Pharmacokinetics and tolerability of vandetanib in Chinese patients with solid, malignant tumors: an open-label, phase I, rising multiple-dose study.

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Pharmacokinetics and Tolerability of Vandetanib in Chinese
Patients With Solid, Malignant Tumors: An Open-Label,
Phase I, Rising Multiple-Dose Study
Li Zhang, MD1; Su Li, MD1; Yang Zhang, MD1; Jing Zhan, MD1; Ben-Yan Zou, MD1;
Robert Smith, HNC2; Paul D. Martin, PhD3; Yinrui Jiang, MD4; Hai Liao, MD1; and
Zhongzhen Guan, MD1
1State Key Laboratory for Oncology in South China and Department of Medical Oncology, Cancer Center of
Sun Yat-sen University, Guangzhou, China;2AstraZeneca, Alderley Park, Macclesfield, Cheshire, United
Kingdom;3AstraZeneca, Cheshire, United Kingdom; and4AstraZeneca China, Shanghai, China
ABSTRACT
Background: Vandetanib (ZD6474) is an orally
available inhibitor of 3 signaling pathways important
in tumor progression: vascular endothelial growth fac-
tor receptor, epidermal growth factor receptor, and
rearrangedduringtransfectiontyrosinekinaseactivity.
Current development of vandetanib is focused on the
treatment of non–small-cell lung cancer and other tu-
mor types, including thyroid cancer. This study was
conducted as a requirement for regulatory submission
for vandetanib in China.
Objective: To determine the pharmacokinetics of
vandetanib in Chinese patients with advanced, solid,
malignant tumors and to compare these with data ob-
tained in Japanese and Western populations.
Methods: Phase I consisted of a nonrandomized,
open-label, single-center study conducted in Guang-
zhou, China. Adult patients (12 per treatment) who
had tumors refractory to standard treatments or for
whom no appropriate therapies existed received oral
vandetanib (100 mg every other day, 100 mg once
daily, or 300 mg once daily) until disease progression
or discontinuation in the study. The initial cohort was
dosed at 100 mg every other day. Once at least 3 pa-
tients had received this dose of vandetanib for 28 days
without experiencing dose-limiting toxicity, a second
cohort at 100 mg once daily was started. Following the
same criteria, the third cohort received 300 mg once
daily. Pharmacokinetics, tolerability, and tumor re-
sponse were assessed. The pharmacokinetics of van-
detanib in Chinese, Western, and Japanese patients
were compared through a combined population
pharmacokinetic model. Tolerability was assessed
by recording adverse events and monitoring physical
examination, body weight, performance status, vital
signs, urinalysis, biochemistry, hematology, and 12-
lead electrocardiogram.
Results: Thirty-six patients were enrolled (age range
21?82 years, 56% male, body mass index range
17.6?33.0 kg/m2). Thirty-three of 36 patients (92%)
were World Health Organization performance status
0?1. Vandetanib pharmacokinetics were linear over
the dose range studied with AUCssfor the 300 mg once
daily group (38611 ng/h/mL) being 3.6-fold higher
than that for the 100 mg once daily group (10826
ng/h/mL). Absorption was relatively slow following a
single 100- or 300-mg dose, with Tmaxranging from 2
to 10 hours. Interpatient variability in Cmax SSand
AUCSSwas relatively high, with the coefficient of vari-
ation ranging from 29.1% to 40.6%. Vandetanib
plasma clearance was slow (7.8–9.2 L/h) and was in-
dependent of dose. The most common drug-related ad-
verse events were rash (42%) and diarrhea (39%). No
QTCprolongation was observed. Hypertension was
reported as an adverse event in 3 patients. There were
no clinically relevant changes in hematology, urinaly-
sis, or World Health Organization performance status.
Elevation of alanine aminotransferase was reported as
an adverse event in 1 patient. One patient with medul-
lary thyroid cancer showed a partial tumor response.
Population pharmacokinetic analysis suggests that
vandetanibpharmacokineticsappeartobecomparable
in Chinese, Western, and Japanese patients.
Conclusions: Thepharmacokineticpropertiesofvan-
detanib in these Chinese patients were characterized by
Accepted for publication April 6, 2011.
doi:10.1016/j.clinthera.2011.04.005
0149-2918/$ - see front matter
© 2011 Published by Elsevier HS Journals, Inc.
Clinical Therapeutics/Volume 33, Number 3, 2011
March 2011315

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lowplasmaclearanceofapproximately8L/h,alonghalf-
life of approximately 8 to10 days, and an accumulation
of approximately 8?fold to 15-fold on multiple dosing.
In these Chinese patients, the pharmacokinetic profile of
vandetanib appeared to be comparable with that ob-
served in Japanese and Western populations. Oral doses
up to 300 mg once daily appeared to be well tolerated.
(Clin Ther. 2011;33:315–327) © 2011 Published by
Elsevier HS Journals, Inc.
Key words: cancer, Chinese patients, pharmacoki-
netics, tolerability, vandetanib.
INTRODUCTION
Vandetanib(ZD6474)isanorallyavailableinhibitorof3
signaling pathways important in tumor progression: vas-
cular endothelial growth factor receptor (VEGFR),1,2
epidermal growth factor receptor (EGFR),1–3and rear-
ranged during transfection (RET) tyrosine kinase ac-
tivity.4,5Activation of VEGFR by binding of VEGF
stimulates cell proliferation, survival, and migration,
facilitating angiogenesis and vasculogenesis.6EGFR
activation stimulates tumor growth and progression in
several ways by increasing proliferation, invasion, and
metastasis; inhibiting apoptosis; and promoting angio-
genesis.7–9Activation of RET modulates cell prolifer-
ation, differentiation, migration, and survival,10and
RET oncoproteins stimulate cell proliferation via the
?-catenin pathway.11
The development of vandetanib is currently fo-
cused on treatment of non–small-cell lung cancer
(NSCLC) and other tumor types, including thyroid
cancer.12Data from 3 Phase II studies in patients
with advanced NSCLC reported prolonged progres-
sion-free survival with vandetanib in combination
with chemotherapy (carboplatin/paclitaxel or do-
cetaxel)13,14
and when administered as mono-
therapy versus the EGFR inhibitor gefitinib.15These
results supported further evaluation of vandetanib
as second-line therapy for NSCLC. Data have been
reported recently from 3 double-blind, randomized
Phase III studies of vandetanib in patients with ad-
vanced NSCLC.16–18The Zactima in Combination
With Docetaxel in Non–Small Cell Lung Cancer
(ZODIAC) study reported that the addition of van-
detanib to docetaxel (n ? 694) resulted in a statisti-
cally significant improvement in progression-free
survival versus placebo plus docetaxel (n ? 697)
(hazard ratio [HR] ? 0.79 [97.58% CI, 0.70–0.90;
P ? 0.0001]).17Data from a smaller study (Zactima
Efficacy with Alimta in Lung Cancer [ZEAL]) that
evaluated the addition of vandetanib to pemetrexed
did not show a significant prolongation of progres-
sion-free survival with vandetanib plus pemetrexed
(n ? 256) compared with placebo plus pemetrexed
(n ? 278) (HR ? 0.86 [97.58% CI, 0.69–1.06; P ?
0.108]).16The third study (ZACTIMA Efficacy
When Studied Versus Tarceva [ZEST]), which eval-
uated the efficacy of vandetanib (n ? 623) versus
erlotinib (n ? 617), did not meet the primary objec-
tive of demonstrating significant prolongation of
progression-free survival for vandetanib (HR ? 0.98
[95.22% CI, 0.87–1.10; P ? 0.721]).18
Additional studies in patients with advanced solid
tumors have reported vandetanib to be well toler-
ated at doses of up to 300 mg/day.19In an open-
label, nonrandomized, dose-escalation study con-
ducted in the United States, adults with tumors
refractory to standard treatments received vandet-
anib at doses of 50 mg (n ? 9), 100 mg (n ? 19), 200
mg (n ? 8), 300 mg (n ? 25), 500 mg (n ? 8), and
600 mg (n ? 8) once daily.19In another open-label,
nonrandomized, dose-escalation study, Japanese
adults with solid tumors refractory to standard ther-
apy received vandetanib at doses of 100 mg (n ? 3),
200 mg (n ? 6), 300 mg (n ? 6), and 400 mg (n ? 3)
once daily.20Both studies indicated that increased
exposure to vandetanib was achieved with increas-
ing dose over the dose ranges 50 to 600 mg in West-
ern patients19and 100 to 400 mg in Japanese pa-
tients.20Accumulation occurred on multiple dosing
consistent with the long half-life of vandetanib of
approximately 120 hours in Western patients19and
approximately 100 hours in Japanese patients.20
The pharmacokinetic characteristics of vandetanib
appeared to be comparable in these Western19and
Japanese20patient populations.
The primary objective of this study was to establish
the pharmacokinetics of vandetanib after single and
multiple dosing (100 mg every other day, 100 mg once
daily, or 300 mg once daily) in Chinese patients with
advanced, solid, malignant tumors and to compare
them with the pharmacokinetics in Western and Japa-
nese patient populations. Additional objectives in-
cluded assessment of tolerability and preliminary ob-
servation of antitumor activity. This study was
conducted as a requirement for regulatory submission
in China.
Clinical Therapeutics
316Volume 33 Number 3

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PATIENTS AND METHODS
Patients
Adult patients aged ?18 years with solid malig-
nant tumors refractory to standard treatments, or
those for whom no appropriate therapy existed,
were eligible for inclusion. Patients were required to
have a life expectancy of at least 12 weeks and a
World Health Organization performance status of 0,
1, or 2.21The main exclusion criteria were signifi-
cant hematopoietic, hepatic, or renal dysfunction;
significant cardiac dysfunction (including history
of arrhythmia, QT syndrome/prolongation); poorly
controlled hypertension; systemic anticancer ther-
apy or radical radiotherapy within the previous 4
weeks; localized radiotherapy within the previous 2
weeks; unresolved adverse effects from prior anti-
cancer therapy or radiotherapy; cerebral tumors or
metastases; any gastrointestinal disease that would
affect drug bioavailability; and incomplete recovery
from prior surgery. Before enrollment in the study,
patients were assessed to ensure that they met the
entry criteria and were required to provide written
informed consent.
Study Design
This was a Phase I, nonrandomized, open-label, ris-
ing-dose study conducted at the Cancer Center of Sun
Yat-sen University (CCSYSU) in Guangzhou, China
(clinicaltrials.gov study identifier NCT00503711).22
Initially, 3 patients (cohort 1) were given oral vandet-
anib 100 mg every other day for a total of 28 days. If a
dose-limiting toxicity (DLT) was observed during this
time, 3 new patients were to be enrolled to start treat-
ment at that dose. Dose escalation was permitted when
a minimum of 3 patients completed 28 days’ treatment
without experiencing a DLT. If 2 or more DLTs oc-
curred,nofurtherdoseescalationwastobeconducted.
Following successful completion of 28 days’ treat-
ment, 3 patients were enrolled into cohort 2 and re-
ceived vandetanib 100 mg once daily for 28 days, as
above. After at least 3 patients had successfully com-
pleted 28 days’ treatment at 100 mg once daily, 3 pa-
tients were enrolled into cohort 3 and received vande-
tanib 300 mg once daily. No dose escalation was
planned beyond 300 mg once daily. All patients con-
tinued with vandetanib at the same dose level until
evidence of tumor progression or other discontinua-
tion criteria were met. Once dose escalation was com-
plete, patient numbers were expanded up to 12 pa-
tients in each cohort to further characterize the
pharmacokinetics and tolerability of vandetanib. No
intrapatient dose escalation was performed.
DLT was defined as drug-related grade 2 diarrhea
daily for ?7 days or grade 3 for ?24 hours, despite
maximal antidiarrheal support; drug-related grade 2
skin toxicity for ?7 days that affected the patient’s
well-being and required cessation of treatment; cor-
rected QT interval (QTC) prolongation (a single QTC
value of ?550 msec or an increase of ?100 msec from
baseline or 2 consecutive QTCmeasurements within
48 hours during which either both values were ?500
msec or both values increased from baseline by ?60
msec but ?100 msec to a value ?480 msec); or any
other vandetanib-related toxicity at least grade 3 (as
defined by the Common Terminology Criteria for Ad-
verse Events [CTCAE], Version 3.0). In the event of a
DLT,treatmentwastobestoppedandsupportivether-
apy administered, as required. Patients experiencing a
DLT were permitted to restart vandetanib treatment at
the preceding dose level following resolution of the
DLT (CTCAE grade 0 or 1) and if they had benefited
from treatment previously.
Concomitant use of rifampicin, phenytoin, carbam-
azepine, barbiturates, St. John’s Wort, and prophylac-
tic antiemetics was not permitted. Vandetanib is a sub-
strate of CYP3A4, and therefore concomitant use of
these agents was prohibited to avoid confounding the
results of the study. Any drugs generally accepted as
having a risk of causing torsades de pointes were not
allowed for 2 weeks before study entry, during the
study, and for up to 4 weeks after discontinuation of
study treatment. Drugs with a possible risk of causing
torsades de pointes were not allowed for 2 weeks be-
forethestudybutwerepermittedduringthestudywith
electrocardiogram (ECG) and electrolyte monitoring.
At entry, and throughout the trial, patients did not
receive any concurrent anticancer therapy, including
traditional Chinese medicines. Other medication con-
sidered necessary for the patient’s safety and well-be-
ing was permitted at the investigator’s discretion.
There were no food restrictions during the study, and
all vandetanib doses were administered at the same
time in the morning.
The study protocol was approved by the Research
Ethics Committee of the Cancer Center of Sun Yat-sen
University and was conducted in compliance with the
ethical principles of Declaration of Helsinki23consis-
L. Zhang et al.
March 2011317

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tent with International Conference on Harmonisation/
Good Clinical Practice.24
Assessments
Pharmacokinetic
Blood samples (4 mL) were collected for the deter-
mination of plasma concentrations of vandetanib after
the first dose (day 1) and when vandetanib had at-
tained steady-state exposure (day 43) predose and at 1,
2, 4, 6, 8, 10, and 24 hours after dosing. These samples
were taken from an indwelling catheter that was in-
serted into a forearm vein before dosing. The catheter
was sealed with 0.9% saline, which was discarded be-
fore blood sampling. In addition, blood samples were
taken by venipuncture predose and as close as possible
totheECG(4–8hoursafterdosing)onDays8,15,29,
57, and 85, and predose only on days 22 and 36. For
patients receiving 100 mg every other day, blood sam-
ples (and all other procedures) scheduled for days 8,
22, and 36 were delayed until the following day. Each
blood sample was collected into a tube containing lith-
ium heparin anticoagulant and mixed thoroughly.
Samples were centrifuged within 30 minutes of collec-
tion at 1000g for 10 minutes. Plasma was stored at
–20°C and thawed before use at room temperature.
Sample tubes were labelled with the study number,
patient number, day, and nominal time of sampling.
Plasma concentrations of vandetanib were deter-
mined by liquid/liquid extraction followed by reverse-
phase high-performance liquid chromatography and
detection by tandem mass spectrometry. One hundred
microliter plasma samples were added to 100 ?L of
sodium hydroxide containing internal standard. The
samples were extracted with 600 ?L of methyl tert-
butyl ether. The extracts were evaporated to dryness,
and the residues were reconstituted in mobile phase.
Following this extraction procedure, vandetanib is sta-
ble for 76 hours at room temperature in injection sol-
vent. Human plasma utilizing lithium heparin as anti-
coagulant was used for the preparation of standards
and quality control samples. The lower and upper lim-
its of quantification were 5 and 1000 ng/mL, respec-
tively. Based on the quality control analysis, the preci-
sion (%CV) for vandetanib at 15, 500, and 800 ng/mL
was 3.8%, 6.3%, and 5.2%, respectively, and mean
accuracy (% of nominal) was 107.3%, 101.8%, and
103.6%, respectively. Plasma concentration analysis
was performed by BASi (Kenilworth, United King-
dom). Pharmacokinetic analyses were performed at
AstraZeneca Pharmaceuticals (Alderley Park, United
Kingdom).
The pharmacokinetic parameters calculated from
data collected after a single dose (Day 1) were max-
imum plasma concentration (Cmax), time to maxi-
mum plasma concentration (Tmax), and area under
plasma concentration-time curve from 0 to 24 hours
(AUC0–24). At steady state (Day 43), the pharmacoki-
netic parameters calculated were area under plasma
concentration-time curve (AUCss), maximum plasma
concentration (Cmax.ss), minimum plasma concentra-
tion (Cmin.ss), average plasma concentration (Cav.ss),
time to maximum plasma concentration (Tmax.ss), total
plasma clearance after an oral dose (CLss/F), apparent
volume of distribution after an oral dose (Vdist), ter-
minal half-life (t1/2), and accumulation ratio (R). All
parameters apart from t1/2(all dosage groups), Vdist
(population mean), and R (100 mg every other day
group) were determined by noncompartmental anal-
ysis of the plasma concentration data using Win-
Nonlin®Enterprise version 4.1 (Pharsight Corpora-
tion, Mountain View, California).25The t1/2at each
dose level, population mean Vdist, and R for the 100
mg every other day group were determined from the
population pharmacokinetic analysis, as these pa-
rameters could not be determined from the noncom-
partmental analysis.
A population pharmacokinetic analysis was carried
out to compare the pharmacokinetic data obtained in
this study with existing pooled data from Phase I stud-
ies in Western19and Japanese20patients. A nonlinear
mixed-effects modeling program (NONMEM V ver-
sion 1.1 [Icon Development Solutions, Ellicott City,
Maryland]) was used for this analysis.26,27A 2-com-
partment first-order absorption and first-order elimi-
nation model was used to fit all the data, using the
parameters of clearance, initial volume, peripheral vol-
ume, and distributional clearance. The volume of dis-
tribution at steady state was defined as the initial vol-
ume plus the peripheral volume. During the analysis,
separate clearance estimates were used to describe the
separate demographic populations (Chinese, Western,
and Japanese) and to test for differences in exposure.
Outputs included individual parameter estimates and
individual predicted plasma concentrations.
Tolerability
All tolerability assessments were carried out at the
Cancer Center of Sun Yat-sen University. Tolerability
Clinical Therapeutics
318 Volume 33 Number 3

Page 5

assessments conducted at screening and throughout
the study included physical examination and measure-
ment of body weight, performance status, vital signs
(systolic and diastolic blood pressure, heart rate, body
temperature), urinalysis, biochemistry and hematol-
ogy, and 12-lead ECG. Physical examination and mea-
surement of body weight were repeated at 2-week in-
tervals. Performance status was evaluated every week
for the first 2 weeks of vandetanib dosing and at
2-week intervals thereafter. Vital signs were monitored
at 2, 4, 6, 8, 10, and 24 hours after the first dose of
vandetanib and then at weekly intervals. Blood pres-
sure was measured with the patient in a sitting position
after a 5-minute rest. Urine samples were collected at
2-week intervals and analyzed for protein, blood, and
glucose. Blood samples were collected for routine he-
matology and biochemistry tests once weekly for the
first month of vandetanib dosing and then at 2-week
intervals. Blood and urine samples were analyzed by
the Clinical Laboratory, Cancer Center of Sun Yat-sen
University. Hematology tests comprised hemoglobin,
differential white cell count, and platelet count. Bio-
chemical screening included alkaline phosphatase, ala-
nine aminotransferase, aspartate aminotransferase,
bilirubin, blood urea nitrogen, creatinine, magnesium,
potassium, sodium, calcium, chloride, and albumin. A
12-lead ECG was performed at screening; before ad-
ministration of the first vandetanib dose; at 1, 2, 4, 8,
and 12 weeks after the first dose; then every 3 months
and on treatment withdrawal. When possible, ECGs
were performed at the same time throughout the study.
Adverse events were collected by spontaneous report-
ing throughout the study, and their severity and rela-
tionship to treatment, as judged by the investigator,
were recorded.
Tumor Response
Radiologic tumor assessment was performed at
baseline (?4 weeks before the start of treatment) and
every 56 days during treatment. Clinical assessment
was conducted at every visit and at the time of with-
drawal. Objective tumor response to vandetanib was
evaluated by Response Evaluation Criteria in Solid Tu-
mors (RECIST).28
Statistical Analyses
All analyzes were descriptive, and no formal statis-
tical analysis was performed. Sample size was based on
the Chinese State Food and Drug Administration tech-
nical guideline on pharmacokinetics studies.29A total
of 8 to 12 patients were required for each dosing
group. The tolerability population comprised all pa-
tients who received ?1 dose of vandetanib; the phar-
macokinetic population comprised all patients who
received ?1 dose of vandetanib and had valid pharma-
cokinetic data available. The efficacy population in-
cluded all patients with baseline disease measurements
who received ?1 dose of vandetanib. Data from the
tolerability evaluations were summarized by vandet-
anib dose using Medical Dictionary for Regulatory Ac-
tivities (MedDRA) preferred terms.
RESULTS
Patient Characteristics
Thirty-six patients were enrolled in the study, of
whom12weretreatedateachdosagelevel.Allpatients
were included in the pharmacokinetic and tolerability
analyzes.Itwasintendedtoevaluatetumorresponsein
34 patients; 2 patients (both in the 100 mg every other
day group) were not eligible for evaluation by RECIST
because they had no measurable lesions at baseline.
Demographic and key baseline characteristics ap-
peared to be comparable between dosage groups
(Table I). All patients had refractory malignant tu-
mors, most commonly located in the lung. Overall,
25/34 (74%) and 8/34 (24%) patients had previ-
ously received chemotherapy or radiotherapy, re-
spectively. The mean (range) duration of vandetanib
treatment across all doses was 86.6 days (range
7–416 days; n ? 36).
All but 2 patients withdrew from the study by data
cut-off. The main reason for withdrawal was tumor
progression. In the 100 mg every other day group, the
reasons for withdrawal were tumor progression con-
firmed by imaging (8 cases), clinical tumor progression
according to the judgment of the investigator (2 cases),
and voluntary discontinuation (1 case). In the 100 mg
once daily group, the reasons for withdrawal were tu-
mor progression (9 cases), death (2 cases), and lost to
follow-up (1 case). In the 300 mg once daily group, the
reasons for withdrawal were tumor progression con-
firmed by imaging (8 cases), clinical tumor progression
according to the judgment of the investigator (2 cases),
and adverse events (1 case). Two patients, both with
medullary thyroid cancer, were continuing with van-
detanib treatment (1 at 100 mg every other day and 1
at 300 mg once daily) at data cut-off.
L. Zhang et al.
March 2011 319

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Pharmacokinetics in Chinese Patients
Pharmacokinetic parameters in this Chinese popu-
lation following a single dose of vandetanib and at
steady state are presented in Table II. Geometric mean
plasma concentration-time profiles at steady state for
each dose level are shown in Figure 1.
Absorptionwasrelativelyslowfollowingasingle100-
or300-mgdoseofvandetanib,withTmaxrangingfrom2
to10hours.Exposure(gmean Cmaxand AUC0–24) after
the first 100 mg dose appeared to be comparable in the
100 mg every other day and 100 mg once daily groups
and was around 4-fold higher in the 300 mg once daily
group.
Examination of Cminshowed that steady-state ex-
posure to vandetanib was achieved by individual pa-
tients from Day 22. All patients had achieved steady
state by day 43 when steady-state pharmacokinetic pa-
rameters were determined. At steady state, gmean
Cmax.SSwas around 1.5-fold lower at a dose of 100 mg
every other day than at 100 mg once daily, whereas
gmean AUCSSappeared to be comparable in these 2
dosage groups. This observation can be explained by
Table I. Patient characteristics.
Vandetanib Dose
Characteristic
100 mg Every Other
Day (n ? 12)
100 mg Once
Daily (n ? 12)
300 mg Once
Daily (n ? 12)
Sex, no. (%)
Male8 (67) 5 (42) 7 (58)
Age, y
Mean (SD)
Range
51.5 (15.2)
30–82
53.4 (14.9)
21–71
49.8 (9.8)
35–69
Weight, kg
Mean (SD)59.3 (10.0) 64.5 (15.1) 66.2 (9.1)
BMI, kg/m2
Mean (SD)
Range
22.7 (3.3)
17.6–28.6
24.0 (3.7)
17.6–33.0
24.8 (3.0)
22.0–33.0
WHO performance status, no. (%)
0
1
2
3 (25)
7 (58)
2 (17)
3 (25)
8 (67)
1 (8)
6 (50)
6 (50)
0 (0)
Primary tumor diagnosis, no. (%)
Lung
Head and neck
Medullary thyroid cancer
Colon
Colorectal
Other*
8 (67)
0 (0)
1 (8)
0 (0)
1 (8)
2 (17)
8 (67)
1 (8)
0 (0)
1 (8)
1 (8)
1 (8)
4 (33)
3 (25)
2 (17)
2 (17)
0 (0)
1 (8)
Duration of vandetanib treatment, d
Mean (SD)
Range
96.8 (113.4)
7–416
85.1 (64.9)
20–225
77.8 (58.1)
21–198
BMI ? body mass index; WHO ? World Health Organization.
*Various other tumor types.
Clinical Therapeutics
320Volume 33 Number 3

Page 7

the fact that AUCSSis measured over the dosing inter-
val, that is, 0 to 48 hours for the 100 mg every other
day group and 0 to 24 hours for the 100 mg once daily
group. During the first 24 hours after dosing, exposure
(AUC0–24) in the 100 mg every other day group (ex-
trapolated from AUC from 0–48 hours [AUC0–48]:
11767 ng/h/mL) was around half that seen in the 100
mg once daily group (10826 ng/h/mL). Increase in ex-
posure (gmean Cmax.SSand AUCSS) in the 300 mg once
daily group compared with the 100 mg once daily
group was approximately proportional to the increase
in dose. Interpatient variability in Cmax.SSand AUCSS
was relatively high, with CV ranging from 29.1% to
40.6%. Plasma clearance of vandetanib was slow
(7.8?9.2 L/h) and was independent of dose.
The population pharmacokinetic analysis was based
on 768 plasma samples from 36 patients. The pharma-
cokinetics were described by a 2-compartment model
(Table III). Examination of the observed and predicted
individual plasma concentrations determined from this
model (Figure 2) indicated good correlation.
The population mean estimate of total plasma clear-
ance was 7.26 L/h, and the apparent total volume of
distribution, calculated as the sum of the apparent vol-
ume of distribution into the central compartment and
the tissues, was estimated at 1896 L. The terminal half-
life determined from the population analysis appeared
to be independent of dose and was long (around 9
days), leading to marked accumulation (?10-fold) at
steady state compared with that of single dose.
Comparison of Pharmacokinetics in Chinese,
Western, and Japanese Populations
Comparison of predicted individual values of total
plasma clearance, Cmax.SS, and half-life in this Chinese
population with those obtained from models derived
Table II. Pharmacokinetic parameters of vandetanib after a single dose (day 1) and at steady state (day 43).
Vandetanib Dose
Variable
100 mg Every
Other Day
100 mg Once
Daily
300 mg Once
Daily
Single dose (day 1)
AUC0–24, gmean (CV%), ng/h/mL
Cmax, gmean (CV%), ng/mL
Tmax(h) median (range)
n ? 12n ? 12n ? 12
1392 (51.5)
81.8 (48.7)
6 (4–10)
1294 (30.5)
71.8 (32.3)
6 (2–10)
5643 (58.8)
329.5 (70.0)
8 (2–10)
Steady state (day 43)
AUCss, gmean (CV%), ng/h/mL
Cmax.ss, gmean (CV%), ng/mL
Cmin.ss, gmean (CV%), ng/mL
Cav.ss, gmean (CV%), ng/mL
Tmax.ss, median (range), h
CLss/F, gmean (CV%), L/h
Vdist, population mean, L†
t1/2, mean (SE), d†
R, mean (range)
n ? 8*
n ? 9n ? 7
11767 (29.1)
342.9 (38.0)
213.3 (24.5)
245.2 (29.1)
4 (4–8)
8.5 (29.1)
10826 (40.6)
521.7 (35.3)
436.6 (44.0)
451.1 (40.6)
6 (0–24)
9.2 (40.6)
1896
8.9 (0.9)
9.1 (5.9–12.2)
38611 (38.4)
2024 (39.1)
1497 (42.9)
1608 (38.3)
4 (0–24)
7.8 (38.4)
10.4 (2.2)
14.9 (5.3–45.1)†
7.6 (1.8)
8.1 (4.3–13.1)
AUC0–24? area under plasma concentration-time curve from 0 to 24 hours; AUCss? area under plasma concentration-time
curve during the dosing interval at steady state; Cav.ss? average plasma concentration at steady state; Cmax? maximum
plasmaconcentration;Cmax.ss?maximumplasmaconcentrationatsteadystate;Cmin.ss?minimumplasmaconcentrationat
steadystate;CLss/F?totalplasmaclearanceafteranoraldoseatsteadystate;CV?coefficientofvariation;R?accumulation
ratio; t1/2? terminal half-life; Tmax? time to maximum plasma concentration; Vdist? apparent total volume of distribution
after an oral dose.
*n ? 9 for Cmax.SSand Tmaxonly.
†Determined from the population analysis.
L. Zhang et al.
March 2011321

Page 8

from Western19and Japanese20populations (Figure 3)
suggested that vandetanib pharmacokinetics appeared
to be comparable in these 3 populations. A combined
analysis showed that population mean (95% CI) total
plasma clearance appeared to be comparable in these
Chinese (7.0 L/h [5.6–8.4 L/h]), Western (8.5 L/h
[5.4–11.6 L/h]), and Japanese (5.5 L/h [4.3–6.7 L/h])
populations.
Tolerability
Adverse events were reported by 11 (92%), 10
(83%), and 12 (100%) patients in the 100 mg every
other day,100 mg once daily, and 300 mg once daily
groups, respectively. The most common drug-related
adverse events were rash (100 mg every other day, n ?
5/12; 100 mg once daily, n ? 4/12; 300 mg once daily,
n ? 6/12) and diarrhea (100 mg every other day, n ?
1/12; 100 mg once daily, n ? 5/12; 300 mg once daily,
n ? 8/12) (Table IV). Various types of rash were ob-
served, including dermatitis acneiform (n ? 2), macu-
lopapular rash (n ? 2), exfoliative dermatitis (n ? 1),
and urticaria (n ? 1). Two deaths (both 100 mg once
daily subjects) were reported while the patients were
participating in the study. Two further deaths (both
300 mg once daily subjects) were reported after the
patients had withdrawn from study treatment. All 4
deaths were judged to be due to disease progression.
Two patients reported serious adverse events (exfolia-
tive dermatitis, chest discomfort), both of which were
considered to be drug related. No grade 4 adverse
Figure 1. Geometric mean steady state plasma concentration-time profiles of vandetanib.
Table III. Model parameters derived from the
population pharmacokinetic analysis
of vandetanib.
ParameterMean SE CV (%)
? (%)
Ka, h–1
CL/F, L/h
V1/F, L
VT/F, L
Overall Vdist, L
CLD/F, L/h
?, %
Obj
0.83
7.26
0.08
0.56
11.3
7.7
8.0
17.9
NA
28.8
NA
NA
?100
40.7
53.81280
616
1896
102
110
?100
NA
?100
NA
NA
NA
4.2
NA
NA
14.7
18.0
?1371
? ? residual variability; ? ? inter-subject variability;
CLD/F ? distribution clearance after an oral dose; CL/F ?
total plasma clearance after an oral dose; CV ? coefficient
of variation; Ka ? absorption rate constant; NA ? not ap-
plicable; Obj ? NONMEM objective function; SE ? stan-
darderror;V1/F?apparentvolumeofdistributionintothe
central compartment after an oral dose; Vdist? apparent
total volume of distribution after an oral dose; VT/F ? ap-
parentvolumeofdistributionintotissuesafteranoraldose.
Clinical Therapeutics
322 Volume 33 Number 3

Page 9

events were reported. Five patients experienced a total
of 6 grade 3 adverse events, of which the following 3
were considered to be drug related. One patient in the
100 mg every other day group had a grade 3 rash 13
days after treatment was discontinued (on day 58) due
to disease progression. The rash was previously evalu-
ated as grade 1 (33 days after dosing) and grade 2 (56
days after dosing). At the final follow-up appointment,
2 weeks later, the rash had improved to grade 2 and
resolved 2 months after withdrawal from treatment.
One patient in the 300 mg once daily group had grade
3 serious exfoliative dermatitis 9 days after the first
dose; she recovered 15 days after withdrawal from
treatment. One patient in the 300 mg once daily group
experienced grade 3 serious chest discomfort 38 days
after the start of dosing. The symptoms improved to
grade 1 after 7 days of treatment interruption and re-
solved 1 week after withdrawal from treatment. These
were the only 3 patients to report DLTs during the
study; all incidences of DLT occurred during the co-
hort expansion phase of the study.
No episodes of protocol-defined QTc prolongation
wereobservedinthisstudy.Toinvestigatetherelation-
ship between plasma concentration of vandetanib and
observed QTc, the pharmacokinetic model was used to
predict individual plasma concentrations at the time
whentheQTcwasrecorded.Visualexaminationofthe
data suggested that QTc tended to be higher during
treatment with vandetanib than at baseline. However,
the minor increase appeared to be independent of
plasma concentration (up to 500 ng/mL) and remained
relatively constant over time at around 9 to 13 msec. A
nonlinear model was fitted to define the relationship
between QTc and predicted vandetanib plasma con-
centration in this select Chinese population. This
modelpredictedameanbaselineQTcof404msecwith
a maximum increase on treatment of 39 msec.
Diastolic blood pressure increased by more than 15
mm Hg in a total of 13 patients after multiple dosing
with vandetanib (100 mg every other day, n ? 5/12;
100 mg once daily, n ? 3/12; 300 mg once daily, n ?
5/12). Grade 1 or 2 hypertension was reported as an
adverse event in 3 patients (100 mg every other day,
n ? 1/12; 300 mg once daily, n ? 2/12). There were no
clinically relevant changes in hematology, urinalysis, or
World Health Organization performance status. Eleva-
tion of alanine aminotransferase was reported as an ad-
verse event in 1 patient at a dose of 100 mg once daily.
Tumor Response
Imaging-defined tumor response was evaluated in
34 patients according to RECIST criteria. No patients
achieved a complete response, but 1 patient with med-
ullary thyroid cancer showed an objective partial re-
sponse during treatment with vandetanib 300 mg once
daily. At data cutoff, the duration of response was 68
days, and the patient was continuing with vandetanib
treatment. Ten patients had stable disease: 2/10 (20%)
in the 100 mg every other day group, 5/12 (42%) in the
100 mg once daily group, and 3/12 (25%) in the 300
mg once daily group. Disease progression was con-
firmed by imaging in 5/10 patients (50%) in the 100
mg every other day group, 4/12 (33%) in the 100 mg
once daily group, and 5/12 (42%) in the 300 mg once
Figure 2. Individual observed and predicted plasma concentrations of vandetanib.
L. Zhang et al.
March 2011 323

Page 10

dailygroup.Fouradditionalpatientswereevaluatedas
having progressive disease by clinical observation only
(2 each in 100 mg every other day and 300 mg once
daily groups). The remaining 5 patients had an un-
known response due to death (2 patients, both 100 mg
once daily), voluntary discontinuation (1 patient, 100
mg every other day), lost to follow-up (1 patient, 100
mg once daily), or withdrawal from the study owing to
an adverse event (1 patient, 300 mg once daily).
DISCUSSION
In this Phase I, escalating, multiple-dose study, the
pharmacokinetics of vandetanib over the dose range
100 mg every other day to 300 mg once daily were
determined in Chinese patients with solid, malignant
tumors. Exposure to vandetanib increased with in-
creasing dose, and for 100 and 300 mg once daily, this
increase appeared to be in reasonable approximation
to the increase in dose. In addition, the geometric mean
(%CV)andindividualtotalplasmaclearancevaluesof
vandetanib at steady state appeared to be comparable
for each dose level, further indicating that the pharma-
cokinetics of vandetanib were linear in this population
over the dose range studied. Total plasma clearance of
vandetanib was slow (7.8?9.2 L/h), and vandetanib
had a large volume of distribution (?2000 L), thus
indicating an extensive distribution to the tissues. The
slow clearance and large volume of distribution re-
sulted in a long terminal half-life of approximately 9
days. Consequently,steady-stateexposuretovandetanib
wasnotachieveduntilafteratleast22daysofonce-daily
dosing. In addition, there was marked accumulation,
with the exposure to vandetanib at steady state being
around 10-fold higher than that observed after a single
dose.Thesesustainedandconsistentplasmalevelsofvan-
detanib are considered to be an important factor in
achieving effective inhibition of VEGFR.30
Comparison of data obtained in this Chinese popu-
lation with those reported in Phase I studies in West-
ern19and Japanese20patients showed a consistent
pharmacokinetic profile for vandetanib across the 3
populations. As in the present study, the studies in
Western and Japanese patients suggested that vandet-
anib is absorbed slowly and extensively distributed,
with a long half-life in excess of 5 days. Population
mean total plasma clearance was estimated to be 7.0
L/h in Chinese patients, compared with 8.5 L/h in
Western and 5.5 L/h in Japanese patients. The distri-
bution of estimated individual values of total plasma
clearance,steady-statepeakplasmaconcentration,and
half-life appeared to be comparable across the 3
populations.
Vandetanib appeared to be well tolerated in this
small population of Chinese patients up to a dose of
300 mg once daily over an average of 12 weeks (max-
imum 59 weeks). There were no incidences of DLT
during the dose escalation phase of the study. Most of
the reported adverse events were mild and manageable
with supportive care. The tolerability profile of vande-
Figure 3. Individualestimatedapparenttotal
plasma clearance (A), maximum plasma
concentration at steady state (Cmax.SS)
(B), and half-life (C) values of vandet-
anib in Western,19Japanese,20and Chi-
nese patients.
Clinical Therapeutics
324 Volume 33 Number 3

Page 11

tanib in Chinese patients was consistent with that pre-
viously observed in Western19and Japanese20patients
with solid, malignant tumors. In the Western and Jap-
anesestudies,vandetanibappearedwelltoleratedupto
and including doses of 300 mg once daily. In all 3
populations, the most common drug-related adverse
events were rash and diarrhea. In the Chinese study,
only 1 patient with rash required discontinuation of
treatment, and the symptoms resolved within 2 weeks.
Different types of rash have been observed in other
studies of vandetanib and may be related to EGFR
inhibition.31Grade 1 or 2 hypertension was also noted
in 3 patients; 2 of whom were treated at the highest
dose level. Hypertension has also been reported in
studies of other VEGF-targeted therapies.32,33
QTc prolongation has been noted in previous stud-
ies of vandetanib,13–15but no protocol-defined QTC
prolongation was observed in this study of Chinese
patients. Population pharmacokinetic analysis sug-
gested that there is a small increase in QTc during
treatment with vandetanib, which reaches a plateau
with continued dosing. However, there was no clear
evidence that the increase in QTc is related to vandet-
anib plasma concentration. Clinical experience with
vandetanib to date suggests that QTc prolongation is
largely asymptomatic and resolves with dose interrup-
tion or reduction.13–15
Although this study was designed primarily to as-
sess the pharmacokinetics of vandetanib, it was
noted that several patients had stable disease and 1
patient with medullary thyroid cancer experienced a
partial response. In addition to inhibition of VEGFR-
dependent tumor angiogenesis,1,2vandetanib also tar-
gets EGFR-1–3and RET-dependent4,5tumor cell prolif-
eration and survival. Agents such as vandetanib with
multiple modes of action may have the potential for en-
hanced clinical benefit in tumor types that show abnor-
malities in more than 1 signaling pathway.
This study was limited by its nonrandomized,
open-label design, and small number of patients in
each dosage group. It is recognized that these factors
and the inclusion/exclusion criteria applied to re-
cruitment limit the extrapolation of results to the
wider disease setting.
CONCLUSIONS
The pharmacokinetic properties of vandetanib in these
Chinese patients were characterized by low plasma
clearance of approximately 8 L/h, a long half-life of
approximately 8 to 10 days, and accumulation of ap-
Table IV. Adverse events reported by more than 1 patient in any treatment group.
Vandetanib Dose
100 mg Every
Other Day
(n ? 12)
100 mg
Once Daily
(n ? 12)
300 mg
Once Daily
(n ? 12)
Adverse Eventn%n%n%
Rash
Diarrhea
Cough
Pyrexia
Hypertension
Upper respiratory tract infection
Back pain
Maculopapular rash
Dyspnea
Dermatitis acneiform
Toothache
Cancer pain
6
2
1
1
1
0
1
1
0
0
0
0
50%
17%
8%
8%
8%
0%
8%
8%
0%
0%
0%
0%
6
5
1
1
0
2
1
0
1
1
1
0
50%
42%
8%
8%
0%
17%
8%
0%
8%
8%
8%
0%
6
8
2
1
2
1
0
1
1
1
1
2
50%
67%
17%
8%
17%
8%
0%
8%
8%
8%
8%
17%
L. Zhang et al.
March 2011 325

Page 12

proximately 8- to 15-fold on multiple dosing. In these
Chinese patients, the pharmacokinetic profile of van-
detanib appeared to be comparable with that observed
in Japanese and Western populations. Oral doses up to
300 mg once daily appeared to be well tolerated.
ACKNOWLEDGMENTS
This study was supported financially by AstraZeneca.
AstraZeneca was responsible for the design and con-
duct of the study, overall management, data collection
and analysis, and interpretation of the data. All au-
thors listed were involved in critical review and revi-
sion of the manuscript and provided final approval of
content.
Li Zhang has been a paid consultant to AstraZeneca
andhasreceivedresearchfundingfromAstraZenecaand
Lilly.ZhongzhenGuanhasbeenapaidconsultanttoand
has received research funding from AstraZeneca. Su Li,
Yang Zhang, Jing Zhan, Ben-Yan Zou, and Hai Liao
have disclosed no potential conflicts of interest. Paul
Martin is an employee and shareholder of AstraZeneca.
Robert Smith and Yinrui Jiang were employees of Astra-
Zeneca at the time this research was conducted.
The authors would like to thank the following indi-
vidualsfortheirassistancewiththisstudy:TongyuLin,
Guangchuan Xu, Lianzhu He, and Zhang Zhang from
the Cancer Center of Sun Yat-sen University. This
study was supported financially by AstraZeneca. The
staff of BASi, Kenilworth, United Kingdom, conducted
the bioanalysis, which was funded by AstraZeneca.
Jennifer Stewart, MSc, of InforMed, Macclesfield,
United Kingdom, provided editorial and writing assis-
tanceinthemanuscriptpreparation,whichwasfunded
by AstraZeneca.
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Address correspondence to: Zhongzhen Guan, State Key Laboratory for
Oncology in South China and Department of Medical Oncology, Cancer
Center of Sun Yat-sen University, 651 Dongfeng East Rd, Guangzhou
510060, Guang Dong Province, China. E-mail: guanzhzh@mail.sysu.edu.cn
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