any severe grade 3 (10.0) 2 (40.0)
Grade 3 (3.3) 2 (40.0)
Grade 4 2 (6.7) 0
Hemoglobin: anemia
Number of patients with result 30 5
Any severe grade 0 
Platelets: platelet count decreased
Number ofpatients with result 30 5
Any severe grade 0 0
Grade 3 0 0
Grade 4 0 

 

The Clinical reviewer presented a pooled analysis of patients exposed to docetaxel across the

trials, reproduced below, which doesn?t take into consideration the severity of cytopenias or

infections. However, the table summarizes the distribution of any SAEs across treatment arm

in this subgroup, as well as ?serious? diarrhea. There was one case of serious diarrhea in
docetaxel exposed patients treated with Akynzeo and none in the other antiemetic arms.

Table 8 SAEs and TEAEs in the Docetaxel chemotherapy subgroup, by treatment arm, across trials.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Palo IV 0.25 Palo OS 0.50 FDC Apre plus Palo
N-l3 . ?-37 N49 N-S
C-l3 C-77 C-l96 
Number of at least
one SAE 4 (30.8) 5 (13.5) 10 (20.4) 1 (20.0)


1%?35353?1? 2 (15.4) 3 (8.1) 10 (20.4) -
Anaemia - - 5 (10 3) -
Leukopema - 1 (2.7) 7 (14.3) -
Neutropenia (7.7) 2 (5.4) 6 (12.2 -
Thronbocytopenia 1 (7.7) 1 (2.7) 4 (8.2) -
Sen'ous Diarrhoea - - 1 (2.0) -
Infections 1 (7.7) 1 (2.7) 9 (18.4) -

- number of patients

C-number of cycles

The percentage is calculated based on 

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I also contacted the clinical review group in the Oncology Division that manages docetaxel to
confirm that no new safety issue had been identified related to interactions with moderate
CYP3A4 inhibitors. The team leader confirmed that there is currently no plan to alter the
docetaxel label regarding moderate CYP3A4 inhibitors. The Akynzeo label will state in
Section 7.1 Effects of AKYNZEO on Other Drugs:
Interaction with chemotherapeutic agents
The systemic exposure of chemotherapy agents metabolized by CYP3A4 can increase when
administered with AKYNZEO. Chemotherapy agents that are known to be metabolized by
CYP3A4 include docetaxel, paclitaxel, etoposide, irinotecan, cyclophosphamide, ifosfamide,
imatinib, vinorelbine, vinblastine, and vincristine [see Clinical Pharmacology)]. Caution and
monitoring for chemotherapeutic related adverse reactions are advised in patients receiving
chemotherapy agents metabolized primarily by CYP3A4.
Emend labeling includes dexamethasone dose instructions as part of the Dosage and
Administration section because it is part of the overall antiemetic regimen (along with a 5HT3
inhibitor). The Akynzeo efficacy trials included dexamethasone in the antiemetic regimen as
well. Like Emend, netupitant increases dexamethasone exposure due to CYP3A4 inhibition.
Drug interaction studies determined that the AUC 0-24 of dexamethasone increased 1.7 fold
with coadministration of netupitant. CYP3A4 inhibition persisted after a single netupitant dose
for at least 4 days, and the dexamethasone AUC 84-∞ was 2.4 higher. Dexamethasone Cmax
increased 1.2 fold on Day1 and 1.7 fold on Day 2 and Day 4. See data summarized in Table 9
below, which is reproduced from the Clinical Pharmacology review. Based on these data,
similar to the Emend regimen, the dexamethasone doses administered in the Akynzeo clinical
trials were reduced from the usual antiemetic regimen dose to 12 mg (reduced from 20 mg) on
Day 1 and to 8 mg once a day (reduced from twice a day ) on Days 2-4 (for highly emetogenic
chemotherapy). The Dosage and Administration Section of the Akynzeo label will reflect this
dexamethasone dosing schedule for cisplatin based chemotherapy. For anthracycline plus
cyclophosphamide chemotherapy and non-highly emetogenic chemotherapy, the
dexamethasone dose for co-administration will be 12 mg on Day 1 only.
Table 9 Mean Ratio PK Parameters for Dexamethasone with and without concomitant netupitant 300 mg
(ratio: with/without)

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Because CYP 3A4 inhibition appeared to persist even by Day 4, and no data were available to
document the impact beyond Day 4, the Clinical Pharmacology reviewers requested that the
applicant estimate the [I]/Ki for CYP3A4 inhibition by netupitant and its metabolites, beyond
Day 4. The estimation suggested that the drug interaction via CYP 3A4 inhibition was less
likely on Day 6; however, it could not be entirely ruled out. Based on this, Section 7.1 Effects
of AKYNZEO on Other Drugs will state:
Dexamethasone
A two-fold increase in the systemic exposure of dexamethasone was observed 4 days
after single dose of netupitant. The duration of the effect was not studied beyond 4
days. Administer a reduced dose of dexamethasone with AKYNZEO.
In addition, there will be a PMC to evaluate duration of Akynzeo’s inhibition of CYP3A4 (see
below).
QT evaluation. The Clinical Pharmacology reviewer and QT Interdisciplinary Review Team
(IRT-QT) determined there was no significant QTC interval prolongation observed with a
combination of netupitant 600 mg and palonosetron 1.5 mg in healthy subjects. (QTIRT
consult was entered in DARRTS under IND 73493 in January 2010.) The 600 mg netupitant
dose was selected for study based on an assumption that the to-be-marketed dose of netupitant
would be 200 mg, i.e., the supratherapeutic dose would be 3-fold higher than the assumed tobe-marketed dose. However, the applicant ultimately chose to develop a higher netupitant
dose, 300 mg. Therefore, the supratherapeutic dose studied in the tQT study is 2-fold higher
than the to-be-marketed dose. The Clinical Pharmacology reviewers determined that an
additional tQT study of a higher netupitant dose (i.e., >600 mg) is not necessary, as the Cmax
of the 600 mg dose covers the Cmax observed in patients with moderate hepatic impairment
and in healthy subjects coadministered a strong CYP3A4 inhibitor. The upper bound of the
confidence interval for the change in QT interval with the 600 mg dose was <10 ms; whereas
the upper bound for moxifloxacin 400 mg was 16.3 ms. These data are summarized in the
table below, which is reproduced from the Clinical Pharmacology review.
Table 10: Point Estimates and 90% Confidence Intervals for ∆∆QTcF(ms) from tQT Study

Summary. I concur with the Clinical Pharmacology reviewers’ labeling recommendations
and I concur with their recommendation for the following PMCs:

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2769-4

In vivo drug interaction study to evaluate the duration of inhibitory effects of
Akynzeo (netupitant and palonosetron) on CYP3A4 enzyme activity beyond
4 days after Akynzeo (netupitant and palonosetron) administration.

2769-5 In vitro study to evaluate the potential of netupitant to act as a substrate for Pgp transporter in a bi-directional transport assay system.

6. Clinical Microbiology
Not applicable because palonosetron is not an antimicrobial product.

7. Clinical/Statistical-Efficacy
The Clinical and Statistical Reviewers have concluded that the applicant provided substantial
evidence of efficacy for the fixed combination product Akynzeo (netupitant plus palonosetron)
for the proposed indications for prevention of CINV. The clinical development program was
designed with substantive input from FDA to assure there would be adequate evidence to
establish the contribution of each component drug to treatment effect. The development
program followed what has become a very traditional approach for antiemetic products
intended to treat CINV, i.e., separate clinical trials were conducted in the setting of what has
been considered HEC and what has been traditionally considered MEC. The Division has
requested that trials evaluate efficacy and safety in repeat dosing to support labeling for repeat
dosing. The following key trials established the efficacy of Akynzeo, and established the
contribution of each of its component drugs to the treatment effect. See Section 2 Background
for regulatory history regarding the primary endpoints of key interest to FDA.

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Table 11

Overview of Key Trials Providing Efficacy Data for the
Netupitant/Palonosetron Fixed Combination (Akynzeo) Program

Trial
No.

Design

NETU
-07-07

Doubleblind,
randomized
(1:1:1:1:1)
parallel
group

No. of Patients
randomized/treated/F
AS
PALO oral
136/136/136*

Duration

Indication

Singlecycle

HEC

Single and
Multiple
cycles

MEC∂

CR
Delayed
phase (25120 hr)#

Pivotal evidence
of FDC efficacy
in MEC

Multiple
cycles

MEC and
HEC

Safety

Supportive
Evidence
of
multicycle
efficacy in MEC
and HEC

Singlecycle

HEC

CR Acute
phase (024 hr)

Establishes oral
palonosetron
efficacy in
HEC and its
contribution to
Akynzeo
treatment effect
in HEC

PALO + NETU 100
135/135/135*
PALO +NETU 200
142/138/137*
PALO +NETU 300
143/136/135*

Primary
Endpoint

Role of Study for
efficacy
demonstration
CR Overall Key evidence of
phase (0contribution of
120 hr)
netupitant to the
efficacy of
Key
Akynzeo in
endpoint of setting of HEC
interest for (cisplatin based
FDA= CR in chemotherapy)
delayed
phase (25120 hours)

Aprepitant +Onda
138/134/--

NETU
-08-18

NETU
-10-29

PALO10-01

APPEARS THIS
WAY ON
ORIGINAL

Doubleblind,
randomized
(1:1)
parallel
group
Doubleblind,
randomized
(3:1)
parallel
group
Doubleblind,
randomized
(1;1)
parallel
group

Total
694/679/543*
PALO oral
726/725/725
Akynzeo
729/725/724
Total
1455/1450/1449
Akynzeo
309/308/309
Aprepitant + PALO oral
104/104/103
Total
413/412/412
PALO oral
371/370/369
PALO IV
372/369/369
Total
743/739/738

*For NETU-07-07 the numbers of patients are randomized/number treated/MFAS
# Key secondary endpoints: CR acute phase (0-24 hr), overall phase (0-120 hr)
∂ The chemotherapy administered in this study was anthracycline plus cyclophosphamide
Akynzeo= Netupitant/Palonosetron Combination Capsule (palonosetron 0.50 mg/netupitant 300 mg)
Dexamethasone was included in all dose regimens.
P LO P l
NETU N
i
O d O d

Refer to the Statistical and Clinical reviews for more detailed information regarding the FDA’s
evaluation of the efficacy data from these trials. I will focus on a few key review issues.

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Study 07-07 established the contribution of netupitant to efficacy in the setting of cisplatin
based chemotherapy. The major efficacy issue was evaluation of the impact of the study
conduct issues identified by the applicant at Site 120. This trial was originally designed as a
netupitant dose ranging trial to identify the phase 3 dose. When FDA noted this trial had the
potential to establish the contribution of the netupitant component of Akynzeo to its efficacy in
the setting of cisplatin based chemotherapy, HEC, the applicant further audited the trial sites.
Protocol deviations at Site 120 raised concerns that caused the applicant to present the efficacy
data from Study 07-07 with and without inclusion of that site. The applicant determined that
elimination of Site 120 data did not impact the statistically significant efficacy results favoring
the combination in the 300mg + palonosetron 0.5 mg arm relative to palonosetron 0.5 mg. The
FDA Statistical reviewer didn’t agree and found that when the data were analyzed with
methods considered appropriate by FDA, the analysis that excluded Site 120 was not
statistically significant favoring the combination. This difference in conclusions prompted
multiple sensitivity analyses which produced varying outcomes, some with statistically
significant results favoring the combination and some not.
In order to understand the importance of inclusion/exclusion of Site 120 for the purposes of
understanding the strength of evidence provided by this trial, the Clinical reviewers requested
detailed information on the violations that had caused the applicant’s concerns. There were 3
violations in the palonosetron only arm considered major by the applicant and 10 minor. In
the netupitant 300 mg plus palonosetron arm, there were also 3 major and 15 minor violations.
The Clinical reviewers found that the major violations were related to co-administration of
another antiemetic and the minor violations were related to a patient having taken a prior dose
of dexamethasone within the study window prior to entry, a period when a patient was not to
have received dexamethasone.
The reviewers confirmed with the applicant that these patients with dexamethasone violations
had still received the dexamethasone dose they should have received as part of antiemetic
therapy. Based on this, these minor violations would not be expected to have a significant
efficacy effect. The vast majority of concomitant antiemetic violations were concomitant
administration of ondansetron on Day 1 of chemotherapy. I concur with the Clinical
reviewers’ conclusions that co-administration of another 5HT-3 inhibitor on Day 1 of
chemotherapy would not be expected to impact efficacy. Even if it had a theoretical
psychological effect on patients, this effect would be expected to be limited to the first 24
hours (prior to the delayed phase, the primary period of interest for the NK-1 component). It
is also important to note that there were equal numbers of these violations in the two arms of
interest. (There was a numerically higher number of major violations, i.e., 5, in the 200 mg
netupitant arm; however this arm was not the focus of the efficacy analysis.)
Ultimately, the reviewers concurred that the full analysis set, without exclusion of Site 120,
was most appropriate for efficacy analysis of Study 07-07. This analysis established the
efficacy of netupitant in the delayed and acute phases in the setting of cisplatin chemotherapy.
The analysis that includes Site 120 will be presented in product labeling (see table below).

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Table 12 Proportion of Patients Responding by Treatment group and Phase in Study 07-07
AKYNZEO
300 mg netupitant/
0.5 mg palonosetron
N=135

Palonosetron
0.5 mg
N=136

%

%

Delayed Phase†

90.4

80.1

0.032

Acute Phase‡

98.5

89.7

0.002

89.6

76.5

0.003

p-value*

COMPLETE RESPONSE

§

Overall Phase

*Adjusted p-values for multiple comparisons using Cochran-Mantel-Haenszel test, stratified by gender.
†Delayed phase: 25 to 120 hours post-cisplatin treatment.
‡Acute phase: 0 to 24 hours post-cisplatin treatment.
§Overall: 0 to 120 hours post-cisplatin treatment.

Study 08-18 established the contribution of netupitant to efficacy of Akynzeo in the delayed
and acute phases, in the setting of anthracycline plus cyclophosphamide (AC) chemotherapy.
The latter has been traditionally designated MEC in previous CINV development plans,
including oral palonosetron 0.5 mg. Palonosetron 0.5 mg is a component (in addition to
netupitant) of Akynzeo. Therefore, Study 08-18 was adequate to establish the contribution of
each component of Akynzeo for this chemotherapy regimen. The efficacy data from Study 0818 are summarized in the table below.
Table 13: Proportion of Patients Responding by Treatment Group and Phase – Cycle 1 in Study 08-18
AKYNZEO
300 mg netupitant/
0.5 mg palonosetron

Palonosetron
0.5 mg

N=724

N=725

%

%

p-value*

76.9

69.5

0.001

88.4

85.0

0.047

74.3

66.6

0.001

PRIMARY ENDPOINT
COMPLETE RESPONSE
Delayed Phase†
MAJOR SECONDARY ENDPOINTS
COMPLETE RESPONSE
Acute Phase‡
§

Overall Phase

*p-value from Cochran-Mantel-Haenszel test, stratified by age class and region.
‡

Acute phase: 0 to 24 hours after anthracycline and cyclophosphamide regimen.
Delayed phase: 25 to 120 hours after anthracycline and cyclophosphamide regimen.
§
Overall: 0 to 120 hours after anthracycline and cyclophosphamide regimen.
†

Study 10-10 established the contribution of the oral palonosetron 0.5 mg component of Akynzeo
to its efficacy in the setting of cisplatin based chemotherapy. This trial was necessary because
oral palonosetron does not carry a HEC indication. This noninferiority trial in the setting of
cisplatin based chemotherapy (≥70 mg/kg) compared oral palonosetron 0.5 mg to IV

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palonosetron 0.25 mg. IV palonosetron 0.25 mg does have an indication for prevention of CINV
in the acute phase in the setting of cisplatin based chemotherapy. Noninferiority of oral
palonosetron to IV palonosetron was established for the acute phase in this trial. The applicant’s
delayed phase noninferiority analysis was not considered valid and relevant as the treatment
effect of palonosetron IV in the delayed phase has not been established in the setting of cisplatin
based chemotherapy. In the oral palonosetron arm, 89.4% of patients achieved a CR in the acute
phase compared to 86.2% of patients in the intravenous palonosetron arm, with a difference of
3.21% (99% CI: -2.74% to 9.17%). Non-inferiority of oral palonosetron versus intravenous
palonosetron was demonstrated since the lower limit of the two-sided 99% CI for the difference
in proportions of patients with CR was greater (i.e., closer to zero) than the pre-defined
non-inferiority margin set at -15%.
Efficacy with repeat dosing. I agree with the reviewers that the data from Study 10-29 and
the repeat dose data from Study 08-18, support the efficacy of Akynzeo in repeated cycles of
chemotherapy.
Special population exploratory analyses. In the course of evaluating the special population
subset analyses for purposes of product labeling, it was noted that the applicant had utilized an
age cut point of 55 years, which is not the cut off utilized for inclusion in Section 8.5 Geriatric
Use. It appeared the applicant had focused on age 55 years for subgroup analysis because
publications in the literature report differences in propensity for CINV in individuals younger
than 55 years relative to those older. I will summarize the efficacy data by age for each age
cut point (55 or 65 years) for Study 08-18, Study 07-07 and Study 10-10 below. There
appeared to be a difference in efficacy for older patients in the setting of AC chemotherapy
(Study 08-18) compared to younger patients, in both the 55 year and the 65 year cut point
analyses. Older patients seemed to demonstrate a lower netupitant treatment effect in the
delayed phase, and the diminution appeared to be related to a higher palonosetron delayed
phase response in the older patients.
Table 14: Study 08-18 (AC Chemotherapy) Efficacy Analysis by Age: 55 year Cut point Age
analysis
Age <55 Years
Complete Response Cycle 1 Delayed Phase (25-120 hours)
Responder, n (%)
Difference from PALO alone, %
Complete Response Cycle 1 Acute Phase (0-24 hours)
Responder, n (%)
Difference from PALO alone, %
Complete Response Cycle 1 Overall Phase (0-120 hours)
Responder, n (%)
Difference from PALO alone, %
Age >=55 Years
Complete Response Cycle 1 Delayed Phase (25-120 hours)
Responder, n (%)
Difference from PALO alone, %
Complete Response Cycle 1 Acute Phase (0-24 hours)
Responder, n (%)
Difference from PALO alone, %

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NETU/PALO FDC(N=724)
N=371

PALO alone(N=725)
N=372

279 (75.2%)
12.8%

232 (62.4%)

313 (84.4%)
5.1%

295 (79.3%)

266 (71.7%)
41.8%

217 (29.9%)

N=353
278 (78.8%)
1.7%

N=353
272 (77.1%)

327 (92.6%)
1.7%

321 (90.9%)

 Division Director Review

Complete Response Cycle 1 Overall Phase (0-120 hours)
Responder, n (%)
272 (77.1%)
266 (75.4%)
Difference from PALO alone, %
-3.7%
Note: The sponsor indeed conducted the analysis for the delayed phase and the results were the same as shown.

Table 15: Study 08-18 Efficacy Analysis by Age 65 year Cut Point Age analysis:
NETU/PALO
N=608
Age <65 Years
Complete Response Cycle 1 Delayed Phase (25-120 hours)
Responder, n (%)
463 (76.2%)
Difference from PALO alone, %
8.9%
Complete Response Cycle 1 Acute Phase (0-24 hours)
Responder, n (%)
531 (87.3%)
Difference from PALO alone, %
3.8%
Complete Response Cycle 1 Overall Phase (0-120 hours)
Responder, n (%)
446 (73.4%)
Difference from PALO alone, %
9.2%
Age >=65 Years
N=116
Complete Response Cycle 1 Delayed Phase (25-120 hours)
Responder, n (%)
94 (81%)
Difference from PALO alone, %
0.5%
Complete Response Cycle 1 Acute Phase (0-24 hours)
Responder, n (%)
109 (94.0%)
Difference from PALO alone, %
2.1%
Complete Response Cycle 1 Overall Phase (0-120 hours)
Responder, n (%)
92 (79.3%)
Difference from PALO alone, %
0.4%

PALO alone
N=602
405 (67.3%)
503 (83.6%)
386 (64.1%)

N=123
99 (80.5%)
113 (91.9%)
97 (78.9%)

Study 07-07: cisplatin based chemotherapy
In contrast, in the setting of cisplatin based chemotherapy, i.e., Study 07-07, there was an
apparent difference in efficacy based on age that varied depending on the age cut point used
for analysis. When 65 years was the cut point, the dose response in efficacy attributable to
netupitant in the delayed phase appeared to be limited to the elderly population. Note that the
sample sizes are quite small, particularly in the older age groups in the 65 year cut point
analysis. In both analyses (55 and 65 years), there was an apparent difference between the
older and younger subgroups in the point estimate for delayed phase complete response (i.e.,
higher rate in the older than younger subgroup within each cut point analysis). However, this
was not seen in the age subgroup exploratory analysis of the delayed phase of Study 10-01
(see later presentation of Study 01-01 age analysis), a trial in which patients were also treated
with cisplatin.

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Table 16: Study 07-07 Efficacy Analysis by Age: 55 year Cut point Age analysis
PALO alone
PALO+NETU
PALO+NETU
(N=136)
100 mg (N=135) 200 mg (N=142)
N=67
N=63
N=67
Age < 55 Years
Delayed Phase (25-120 hours)
Number (%) of Subjects
50 (74.6%)
55 (87.3%)
59 (88.1%)
Difference from PALO alone
12.7%
13.5%
Acute Phase (0-24 hours)
Number (%) of Subjects
58 (86.6%)
59 (93.7%)
58 (86.6%)
Difference from PALO alone
7.1%
0%
Overall Phase (0-120 hours)
Number (%) of Subjects
47 (70.1%)
54 (85.7%)
54 (80.6%)
Difference from PALO alone
15.6%
10.5%
N=69
N=72
N=70
Age >=55 Years
Delayed Phase (25-120 hours)
Number (%) of Subjects
59 (85.5%)
67 (93.1%)
66 (94.3%)
Difference from PALO alone
7.6%
8.8%
Acute Phase (0-24 hours)
Number (%) of Subjects
64 (92.8%)
67 (93.1%)
69 (98.6%)
Difference from PALO alone
0.3%
5.8%
Overall Phase (0-120 hours)
Number (%) of Subjects
57 (82.6%)
64 (88.9%)
66 (94.3%)
Difference from PALO alone
6.3%
11.7%

Table 17: Study 07-07 Efficacy Analysis by Age: 65 year Cut point Age analysis
PALO alone
PALO+NETU
PALO+NETU
100 mg
200 mg
N=116
N=112
N=117
Age < 65 Years
Delayed Phase (25-120 hours)
Number (%) of Subjects
91 (78.4%)
101 (90.2%)
106 (90.6%)
Difference from PALO alone
11.7%
12.2%
Acute Phase (0-24 hours)
Number (%) of Subjects
104 (89.7%)
104 (92.9%)
107 (91.5%)
Difference from PALO alone
3%
1.8%
Overall Phase (0-120 hours)
Number (%) of Subjects
87 (75%)
98 (87.5%)
101 (86.3%)
Difference from PALO alone
12.5%
11.3%
N=20
N=23
N=20
Age >=65 Years
Delayed Phase (25-120 hours)
Number (%) of Subjects
18 (90%)
21 (91.3%)
19 (95%)
Difference from PALO alone
1.3%
5%
Acute Phase (0-24 hours)
Number (%) of Subjects
18 (90%)
22 (95.7%)
20 (100%)
Difference from PALO alone
5.7%
10%
Overall Phase (0-120 hours)
Number (%) of Subjects
17 (85%)
20 (87%)
19 (95%)
Difference from PALO alone
2%
10%

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PALO+NETU
300 mg(N=143)
N=73
66 (90.4%)
15.8%
71 (97.3%)
10.7%
65 (89.0%)
18.9%
N=62
56 (90.3%)
4.8%
62 (100%)
7.2%
56 (90.3%)
7.7%

PALO+NETU
300 mg
N=115
102 (88.7%)
10.2%
113 (98.3%)
8.6%
101 (87.8%)
12.8%
N=20
20 (100%)
10%
20 (100%)
10%
10 (100%)
15%

 Division Director Review

Study 10-01: Noninferiority trial in cisplatin based chemotherapy setting.
In the IV palonosetron 0.25 mg vs. oral palonosetron 0.5 mg trial, when the younger age cut
point was used there is a sizeable numerical difference between arms favoring the oral dose
form in the younger age group relative to the older group. This difference diminished in the
analysis that used 65 years as the cut point.
Table 18 Statistical Reviewer’s Subgroup Analysis Results for CR in the Acute Phase on
FAS Population for Study PALO-10-01
Oral PALO
(N=369)
N=124
Age <55 Years
Complete Response Cycle 1 Acute Phase (0-24 hours)
Responder, n (%)
107 (86.3%)
Difference from PALO alone, %
9.1%
N=245
Age >=55 Years
Complete Response Cycle 1 Acute Phase (0-24 hours)
Responder, n (%)
223 (91%)
Difference from PALO alone, %
0.11%

Table 19 Statistical Reviewer’s Subgroup Analysis Results for CR in the Acute Phase on
FAS Population for Study PALO-10-01
Oral PALO
(N=369)
N=272
Age <65 Years
Complete Response Cycle 1 Acute Phase (0-24 hours)
Responder, n (%)
243 (89.3%)
Difference from PALO alone, %
4.6%
N=97
Age >=65 Years
Complete Response Cycle 1 Acute Phase (0-24 hours)
Responder, n (%)
87 (89.7%)
Difference from PALO alone, %
-1.2%

I.V. PALO
(N=369)
N=127
98 (77.2%)
N=242
220 (90.9%)

I.V. PALO
(N=369)
N=281
238 (84.7%)
N=88
80 (90.9%)

The following 65 year cut point data from the exploratory analysis of the delayed phase in
Study 10-01 provides point estimates of response to oral palonosetron in the delayed phase in
the setting of cisplatin based chemotherapy for purposes of comparison to the oral
palonosetron delayed phase results from Study 07-07 above. The response rates in the
subgroup older than 65 years in Study 10-01 are very similar to its <65 years subgroup, and
are similar to the point estimates associated with the <65 years subgroup of Study 07-07
treated with palonosetron alone.
Table 20. Exploratory Subgroup Analysis Results for CR in the Delayed Phase of Study PALO-10-01 using
a 65 year cut point
Oral PALO
I.V. PALO
(N=369)
(N=369)
N=272
N=281
Age <65 Years
Complete Response Cycle 1 Delayed Phase (25-120 hours)
Responder, n (%)
208 (76.5%)
212 (75.4%)
Difference from PALO alone, %
1%
N=97
N=88
Age >=65 Years
Complete Response Cycle 1 Acute Phase (25-120 hours)
Responder, n (%)
73 (75.3%)
64 (72.7%)
Difference from PALO alone, %
2.5%

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Section 8.5 Geriatric Use of the label will state:
Of the 1169 adult cancer patients treated with AKYNZEO in clinical studies, 18%
were aged 65 and over, while 2% were aged 75 years and over. The nature and
frequency of adverse reactions were similar in elderly and younger patients.
Exploratory analyses of the impact of age on efficacy were performed in the two trials
that compared AKYNZEO to palonosetron [see Clinical Studies]. In Study 1 in
patients treated with cisplatin chemotherapy, among the patients less than age 65 years,
(b) (4)
116 were treated with palonosetron alone and
were treated with AKYNZEO.
Among the patients 65 years or older, 20 were treated with palonosetron alone and 20
were treated with AKYNZEO. The difference in Complete Response (CR) rates
between palonosetron alone and AKYNZEO was similar between the two age groups
in both the acute and delayed phases. In Study 2 in patients treated with anthracycline
plus cyclophosphamide chemotherapy, among the patients less than age 65 years, 602
were treated with palonosetron alone and 608 were treated with AKYNZEO. Among
the patients 65 years or older, 123 were treated with palonosetron alone and 116 were
treated with AKYNZEO. The difference in CR rates between AKYNZEO and
palonosetron alone (4% in <65 years and 2% in >65 years) was similar between the
two age groups in the acute phase. In the delayed phase, the difference in CR rates
between AKYNZEO and palonosetron alone (9% in <65 years and 1% in ≥ 65 years)
was numerically higher in patients <65 years. This difference between age groups in
the delayed phase of Study 2 may be explained, in part, by higher CR in the delayed
phase associated with palonosetron alone in the older age group (81%) relative to the
younger patients treated with palonosetron alone (67%).

Summary.
The applicant has established the efficacy of Akynzeo for acute and delayed phases of CINV.
The trials submitted for review establish the contribution of each component to the proposed
indication. Palonosetron contributes to prevention of CINV in the acute phase. The
netupitant component contributes to prevention of CINV in both the acute and delayed
phases.
As discussed in Section 2 Background of this review, in light the changes in designation of
doxorubicin plus cyclophosphamide chemotherapy to HEC, the indication will state:
AKYNZEO is indicated for the prevention of acute and delayed nausea and vomiting
associated with initial and repeat courses of cancer chemotherapy, including, but not
limited to, highly emetogenic chemotherapy. AKYNZEO is an oral combination of
palonosetron and netupitant: palonosetron prevents nausea and vomiting during the acute
phase and netupitant prevents nausea and vomiting during both the acute and delayed
phase after cancer chemotherapy.

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8. Safety

The NDA included 1538 patients and healthy volunteers who had been exposed to Akynzeo,
including 1169 who had been exposed in the setting of one of 3 active controlled trials.
Among those patients, 782 had been exposed to at least 4 cycles, 321 were exposed for at least
6 cycles. (Dr. Snow?s review contains a table that states 317 patients were exposed for at least
6 cycles, however, the ISS re?ects that 321 patients were exposed to Akyzneo for at least 6
cycles. The applicant clari?ed that the table in Dr. Snow?s review refers to completion of an
entire chemotherapy cycle and the ISS counts exposru?e to Akynzeo at the beginning of the
cycle. For this reason the product label will re?ect 321.) The maximum number of cycles
patients received in Study 08-18 was 8 In Study 10-29, the maximlun number of cycles
of exposure was 14 Although these nrunbers do not represent analyses based on time
exposed, e. munber treated for 1 year, the product is administered intermittently with
chemotherapy cycles, which are usually scheduled on a every 3 or 4 week basis. Section 6 of
the Emend product label indicates that the maximum number of exposures in the trials
supporting its approval ranged from 4 to 6 cycles. The reviewers identi?ed no safety issues
that precluded approval or prompted a recommendation to require a postmarketing safety
study/trial (PMR) or a REMS.

A particular challenge in the safety review of antiemetics for INV is that patients are treated
with concomitant chemotherapeutic agents that have signi?cant associated toxicities. For this
reason, even numeric imbalances of speci?c events between the Akynzeo arm and a control
arm are dif?cult to attribute to study drug, as the imbalance could merely re?ect a random
imbalance in one of many wide ranging toxicities associated with chemotherapeutic agents
and/or the rmderlying malignancy. The applicant proposed to (4)

The review
team concluded that given the potential differences between the populations studied in the
randomized, controlled trials (including rmderlying malignancy) and the chemotherapy
regimens studied in each trial (AC in 08-18; cisplatin in Study 07-07 and Study 10-01), the
safety data in the label should be presented separately by trial. In addition, the reviewers
recommended that, consistent with FDA Guidance, the M4) should not be
the sole basis for inclusion of events. Instead, the reviewers recommended that the events
reported at a higher rate in the Akynzeo arm than the control arm (palonosetron in Study 07-07
and Study 10-01) should be reported in the label?s Section 6.

Because the product is a ?xed combination of netupitant and palonosetron, the review team
recommended including the safety data from the noninferiority trial Study 10-10, which only
evaluated palonosetron (IV vs. oral).

I will limit my review discussion to two speci?c safety issues, cardiac safety and hepatic
safety data. Refer to the Clinical and DTL reviews for a more comprehensive summary of
the safety data presented in this NDA.

Cardiac Safety. The Agency was aware of nonclinical data in another (different) 

inhibitor development program that demonstrated cardiac necrosis. This was n_0t noted in the

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nonclinical studies of netupitant; however, there were nonclinical data available that
documented drug levels in the myocardium of dogs. As noted in Section 2 Background of this
review, the Division recommended that repeat dosing of Akynzeo should be evaluated in the
setting of a control arm, and should specifically be evaluated in the setting of cardiotoxic
chemotherapy to permit assessment of a signal of potential additive/synergistic cardiotoxicity.
Study 08-18, was a multicycle study that included doxorubicin chemotherapy. The applicant
evaluated baseline ECGs, cardiac ejection fractions and troponin levels. These were repeated
at end of study to evaluate for changes and differences between study arms. There was no
definitive signal noted. There was no clear difference between arms in cardiac treatment
emergent adverse events. See table below, which is reproduced from the Clinical Review.
Table 21. Cardiac treatment emergent adverse events in Study 08-18

Cardiac Disorder
Arrhythmia
Atrial Fibrillation
Cardiac failure
Cardiomyopathy
Cytotoxic cardiomyopathy
Metabolic cardiomyopathy
Tachycardia

Akyzneo
N=197

Palonosetron
N=191

5 (2.5%)
1 (0.5%)
0
1 (0.5%)
1 (0.5%)
0
1 (0.5%)

3 (1.6%)
0
1 (0.5%)
1 (0.5%)
1 (0.5%)
0

In the multi-cycle study that compared Akynzeo to aprepitant plus palonosetron, Study 10-29,
there was also no cardiac signal noted. Treatment emergent events in similar categories to
those identified by the Clinical reviewer for Study 08-18 are summarized in the table below,
which is derived from the applicant’s study report Table 14.3.1.1.2.1.
Table 22. Cardiac treatment emergent adverse events in Study 10-29

Cardiac Disorder
Atrial Fibrillation
Cardiopulmonary failure
Cardiac arrest
Myocardial ischaemia
Metabolic cardiomyopathy
Tachycardia
Sinus tachycardia

Akyzneo
N=308

Aprepitant/palonosetron
N=104

2 (0.6%)
3 (1%)
1 (0.3%)
3 (1%)
1(0.3%)
5 (1.6%)
7 (2.3%)

0
0
0
1 (1%)
1 (1%)
3 (3%)
2 (1.9%)

Evaluation of ECG changes over multiple cycles revealed no evidence of meaningful
differences between the two arms. There was a numerically higher rate of sinus tachycardia
(25% vs. 21%), ectopic supraventricular rhythm (2% vs. 1 %), premature atrial complexes
(12% vs. 10%, first degree AV block (7% vs. 5%), and flat T waves (34% vs. 30%) in the

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Akynzeo group in a summary analysis of ECG changes that were noted in at least 1% or
greater.
Left ventricular ejection fractions were assessed at baseline and at end of study in Study 08-18.
The change from baseline in EF, based on medians from MUGA, was similar between arms:4.45% in the Akynzeo arm and -5.0% in the palonosetron arm.
Troponin monitoring was performed in both multi-cycle trials, i.e., Study 08-18 and Study1029. All patients in Study 08-18 and some patients in Study 10-29 received anthracycline
chemotherapy. Troponin levels were obtained during screening for cycle 1 and on days 2 and
6 of each subsequent cycle. If a cTNI level ≥0.12 ng/ml was detected, patients had a
cardiovascular functional assessment. If the cTNI was ≥0.5 ng/mL a functional assessment
was performed and the patient was withdrawn from study. The following table, reproduced
from the Clinical review, is an integrated summary of the troponin data from these two
controlled, multi-cycle trials. No difference was noted between Akynzeo and the controls.
Table 23 Proportions of Patients with Documented Troponin Elevations in the Multicycle Controlled Trials
– All Cycles.

The Clinical reviewer noted that most patients who had an elevated troponin level did not have
a significant change in cardiac function, defined as change in ejection fraction <10%. There
were 6 patients in Study 08-18 who had an elevated troponin and a change in LVEF of ≥10% 4 treated with Akynzeo and 2 with palonosetron alone. The Akynzeo arm patients were
detected at Cycle 6 of chemotherapy or “post withdrawal,” while the palonosetron patients
were detected at Cycle 5. The largest change occurred in an Akynzeo treated patient, whose
ejection fraction (EF) dropped 39% to an EF of 21%. The lowest documented EF in the
palonosetron treated patients who had an elevated troponin value was 47%, in a patient whose
EF dropped 22%. There was only one patient in the multi-cycle trial NETU10-29 with a
significant drop in EF and a concurrent troponin elevation, and this occurred on the aprepitant
arm. See the table below, which is reproduced from the Clinical review.
Table 24 Patients with Both Elevated Troponin and Decrease in LVEF of ≥10 in Study 08-18 and Study 1029.

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Hepatic safety. Evaluation of liver safety was of particular interest in light of the netupitant
non-clinical study findings of phospholipidosis. In her review of laboratory abnormalities in
the safety database, the Clinical reviewer stated that there “were no major differences in
laboratory findings between treatment groups for hematology or chemistry, as shown in Table
83.” That table includes ALT, AST and Alkaline phosphatase across the major trials. The
relevant section of the table is reproduced below.
Table 25. Summary of Elevated Transaminases across the randomized controlled trials.

As summarized in the CDTL review, patients were identified in the controlled clinical trials
with transaminase and bilirubin elevations that were consistent with drug induced liver injury
(DILI). The applicant had a consultant review the cases and that report has been reproduced,
nearly in its entirety, in the CDTL review. I have summarized the tabulations of cases from
that report, by treatment arm, below. The cases included patients who were exposed to
palonosetron alone and Akynzeo (which contains palonosetron as a component). Based on
this, it was difficult to attribute a causal relationship with netupitant. The applicant’s
consultant concluded that it was difficult to distinguish the potential contribution of the
antiemetics to these events vs. concomitant chemotherapy, or other concomitant medications.
In Study 07-07 (cisplatin based chemotherapy), there were seven cases of “possible or
probable” DILI, as designated by the applicant’s expert:
Palonosetron only =1/136 (0.7%)
Palo plus netupitant 100mg, 200mg, or 300mg =5/135; 1/138; 1/136 = 5/410 (1.2%)
Aprepitant plus ondansetron= 1/134 (0.8%)
The following table summarizes the magnitude of elevation of transaminase across the
treatment groups, for those elevations that were at least 5 X ULN. With that cut point, the
distribution was similar across treatment arms.
At least 5x ULN
At least 10X ULN

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Palonosetron
1/136 (0.7%)
1/136 (0.7%)

Netup+Palo
3 (0.7%)
3 (0.7%)

Aprepitant + Ondansetron
1 (0.8%)
1 (0.8%)

 Division Director Review

It should be noted that one of the patients who received netupitant 300 mg +palonosetron and
experienced a transaminase elevation that exceeded 10X ULN had a normal bilirubin. All
decreased, but didn’t completely normalize, by day 6 with no further follow up, with the
exception of two cases:
One Netup/palo patient, had an increase on Day 6 with no further f/u
One Netup/palo patient had documented resolution on Day 14
In Study 08-18 (AC chemotherapy), there were five cases of “possible or probable” (N=3) and
“unlikely” (N=2) DILI, as designated by the applicant’s consultant:
Palonosetron only = 4/725 = (0.6%)
Palo plus netupitant = 1/725 = (0.1%)
The two cases considered unlikely were two patients treated with palonosetron alone. They
occurred in Cycle 2 or Cycle 3, but there no similar elevations in the patients’ subsequent
cycles.
The following table summarizes the magnitude of transaminase elevation across the treatment
groups, for those elevations that were at least 5 X ULN. With that cut point, the distribution
was similar, though numerically higher in the palonosetron only group, between arms.
At least 5x ULN
At least 10X ULN

palonosetron
2/725 (0.3%)
1/725 (0.1%)

Netup+palonosetron
1 (0.1%)
0

There were two patients flagged by the consultant for evaluation for potential Hy’s Law due to
bilirubin rising to at least 2 X ULN (one treated with palonosetron only and the other with
Akynzeo). The abnormal values in the palonosetron only patient were first observed in Cycle 2
(Day 2 rise with a further increase on Day 6). The values had returned to normal by the start
of Cycle 3; however, they increased again to the highest values documented for this patient on
Day 2 of Cycle 3. They normalized by Day 6 of that same cycle.
The Akynzeo arm patient flagged for Hy’s Law had experienced transaminase and alkaline
phosphatase elevations in Cycles 1-3. Levels decreased or normalized in time for each cycle.
Levels were normal at the start of Cycle 4, but on Day 2 transaminases increased to over 7 X
ULN, bilirubin increased to 1.5 X ULN and alkaline phosphatase increased to 2.3 X ULN. On
Day 6 of that cycle, transaminases and alkaline phosphatase decreased slightly; however,
bilirubin increased to 2 X ULN. The last documented follow-up laboratory values were ALT
1.4 XULN, AST 2.9 X ULN, Alkaline phosphatase 1.6 X ULN and normal bilirubin. The
applicant’s consultant pointed out the elevated alkaline phosphatase and ALT/Alk Phos ratio
of 3, and said this was “not in accordance of the definition”, i.e., Hy’s law.
In the 4 patients treated with palonosetron only who had possible/probable DILI, a Day 6 rise
was noted in 2 patients with subsequent normalization. There was a Day 2 rise in 1 patient,
who had documented subsequent normalization. One patient had a Day 6 rise and no f/u to
document improvement.
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In Study 10-01, which was a single cycle trial that compared IV palonosetron to oral
palonosetron, there were two cases of “possible DILI” identified. Both were on the IV arm
and neither was elevated ≥5 X ULN. One was documented on Day 2 and the other on Day 6.
There was no follow up of either case to document decline or normalization.
Overall, these events were clustered primarily on Day 2, with some detected at Day 6.
Generally, laboratory monitoring post chemotherapy in clinical practice does not include
evaluation of transaminases and bilirubin on Day 2 and/or 6 for the chemotherapy drugs that
were administered in the trials submitted in this NDA. It is possible that if such frequent
monitoring of transaminases and bilirubin were conducted on a routine basis, we would have a
clearer picture of what extent these changes are in fact attributable purely to the chemotherapy.
A literature search identified reports of DILI associated with cisplatin, VP-16, doxorubicin and
cyclophosphamide2, 3, 4, 5. Larroquette, et al, summarized the transaminases, bilirubin and
alkaline phosphatase from the records of 190 consecutive patients with breast cancer who were
treated with doxorubicin, cyclophosphamide and 5-flourouracil. Approximately half received
the chemotherapy as adjuvant treatment. The authors reported that 77% of the patients who
received their chemotherapy in the adjuvant setting and 82% of those treated for metastatic
disease developed abnormalities in “liver function tests” during treatment. Among the patients
receiving adjuvant treatment, 35% developed new abnormal aspartate aminotransferase.
Similarly, 31% of the patients treated for metastatic disease developed a transaminase
abnormality. Total bilirubin increased in 4% of the patients treated with adjuvant
chemotherapy, and 2% of patients with metastatic disease developed a new abnormally high
bilirubin. Alkaline phosphatase increased in 31% of adjuvant patients and 47% of patients
with metastatic disease. The maximum elevation of bilirubin was 2.5 in the adjuvant group
and 1.9 in the metastatic disease group. The maximum elevation in transaminase was just over
3 x ULN in the adjuvant group and just over 4 x ULN in the metastatic disease group. They
concluded that the abnormalities were a manifestation of drug toxicity. These publications
support the applicant’s consultant’s conclusion that the changes observed in the Akynzeo
clinical trials could have been caused by the chemotherapy the patients received.
I concur with the Clinical reviewers that there is no compelling evidence in this safety dataset
that netupitant causes DILI. Beside the fact that all patients were also exposed to
chemotherapy drugs that could have contributed to the observed laboratory changes, cases
were also identified in patients treated only with palonosetron. The Aloxi product label states
that elevations of transaminases have been reported in patients treated with palonosetron. OSE
reviewers conducted a FAERS search on August 14, 2014 for evidence of reported cases of
severe cases liver toxicity associated with antiemetics, including palonosetron, ondansetron,
aprepitant and fosapreptitant. The database was searched for reports for severe liver
injury/failure using MedDRA Preferred Terms acute hepatic failure, asterixis, chronic hepatic
failure, coma hepatic, hepatic encephalopathy, hepatic failure, hepatorenal syndrome, subacute
hepatic failure, hepatic necrosis, hepatitis fulminant and liver transplant. The search retrieved
2

King P and Perry M. The Oncologist 2001, 6:162-176.
Larroquette C, Hortobagyi G, et al. JAMA, Dec 5, 1986: Vol 256, No.21: 2988-2990
4
Cersosimo RJ. Ann Pharmacother 1993 Apr; 27(4):438-41
5
Tra A, Housset C, et al. Journal of Hepatology, 1991;12:36-39.
3

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(without removal of duplicates) 72 reports for ondansetron, 4 for aprepitant and 2 for
palonosetron. There were no reports for fosaprepitant. Only 2 “suspect cases” were identified
– one in the US and one from the UK; both were for ondansetron. They occurred in 1998 and
2002. The OSE reviewer commented that “it is noteworthy that no additional cases have been
received in FAERS since 2002.” He concluded that there was no new, actionable safety signal
identified in this search.
Summary. I agree with the reviewers that there are no safety issues identified in this NDA
that preclude approval or necessitate a postmarketing trial/study. The changes in
transaminases observed in the clinical trials, which occurred in both the Akynzeo and
comparator arms, will be described in product labeling, since the comparator was
palonosetron in two of the trials and palonosetron is also a component of Akynzeo.

9. Advisory Committee Meeting
There was no Advisory Committee meeting convened for this NDA as there were no issues
that required discussion in an Advisory Committee.

10.

Pediatrics

PMHS provided input on the proposed pediatric plan. The Pediatric Review Committee
(PeRC) concurred with the division’s recommendations regarding the pediatric study plan.
The pediatric development of this product is anticipated to be challenging because the product
is a fixed combination oral drug, and flexibility of dosing may become necessary if weight
based dosing is needed in younger pediatric age groups. The age appropriate formulation may
be an IV formulation of netupitant (for patients less than age 6 years, in whom swallowing oral
capsules is anticipated to be difficult) administered in addition to the approved pediatric dose
of intravenous palonosetron, if an alternative oral combination formulation for this age group
cannot be developed (such as a liquid). The following PREA PMRs will be included in the
Approval letter:
2769-1

An 8-week GLP toxicology study with fertility evaluation in neonatal rats
treated with netupitant alone.
Final Protocol Submission:
Study Completion:
Final Report Submission:

2769-2

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05/30/2015
12/30/2015
03/30/2016

A PK/PD dose finding study of netupitant to characterize the netupitant PK/PD
relationship for complete response in the delayed phase following oral
administration of a single dose of netupitant given concomitantly (in separate
formulations) with an oral single administration of palonosetron in pediatric
cancer patients ages 0 to17 years undergoing treatment with emetogenic
chemotherapy, including highly emetogenic chemotherapy. You must conduct
this study with an age appropriate formulation.

 Division Director Review

Final Protocol Submission:
Study Completion:
Final Report Submission:
2769-3

An adequate, well-controlled, double-blind, randomized study to evaluate the
safety and efficacy of a dose of the netupitant/palonosetron fixed
combination compared to standard therapy in pediatric cancer patients ages 0 to
17 years undergoing treatment with emetogenic chemotherapy, including highly
emetogenic chemotherapy. You must conduct this study with an age
appropriate formulation.
Final Protocol Submission:
Study Completion:
Final Report Submission:

11.

11/01/2015
04/30/2018
09/30/2018

04/30/2019
12/31/2021
04/30/2022

Other Relevant Regulatory Issues

Financial Disclosures. The Clinical reviewer stated that the applicant provided sufficient
documentation to show that there was no financial arrangement with clinical investigators whereby
the value of compensation could affect the outcome of the studies. Because Study 07-07 was not
originally intended to be a key study supporting the efficacy and safety of Akynzeo, the applicant
attempted to locate investigator to obtain financial disclosure information. They were not able to
locate all the investigators and subinvestigators. The Clinical reviewer evaluated documentation of
the applicant’s efforts to locate all reviewers and determined they had acted with due diligence to
obtain the information required.
OSI. OSI was unable to inspect the Ukrainian sites initially selected for inspection because of
travel restrictions related to political unrest in the region. Six clinical investigator sites and the
applicant were inspected. The clinical sites included a Hungarian site, two Polish sites, a Russian
site and two sites in India. OSI conducted a sponsor inspection to evaluate compliance with
sponsor responsibilities, including selection and oversight of contract research organizations
(CROs), monitoring, financial disclosure and quality assurance, as per OSI procedures for a new
molecular entity.
In the inspection of the sponsor, OSI inspector reviewed the Trial Master Files, with special
attention to Ukrainian sites that could not be inspected due to regional unrest. These included sites
from Study 08-18, Study 10-29 and Study 07-07. Inspection of the files for Study 07-07 included
records for Site 120, which the applicant had reported as having “multiple major audit findings,
ranging from failure to meet eligibility criteria and administration of prohibited medications to
inconsistencies between source data and CRFs.” OSI found that Site 120 issues included not
transmitting ECGs by phone, errors in timing of ECGS and vital signs, and temperature issues in

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transport of drug supply. They noted there was some shift of values between pages in the NCR
pages for the visual analog scale. (The visual analog scale was not a key endpoint for labeling.)
The OSI reviewer concluded the issues at Site 120 were isolated in nature. The monitoring reports
and QA audits of NETU 07-07 revealed no evidence of other non-compliant PIs or under reporting
of AEs. Otherwise the oversight appeared adequate. The studies appeared to have been conducted
adequately and the OSI reviewer determined that the data generated by the studies appear
acceptable in support of the indications.

Controlled Substance Staff review. The CSS reviewers concluded that the data submitted in
the NDA supported that Akynzeo has no potential for abuse or dependence. The applicant
proposed to eliminate Section 9.0 from the product label, consistent with the Guidance for
Industry: Labeling for Human Prescription Drug and Biological Products – Implementing the
PLR Content and Format Requirements, and CSS ultimately concurred.

12.

Labeling

I have addressed the major labeling issues and how they were resolved in the earlier Sections
of this review.

13.

Decision/Action/Risk Benefit Assessment



Regulatory Action – Approval for indication of prevention of acute and delayed nausea
and vomiting associated with initial and repeat courses of cancer chemotherapy,
including, but not limited to, highly emetogenic chemotherapy. The indication will
state that the product is an oral combination of palonosetron and netupitant and that the
palonosetron prevents nausea and vomiting during the acute phase, and netupitant
prevents nausea and vomiting during both the acute and delayed phase after cancer
chemotherapy.



Risk Benefit Assessment- I concur with the reviewers that the risk benefit ratio for
Akynzeo, a fixed combination of palonosetron and netupitant is favorable. The
applicant has provided substantial evidence of efficacy for the CINV indication, and
the trials submitted establish the contribution of each drug in the combination to the
treatment effect. No safety issue was identified that precluded approval, and there was
no issue identified that necessitated a PMR study/trial as a condition of approval.



Recommendation for Postmarketing Risk Evaluation and Mitigation Strategies
None necessary.



Recommendation for other Postmarketing Requirements and Commitments
PREA applies to this NDA. See Section 10 Pediatrics for the PREA PMRs. In
addition, the Clinical Pharmacology reviewers have recommended two post marketing
commitments. See Section 5 Clinical Pharmacology.

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 --------------------------------------------------------------------------------------------------------This is a representation of an electronic record that was signed
electronically and this page is the manifestation of the electronic
signature.
--------------------------------------------------------------------------------------------------------/s/
---------------------------------------------------DONNA J GRIEBEL
09/26/2014

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