Department of Pharmacology, Cornell University Medical College, New
York, New York (H.H.S., Y.S., D.W.);
Department of Reproductive Biology
and Obstetrics and Gynecology, Case Western Reserve University and
MetroHealth Medical Center, Cleveland, Ohio (J.F.C., N.O.);
The Charles
B. Stout Neuroscience Mass Spectrometry Laboratory (D.M.D., O.O.G.,
J.L.T., R.B.) and Departments of
Neurology and Biochemistry (D.M.D.),
University of Tennessee, Memphis, Tennessee; and
Laboratory of Chemical
Biology and Peptide Research, Clinical Research Institute of Montreal,
Montreal, Quebec, Canada (P.W.S.)
Although synthetic opioid peptide analogs have been used extensively to
study the functional roles of opioid receptors, little is known about
their in vivo disposition. Our goal was to develop novel
opioid drugs with limited transfer across the placenta. DALDA
(Tyr-D-Arg-Phe-Lys-NH2) is a potent and highly
selective mu agonist that is quite polar because of its
3+ charge at physiological pH. It can therefore be expected that the
distribution of DALDA across the placenta would be highly restricted.
In this study, we determined the pharmacokinetics and placental
transfer of DALDA after systemic administration in sheep. DALDA was
infused intravenously to four nonpregnant and four pregnant sheep at a
dose of 0.6 mg/kg/hr for 4 hr. Steady state plasma levels of DALDA were
5436 ± 464 ng/ml in nonpregnant sheep and 5214 ± 661 ng/ml
in pregnant sheep. A one-compartment open model provided an excellent
fit for nonpregnant and pregnant plasma data. The apparent volume of
distribution was estimated to be 45.6 ± 4.4 and 59.2 ± 7.9 ml/kg in nonpregnant and pregnant animals, respectively. There was no
difference in the elimination half-life of DALDA in nonpregnant
(1.4 ± 0.1 hr) and pregnant (1.7 ± 0.2 hr) animals, and
clearance was also similar in nonpregnant (23.1 ± 1.7 ml/kg/hr)
and pregnant (23.7 ± 1.3 ml/kg/hr) animals. These data suggest
that the distribution of DALDA is restricted to plasma volume and that
its disposition is not altered in pregnancy. DALDA was not detected in
any of the fetal plasma samples (<50 ng/ml), indicating that fetal
plasma concentration is <1% of maternal concentration. The highly
restricted placental distribution of DALDA suggests that it may be a
promising opioid drug for obstetrical use.
 |
Introduction |
Opiate
alkaloids such as meperidine and morphine are extensively used for pain
relief during labor and delivery. Their use, however, is associated
with a number of adverse effects in the neonate because of their rapid
transfer across the placenta to the fetus. The distribution of
compounds across the placenta is dependent on molecular size and
lipophilicity, and all available opiate alkaloids are small and highly
lipophilic. The goal of our research group has been to develop novel
opioid drugs with limited transfer across the placenta.
The physicochemical characteristics of a peptide drug may be
advantageous in the design of an opioid drug for obstetrical use. The
incorporation of D-amino acids in endogenous opioid
peptides protects them from certain peptidase activity and
significantly increases their stability in vitro, but no
information exists on their disposition in vivo. Dermorphin
(Tyr-D-Ala-Phe-Gly-Tyr-Pro-Ser-NH2) is an endogenous opioid peptide found in amphibian skin that naturally contains a D-amino acid and has been shown to possess many
opioid properties (Broccardo et al., 1981
; Montecucchi
et al., 1981). In vitro degradation studies
revealed that dermorphin is hydrolyzed at the Gly-Tyr bond, resulting
in dermorphin(1-4) being the major metabolite (Sasaki et
al., 1985; Scalia et al., 1986). A synthetic analog of
dermorphin(1-4), DALDA
(Tyr-D-Arg-Phe-Lys-NH2), has been
found to be a potent and highly selective agonist for the mu
opioid receptor (Schiller et al., 1989). In addition, DALDA is unique in that it has a 3+ charge at physiological pH and is therefore very polar and has very limited distribution across the
blood-brain barrier (Samii et al., 1994). It can therefore be expected that the distribution of DALDA across the placenta would
also be highly restricted, which would make this peptide a promising
candidate for use as an obstetrical analgesic.
The objective of this study was to determine the pharmacokinetics of
DALDA in nonpregnant and pregnant sheep. We recently developed a
specific and sensitive method for the quantification of DALDA in ovine
plasma samples (Grigoriants et al., 1997). Here, we present
evidence that supports the highly restricted transfer of DALDA across
the placenta.
| |
Materials and Methods |
Animal preparation.
Chronic indwelling catheters were
surgically placed in four nonpregnant ewes and four pregnant ewes
(gestational age, 115-120 days; term, 
145 days) as described by
Szeto et al. (1990). One polyvinyl catheter was inserted
into the femoral artery and advanced to the distal aorta for blood
sampling and another was advanced into the inferior vena cava
via the femoral vein for drug infusion. In pregnant animals,
a fetal hindlimb was exposed via a hysterotomy incision, and
chronic indwelling catheters were also placed in the fetal distal aorta
and inferior vena cava. Guidelines approved by the Institution for the
Care and Use of Animals at Cornell University Medical College were
followed for all surgical procedures and experimental protocols.
Compounds.
DALDA was prepared by solid-phase synthesis
according to a protocol described earlier (Schiller et al.,
1989). The synthesis of the deuterated DALDA analog
[H-Tyr-D-Arg-Phe(d5)-Lys-NH2]
was based on the same protocol, except
Boc-Phe(d5)-OH was used in place of Boc-Phe-OH.
Pentadeuterophenylalanine was purchased from C/D/N Isotope (Vaudreuil,
Quebec, Canada) and converted to Boc-Phe(d5)-OH through reaction with di-tert-butyldicarbonate. The
deuterated peptide was purified by semipreparative reversed-phase HPLC
as described previously (Schiller et al., 1989). The purity
of DALDA and d5-DALDA was verified by fast
atom bombardment-MS, and the precise amino acid sequence was confirmed
by tandem MS.
Experimental protocol.
Experiments were performed a minimum
of 5 days after surgery to ensure complete recovery from surgical
stress. The ewe was placed in a mobile cart with free access to food
and water. All studies commenced at 8:00 a.m. with a minimum of 2.5 hr
to allow for acclimation of the animal to the study conditions. DALDA
(supplied by Dr. Peter Schiller and the National Institute on Drug
Abuse) was administered as a constant-rate intravenous infusion (0.6 mg/kg/hr for 4 hr) to the sheep, and blood samples were collected at 0, 1, 2, 3, 3.5, 4, 4.25, 4.5, 5, 6, 7, 12 and 24 hr. Blood samples were
collected from the fetus at 0, 3, 3.5, 4, 5 and 6 hr. All blood samples
were collected into chilled borosilicate glass tubes containing EDTA
and centrifuged, and the plasma was stored in glass containers with
Teflon-lined caps and frozen at 
80°C until they were shipped
overnight to Dr. Dominic Desiderio.
Quantitative analysis of DALDA.
DALDA was quantified by
using reversed-phase HPLC and MS detection. Details of the quantitative
method have been published (Grigoriants et al., 1997) and
are presented here briefly. Plasma samples were deproteinated and
eluted through a solid-phase extraction cartridge (Sep-Pak C18;
Millipore, Milford, MA) with CH3CN. An internal
standard, the deuterated DALDA analog
[Tyr-D-Arg-Phe(d5)-Lys-NH2], was added to each plasma sample before deproteinization. The filtered plasma sample was chromatographed on an RP-analytical column (Delta Pak, 5 µm, C18, 100Å, 150 × 3.9 mm; Waters, Milford, MA) at a flow rate of 1.5 ml/min, and UV absorption was monitored at 200 nm
(Varian Assoc., Walnut Creek, CA). One-minute fractions were collected,
and each fraction was lyophilized for MS analysis (AutoSpecQ tandem
mass spectrometer; Micromass, Altrincham, UK). Continuous flow-LSIMS
was used to quantify DALDA. The (M+H)+ ion
current for DALDA at m/z 612 was compared with the ion
current from d5-DALDA at m/z 617. The
limit of sensitivity of this method is 50 ng/ml DALDA.
Pharmacokinetic analyses.
Plasma levels of DALDA during and
after the 4-hr infusion of DALDA were analyzed using both
model-dependent and -independent methods with nonlinear regression
(WINNONLIN). A one-compartment open model with zero-order input and
first-order elimination provided an excellent fit for nonpregnant and
pregnant plasma data. The derived pharmacokinetic constants were used
to calculate the apparent volume of Vd,
t1/2 and CL. The plasma data were
also analyzed using a model-independent approach with area analysis
(Perrier and Mayersohn, 1982). Rather than ascribing the data to a
specific model, the model-independent approach assumes only that all
dispositional processes may be described by first-order kinetics, with
elimination occurring from the rapidly equilibrating compartment. The
parameters of Vd, CL and MRT are determined from
the total AUC and AUMC.
| |
Results |
DALDA was infused into four nonpregnant and four pregnant sheep at
a dosage of 0.6 mg/kg/hr for 4 hr. This infusion rate was selected on
the basis of preliminary studies using 0.3 to 0.9 mg/kg/hr for 2 to 4 hr. From these preliminary studies, it was apparent that a 4-hr
infusion was necessary for steady-state kinetics; all subsequent
studies were therefore carried out using 4-hr infusions. Figures
1 and 2
illustrate the mean plasma DALDA levels in nonpregnant and pregnant
sheep, respectively. Steady-state levels were achieved by the end of
the 4-hr infusion, with no statistical difference between plasma DALDA
levels at 3.5 and 4 hr (paired t test, P > .05). There
was no significant difference between the plasma concentration at the
end of infusion in nonpregnant (5436 ± 464 ng/ml) and pregnant
(5214 ± 661 ng/ml) animals. Samples obtained at 24 hr did not
contain measurable levels of DALDA. DALDA was not detected in any of
the fetal plasma samples. Because the limit of sensitivity of the
analytical method is 50 ng/ml, the ratio of fetal-to-maternal plasma
concentration is <0.01.
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Fig. 1.
Plasma concentration of DALDA in nonpregnant sheep.
DALDA was infused at a constant rate of 0.6 mg/kg/hr for 4 hr. Data are presented as mean ± S.E.M. (n = 4).
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Fig. 2.
Plasma concentration of DALDA in pregnant sheep.
DALDA was infused at a constant rate of 0.6 mg/kg/hr for 4 hr. Data are
presented as mean ± S.E.M. (n = 4).
|
|
Individual plasma data from nonpregnant and pregnant sheep were
analyzed using compartmental and noncompartmental methods. Compartmental analysis revealed that a one-compartment open model provided an excellent fit for both nonpregnant and pregnant animals, with the correlation between observed and predicted values ranging from
.92 to .99. Figures 3 and
4 are the observed and predicted values
for a representative nonpregnant and pregnant animal, respectively. The
calculated parameters for nonpregnant and pregnant animals are
summarized in tables 1 and
2, respectively. The coefficient of
variation was <10% for all parameter estimates. There was no significant difference in any of the pharmacokinetic parameters between
nonpregnant and pregnant animals.
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Fig. 3.
Observed ( ) and predicted ( ) plasma
concentration of DALDA in one representative nonpregnant sheep. DALDA
was infused at a constant rate of 0.6 mg/kg/hr for 4 hr. Plasma DALDA
concentrations were fitted to a one-compartment open model.
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Fig. 4.
Observed () and predicted () plasma
concentration of DALDA in one representative pregnant sheep. DALDA was
infused at a constant rate of 0.6 mg/kg/hr for 4 hr. Plasma DALDA
concentrations were fitted to a one-compartment open model.
|
|
The results of the noncompartmental analyses are summarized in tables
3 and 4.
The calculated values for Vd, MRT and CL are
quite similar to those estimated from the compartmental analysis. The
data also show no significant difference between the disposition of
DALDA in nonpregnant and pregnant animals.
| |
Discussion |
Although synthetic opioid peptide analogs have been used
extensively to study the functional roles of opioid receptor subtypes, there is no information available on the pharmacokinetics of these peptide analogs in vivo. These data represent the first
attempt in understanding the in vivo disposition of
synthetic opioid peptide analogs, and this is the first time that
detailed pharmacokinetic analyses have been performed using a highly
specific method for peptide quantitation in biofluids. The endogenous
opioid peptides are rapidly degraded in plasma, and the
t1/2 of met-enkephalin was reported
to be 2 min in plasma in vitro (Hambrook et al., 1976). Substitution with D-amino acids significantly
increases peptide stability and has been the rationale behind the
synthesis of a large number of peptide analogs
(D-Ala2) based on the enkephalin
structure. However, pharmacokinetic data are not available for even the
most widely used analogs, such as DAMGO and DPDPE. Using
radioimmunoassay, the t1/2 of DAMME
was determined to be 52 min in sheep (Bolton et al., 1982).
The disadvantage with radioimmunoassay, however, is the lack of
specificity for the parent peptide, and the antibody may cross-react
with degradative fragments. Other in vitro degradation studies used HPLC, but there always is the problem with biofluid samples of coeluting peaks. To the best of our knowledge, this is the
first study in which plasma peptide levels were quantified using HPLC
and MS. MS optimizes the molecular specificity of the detection of
DALDA because the protonated molecule ion,
(M+H)+, of DALDA at m/z 612 is
monitored. Furthermore, an internal standard, the deuterated DALDA
analog, was added to each ovine plasma sample before deproteinization.
In addition to MS analysis, tandem MS/MS was used to confirm the amino
acid sequence of DALDA in selected samples.
Our data show that steady-state plasma levels were achieved with a 4-hr
infusion of DALDA to nonpregnant and pregnant sheep and that there was
no significant difference in the steady-state plasma levels between
pregnant and nonpregnant animals. Model-dependent and -independent
methods resulted in similar pharmacokinetic parameters. The results
show that the distribution of DALDA is very limited, with an apparent
volume of distribution (50 ml/kg) that is approximately equivalent
to plasma volume. This small volume of distribution is consistent with
the polar character of this highly charged (3+) peptide at
physiological pH and is consistent with earlier findings of very
restrictive distribution of DALDA across the blood-brain barrier (Samii
et al., 1994; Schiller et al., 1990). This
apparent volume of distribution is even smaller than the distribution
volume reported for 
-endorphin (180 ml/kg) in humans (Foley et
al., 1979), DAMME (190 ml/kg) in sheep (Bolton et al., 1982) and DPDPE (486 ml/kg) in rats (Chen and Pollack, 1996, 1997). In
addition to the polar nature of DALDA, the small volume of distribution
may also be due to an extensive binding of DALDA to plasma proteins.
There is at present no information on the plasma protein binding of
DALDA. Studies in rats recently showed that 50% of DPDPE is bound
to plasma proteins (Chen and Pollack, 1997).
The structural features of DALDA, with its
D-Arg2 and
Lys4-amide, should confer high metabolic
stability. Indeed, our results revealed a
t1/2 of 1.6 hr in sheep, which is
longer than the t1/2 of
-endorphin in humans (37 min) (Foley et al., 1979) or
DAMME in sheep (52 min) (Bolton et al., 1982). More
importantly, the t1/2 of DALDA is
considerably longer than that for the opiate alkaloids in the sheep,
which is on the order of 20 to 30 min (Szeto et al., 1982,
1978, 1981). These data suggest that the incorporation of the
D-Arg2 and
Lys4-amide significantly enhanced the stability
of the dermorphin peptide against peptidase activity. The elimination
pathway of DALDA in vivo is not known but is likely to be
via renal excretion because of its polar character. The
plasma CL of DALDA was estimated to be 20 ml/kg/hr, which is much
less than the reported CL for -endorphin (192 ml/kg/hr) or DAMME
(168 ml/kg/hr) (Bolton et al., 1982; Foley et
al., 1979). The slow CL of DALDA can be explained, at least in
part, by its very small apparent volume of distribution. In addition,
tubular reabsorption may contribute to the recirculation of DALDA into
plasma.
The results of this study suggest that the pharmacokinetics of DALDA
are not significantly altered in pregnancy. Pregnancy is associated
with a number of physiological changes that are expected to affect the
disposition of hydrophilic and hydrophobic drugs, including an increase
in plasma volume, total body water and fat mass (Reynolds and Knott,
1989). Although the apparent volume of distribution of DALDA was higher
in pregnant animals based on compartmental and noncompartmental
estimation, the difference did not reach statistical significance. The
influence of pregnancy on pharmacokinetics may be more considerable for
lipophilic drugs with more extensive distribution. Similarly, neither
the t1/2 nor CL of DALDA was altered
in pregnant animals.
As we predicted, the placental transfer of DALDA was highly restricted,
with no measurable levels detected in fetal plasma even after 4 hr of
drug infusion to the mother. With the limit of sensitivity of our
analytical method being 50 ng/ml, our data suggest that <1% of the
peptide reaches the fetus. In contrast, the percentages of methadone,
meperidine and morphine reaching the ovine fetus are 30%, 15% and
13%, respectively. The negligible distribution of DALDA to the fetus
can readily account for the lack of effects on fetal cardiovascular and
metabolic function after maternal DALDA administration (Clapp et
al., in press).
The very low extent of fetal drug exposure suggests that DALDA would be
a very safe drug for use in pregnancy. However, the restricted
distribution of DALDA would also mean that it would have difficulty
gaining access into the central nervous system. In fact, available data
have shown that the distribution of DALDA to the central nervous system
is very slow (Samii et al., 1994), and DALDA has only a
small effect in the hot-plate test 2 hr after subcutaneous
administration to mice (Schiller et al., 1990). A solution
to the problem would be to administer DALDA via the
intrathecal route. When administered intrathecally to rats with
indwelling intrathecal catheters, a single dose of DALDA was found to
be highly effective in the tail-flick assay with a duration of action of >4 hr.2 The polar
character of DALDA, together with its metabolic stability, can account
for the extraordinary long duration of antinociception. When
administered in the subdural space, its distribution across the dura is
likely to be very restricted, and DALDA can therefore remain in
cerebrospinal fluid for a long time. Together, these data suggest that
DALDA is a most promising drug for regional obstetrical analgesia.
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Abstract
Introduction
-receptors.
Am J Physiol
258: R1453-R1458
