Departments of Obstetrics and Gynecology, and Physiology, Virginia
Commonwealth University, Medical College of Virginia, Richmond,
Virginia
We hypothesized that AA-2414, a novel thromboxane receptor blocker with
antioxidant properties, would inhibit peroxide-induced vasoconstriction
in the isolated perfused human placental cotyledon. In study 1, placental cotyledons (n = 5) were perfused serially for 20- min intervals with control KrebsRinger-bicarbonate (KRB) buffer, t-butyl hydroperoxide (Px; 100 µM), KRB
buffer, and KRB buffer containing Px to which progressively increasing
concentrations of AA-2414 were added (1 × 10
8 to
1 × 104 mol/l). In study 2, placental cotyledons
(n = 6) were perfused with control KRB buffer, Px
alone, KRB buffer, 1 × 105 mol/l AA-2414 alone, Px
plus AA-2414, and Px alone. Compared with control, perfusion with Px
significantly increased perfusion pressure, vascular resistance, and
the maternal and fetal secretion rates of lipid peroxides, thromboxane
B2 (TXB2) and 6-keto prostaglandin F1
. In study 1, AA-2414 + Px produced a dose-response
inhibition of Px-induced increases in perfusion pressure, vascular
resistance, and maternal secretion of lipid peroxides and
TXB2. In study 2, perfusing AA-2414 at a dose of 1 × 105 mol/l completely inhibited Px-induced
vasoconstriction and increases in lipid peroxide and TXB2
secretion rates, but only partially inhibited the increase in 6-keto
prostaglandin F1 secretion. We conclude that AA-2414
inhibited peroxide-induced vasoconstriction in the human placenta, as
well as peroxide- induced increases in the placental secretion rates of
lipid peroxides and thromboxane, but only partially inhibited
peroxide-induced increases in the placental secretion rate of prostacyclin.
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Introduction |
Preeclampsia
is one of the most significant health problems of human pregnancy. It
is a leading cause of fetal growth retardation, premature birth, and
low birth weight babies. Preeclampsia is characterized by maternal
hypertension, reduced uteroplacental blood flow, increased platelet
aggregation, endothelial cell dysfunction, proteinuria, and edema.
Biochemically preeclampsia is associated with two significant
imbalances: 1) an imbalance of increased thromboxane and decreased
prostacyclin (Walsh, 1985
; Friedman, 1988), and 2) an imbalance of
increased lipid peroxides and decreased antioxidants (Walsh, 1994).
These imbalances may be significant because many of the physiologic and
biochemical actions of lipid peroxides pertain to the abnormalities
that are seen with preeclampsia, as recently reviewed in Walsh (1994).
Some of the effects of lipid peroxides include the following. 1)
Stimulation of prostaglandin endoperoxide synthase to increase
production of thromboxane, but inhibition of prostacyclin synthase to
decrease production of prostacyclin. This imbalance is believed to
contribute to the increased platelet aggregation, maternal
hypertension, and reduced uteroplacental blood flow that occur in
preeclampsia because thromboxane is a potent vasoconstrictor and a
stimulator of platelet aggregation, whereas prostacyclin is a potent
vasodilator and an inhibitor of platelet aggregation. 2) Increased cell
membrane permeability to proteins and increased incorporation of fatty
acids into endothelial cell membranes. Alteration of endothelial cell
membranes in the renal and systemic vasculatures with increased
permeability to proteins could explain proteinuria and edema. 3)
Increased thrombin generation and decreased antithrombin III levels to
trigger thrombus formation. This, along with increased thromboxane
synthesis, could explain coagulation abnormalities, such as
disseminated intravascular coagulation and platelet consumption.
AA-2414 [(±)-7-(3,5,6-trimethyl
1-1,1,4-benzoquinon-2-yl)-7-phenylheptanoic acid] is a novel,
long-acting, potent stereospecific thromboxane
A2/prostaglandin endoperoxide type 2 receptor antagonist (Hussein et al., 1994). AA-2414 inhibits the
contractile response of aortic and saphenous vein preparations to the
thromboxane analog, U-46619, and it is a potent inhibitor of platelet
aggregation. Its effects are thought to be primarily by blocking
thromboxane receptors rather than by affecting the synthesis of
thromboxane, because AA-2414 has been shown to have only weak
inhibitory effects on the activity of the cyclooxygenase enzyme. In
addition to its thromboxane receptor blocking effects, AA-2414 also has
antioxidant properties. AA-2414 inhibits the generation of reactive
oxygen species by alveolar macrophages and polymorphonuclear leukocytes (Matsumoto and Ashida, 1996). These properties of AA-2414 might make it
a potentially useful drug to consider for the treatment of women with preeclampsia.
The isolated perfused human placental cotyledon presents a useful model
to study the potential effects of this drug in pregnancy. This model
offers the advantage of studying the effects in a tissue unique to
pregnancy, and one in which a physiological event, such as
vasoconstriction, can be correlated to a biochemical event, such as
secretion of vasoactive compounds. The following study was done to
evaluate the ability of AA-2414 to block peroxide-induced vasoconstriction in the isolated perfused human placental cotyledon. Maternal and fetal effluent samples were also collected and analyzed for lipid peroxides, thromboxane, and prostacyclin to determine whether
AA-2414 affects their secretion rates by the placenta.
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Materials and Methods |
Placentas were obtained immediately after term delivery from
normally pregnant women delivering at the Medical College of Virginia
main hospital. Institutional approval to conduct this study was granted
by the Committee on the Conduct of Human Research at the Medical
College of Virginia.
Isolated Perfused Placental Cotyledon Methodology.
This
methodology was used as previously described (Walsh et al., 1993).
Briefly, a chorionic plate artery leading to a single placental
cotyledon and a chorionic plate vein draining the cotyledon were
catheterized and perfusion was begun immediately.
Krebs-Ringer-bicarbonate (KRB) buffer gassed with 95%
O2, 5% CO2 and warmed to
37°C was used for perfusion. The composition of the KRB buffer was
125 mM NaCl, 4.5 mM KCl, 0.2 mM
Na2HPO4, 0.7 mM
NaH2PO4, 2.5 mM
CaCl2, 1.0 mM MgSO4, 4.4 mM
glucose (80 mg/100 ml), and 29.8 mEq/l NaHCO3. The placenta was placed in a water-jacketed perfusion chamber warmed to
37°C by a Haake constant-temperature circulating water bath (Haake
model D1L, Fisher Scientific Co., Pittsburgh, PA). To continuously
monitor the perfusion pressure, the fetal arterial catheter was
connected to a pressure transducer connected to a Transbridge TBM 4 transducer amplifier connected to a MP100WS data acquisition
workstation (World Precision Instruments, Inc., Sarasota, FL). A
Macintosh computer was used with AcqKnowledge wave form data analysis
software (World Precision Instruments, Inc., Sarasota, FL). The fetal
side of the cotyledon was perfused at a rate of 3 to 4 ml/min to adjust
the starting fetal side perfusion pressure to approximately 30 mm Hg.
The intervillous space on the maternal side of the cotyledon was
perfused at a rate of 6 to 8 ml/min by placing a butterfly needle
attached to a catheter underneath the basal plate. Two Masterflex
multichannel pumps were used for perfusion (Cole-Parmer Instrument Co.,
Chicago, IL).
Experimental Design.
The experimental designs were based on
a previous study demonstrating that t-butyl hydroperoxide
(Px) induces vasoconstriction in the human placenta specifically by
stimulating thromboxane (Walsh et al., 1993). Peroxides stimulate the
synthesis of thromboxane by stimulating the activity of the
cyclooxygenase enzyme (Hemler et al., 1979; Kulmacz and Lands, 1983). A
vasoconstrictive state can therefore be simulated by perfusing the
human placental cotyledon with Px. Px was obtained from Sigma Chemical
Co. (St. Louis, MO) and AA-2414 was obtained from TAP Holdings,
Inc. (Deerfield, IL). AA-2414 was synthesized at Takeda Chemical
Industries, Ltd., Osaka, Japan.
Study 1: Dose Response of AA-2414.
The first study evaluated
whether the effects of AA-2414 were dose dependent. Placental
cotyledons (n = 5) were perfused serially for 20-min
intervals with control KRB buffer, Px (100 µM), KRB buffer, and KRB
buffer containing Px (100 µM) to which progressively increasing
concentrations of AA-2414 were added (1 × 108, 1 × 107,
1 × 106, 1 × 105, and 1 × 104
mol/l). To validate the specificity of any inhibitory effects observed
for AA-2414, four additional term placentas were studied in which the
Px (100 µM) perfusions were repeated without AA-2414.
Maternal effluent samples were collected during the last 10 min of each
perfusion period, and the effluent flow rates were recorded. Five
milliliters of each sample were evaporated under vacuum centrifugation
(SpeedVac Concentrator, Savant Instruments, Holbrook, NY) and then
reconstituted with ultrapure water to 0.5 ml. Px is a low molecular
weight molecule that is evaporated by vacuum centrifugation (Walsh and
Wang, 1993). Therefore, the Px perfused in the experiment was not a
contaminant of the concentrated samples and did not influence the
measurement of the lipid peroxides.
Study 2: Single Dose of AA-2414.
A second study was done
using a dose of AA-2414 of 1 × 105 mol/l
that is equivalent to plasma levels achieved in clinical studies after
oral administration of AA-2414 (Hussein et al., 1994). In the second
study we evaluated the effects of AA-2414 on fetal, as well as
maternal, secretion rates of lipid peroxides, thromboxane, and
prostacyclin, and we evaluated whether its inhibitory effects persisted
after its perfusion is discontinued. Placental cotyledons (n = 6) were perfused serially for 20-min intervals
with the following treatments: control KRB buffer, Px (100 µM),
control KRB buffer, AA-2414 (1 × 105
mol/l), AA-2414 plus Px, and Px alone. Both maternal and fetal effluent
samples were collected and processed as described above for study 1.
Sample Analysis.
The samples were analyzed for thromboxane
and prostacyclin by radioimmunoassay of their stable metabolites,
thromboxane B2 (TXB2) and
6-keto prostaglandin F1 (6-keto
PGF1). Both assays were validated for
placental perfusion samples as previously described (Walsh et al.,
1993). TXB2 and 6-keto
PGF1 standards and antibodies were purchased
from PerSeptive Diagnostics, Inc. (Cambridge, MA). Tritiated
TXB2 and 6-keto PGF1
were purchased from New England Nuclear (Dupont Research, Wilmington,
DE). Analysis of various volumes of perfusate samples resulted in
parallelism with the standard curve for both assays. Recovery of
exogenously added known amounts of TXB2 or 6-keto
PGF1 to 5 ml of KRB buffer followed by the
concentration procedure was 83 to 98%. KRB buffer blanks resulted in
zero dose responses. Within- and between-assay variations were <10%
for both assays.
Lipid peroxides were analyzed by a spectrophotometric method specific
for peroxides (Frew et al., 1983). Hydrogen peroxide (H2O2) was used to generate
the standard curve so the data are expressed as peroxide equivalents.
We previously described this procedure and its validation for placental
secretion of lipid peroxides (Walsh and Wang, 1993). The results
obtained after concentrating different volumes of placental perfusates
resulted in parallelism with the standard curve. Analysis of a
concentration of 200 µM Px in KRB buffer processed by the
concentrating procedure resulted in a zero dose response verifying that
Px is evaporated by the vacuum centrifugation process. KRB buffer
blanks also resulted in zero dose responses. Within- and between-assay
variations were <10%.
Calculations.
Placental secretion rates were calculated by
multiplying the concentrations in either the fetal or maternal
effluents by their respective effluent perfusion flow rates. Placental
vascular resistance was calculated by dividing the chorionic plate
arteriovenous pressure difference by the fetal effluent flow rate.
Statistical Analysis.
Data were analyzed by ANOVA using the
randomized complete block design to account for variation between
placentas. Duncan's new multiple range post hoc test was used to
determine statistical differences between treatment means. A
statistical computer software program was used (SuperANOVA, Abacus
Concepts, Inc., Berkeley, CA). Log (X + 1) transformation was used when
the variances were not equal. A probability level of P < .05 was considered significant. Data are presented as the mean ± S.E.
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Results |
Study 1: Dose Response of AA-2414.
Figure
1 shows a representative tracing of the
changes in perfusion pressure in response to peroxide perfusion and
peroxide perfusion plus increasing concentrations of AA-2414. Perfusion pressure was substantially increased by the peroxide (Px) alone, but
the increase in pressure was inhibited in a dose-response manner by
AA-2414. Endothelin (ET; 40 nM), a compound that vasoconstricts independent of thromboxane, was perfused at the end of the experiment to demonstrate that the tissue was viable and capable of
vasoconstriction.
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Fig. 1.
A representative recording of changes in placental
perfusion pressure in response to perfusion with Px, and Px + varying
doses of AA-2414 (AA), a potent antioxidant and thromboxane receptor
blocker. Perfusion with peroxide alone (Px-1) significantly increased
the perfusion pressure. Doses of AA-2414 between 1 × 108 mol/l (AA-8) to 1 × 106 mol/l
(AA-6) produced a dose-response inhibition of Px-induced increases in
perfusion pressure. Doses of AA-2414 between 1 × 106 mol/l to 1 × 104 mol/l (AA-4)
completely inhibited Px-induced increases in perfusion pressure. To
demonstrate that the effects of AA-2414 were specific and not due to
vascular fatigue, ET, 40 nM, a hormone that vasoconstricts independent
of thromboxane receptors, was perfused at the end of the experiment. ET
resulted in an immediate and substantial increase in perfusion
pressure.
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Figure 2 demonstrates that the increase
in perfusion pressure and vascular resistance induced by peroxide is
inhibited in a dose-response manner by AA-2414. Compared with the
control perfusion, perfusion with t-butyl hydroperoxide
significantly increased placental perfusion pressure (32.1 ± 0.8 versus 59.6 ± 3.9 mm Hg, P < .01) and vascular
resistance (10.3 ± 1.0 versus 27.9 ± 8.6 mm
Hg · min/ml). Perfusion of the placenta with Px in combination with increasing doses of AA-2414 resulted in a significant dose-response inhibition of peroxide-induced vasoconstriction. Significant inhibition was achieved with a dose as low as 1 × 108 mol/l.
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Fig. 2.
Perfusion with peroxide alone (Px-1) significantly
increased placental perfusion pressure and vascular resistance.
Perfusion of Px in combination with progressively increasing
concentrations of AA-2414 (AA) resulted in a dose-dependent decrease in
peroxide-induced increases in perfusion pressure and vascular
resistance. C represents KRB buffer control perfusions.
AAx represents log concentration of AA-2414. a = significantly higher than controls; b = significantly higher than
controls but significantly lower than Px-1; c = not
significantly different from controls; P < .05. Data represent mean ± S.E.
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Attenuation of the peroxide-induced increases in perfusion pressure and
vascular resistance observed with AA-2414 was a specific effect and not
due to vascular fatigue or some other nonspecific factor, because when
we repeatedly challenged the placental cotyledon with Px without
AA-2414, Px increased perfusion pressure and vascular resistance
comparable with the initial challenge (Fig.
3). Figure 4 shows a representative recording of a
placenta that was repeatedly challenged with Px. Note that the
subsequent challenges with Px result in faster rates of rise in
pressure than what occurs with the initial challenge.
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Fig. 3.
To evaluate whether attenuation in perfusion pressure
was a specific effect of AA-2414 and not due to vascular fatigue or
some other nonspecific factor, we conducted additional experiments
(n = 4) in which we repeatedly challenged placental
cotyledons with Px without AA-2414. The repeated challenges without
AA-2414 resulted in increases in perfusion pressure and vascular
resistance comparable with the first challenge demonstrating that the
inhibitory effect observed for AA-2414 was specific. a = significantly higher than controls; P < .05. Reprinted from Holles SM et al. (1997) courtesy of Marcel Dekker,
Inc.
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Fig. 4.
Recording of changes in placental perfusion pressure
for a placenta repeatedly challenged with Px. Note that the second
response in this placenta is greater than the first response and that
subsequent challenges with Px result in faster rates of rise in
pressure than what occurs with the first challenge. C, Control KRB
buffer perfusion. Reprinted from Holles SM et al. (1997) courtesy of
Marcel Dekker, Inc.
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The changes in the pattern of perfusion pressure and vascular
resistance were paralleled by changes in the maternal secretion rates
of lipid peroxides and thromboxane (Fig.
5). Compared with control, Px
significantly increased the maternal secretion rates of lipid peroxides
(19.8 ± 7.0 versus 31.3 ± 5.5 nmol/min, P < .05) and thromboxane (1.6 ± 0.8 versus 3.4 ± 0.8 ng/min,
P < .01). Significant inhibition of peroxide-induced
increases in the maternal secretion of lipid peroxides was achieved
with a dose of AA-2414 of 1 × 107 mol/l
(14.6 ± 5.5 nmol/min) and of thromboxane with a dose of 1 × 108 mol/l (2.3 ± 0.5 ng/min).
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Fig. 5.
Perfusion with Px alone significantly increased the
maternal secretion rates of lipid peroxides and thromboxane. When
AA-2414 was perfused in conjunction with Px, it resulted in a
dose-dependent inhibition of the Px-induced increases that paralleled
the declines in perfusion pressure and vascular resistance shown in
Fig. 2. a = significantly higher than controls; c = significantly lower than Px-1, not significantly different from
controls; P < .05. Abbreviations are the same as
for Figs. 1 and 2.
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Study 2: Single Dose of AA-2414.
Consistent with the first
study, compared with the control perfusion, perfusion with Px
significantly increased perfusion pressure (30.8 ± 0.8 versus
60.3 ± 5.6 mm Hg, P < .01) and vascular resistance (11.5 ± 1.3 versus 23.4 ± 1.9 mm
Hg · min/ml, respectively, Fig. 6).
Perfusion with AA-2414 alone had no effect, but when the placenta was
again challenged with Px, AA-2414 completely blocked the ability of
peroxide to increase perfusion pressure (25.7 ± 1.1 mm Hg) and
vascular resistance (9.4 ± 0.8 mm Hg · min/ml).
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Fig. 6.
Perfusion with AA-2414 at a concentration of 1 × 105 mol/l completely inhibited the ability of Px to
induce vasoconstriction. a = significantly higher than controls;
c = not significantly different from controls;
P < .05. Abbreviations are the same as for Figs. 1
and 2.
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AA-2414 inhibited peroxide-induced increases in both the maternal and
fetal secretion rates of lipid peroxides (Fig.
7). Compared with control, Px
significantly increased the secretion rates of lipid peroxides on both
the maternal (M) and fetal (F) sides of the placenta (M, 48.9 ± 6.0 versus 68.0 ± 2.7 nmol/min, P < .01; F,
4.1 ± 1.6 versus 7.1 ± 1.9 nmol/min, P < .05, respectively). Perfusion with AA-2414 alone for 20 min resulted in
slight decreases in the maternal and fetal secretion rates of lipid
peroxides, but the declines were not statistically significant. When
AA-2414 was perfused along with Px, it completely inhibited the ability of peroxide to increase the maternal (23.2 ± 4.1 nmol/min) and fetal (4.0 ± 0.7 nmol/min) secretion rates of lipid peroxides. The maternal secretion rate of lipid peroxides was highly correlated with changes in perfusion pressure, r = 0.750, as was
the fetal secretion rate, r = 0.514.
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Fig. 7.
AA-2414 at a concentration of 1 × 105 mol/l completely inhibited the Px-induced increases
in maternal and fetal lipid peroxide secretion. a = significantly
higher than controls; c = not significantly different from
controls; P < .05. Abbreviations are the same as
for Figs. 1 and 2.
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The results for thromboxane (Fig. 8) were
similar to those for lipid peroxides. Compared with control, Px
significantly increased both maternal and fetal thromboxane secretion
rates (M, 1.4 ± 0.5 versus 4.8 ± 0.7 ng/min; F, 0.02 ± 0.01 versus 0.97 ± 0.18 ng/min, respectively). Perfusion with
AA-2414 alone for 20 min resulted in declines in both the maternal and
fetal secretion rates of thromboxane from 1.6 ± 0.4 to 0.8 ± 0.2 ng/min and from 0.4 ± 0.2 to 0.05 ± 0.04 ng/min,
respectively. The decline in the fetal secretion rate for thromboxane
was statistically significant (P < .05). When the
placenta was again challenged with Px in combination with AA-2414,
AA-2414 inhibited the peroxide-induced increases in maternal and fetal
thromboxane secretion in comparison with peroxide perfusion alone
(Px-1) (M, 1.9 ± 0.5 ng/min, P < .01, F,
0.4 ± 0.08 ng/min, P < .01). The maternal
secretion rate of thromboxane was highly correlated with changes in
perfusion pressure, r = 0.725, as was the fetal
secretion rate, r = 0.493.
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Fig. 8.
AA-2414 at a concentration of 1 × 105 mol/l significantly inhibited the Px-induced
increases in maternal and fetal TXB2 secretion. Perfusion
with AA-2414 alone (AA) resulted in declines in the maternal and fetal
basal secretion rates of TXB2 that reached statistical
significance on the fetal side. a = significantly higher than
controls; c = not significantly different from controls; d = significantly lower than controls; P < .05. Abbreviations are the same as for Figs. 1 and 2.
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The effect of AA-2414 on prostacyclin secretion (Fig.
9) was somewhat different than that on
lipid peroxide and thromboxane secretion rates. As for lipid peroxides
and thromboxane, Px increased the secretion rate of prostacyclin (M,
2.7 ± 2.3 versus 8.1 ± 5.4 pg/min; P = N.S.; F, 1.8 ± 0.4 versus 28.3 ± 7.7 pg/min,
P < .01). AA-2414 alone did not affect prostacyclin
secretion. Unlike the results for lipid peroxides and thromboxane,
perfusion of AA-2414 in conjunction with Px did not block the ability
of peroxide to increase prostacyclin secretion, although the increase
was not as great as with peroxide alone (M, 6.0 ± 2.9 ng/min,
P = N.S.; F, 15.9 ± 4.2 ng/min, P < .05). The maternal secretion rate of prostacyclin was not correlated
with changes in perfusion pressure, r = 0.130, but the
fetal secretion rate was correlated, r = 0.442.
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Fig. 9.
Px significantly increased fetal secretion of
prostacyclin. In contrast to results obtained for lipid peroxides and
thromboxane, AA-2414 only partially inhibited ability of Px to increase
fetal secretion of prostacyclin. Although the fetal concentration for
AA + Px was lower than peroxide alone (Px-1), it was nevertheless
significantly higher than controls and AA alone. a = significantly
higher than controls; b = significantly higher than controls but
significantly lower than Px-1; c = not significantly different
from controls; P < .05. Abbreviations are the same
as for Figs. 1 and 2.
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In the second study we also evaluated whether the antioxidant and
thromboxane receptor blocking effects persisted after perfusion with
AA-2414 was discontinued. At the end of each experiment, we challenged
the placenta a second time with Px (100 µM) alone. As seen in Figs.
6-9, the second challenge with peroxide (Px-2) had no significant
effect when it was given immediately following the AA-2414 perfusion.
To see whether the inhibitory effects of AA-2414 were long lasting, we
conducted two additional experiments in which we first perfused Px
alone to demonstrate an increase in perfusion pressure and then
peroxide plus AA-2414 (1 × 105 mol/l) to
verify inhibition. The AA-2414 perfusion was then discontinued and the
placental cotyledon was repeatedly challenged with 20-min peroxide
perfusions alternated with 20-min KRB buffer control perfusions for
2 h and 20 min. The inhibitory effects of AA-2414 persisted during
this time period as demonstrated by the inability of peroxide to induce
an increase in perfusion pressure (data not shown). The antioxidant
effect of AA-2414 also persisted because the peroxide challenges did
not increase lipid peroxide or thromboxane secretion rates (data not
shown). To demonstrate persistent antagonism of the thromboxane
receptors, we gave a bolus injection of the thromboxane mimic, U46619,
5 µg, at the end of these experiments. In previous experiments, a
2.5-µg bolus injection of U46619 routinely increased perfusion
pressure 100 to 140 mm Hg and the effect was long lasting, but after
perfusion with AA-2414, a 5-µg bolus injection increased perfusion
pressure by only 5 to 20 mm Hg and then only transiently.
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Discussion |
This study demonstrated that AA-2414, a compound that is both a
potent antioxidant and thromboxane receptor antagonist, caused dose-response inhibition of peroxide-induced vasoconstriction in the
isolated perfused human placental cotyledon. The inhibition was a
specific effect of AA-2414 because the isolated placental cotyledon
will repeatedly vasoconstrict to repeated challenges with Px.
AA-2414 also inhibited in a dose-response manner the maternal secretion
rates of lipid peroxides and thromboxane. At a dose of AA-2414 of
1 × 105 mol/l that approximates plasma
levels achieved in clinical studies (Hussein et al., 1994), there was
essentially complete inhibition of peroxide-induced vasoconstriction,
as well as inhibition of peroxide-stimulated increases in the maternal
secretion rates of lipid peroxides and thromboxane. Interestingly,
AA-2414 only partially inhibited peroxide-stimulated increases in the
fetal secretion rate of prostacyclin. The inhibitory effects of AA-2414 persisted after perfusion of the drug was discontinued.
The maternal and fetal secretion rates of both lipid peroxides and
thromboxane were highly correlated with changes in perfusion pressure, suggesting that peroxide-induced changes in vascular tone
were dependent on its ability to stimulate both lipid peroxidation and
synthesis of thromboxane. These data also suggest that the inhibitory
effects of AA-2414 were manifest both through its antioxidant effect
and its thromboxane receptor blocking effect.
When AA-2414 was perfused alone for 20 min, basal maternal and fetal
secretion rates of lipid peroxides and thromboxane started to decline
with the decline in fetal thromboxane reaching statistical significance. A 20-min perfusion period is a rather short time to test
the effects of AA-2414 by itself, and was used primarily as a
pretreatment for the combined perfusion of AA-2414 plus peroxide. It is
impressive that within such a short time AA-2414 was able to
significantly inhibit basal secretion of thromboxane on the fetal side
of the placenta and it is possible that the declines in the secretion
rates of lipid peroxides and maternal thromboxane would have reached
statistical significance if the duration of the perfusion with AA-2414
would have been longer.
The ability of AA-2414 to block peroxide-induced secretion of
thromboxane is a rather interesting finding with regard to the mechanism of action of AA-2414. In other studies using cyclooxygenase purified from bovine vesicular glands, AA-2414 had only weak inhibitory effects on cyclooxygenase activity. In our study, it is likely that the
inhibitory effects on thromboxane secretion were indirect and related
to the inhibition of lipid peroxidation. The amount of peroxide tone in
a tissue is an important factor in determining the activity of
cyclooxygenase (Hemler et al., 1979; Kulmacz and Lands, 1983). When the
level of peroxide tone increases, the activity of cyclooxygenase
increases. When the level of peroxide tone decreases, the activity of
cyclooxygenase decreases. In our study, AA-2414 completely inhibited
the ability of exogenous peroxide to stimulate an increase in lipid
peroxide secretion, indicating inhibition of endogenous lipid peroxide
formation. Therefore, in the presence of AA-2414, the level of
endogenous peroxide tone was not increased by exogenous peroxide and
the secretion rates of thromboxane did not increase over control.
AA-2414 differentially affected the placental secretion rates of
eicosanoids. AA-2414 completely blocked the ability of peroxide to
increase the secretion of thromboxane above control, but it only
partially inhibited the ability of peroxide to increase prostacyclin secretion. Although the fetal prostacyclin secretion rate for AA-2414
plus peroxide was significantly lower than for peroxide alone, it was
significantly higher than control. A lesser blocking effect on the
fetal side would be a favorable effect because the increase in
prostacyclin would promote vasodilatation of the placental vasculature,
whereas the vasoconstrictive effects of thromboxane would be blocked by
the thromboxane receptor antagonistic properties of AA-2414.
The reason AA-2414 differentially affects placental eicosanoid
secretion is not known, but it may relate to the compartmentalization of thromboxane and prostacyclin synthesis within the human placenta. Thromboxane is primarily synthesized by the trophoblast cells on the
maternal side of the placenta, whereas prostacyclin is primarily
synthesized by the endothelial cells on the fetal side of the placenta
(Thorp et al., 1988; Nelson and Walsh, 1989; Shellhaas et al., 1997).
Lipid peroxides are also primarily synthesized by trophoblast cells as
opposed to the vasculature (Walsh and Wang, 1995), so inhibition of
lipid peroxidation by AA-2414 would conceivably have a greater impact
on thromboxane synthesis in the trophoblast cells than on prostacyclin
synthesis in the endothelial cells because peroxide-induced activity of
cyclooxygenase would be inhibited to a greater extent in the
trophoblast cells than in the endothelial cells.
AA-2414 clearly prevents peroxide-induced vasoconstriction and
placental secretion of lipid peroxides demonstrating both its antioxidant and thromboxane receptor blocking effects. It also inhibits
peroxide-induced increases in thromboxane secretion. Given the abnormal
increases of lipid peroxides and thromboxane in preeclampsia, AA-2414
has pharmacologic properties that would make it a candidate to consider
for the treatment of women with preeclampsia. Its actions as a
thromboxane receptor blocker should prevent thromboxane-induced
vasoconstriction and platelet aggregation, and its action as an
antioxidant should decrease lipid peroxide production.
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Abstract
Introduction
