Pharmacokinetics and tolerability of etamicastat following single and repeated administration in elderly versus young healthy male subjects: an open-label, single-center, parallel-group study.

Page 1

Pharmacokinetics and Tolerability of Etamicastat Following
Single and Repeated Administration in Elderly Versus Young
Healthy Male Subjects: An Open-Label, Single-Center,
Parallel-Group Study
Teresa Nunes, MD, PhD1; José Francisco Rocha, BSc1; Manuel Vaz-da-Silva, MD, PhD1;
Amilcar Falcão, PharmD, PhD2; Luis Almeida, MD, PhD3; and
Patricio Soares-da-Silva, MD, PhD1,4
1Department of Research and Development, BIAL-Portela & Co., S Mamede do Coronado, Portugal;
2Faculty of Pharmacy & CNC, University of Coimbra, Coimbra, Portugal;3Health Sciences Section,
University of Aveiro, Aveiro, Portugal; and4Institute of Pharmacology and Therapeutics, Faculty of
Medicine, University of Porto, Porto, Portugal
ABSTRACT
Background: Etamicastat is a new dopamine-?-hy-
droxylase (D?H) inhibitor currently in clinical develop-
ment for the treatment of hypertension and heart failure.
Objectives:Toevaluatethepharmacokineticsandtol-
erability of etamicastat after single and repeated admin-
istration in elderly subjects (aged ?65 years) relative to
young adult healthy controls (aged 18–45 years).
Methods: This was a single-center, open-label, paral-
lel-group study in young male adults (n ? 13; mean [SD]
age 32.6 [16.4] years; range, 18–44 years; weight 79.0
[16.4] kg; systolic blood pressure 117 [12] mm Hg and
diastolic blood pressure 61 [7] mm Hg) and 12 elderly
malevolunteers(n?12;age69.3[3.3]years;weight69.2
[9.5] kg; systolic blood pressure 115 [13] mm Hg and
diastolic blood pressure 64 [4] mm Hg), conducted in 2
consecutive periods. All subjects were white, except for 1
blackelderlysubject.InPhaseA,subjectsreceivedasingle
dose of 100 mg etamicastat. In Phase B, subjects received
100 mg/d etamicastat for 7 days. The pharmacokinetic
parameters of etamicastat and its acetylated metabolite
BIA5-961werecalculatedafterthesingledoseofPhaseA
andthelastdoseofPhaseB.Subjects’N-acetyltransferase
type 1 (NAT1) and type 2 (NAT2) genotyping was per-
formed and acetylator status inferred.
Results: After a single dose of etamicastat 100 mg,
mean (SD) plasma Cmaxand plasma AUC0–?were,
respectively, 1.3 (0.5) ng/mL/kg and 12.4 (7.8) ng ?
h/mL/kg in elderly subjects, and 1.3 (0.4) ng/mL/kg
and 10.0 (6.6) ng ? h/mL/kg in young subjects. At
steady-state, Cmaxand AUC0–24were 1.8 (0.5) ng/mL/kg
and 15.0 (6.4) ng ? h/mL/kg in elderly subjects, and
1.5 (0.7) ng/mL/kg and 12.5 (6.5) ng ? h/mL/kg in
young subjects. Elderly/young geometric mean ratios
and 90% CIs were, respectively, 0.944 (0.788–1.131)
and 1.164 (0.730–1.855) for etamicastat Cmaxand
AUC0–?after a single dose, and 1.225 (0.960–1.563)
and 1.171 (0.850–1.612) for etamicastat Cmaxand
AUC0–24at steady state. Etamicastat steady-state
plasma concentrations were reached after 3 to 4 days
of dosing. The mean etamicastat accumulation ratio
was 1.7 in both age groups. Following etamicastat sin-
gle dose, mean (SD) BIA 5-961 Cmaxand AUC0–?
were, respectively, 3.5 (2.1) ng/mL/kg and 28.4 (14.7)
ng ? h/mL/kg in elderly subjects, and 2.5 (1.5) ng/
mL/kg and 16.5 (9.7) in young subjects. At steady
state, BIA 5-961, Cmax, and AUC0–24were 4.3 (2.6)
ng/mL/kg and 34.6 (17.6) ng ? h/mL/kg in elderly sub-
jects, and 3.1 (2.0) ng/mL/kg and 22.2 (11.8) ng ?
h/mL/kg in young subjects. Large interindividual vari-
ability dependent on the NAT2 acetylator status was
found in the pharmacokinetic parameters of etami-
castat and BIA 5-961. Systemic exposure to etami-
castat was higher and systemic exposure to BIA 5-961
was lower in NAT2 poor metabolizers compared with
rapid metabolizers. No effect on heart rate and blood
pressure was found in the young group. In the elderly,
a decrease of supine blood pressure was observed. Pos-
tural changes in blood pressure were unaffected. Four
Accepted for publication May 7, 2011.
doi:10.1016/j.clinthera.2011.05.048
0149-2918/$ - see front matter
© 2011 Published by Elsevier HS Journals, Inc.
Clinical Therapeutics/Volume 33, Number 6, 2011
776Volume 33 Number 6

Page 2

adverse events (AEs) were reported by each group: na-
sopharyngeal pain, sciatica, asthenia, and back pain
the elderly group, and headache (2 cases), insomnia,
and myopericarditis by the young group. Myopericar-
ditis led to study discontinuation for this subject and
was considered to be of probable viral etiology. All
other AEs were mild to moderate in intensity.
Conclusion: The pharmacokinetic profile of etami-
castat was not significantly different in these small
groups of healthy young versus elderly adult male
volunteers. (Clin Ther. 2011;33:776–791) © 2011
Published by Elsevier HS Journals, Inc.
Key words: age effect, dopamine-?-hydroxylase,
dopamine-?-hydroxylase
heart failure, hypertension, pharmacokinetics.
inhibition,etamicastat,
INTRODUCTION
Activation of the sympathetic nervous system is an im-
portant feature in hypertension and congestive heart fail-
ure.1–6This sympathetic activation, in addition to caus-
ing blood pressure elevation, most likely also contributes
to left ventricular hypertrophy and to the commonly as-
sociatedmetabolicabnormalitiesofinsulinresistanceand
dyslipidemia.1Inhibition of sympathetic nerve function
withadrenoceptorantagonistsisarationalapproach,but
some patients do not tolerate the immediate hemody-
namic deterioration that accompanies adrenoceptor
blockade, particularly heart failure patients.7
An alternative strategy for directly modulating sym-
pathetic nerve function is to reduce the biosynthesis of
noradrenaline via inhibition of dopamine-?-hydroxy-
lase (D?H),8the enzyme that catalyzes the conversion
of dopamine into noradrenaline in the catecholamine
biosynthetic pathway. The inhibition of D?H has sev-
eral putative advantages over adrenoceptor blockade,
such as gradual sympathetic modulation as opposed to
abrupt inhibition of the sympathetic system observed
with ?-blockers.9In addition, inhibition of D?H in-
creases the release of dopamine,10,11which can pro-
mote renal vasodilation, diuresis, and natriure-
sis.9,12,13Therefore, it may be hypothesized that D?H
inhibitors could be advantageous over conventional
pure ?-blockers or mixed ?,?-blockers.
Several D?H inhibitors have been described. The
early first and second generation D?H inhibitors, such
as disulfiram,14diethyldithiocarbamate15or fusaric
acid,16and aromatic or alkyl thioureas,17were devoid
of selectivity for D?H and presented a nonsatisfactory
tolerability profile. A third generation D?H inhibitor,
nepicastat (RS-25560-197, Roche Bioscience, Palo Alto,
California),8was a selective and potent D?H inhibitor
that was developed in early clinical trials.18Although
devoid of some of the problems associated with the
earlier D?H inhibitors, nepicastat development in
congestive heart failure did not progress. Because
nepicastat is able to cross the blood–brain barrier
and is a central nervous system active D?H inhibi-
tor, its clinical development is in progress for the
indication of cocaine addiction (NCT00656357 at
www.clinicaltrials.gov) and post-traumatic stress
disorder(NCT00641511andNCT00659230atwww.
clinicaltrials.gov). Therefore, there yet remains an
unmet clinical need for a potent, safe, and peripher-
ally selective D?H inhibitor.
Etamicastat (development code BIA 5-453) is a po-
tent and reversible inhibitor of peripheral D?H cur-
rently under clinical development for the treatment of
hypertension and heart failure. Etamicastat is a revers-
ibleD?Hinhibitor,displayingmixed(noncompetitive)
type inhibition with respect to dopamine with a low
nanomolar inhibition constant (Ki) value,19which pre-
vents the conversion of dopamine to noradrenaline in
peripheral sympathetically innervated tissues and
slows down the drive of the sympathetic nervous sys-
tem.20In contrast to that found in peripheral tissues,
etamicastat does not affect dopamine and noradrena-
line tissue levels in the brain.20
Etamicastat was tested in animal models predictive
of efficacy in cardiovascular disorders.21–23Etami-
castat reduced systolic (SBP) and diastolic blood pres-
sure (DBP) in spontaneously hypertensive rats with no
changes in normotensive Wistar-Kyoto rats.21,22Et-
amicastat did not affect heart rate (HR) in both spon-
taneously hypertensive rats and Wistar-Kyoto (WKY)
rats. Etamicastat increased survival rates in male car-
diomyopathic hamsters (Bio TO-2 dilated strain) with
advanced congestive heart failure.23
The metabolism of etamicastat is species depen-
dent.24In the rat, N-acetylation is the major metabolic
pathway leading to the formation of BIA 5-961. All
other metabolites occur in minor amounts and corre-
spond to oxidative deaminated (BIA 5-965), C-oxi-
dated (BIA 5-998), and N-oxidated (BIA 5-1016) de-
rivatives of etamicastat.25Entry-into-man studies in
healthy subjects administered a single oral doses of
etamicastat (range, 2–1200 mg) and multiple doses
(range, 25–600 mg/d) showed approximately dose-
T. Nunes et al.
June 2011777

Page 3

proportional pharmacokinetics.26,27In humans, et-
amicastat is metabolized to the acetylated metabolite
BIA 5-961.26,27A high interindividual variability of
etamicastat and BIA 5-961 pharmacokinetic parame-
terswasobserved,andpharmacogenomicdatashowed
that such variability was mainly dependent upon the
N-acetyltransferase (NAT) type 2 acetylator status
(rapid or slow acetylating ability).26,27
Hypertension and cardiac heart failure are very
common in the elderly population, and etamicastat is
in clinical development for the treatment of those con-
ditions. To treat elderly patients, it is necessary to
know if any dose adjustment is needed. Most of the
recognized important differences between young and
elderly patients are pharmacokinetic differences, often
related to impaired excretory function or to drug–drug
interactions. The present study aimed to provide an
initial assessment of the effects of age on the pharma-
cokineticsofetamicastatandonitsclinicaltolerability.
The influence of NAT1 and NAT2 genotype on etami-
castat pharmacokinetics was also explored.
METHODS
Population
Subjects were drawn from the study center’s pool of
volunteers. Volunteers eligible for participation were
healthy male volunteers aged 18 to 45 years (young
group) or ?65 years (elderly group) and nonsmokers
or smokers of ?10 cigarettes/d. Healthy status was
determined by interview, medical history, physical ex-
amination, vital signs, 12-lead electrocardiogram
(ECG), and results of clinical laboratory tolerability
tests (including hematology, plasma biochemistry),
urinalysis, drugs abuse screening, and HIV and hepa-
titis B and C serology considered clinically acceptable
at screening and admission. Subjects were considered
ineligible for participation if they: received any inves-
tigational drug within 90 days, prescription drug
within 30 days, or over-the-counter drugs within 7
days before admission; were prone to orthostatic hy-
potension (defined by a difference between supine SBP
and standing SBP ?20 mm Hg or a difference between
supine DBP and standing DBP ?10 mm Hg); or pre-
sented a ECG QTc interval reading ?450 ms (young
subjects) or ?470 ms (elderly subjects).
Because acetylation is an important metabolic path-
way of etamicastat, the NAT genes, NAT1 and NAT2,
were genotyped by DNAVision (Gosselies, Belgium)
for all those participating in the study. Genomic DNA
was extracted from total venous blood. For NAT1, 8
single nucleotide polymorphisms (SNPs) were ana-
lyzed (190 c?t, 445 g?a, 459 g?a, 559 c?t, 560 g?a,
640 t?g, 1088 t?a, and 1095 c?a) and the genotypes
determined. The corresponding acetylation status was
inferred according to the literature28,29: patients were
classified NAT1 rapid (fast) metabolizers if they car-
ried the NAT1*10(except
NAT1*11 alleles; normal metabolizers if they carried
the NAT1*4 or NAT1*3 alleles or the NAT1*10/*14
genotype; and poor (slow) metabolizers if they carried
the NAT1*14 (except NAT1*10/*14) or NAT1*17
alleles. For NAT2, 4 coding SNPs were analyzed (191
g?a, 341 t?c, 590 g?a, and 857 g?a) and the geno-
types determined. The corresponding acetylation sta-
tus was inferred according to the literature.30,31The
NAT2*4 allele encodes for a fully active enzyme and is
considered the wild type (rapid acetylator) allele. Sub-
jects were classified NAT2 rapid metabolizers if they
carried the NAT2*4/*4 allele or the NAT2*/*5,
NAT2*4/*6, or NAT2*4/*7 genotype, and poor me-
tabolizersiftheycarriedtheNAT2*5/*5,NAT2*6/*6,
or NAT2*7/*7 alleles, or the NAT2*5/*6, NAT2*5/
*7, or NAT2*6/*7 genotype.
NAT1*10/*14) or
Study Design and Procedures
This was an open-label, single-center, parallel-
group study conducted at Biotrial SA (Rennes, France)
in a group of 12 healthy young male subjects and a
group of 12 healthy elderly male subjects. At the time
of the study, no data were available regarding the in-
tra-subject CV for the main pharmacokinetic parame-
ters of etamicastat. Assuming an intra-subject CV
?20%, a sample size of 12 subjects in each age group
provides a power of at least 80% to detect a 20%
difference in the pharmacokinetic parameters at a sig-
nificance level of 5%.32
The trial consisted of a 100 mg etamicastat single-
dose period (Phase A) followed by a multiple-dose pe-
riod(PhaseB)duringwhichsubjectsreceived100mg/d
etamicastat for 7 days (days 6 to 12). First dose of
Phase B occurred 96 hours (day 6) after Phase A single
dose (day 1).
Screening procedures occurred within 28 days be-
fore admission. Subjects were confined to the study
center from the day before the single dose (day –1) to
24hourspostdose(day2)inPhaseA,andfromtheday
before the last dose (day 11) to 24 hours after last dose
(day 13) in Phase B. Ambulatory visits occurred on
Clinical Therapeutics
778 Volume 33 Number 6

Page 4

days3to10anddays14to17(discharge).Etamicastat
was administered in the morning, with 250 mL of wa-
ter, after at least 8 hours of fasting; after dosing, sub-
jects fasted for an additional 4 hours on day 1 (Phase A
single dose) and day 12 (Phase B last dose) and for 30
minutes after dose on the remaining dosing days. The
doseofetamicastatwasobtainedasacombinationof2
capsules of 50 mg manufactured by BIAL (S. Mamede
do Coronado, Portugal). Subjects were requested to
abstain from consuming grapefruit or other citrus fruit
(eg,orange),citrusjuice,andalcohol-orxanthine-con-
taining beverages or foods for 2 days before the Phase
A single dose until 120 hours after the last dose of
Phase B (day 17, discharge). Concomitant medications
were not permitted throughout the study, unless re-
quired for treatment of adverse events (AEs).
Blood samples (3 mL) for the determination of
plasma concentrations of etamicastat and its metabo-
lite BIA 5-961 were collected in lithium-heparin Vacu-
ette (Greiner Bio-One) tubes using an indwelling cath-
eter or venepuncture at the following time points:
Phase A (single dose)—pre-dose (day 1) and at 0.5, 1,
2, 3, 4, 5, 6, 8, 10, 12, 24, 36, 48, 72, and 96 hours
post-dose; Phase B—pre-dose on days 6 to 11, on day
12 at pre-dose, and at 0.5, 1, 2, 3, 4, 5, 6, 8, 10, 12, 24,
36, 48, 72, 96, and 120 hours post-dose. After collec-
tion, blood samples were placed on ice; within 60 min-
utes after collection, the blood samples were centri-
fuged at approximately 1500g and at 4°C for 10
minutes. For the assay of etamicastat and metabolites,
4 aliquots of 250 ?L each of the resulting plasma were
withdrawn and placed into 2-mL cryotubes that were
labelled, frozen, and stored at ?–70°C until analysis.
The etamicastat tolerability profile was evaluated
fromreportedAEs,physicalexamination,vitalsigns,dig-
ital 12-lead ECG, and clinical laboratory safety test
results.
All clinical AEs were monitored throughout the en-
tire study period. Their severity (intensity) was catego-
rized according a 3-point scale (mild, moderate, and
severe) and the causality (potential relationship to
drug) was assessed by the investigator. Laboratory
safety tests (hematology: red blood cell count, hemo-
globin, hematocrit, white blood cell count with differ-
entials [neutrophils, lymphocytes, monocytes, eosino-
phils, basophils], activated partial thromboplastin
time [aPTT], and platelet count; blood chemistry:
sodium, potassium, chloride, total bilirubin, aspar-
tate aminotransferase, alanine aminotransferase,
?-glutamyl transpeptidase, glycemia, alkaline phos-
phatase, total protein, albumin, creatinine, and
urea) were performed at admission and repeated on
days 2, 5, and 13. Seven to 10 days after last dose of
Phase B or early discontinuation, a follow-up visit
occurred; medical history and physical examination
were updated and clinical laboratory tolerability
tests performed.
SBP, DBP, and HR, which were considered pharma-
codynamicvariablesbecauseoftheexpectedactivityof
etamicastat, were recorded in the supine position (after
resting for 10 minutes) using a Dinamap (GE Health-
care, Helsinki, Finland) blood pressure monitor at the
following time points: Phase A—pre-dose and at 1, 2,
3, 4, 6, 8, 10, 12, 16, 24, 36, 48, 72, and 96 hours
post-dose; Phase B—pre-dose, on days 6 to 11; and last
dose (day 12) —pre-dose and at 1, 2, 3, 4, 6, 8, 10, 12,
16, 36, 48, 72, 96, and 120 hours post-dose. Ortho-
static SBP, SBP, and HR were recorded in standing
position (after standing for approximately 2 minutes)
ondays1and12atthefollowingtime-points:pre-dose
and at 2, 4, 8, 12, and 24 hours post-dose. Digital
ECGs were performed after 10 minutes of rest in trip-
licate (with an interval of 5 minutes, with a difference
ofatleast1minutebetweeneachofthe3recordings)at
the same time points as supine SBP, DBP, and HR.
Assay of Etamicastat and BIA 5-961 in Plasma
Plasma concentrations of etamicastat and BIA
5-961 were analyzed at Algorithme Pharma Inc. (La-
val, Quebec, Canada) by LC-MS/MS using a previ-
ously validated method described elsewhere.26The lin-
ear ranges of concentrations of etamicastat and BIA
5-961 were 10 to 1000 ng/mL, with a lower limit of
quantification (LLOQ) of 10 ng/mL. The CV for assay
precision ranged from 4.9% to 7.2% for etamicastat
and from 3.6% to 7.1% for BIA 5-961. The overall
accuracy, measured as the proportion of the deter-
mined value in relation to the true or nominal value,
ranged from 97.1% to 103.1% for etamicastat and
95.2% to 103.0% for BIA 5-961.
Pharmacokinetic Analysis
The following etamicastat pharmacokinetic param-
eters were derived by noncompartmental analysis from
the individual plasma concentration versus time pro-
files33after the single dose of Phase A and the last dose
of Phase B: plasma Cmax; time of occurrence of Cmax
(tmax);Cmin; plasma AUC from time zero to the last
T. Nunes et al.
June 2011779

Page 5

sampling time at which concentrations were at or
above the LLOQ (AUC0–t) and AUC0-–24, both calcu-
latedbythelineartrapezoidalrule;AUC0–?,calculated
from AUC0–t? (Clast/?z), where Clastis the last quan-
tifiable concentration; apparent t½, calculated from ln
2/?z, where ?zis the apparent terminal rate constant,
calculated by log-linear regression of the terminal seg-
ment of the plasma concentration versus time curve;
apparent clearance (CL/F); apparent volume of distri-
bution (V/F); observed degree of accumulation (RO),
calculatedfromAUC0–?(lastdoseofPhaseB)/AUC0–?
(single dose of Phase A); observed accumulation index
(IO); theoretical degree of accumulation (RT) calcu-
lated from 1/(1 – exp ?–?z?), where ? is the dosing
interval (24 hours); and swing (%) and fluctuation
(%). The same parameters, except CL/F and V/F, were
determined for the metabolite BIA 5-961. Actual sam-
pling times were used for deriving the pharmacokinetic
parameters. Plasma concentrations below the LLOQ
were taken as zero for all calculations. All calculations
were made using raw data. Values for tmaxwere dis-
played as nominal times.
The pharmacokinetic parameters were summarized
using descriptive statistics for each age group and for
the NAT2 acetylation status subgroups (rapid and
poor metabolizers) within each age group. For each
parameter, summary statistics included geometric
mean, arithmetic mean, SD, SEM, CV, median, and
range (minimum and maximum).
The predefined primary analysis was the investiga-
tion of the effect of age on the etamicastat pharmaco-
kinetics. Comparisons between elderly versus young
subjects for the single- and multiple-dose data were
based on 1-way ANOVA of the logarithmically trans-
formed parameters of interest (Cmax, AUC0–24,
AUC0–?, and Cmin). Geometric means ratios (GMR) of
parameters of interest and their 90% CIs were calcu-
lated.33Whenever the 90% CI included the unit, no
significant statistical differences associated with age
could be concluded. A tmaxcomparison between age
groups was performed using a nonparametric ap-
proach (Mann-Whitney Wilcoxon test); statistical sig-
nificance was assumed at the P ? 0.05.33Trough val-
ues were used for evaluating the steady-state plasma
concentration. A 1-way ANOVA using predose
plasma concentrations from Phase B was used for de-
fining the time to steady state.33
Pharmacokinetic parameters were calculated by us-
ing WinNonlin Professional Edition 5.2.1 release
(Pharsight, Sunnyvale, California). The statistical
package SAS Version 8.2 (SAS Institute Inc, Cary,
North Carolina) was used for statistical calculations.
Tolerability Analysis
Summary statistics for SBP, DBP, HR, ECG, and
laboratory tolerability tests parameters were prepared.
For the laboratory data, out of range values were
flagged in the data listings and clinically significantly
abnormal values were reported as AEs. A cardiologist
was responsible for providing the interpretation of all
ECGs.TheECGresultsincludedHR,PRinterval,QRS
interval, QT interval, and QTc interval, with com-
ments on normality or abnormality. Two corrections
of the QT interval were investigated: Fridericia’s cor-
rection (QTcF) and Bazett’s correction (QTcB). The
primarymethodofcorrectionwastheQTcF.Amanual
reading of the digital ECGs was conducted to assess
prolongation of QT/QTc intervals in accordance with
the current International Conference on Harmoniza-
tion (ICH) guidelines.34Frequency and incidence ta-
bles were prepared for AEs. AEs were coded according
to the Medical Dictionary for Regulatory Activities.
Ethics Compliance
Thestudywasconductedaccordingtotheprinciples
of the Declaration of Helsinki, ICH Good Clinical
Practice, and French regulations. An Independent Eth-
ics Committee (CCP Ouest VI, Brest, France) reviewed
and approved the study protocol and subject informa-
tion. Written informed consent was obtained for each
subjectbeforeanyscreeningprocedurewasperformed.
RESULTS
Subjects
In total, 25 patients (13 young and 12 elderly) were
enrolled. Their demographic and main baseline char-
acteristics are summarized in Table I. All subjects were
white, except for 1 black subject in the elderly group.
One young subject prematurely discontinued the study
due to a serious AE and was replaced. Twenty-four
subjects (12 in each age group) completed the study.
Because acetylation is the most important etamicastat
metabolic pathway, genotyping was performed to dis-
tinguish between poor and faster acetylators; the cor-
responding results are included in Table I.
Pharmacokinetics
Figure 1 displays the mean plasma concentration–
time profiles of etamicastat and BIA 5-961 after a 100
Clinical Therapeutics
780Volume 33 Number 6

Page 6

mg etamicastat single dose and the last dose of a 100
mg/d regimen of etamicastat for 7 days in elderly and
young subjects. The corresponding pharmacokinetic
parameters are presented in Table II.
The elderly/young GMR and 90% CIs of etami-
castat and BIA 5-961 main pharmacokinetic parame-
ters are presented in Table III. The systemic exposure
toetamicastat,asassessedbyCmax,AUC0–24,AUC0–?,
and Cmin, was not significantly different in elderly and
young subjects both after the single and repeated doses
of etamicastat. After multiple doses of etamicastat,
BIA 5-961, AUC0–?, and Cminwere significantly
higher in elderly subjects compared with young sub-
jects. After repeated dosing, the etamicastat Cl/F de-
creased by approximately 20% and the Vd/F in-
creased approximately 30% in the elderly in relation
to the young subjects. The degree of fluctuation was
similar in both age groups. The interindividual vari-
ability in main pharmacokinetic parameters was
high, with a CV of ?60%.
No statistical differences between age groups were
found in etamicastat tmaxafter single (P ? 0.688) or
repeated (P ? 0.403) doses of etamicastat.
Figure 2 displays the pre-dose (trough) plasma con-
centrations of etamicastat and BIA 5-961 during Phase
B. The ANOVA on the pre-dose concentrations
showed that the steady-state plasma concentrations
were reached on the fourth day (etamicastat) or third
day (BIA 5-961) of repeated once daily administration
of etamicastat in both age groups.
In each age group, subjects were classified rapid or
poor metabolizers according to their NAT genotype.
NAT1 acetylator status showed no effect on etamicastat
pharmacokinetics. NAT2 acetylator status appeared to
affect etamicastat pharmacokinetics in both age groups
(Figure3andTableIV).Systemicexposuretoetamicastat
wasupto3-foldhigherinNAT2poormetabolizerscom-
pared with rapid metabolizers; inversely, systemic expo-
sure to BIA 5-961 was lower in poor metabolizers com-
pared with rapid metabolizers. The interindividual
variability in each NAT2 acetylator status subgroup was
small, with a CV consistently ?40%.
Pharmacodynamics
Figure 4 displays the mean change from baseline
of supine SBP, DBP, and HR after the single dose of
Phase A and the last dose of Phase B. SBP, DBP, and
HR values recorded before dosing on Phase A were
taken as baseline values. There was no apparent
Table I. Summary statistics of demographic and
baseline characteristics by age group.
Demographic
Characteristics
Young Group
(n ? 13)
Elderly Group
(n ? 12)
Age, y
Mean (SD)
Range
32.6 (8.8)
18–44
69.3 (3.3)
65–75
Height (cm)
Mean (SD)
Range
175.8 (6.6)
162–185
166.9 (5.7)
160-179
Weight (kg)
Mean (SD)
Range
79.0 (16.4)
57.0–102
69.2 (9.5)
52–86
Body mass index, kg/m2
Mean (SD)
Range
25.8 (4.9)
20.9–34.4
25.2 (3.1)
19.8–29.0
Systolic blood pressure,
mm Hg
Mean (SD)
Range
117 (12)
103–137
115 (13)
98–143
Diastolic blood pressure,
mm Hg
Mean (SD)
Range
61 (7)
50–75
64 (4)
56–68
Heart rate, beats/min
Mean (SD)
Range
58 (8)
47–70
66 (8)
52–76
Race, n (%)
White
Black
13 (100%)
0
11 (91.7%)
1 (8.3%)
NAT1 genotype, n (%)
NAT1*3/*4
NAT1*4/*10
NAT1*4/*11C
NAT1*4/*4
2 (15.4%)
5 (38.5%)
0
6 (46.2%)
0
2 (16.7%)
1 (8.3%)
9 (75.0%)
NAT1 acetylator status,
n (%)
Rapid metabolizers
Poor metabolizers
8 (61.5%)
5 (38.5%)
9 (75.0%)
3 (25.0%)
NAT2 genotype, n (%)
NAT2*4/*4
NAT2*4/*5
NAT2*4/*6
NAT2*5/*5
NAT2*5/*6
1 (7.7%)
6 (46.2%)
0
2 (15.4%)
4 (30.8%)
0
6 (50.0%)
1 (8.3%)
2 (16.7%)
3 (25.0)
NAT2 acetylator status,
n (%)
Rapid metabolizers
Poor metabolizers
7 (53.8%)
6 (46.2%)
7 (58.3%)
5 (41.7%)
NAT ? N-acetyl transferase.
T. Nunes et al.
June 2011 781

Page 7

change in supine SBP and DBP in young subjects. In
elderly subjects, there was an apparent decrease in
supine SBP and DBP after the first and last doses.
Standing SBP, DBP, and HR (Figure 5) showed no
postural changes in blood pressure or HR.
Tolerability
In the young group, a total of 4 treatment-emer-
gent AEs were reported by 4 (30.8%) subjects: 3 AEs
(insomnia and 2 cases of headache) occurred in
Phase A and the remaining 1 AE (myopericarditis)
occurred during Phase B. In the elderly group, a total
of 4 AEs were reported by 4 (33.3%) subjects: 1 AE
(pharyngolaryngeal pain) occurred in Phase A and
the remaining 3 AEs (sciatica, asthenia, and back
pain) occurred in Phase B. Paracetamol was admin-
istered for the treatment of 2 AEs (sciatica and back
pain). All AEs were mild to moderate in intensity but
the myopericarditis was severe and led to the sub-
ject’s discontinuation of the study. Myopericarditis
occurred after 2 days of repeated dosing, in Phase B,
and the subject recovered after 7 days of corrective
Figure 1. Mean (SD) plasma concentration–time profiles of (A) etamicastat and (B) BIA 5-961 after a 100-mg
etamicastat single dose and the last dose of a 100-mg/d etamicastat regimen for 7 days in elderly and
young healthy subjects. Limit of quantification: 10 ng/mL.
Clinical Therapeutics
782 Volume 33 Number 6

Page 8

treatment (enoxaparin, clopidogrel, salicylates, and
pantoprazole) without sequellae. After laboratory
workup, this serious AE was considered to be of
probable viral infection etiology, even if it was not
possible to definitely exclude the responsibility of the
drug.
There were no clinically significant abnormalities
in hematology, blood chemistry, vital signs, or ECG
parameters.
DISCUSSION
The primary objective of the study was to investigate the
effect of age on the pharmacokinetics and tolerability of et-
amicastatinelderly(?65years)versusyoungadult(18–45
years) subjects. Additionally, the influence of NAT1 and
NAT2 genotype on etamicastat pharmacokinetics was
explored.
The dosage regimen (100 mg/d) adopted in this
study was chosen on the basis of preliminary pharma-
Table II. Mean (SD) pharmacokinetic parameters of etamicastat and BIA 5-961 after an etamicastat 100-mg
single dose and the last dose of a 100-mg/d regimen for 7 days in elderly and young healthy subjects.
AnalyteParameter
YoungElderly
Single Dose
(n ? 13)
Multiple Dose
(n ? 12)
Single Dose
(n ? 12)
Multiple Dose
(n ? 12)
EtamicastatCmax(ng/mL/kg)
tmax(h)
AUC0–t(ng ? h/mL/kg)
AUC0–24(ng ? h/mL/kg)
AUC0–?(ng ? h/mL/kg)
t1/2(h)
Cl/F (L/h/kg)
V/F (L/kg)
Cmin(ng/mL/kg)
RO
IO
RT
Swing (%)
Fluctuation (%)
Cmax(ng/mL/kg)
tmax(h)
AUC0–t(ng ? h/mL/kg)
AUC0–24(ng ? h/mL/kg)
AUC0-–?(ng ? h/mL/kg)
t1/2(h)
Cmin(ng/mL/kg)
RO
IO
RT
Swing (%)
Fluctuation (%)
1.32 (0.40)
1.0 (0.5–5.0)
7.82 (5.10)
7.71 (4.05)
10.0 (6.58)
9.4 (6.6)
2.61 (1.68)
22.4 (5.74)
–
–
–
–
–
–
2.47 (1.52)
3.0 (2.0–5.0)
15.3 (9.51
15.9 (8.98)
16.5 (9.69)
4.3 (1.8)
–
–
–
–
–
–
1.46 (0.67)
1.5 (1.0–4.0)
15.8 (10.2)
12.5 (6.49)
20.7 (12.3)
17.3 (5.8)
1.78 (0.78)
40.1 (15.1)
0.21 (0.16)
1.68 (0.24)
1.45 (0.39)
1.63 (0.32)
497 (177)
266 (96)
3.06 (1.96)
2.5 (2.0–4.0)
25.0 (14.6)
22.2 (11.8)
26.1 (13.4)
10.2 (3.7)
0.16 (0.15)
1.38 (0.21)
1.35 (0.22)
1.26 (0.17)
1559 (729)
301 (63)
1.32 (0.45)
1.0 (0.5–2.0)
9.52 (5.46)
8.65 (3.36)
12.4 (7.79)
11.8 (9.1)
2.48 (1.30)
27.2 (9.49)
–
–
–
–
–
–
3.49 (2.13)
4.0 (2.0–6.0)
26.2 (14.4)
25.9 (13.6)
28.4 (14.7)
6.5 (2.9)
–
–
–
–
–
–
1.82 (0.52)
1.0 (0.5–5.0)
24.5 (15.9)
15.0 (6.44)
32.2 (18.9)
28.1 (12.2)
1.66 (0.62)
62.6 (36.0)
0.27 (0.18)
1.73 (0.17)
1.39 (0.35)
2.25 (0.71)
583 (320)
282 (120)
4.34 (2.61)
3.0 (2.0–5.0)
40.0 (21.5)
34.6 (17.6))
43.0 (21.9
13.3 (7.3)
0.28 (0.22)
1.34 (0.19)
1.26 (0.24)
1.42 (0.40)
1184 (711)
272 (79)
BIA 5-961
CL/F ? apparent clearance; IO? observed accumulation index; RO? observed degree of accumulation; RT? theoretical
degree of accumulation; V/F ? apparent volume of distribution.
tmaxvalues are given as median (range).
T. Nunes et al.
June 2011 783

Page 9

cokinetic and pharmacodynamic data of entry-into-
man clinical studies with etamicastat in healthy sub-
jects.26,27The study design agreed with the standard
design for a Phase I study in healthy subjects aiming to
investigate the effect of age on the drug pharmacoki-
netics.35Pharmacokinetic information from this type
Table III. Geometric mean ratios (GMR) and 90% CIs after an etamicastat 100-mg single dose and the last dose
of a 100-mg/d regimen for 7 days in healthy elderly and young subjects.
Analyte PK Parameter
Single DoseRepeated Dose
GMR 90% CIGMR 90% CI
EtamicastatCmax
AUC0–24
AUC0–?
Cmin
Swing
Fluctuation
Cmax
AUC0–24
AUC0–?
Cmin
Swing
Fluctuation
0.944
1.096
1.164
–
–
–
1.313
1.514
1.596
–
–
–
0.788–1.131
0.786–1.527
0.730–1.855
–
–
–
0.837–2.059
0.997–2.299
1.041–2.447
–
–
–
1.225
1.171
1.478
1.092
1.086
1.031
1.353
1.478
1.557
1.569
1.718
1.886
0.960–1.563
0.850–1.612
0.956–2.285
0.781–1.527
0.763–1.546
0.775–1.372
0.838–2.185
0.978–2.232
1.046–2.317
1.048–2.349
0.459–1.122
0.738–1.064
BIA 5-961
PK ? pharmacokinetic.
Figure 2. Mean (SD) pre-dose plasma concentrations of (A) etamicastat and (B) BIA 5-961 during a 100-mg/d
etamicastatregimenfor7days(PhaseB)inelderlyandyounghealthysubjects.Limitofquantification:
10 ng/mL.
Clinical Therapeutics
784Volume 33 Number 6

Page 10

of study is very useful at an early phase of drug devel-
opment to define the dosage regimens to be tested in
elderly subjects enrolled in later therapeutic studies.
However, population pharmacokinetics appear to be
the most adequate and informative tool to be used
across the heterogeneous population of elderly pa-
tients.36Therefore,pharmacokineticinformationfrom
Phase I studies should be complemented by population
pharmacokinetic information from later therapeutic
clinical trials.36
The kinetic profile of etamicastat did not signifi-
cantly differ between age groups after a 100 mg etami-
castat single dose and 100 mg/d etamicastat adminis-
tration for 7 days. The etamicastat mean accumulation
Figure 3. Mean (SD) plasma concentration–time profiles of (A) etamicastat and (B) BIA 5-961 in NAT2 rapid and
poor metabolizers after a 100-mg etamicastat single dose and the last dose of a 100-mg/d etamicastat
regimen for 7 days in elderly and young healthy subjects. Limit of quantification: 10 ng/mL. (Figure 3
continued on next page).
T. Nunes et al.
June 2011785

Page 11

ratio was moderate (ROof approximately 1.7 in both
age groups), indicating a relatively small accumula-
tion. After repeated dosing, the etamicastat Cl/F de-
creased by approximately 20% and V/F increased by
approximately 30% in elderly subjects compared with
young subjects. A possible reason for the reduction in
etamicastat clearance in the elderly may be the reduced
elimination efficiency in this population, leading to an
increase in etamicastat elimination half-lives after re-
peated dosing (t1/2of 17.3 hours in young subjects and
28.1 hours in elderly), and an increased volume of dis-
tribution. Steady-state plasma concentrations were
reached within 3 to 4 days of repeated dosing.
A relatively high interindividual variability (CV of
?60%) in etamicastat pharmacokinetic parameters
wasobservedinthetotalpopulationofeachagegroup.
However, a relatively low interindividual variability
was found in each NAT2 acetylator status subgroup of
each age group, suggesting that the biotransformation
rate of etamicastat into its acetylated metabolite, de-
Figure 3. (continued).
Clinical Therapeutics
786 Volume 33 Number 6

Page 12

Table IV. Mean (SD) pharmacokinetic parameters of etamicastat and BIA 5-961 after an etamicastat 100-mg single dose and the last dose of a
100-mg/d regimen for 7 days in young and elderly healthy subjects grouped according to their N-acetyl transferase (NAT) type 2 acetylator
status.
AnalyteParameter
Elderly Subjects
Rapid Metabolizers Slow MetabolizersRapid Metabolizers Slow Metabolizers
Single Dose
(n ? 7)
Multiple Dose
(n ? 7)
Single Dose
(n ? 6)
Multiple Dose
(n ? 5)
Single Dose
(n ? 7)
Multiple Dose
(n ? 7)
Single Dose
(n ? 5)
Multiple Dose
(n ? 5)
EtamicastatCmax(ng/mL/kg)
tmax(h)
AUC0–t(ng ? h/mL/kg)
AUC0-24(ng ? h/mL/kg)
AUC0–?(ng ? h/mL/kg)
t1/2(h)
Cl/F (L/h/kg)
V/F (L/kg)
Cmin(ng/mL/kg)
RO
IO
RT
Cmax(ng/mL/kg)
tmax(h)
AUC0–t(ng ? h/mL/kg)
AUC0–24(ng ? h/mL/kg)
AUC0–?(ng ? h/mL/kg)
t1/2(h)
Cmin(ng/mL/kg)
RO
IO
RT
1.19 (0.42)
1.0 (0.5–2.0)
4.23 (2.38)
5.06 (2.78)
5.28 (2.94)
4.0 (1.8)
3.91 (1.18)
20.5 (5.95)
–
–
–
–
3.70 (0.82)
2.0 (2.0–5.0)
22.5 (6.70)
22.9 (5.57)
23.9 (6.64)
4.4 (2.2)
–
–
–
–
1.23 (0.69)
1.0 (1.0–2.0)
8.73 (5.21)
8.40 (4.26)
12.2 (6.21)
14.3 (5.6)
2.33 (0.51)
46.4 (16.9)
0.11 (0.11)
1.73 (0.31)
1.68 (0.34)
1.47 (0.30)
4.41 (1.36)
2.0 (2.0–3.0)
35.2 (9.20)
30.6 (7.04)
35.1 (8.64)
9.7 (2.7)
0.23 (0.14)
1.35 (0.16)
1.31 (0.20)
1.23 (0.12)
1.28 (0.42)
1.0 (1.0–5.0)
12.0 (4.06)
10.8 (2.96
15.6 (4.94)
15.7 (3.7)
1.10 (0.12)
24.6 (5.09)
–
–
–
–
1.03 (0.31)
3.0 (3.0–5.0)
6.84 (2.24)
7.61 (2.25)
7.87 (2.44)
4.1 (1.4)
–
–
–
–
1.77 (0.54)
2.0 (1.0–4.0)
25.8 (5.91)
18.2 (4.22)
32.4 (7.98)
21.5 (3.1)
1.01 (0.07)
31.3 (5.40)
0.35 (0.10)
1.61 (0.10)
1.20 (0.12)
1.86 (0.18)
1.17 (0.40)
3.0 (2.0–4.0)
10.7 (4.43)
10.5 (4.26)
13.4 (6.10)
11.0 (5.0)
0.06 (0.08)
1.43 (0.27)
1.41 (0.26)
1.31 (0.23)
1.32 (0.55)
1.0 (0.5–1.0)
5.19 (0.99)
6.11 (1.21)
6.33 (1.33)
4.6 (0.8)
3.51 (0.26)
23.3 (4.38)
–
–
–
–
4.76 (1.93)
2.0 (2.0–6.0)
34.1 (13.8)
33.6 (12.7)
36.0 (14.3)
5.5 (2.1)
–
–
–
–
1.67 (0.49)
1.0 (0.5–5.0)
12.8 (3.87)
10.4 (1.82)
18.4 (6.05)
22.4 (12.1)
2.14 (0.21)
70.5 (45.2)
0.15 (0.11)
1.71 (0.16)
1.65 (0.15)
1.92 (0.70)
6.05 (2.05)
2.0 (2.0–5.0)
50.9 (21.5)
45.1 (15.8)
54.4 (22.3)
12.9 (9.1)
0.34 (0.26)
1.36 (0.15)
1.30 (0.16)
1.41 (0.50)
1.32 (0.29)
2.0 (1.0–2.0)
15.6 (1.19)
12.2 (1.31)
20.9 (2.91)
21.8 (3.4)
1.03 (0.31)
32.6 (12.5)
–
–
–
–
1.72 (0.46)
4.0 (4.0–5.0)
15.1 (4.90)
15.3 (4.59)
17.8 (6.44)
8.0 (3.5)
–
–
–
–
2.03 (0.54)
1.0 (1.0–2.0)
40.8 (10.1)
21.4 (4.47)
51.5 (11.6)
36.0 (7.3)
1.00 (0.23)
51.6 (15.5)
0.44 (0.08)
1.75 (0.21)
1.02 (0.15)
2.70 (0.43)
1.94 (0.38)
4.0 (3.0–4.0)
24.7 (8.54)
20.0 (4.46)
27.2 (5.51)
13.9 (4.6)
0.21 (0.14)
1.35 (0.25)
1.20 (0.33)
1.44 (0.25)
BIA 5-961
CL/F ? apparent clearance; IO? observed accumulation index; RO? observed degree of accumulation; RT? theoretical degree of accumulation; V/F ? apparent volume of distribution.
tmaxvalues are given as median (range).
T. Nunes et al.
June 2011
787

Page 13

Figure 4. Mean(SD)(A)supinesystolicbloodpressure(SBP),(B)diastolicbloodpressure(DBP),and(C)heart
rate(HR)changefrombaselineaftera100-mgetamicastatsingledoseandthelastdoseofa100-mg/d
etamicastat regimen for 7 days in elderly and young healthy subjects.
Clinical Therapeutics
788 Volume 33 Number 6

Page 14

160
A After a single dose
140
120
Mean (SD) Standing SBP
(mm Hg)
Time Post-dose (h)
100
80
60
04812 1620 24
Elderly (n = 12)
Young (n = 13)
160
AAfter the last dose
140
120
Mean (SD) Standing SBP
(mm Hg)
Time Post-dose (h)
100
80
60
048 12 16 2024
Elderly (n = 12)
Young (n = 12)
130
B
110
90
Mean (SD) Standing DBP
(mm Hg)
Time Post-dose (h)
70
50
30
048 1216 2024
Elderly (n = 12)
Young (n = 13)
130
B
110
90
Mean (SD) Standing DBP
(mm Hg)
Time Post-dose (h)
70
50
30
048 1216 2024
Elderly (n = 12)
Young (n = 12)
120
C
100
80
Mean (SD) Standing HR
(beats/min)
Time Post-dose (h)
60
40
120
100
80
60
40
048 12 162024
Elderly (n = 12)
Young (n = 13)
C
Mean (SD) Standing HR
(beats/min)
Time Post-dose (h)
048 1216 2024
Elderly (n = 12)
Young (n = 12)
Figure 5. Mean (SD) (A) standing systolic blood pressure (SBP), (B) diastolic blood pressure (DBP), and (C)
heart rate (HR) after a 100-mg etamicastat single dose and the last dose of a 100-mg/d etamicastat
regimen for 7 days in elderly and young healthy subjects.
T. Nunes et al.
June 2011 789

Page 15

pendent upon the NAT2 acetylator status, was the ma-
jor source of variability.
AlthoughtheNAT1acetylatorstatusshowednoeffect
onetamicastatpharmacokinetics,theresultsofthisstudy
clearlydemonstratedthattheNAT2acetylatorstatushad
an effect on systemic exposure to etamicastat in both age
groups. In both young and elderly populations, etami-
castat systemic exposure in NAT2 rapid metabolizers
was approximately one third of that observed in poor
metabolizers.Inversely,NAT2
showeda2-to3-foldincreaseinsystemicexposuretothe
acetylated metabolite, confirming the involvement of
NAT2 in the biotransformation of etamicastat into BIA
5-961. The overall results suggested that the need of dos-
age adjustment according to the NAT2 acetylator status
shouldbeinvestigatedinfurthertherapeuticclinicaltrials
with etamicastat.
Althoughtherewasnoapparentchangefrombaseline
in supine blood pressure in young subjects, a decrease of
supine blood pressure was apparent in elderly subjects,
beingmorepronouncedapproximately6to8hourspost-
dose, both after a single dose and the last dose of a 7-day
once daily regimen. This age-dependent effect was pre-
sumablyfacilitatedbyslightlyhigherbaselinebloodpres-
sure values in the elderly compared with the young pop-
ulation. It can be speculated that the reported decrease in
blood pressure can be attributed to D?H inhibition by
etamicastat. The results, however, should be interpreted
with caution because there was no control group in the
present study; the sample size was small, the blood pres-
sure profiling along the 24-hour interval was not cor-
rected for the known circadian variation of blood pres-
sure, and the individual exposure to etamicastat varied
markedly among subjects because differences in NAT2
acetylatorstatus.Noapparentdifferencewasobservedin
the effect of etamicastat on supine HR between the age
groups. Standing blood pressure and HR measurements
did not suggest an increased risk of postural changes.
Etamicastat was subjectively well tolerated by
most subjects after single and repeated dosing of
etamicastat in both age groups. One young subject
had a serious AE (myopericarditis), which led to his
premature discontinuation. This AE was considered
to be of probable viral infection etiology, but it was
not possible to exclude the responsibility of etami-
castat. There were no clinically significant abnor-
malities in laboratory safety tests, vital signs, or
ECG parameters.
rapidmetabolizers
CONCLUSION
Etamicastat was generally well tolerated in the popu-
lation studied and its kinetic profile was not signifi-
cantly different in these small groups of healthy young
versus elderly adult male volunteers.
ACKNOWLEDGMENTS
This study was supported by BIAL-Portela & CaSA. T.
Nunes, J. F. Rocha, M. Vaz-da-Silva, L. Almeida, and P.
Soares-da-SilvaareorwereemployeesofBIAL(thesponsor
of the study) at the time of the study. The other author (A.
Falcao) is or was an employee of a contract research orga-
nizationcontractedbythesponsortoreviewthepharmaco-
kinetic data (4Health Consulting). The authors have indi-
cated that they have no other conflicts of interest regarding
thecontentofthisarticle.Allauthorscontributedequallyto
theconductofthestudyandcreationofthemanuscript.
REFERENCES
1. Esler M, Kaye D. Sympathetic nervous system activation in
essential hypertension, cardiac failure and psychosomatic
heartdisease.JCardiovascPharmacol.2000;35(Suppl4):S1–S7.
2. Grassi G, Bolla G, Quarti-Trevano F, et al. Sympathetic
activationincongestiveheartfailure:reproducibilityofneuroa-
drenergicmarkers.EurJHeartFail.2008;10:1186–1191.
3. Grassi G, Seravalle G, Quarti-Trevano F. The ’neuroadrenergic
hypothesis’ in hypertension: current evidence. Exp Physiol. 2010;
95:581–586.
4. Lee CS, Tkacs NC. Current concepts of neurohormonal
activation in heart failure: mediators and mechanisms.
AACNAdvCritCare.2008;19:364–385.
5. ManciaG,GrassiG,GiannattasioC,SeravalleG.Sympathetic
activation in the pathogenesis of hypertension and progres-
sionoforgandamage.Hypertension.1999;34:724–728.
6. ParmleyWW.Neuroendocrinechangesinheartfailureand
theirclinicalrelevance.ClinCardiol.1995;18:440–445.
7. Pfeffer MA, Stevenson LW. Beta-adrenergic blockers and
survivalinheartfailure.NEnglJMed.1996;334:1396–1397.
8. Stanley WC, Li B, Bonhaus DW, et al. Catecholamine
modulatory effects of nepicastat (RS-25560-197), a novel,
potent and selective inhibitor of dopamine-beta-hydroxy-
lase.BrJPharmacol.1997;121:1803–1809.
9. Hegde SS, Friday KF. Dopamine-beta-hydroxylase inhibition: a
novel sympatho-modulatory approach for the treatment of
congestiveheartfailure.CurrPharmDes.1998;4:469–479.
10. Soares-da-Silva P. Evidence for a non-precursor dopamine
pool in noradrenergic neurones of the dog mesenteric artery.
NaunynSchmiedebergsArchPharmacol.1986;333:219–223.
11. Soares-da-Silva P. A comparison between the pattern of
dopamine and noradrenaline release from sympathetic neu-
Clinical Therapeutics
790Volume 33 Number 6