The use of drugs in pregnancy always raises concerns regarding potential fetal exposure and possible adverse effects through their accumulation in fetal tissues and organs. Barusiban is an oxytocin antagonist under development for potential use as tocolytic in preterm-labor patients. It displays greater affinity for the oxytocin receptor compared to vasopressin V1A receptor and would thus not interfere with vasopressin-induced effects of the V1A receptor. Barusiban placental transfer was determined in the rabbit and cynomolgus monkey and in an ex vivo human cotyledon model. In the rabbit, there was an approximately 5% transfer of barusiban from the maternal to the fetal blood, without significant accumulation in any of the investigated fetal tissues. In the cynomolgus monkeys, the mean fetal plasma barusiban concentration was 9.1% of the maternal level. This was similar to the percentage of barusiban transfer in the human placental single cotyledon, which once equilibrated ranged between 9.3 and 11.0% over the observation period. The transfer of the small-molecule antipyrine as a comparator in this human model was approximately three times greater. The similarity in the degree of transfer in the cynomolgus monkey and human cotyledon, while being less in the rabbit, may reflect the species-specific placental barrier structure between the maternal and fetal compartments. In conclusion, limited placental transfer of barusiban occurred in all three models. The similarity of barusiban transfer in the cynomolgus and the human placental single cotyledon suggests the latter ex vivo model to be useful in assessing future drug candidates to be used in pregnant women.
Summary Sentence
Limited barusiban placental transfer occurred in all three models, with the similarity of transfer in the cynomolgus and the human cotyledon, suggesting this ex vivo model to be useful in assessing human placental transfer of pharmaceuticals.
Introduction
There are always potential concerns and regulatory expectations regarding maternal medications and potential fetal exposure during pregnancy. Placental drug transfer studies can help to identify possible hazard and thus the safety of such compounds, because resultant fetal circulatory levels may lead to exposure with or without accumulation in tissues and organs, possibly producing adverse effects.
Premature labor leads to early childbirth, associated with immediate and long-term health problems [1]. Therefore, tocolytic drugs are given for imminent preterm to prevent premature labor. This allows, for example, sufficient time for transfer to a neonatal intensive care unit and accelerated fetal lung maturation by antenatal hydrocortisone treatment, reducing the risk of related medical problems [2]. Molecular size plays a role in placental transfer [3]. Generally, tocolytic peptides display low placental transfer and tend to be less toxic than small molecules, some of which can readily cross the placenta and may have toxic metabolism issues, possibly affecting fetal health. Indeed, up to 100% transfer has been observed for MgSO4 in humans [4, 5], greater than 60% for dihydropyridine nifedipine [6, 7], up to 90% for fenoterol [8], and 26% or 70% for ritodrine hydrochloride used in short- or long-term treatment, respectively [9, 10], whereas only 12% was reported for the peptide atosiban [11]. Several papers have described MgSO4-related reduced fetal heart rate (HR), HR variation (HRV), and bradycardia as well as fetal respiratory depression [12]. Nifedipine was shown to significantly reduce fetal HR while increasing HRV [13]. Ritodrine was reported to increase the fetal HR while lowering the long-term HRV, accompanied by increased left cardiac stroke volume, cardiac output, and pulsatility index of the middle cerebral artery [14, 15]. Although dihydropyridine nicardipine was reported to have a lower transfer of 17% [16], it was shown in rhesus monkey fetus to induce acidosis and hypoxemia [17]. Therefore, low transfer is important to reduce the risk of potential fetal adverse effects of tocolytics.
Barusiban (FE 200440) is a peptide oxytocin antagonist for potential future use as a tocolytic drug in preterm-labor patients, being slightly smaller than atosiban. It displays an approximately 300 times higher affinity for the cloned human oxytocin receptor (OTR) than the cloned human vasopressin V1A receptor (V1AR) when expressed in human embryonic kidney (HEK)-293 cell membranes [18]. Similarly, barusiban has a greater potency for the OTR when expressed in Chinese hamster ovary cells than the V1AR expressed in HEK-293 cells (Ki 0.64 nM vs. 11 nM) (unpublished data). By contrast, atosiban displays a higher affinity for the cloned human V1AR than the OTR (Ki 3.5/4.7 nM vs. 81/397 nM) [19, 20] and greater potency (Ki 0.27 nM vs. 20 nM) (unpublished data). Barusiban binds to transmembrane regions 1 and 2 of the OTR rather than the agonist-binding extracellular N-terminus, while atosiban does not appear to bind to either of these sites [21]. Whereas the extracellular domain of the oxytocin and vasopressin receptors shares approximately 80% amino acid homology [22], this is only 30–50% over the entire receptor molecule [23]. The amino acid sequence difference between the receptors in the barusiban-binding region may thus contribute to barusiban's greater binding affinity for the OTR. Consequently, barusiban had practically no effect on vasopressin-induced contractions of isolated term-pregnant human myometrium [18], whereas it dose-dependently inhibited oxytocin-induced contractions of isolated human preterm and term myometrial strips with a greater tendency than atosiban [24]. In OTR-knockout mice, the dams exhibited normal parturition but displayed an inability to lactate, such that the pups were unable to survive because of a lack of suckling [25]. Because barusiban is planned for use during pregnancy, this raises the question of the potential for placental transfer and possible fetal risks.
The rabbit is a standard model to test reproductive toxicology [26] and has been used previously in the toxicological evaluation of barusiban (unpublished data), is qualified as a relevant non-clinical species, and is accepted by the regulatory authorities for this study type. The rabbit placental barrier at term has two trophoblastic cell layers, syncytiotrophoblasts in direct contact with maternal blood and cytotrophoblasts overlying fetal blood vessels [27], compared to the single trophoblastic layer (syncytiotrophoblasts) of the human placenta at term [28]. The rabbit OTR shares 88% amino acid sequence identity with the human receptor, increasing to 92%, when also including highly similar amino acids (unpublished data). A further non-clinical model, in which barusiban is pharmacologically active, is the cynomolgus monkey, which has similarities to humans in reproductive physiology [29] and embryo/fetal development [30]. Like humans, the cynomolgus monkey is hemomonochorial, with a single syncytiotrophoblast layer separating maternal blood from fetal blood vessels [27, 28]. Moreover, its OTR amino acid sequence shares 97% identity with humans, increasing to 99%, when including highly similar amino acids (unpublished data). The investigation of barusiban's effect in the pregnant cynomolgus monkey found it to be more potent and its action longer lasting than atosiban in reducing oxytocin-induced uterine contractions, the effects being readily reversed by a high-dose oxytocin infusion [31]. This confirmed barusiban's apparent greater potency compared to atosiban observed previously using isolated human preterm and term myometrial strips [24]. Furthermore, barusiban was more effective than fenoterol in the cynomolgus monkey in reducing induced uterine contractions [32]. However, a Phase II clinical trial did not demonstrate a statistically significant effect of barusiban over the placebo group, although there was a tendency in all the barusiban treatment groups toward a higher proportion of women who did not deliver within 48 h with increasing predosing cervical length. [33]. Furthermore, with the high number (72%) in the placebo group who did not deliver within 48 h, this would have reduced the possibility of detecting a significant difference between the barusiban groups and the placebo group. A dually perfused model of a human placental single cotyledon has been used in transplacental studies since 1972 [34]. This model has been shown with numerous compounds to accurately predict in vivo transfer at steady state after modeling for differences in maternal and fetal/neonatal protein binding and blood pH [35].
Here, for pharmacokinetic safety reasons, we investigated barusiban placental transfer in vivo in the rabbit and cynomolgus monkey and in an ex vivo human perfusion model. The results will help to characterize barusiban's placental transfer kinetics in clinical use.
Materials and methods
Placental transfer in rabbits
This study was conducted in compliance with the good laboratory practice (GLP) regulations 1999 (SI 1999 No. 3106) for the United Kingdom and with the OECD GLP Principles (ENV/MC/CHEM (98) 17), which are accepted by the USFDA. Twelve healthy pregnant female New Zealand white rabbits aged 5–6 months and weighing 3.0–4.4 kg were obtained from Harlan UK (Bicester, UK). The rabbits were housed individually in stainless steel rabbit cages under a 12-h light/dark cycle and acclimatized for 4 days. The temperature and relative humidity of the room housing the animals was 19–22 °C and 25.5–92%, respectively. Stanrab diet (Special Diets Services, Witham, UK) and mains tap water were provided ad libitum.
Barusiban supplied by Ferring AB (Limhamn, Sweden) (see Methods Supplement for dose preparation) was administered intravenously as a single bolus injection via an ear vein once daily for 7 days (days 24–30 of gestation). The mean daily dose was 3.01 ± 0.013 mg/kg at 1 mL/kg in 0.9% saline, with a mean radioactive dose of 522 ± 1 kBq/kg (14.1 ± 0.021 µCi/kg).
Blood was obtained via an ear artery immediately prior to sacrifice. Three maternal animals were sacrificed by barbiturate overdose at 10 min and 1, 3, and 10 h post-dose, and blood transferred to a heparinized tube. Necropsy was undertaken for each dam and one fetus of each sex. Fetal blood was obtained by cardiac puncture and various tissues were collected. Radioactivity in plasma and tissue samples was determined by liquid scintillation counting. (See Methods Supplement for preparation of blood, plasma, and tissue samples and determination of barusiban content.)
Placental transfer in cynomolgus monkeys
This study was in compliance with the GLP regulations as outlined in the German Chemical Law, the OECD Principles, and the U.S. FDA for Nonclinical Laboratory Studies and was approved by the Münster District Council, planned experiment No. 14/87. Three female purpose-bred and sexually mature cynomolgus monkeys (Macaca fascicularis), were obtained from Best Engineering Company Ltd. and Vanny Chain Technology Ltd. (both Hong Kong). On gestation day 140, the animals weighed 3.9–4.2 kg and were at least 3 years old. On arrival, all animals received a clinical inspection and were subsequently regularly examined. The animals were acclimatized for a minimum of 6 weeks, being housed under a 12-h light/dark cycle in a climate-controlled room, providing a minimum of 10 air changes/h, with temperature and relative humidity routinely of 19–25 °C and 30–70%, respectively. The animals were individually housed in stainless steel cages (600 × 600 × 800 mm; E. Becker & Co GmbH, Castrop–Rauxel, Germany). Tools for environmental enrichment were provided in each cage. Each animal received twice daily 50 g of a commercial pellet diet for primates (Ssniff P10, Ssniff Spezialdiäten GmbH, Soest, Germany), fresh fruit normally twice weekly, and one slice of bread once weekly. Tap water was provided ad libitum.
Prior to caesarean section (C-section) on day 150 ± 1 of gestation, barusiban (Ferring AB) at 10 mg/mL in isotonic 0.04 M acetate buffer pH 4.3 diluted using 0.9% saline was infused intravenously into the saphenous vein using an infusion pump for 2 h to a maximal dose of 300 µg/kg (based on previous pharmacodynamic experiments [31]) in 5 mL/kg. Maternal blood samples were obtained from the brachial vein (approximately 1.5 mL) prior to initiation of dosing (as control) and 1 and 2 h thereafter.
For C-section, the animals were intramuscularly anesthetized using ketamine hydrochloride (Ketavet; Pharmacia & Upjohn GmbH, Erlangen, Germany) and xylazine hydrochloride (Rompun; Bayer Vital GmbH & Co. KG, Leverkusen–Bayerwerk, Germany). C-section was performed, and amniotic fluid (10 mL) and fetal blood (approximately 1.5 mL) from the umbilical vein were collected. Fetuses were subsequently sacrificed by an intravenous injection of ketamine hydrochloride via the umbilical vein. The fetuses were sexed and examined for external abnormalities. Following completion of the study, there were no signs of major illness in the adults, and all healthy females were returned to the primate colony following CRO procedures.
Plasma samples were analyzed for barusiban by radioimmunoassay and amniotic fluid samples by liquid chromatography-tandem mass spectrometry (LC-MS/MS) (see Methods Supplement for blood and amniotic fluid preparation and analyses).
The ratios of fetal plasma barusiban at C-section/maternal plasma after 2 h and amniotic fluid barusiban concentrations at C-section/maternal plasma after 2 h of infusion were calculated. Assuming that the maternal plasma barusiban concentrations after 2 h and the fetal plasma and amniotic barusiban concentrations at C-section were from normally distributed populations, parametric statistical analyses were performed, with a paired t-test for the barusiban concentrations using GraphPad Prism (Version 6, La Jolla, CA).
Human cotyledon transfer
This study was approved by the Ethics Commission of the Medical Faculty of the University of Vienna and the General Hospital of Vienna AKH, Austria (approval no. EK Nr: 248/2003). Seventeen placentas with no signs of chorioamnionitis were obtained with written consent from women with uncomplicated obstetric histories after pregnancies of gestational weeks 39–41 and birth weights of 3–4 kg (see Methods Supplement for cotyledon preparation).
Ex vivo perfusions were performed according to published methods [34, 36], using a placental double-sided open cotyledon perfusion model (see Methods Supplement for preparation). Following a stabilization period, the fetal circulation flow rate was continued at 2 mL/min, and the maternal circulation was re-established at 10 mL/min, maintaining the perfusate at 36.5 °C using a water bath. Barusiban (Ferring Pharmaceuticals A/S, Copenhagen, Denmark; in isotonic 0.04 M acetate buffer pH 4.3) was applied at 1.2 µM (1 µg/mL) in the perfusate (corresponding to the maximum serum concentrations in clinical trials on intravenous administration of a 10-mg bolus [33]). Antipyrine (Sigma) as an inert reference compound was co-infused at 531 µM (0.1 mg/mL) [37, 38]. Only experiments in which the fetal arterial inflow equaled the venous outflow were analyzed. Perfusate samples were obtained from the fetal venous cannula after 1, 5, 10, 30, 60, 90, and 120 min and stored at –20 °C. Following each experiment, membrane integrity was tested by adding 5 mL Evans blue dye (0.1 mg/mL NaCl; Sigma-Aldrich Co.), which cannot cross the placental barrier, to the fetal circuit. Barusiban was analyzed by automated protein precipitation followed by liquid chromatography and tandem mass spectrometry. Spectrophotometric quantitative determination of antipyrine was based on a published method [39]. (See Methods Supplement for details of the analytical methodology.)
The area under the curve (AUC) of barusiban and the reference small-molecule antipyrine of the transfer time course was calculated using the trapezoidal method. The AUC of the barusiban transfer time course was compared to that of antipyrine using a paired t-test and the Pearson correlation coefficient determined using GraphPad Prism. The mean of the ratios of barusiban to antipyrine transfer AUC time courses was calculated using GraphPad Prism. Normality of the distribution of the Pearson r and AUC ratio values was confirmed using the D'Agostino K2 test.
Results
All data are presented as the mean ± standard deviation.
Rabbit placental transfer
At each time point, there was no maternal mortality (n = 3), and one fetus of each sex was investigated from each dam (maximum n = 6). The highest maternal blood and plasma barusiban levels were detected 10 min post-dose of 18 856 ± 6679 nM and 28 225 ± 7189 nM, respectively (both n = 3) (Figure 1). For technical reasons, no fetal plasma samples were available for analysis and only one for blood containing 1000 nM barusiban (3.8% of the adult). Barusiban was detected in the fetal adrenal gland but only in two out of five fetuses, with minimal levels of 2456 and 5059 nM (9.3 and 19.1%, respectively, of the maternal blood), while in the other three fetuses, it was below the lower level of quantification (LLOQ) of 50 dpm (5.46 × 10–3 nmoles total barusiban) above the background (Table 1). In other fetal tissues, the barusiban level was either extremely low (<1% of the maternal blood) or less than LLOQ.
The mean barusiban 1 h post-dose in maternal blood of 6189 ± 2728 nM and plasma of 9926 ± 4063 nM (both n = 3) were 32.8 and 35.2%, respectively, of the maximum level (Figure 1). Fetal blood barusiban after 1 h was slightly lower at 793 ± 514 nM (n = 3), being 79.3% of that after 10 min and representing 4.2% of the peak maternal level. Fetal plasma barusiban after 1 h was 1421 ± 759 nM (n = 2) (representing 5.0% of the peak maternal level). Barusiban in most tissues samples was less than LLOQ or less than 1% of the maternal peak blood level (Table 2). In the single amniotic fluid sample available, a minimal amount of barusiban of 3070 nM (16.3% of the maximal parental plasma level) was found. In two fetal adrenals, the barusiban was 5.0 and 15.7% of the maximal parental plasma level, in the remaining four adrenals being less than LLOQ (Table 2).
At 3 h post-dose, the barusiban level had fallen further in maternal blood to 1143 ± 769 nM and in plasma to 2224 ± 743 nM (both n = 3) (Figure 1), 6.1 and 7.9% of their respective maximum levels. The fetal blood barusiban was further slightly lower at 600 ± 381 nM (n = 4), while the plasma barusiban remained similar at 1383 ± 169 nM (n = 2) to that after 1 h. Barusiban was again present at a minimal level of 3061 nM (16.2% of the maximum maternal plasma level) in the single available amniotic fluid sample (Table 3). In two fetal adrenals, barusiban was 26.6 and 16.4% of the maximum maternal plasma level, in the other three available adrenals being less than LLOQ (Table 3). The mean fetal carcass barusiban level was 705 ± 360 nM (n = 5), similar to that in fetal blood but less than in fetal plasma at this time.
By the final time-point of 10 h post-dose, the barusiban in maternal blood of 111 ± 37 nM and plasma of 488 ± 55 nM (both n = 3) (Figure 1) were less than 1% and less than 2% of the first determination, respectively. Final barusiban in fetal blood was 348 ± 349 nM and in plasma 742 ± 420 nM (both n = 6), less than 2% and less than 3% of initial maternal levels, respectively. In the two available amniotic fluid samples, again a minimal barusiban concentration could be detected of 1077 ± 243 nM (5.7% compared to the maximal maternal blood level), being lower compared to 3 h (Table 4). Only one of the six adrenals in the fetuses was the barusiban above the LLOQ at a minimal level of 2258 nM (12.0% of the maximal maternal blood level). In all other fetal tissues, barusiban was present at less than 1% of peak maternal blood level or less than LLOQ.
The results indicate that following intravenous bolus barusiban administration, only a minimal amount of the barusiban crossed the placental barrier to reach the fetal blood. In most of the fetal tissues, the barusiban concentrations were generally much lower than in the blood/plasma, with many individual results below the limit of reliable quantification.
Cynomolgus monkey placental transfer
There was no mortality or treatment-related clinical signs throughout the study. Live fetuses (one male, two females) displaying no abnormalities were delivered by C-section in the three adults.
The mean maternal plasma barusiban concentration was 1952 ± 628 nM (n = 3) 1 h after initiating dosing (Table 5). After 2 h, the mean maternal plasma barusiban was 2666 ± 1319 nM, having increased in two animals by 40.4 and 54.6% while decreasing by 5.0% in the third animal. Fetal plasma obtained during C-section contained a mean of 213 ± 57 nM barusiban (n = 3), being 9.1% of the mean maternal plasma level after 2 h (P = 0.0415). The mean amniotic barusiban concentration at C-section of 47 ± 18 nM (n = 3) was 1.9% of the maternal plasma after 2 h (P = 0.0109).
Table 1.
Rabbit fetal tissue barusiban levels 10 min after the final maternal dose.
Table 2.
Rabbit fetal tissue barusiban levels 1 h after the final maternal dose.
Table 3.
Rabbit fetal tissue barusiban levels 3 h after the final maternal dose.
Table 4.
Rabbit fetal tissue barusiban levels 10 h after the final maternal dose.
Table 5.
Cynomolgus monkey maternal and fetal barusiban levels.
Human placental transfer
In total, 17 placentas were perfused. Two were excluded before barusiban application, because the arterial inflow and venous outflow were unequal, while in the other Evans blue leakage occurred in the membrane-integrity test. In a further two placenta, the barusiban level was above the highest measurable limit for the inflow (maternal side), the data thus being excluded from calculations. Overall, a steady-state barusiban transfer from maternal to fetal side of approximately 11% was attained within 10 min in the 13 placentas included for analysis (Figure 2). For the reference small molecule antipyrine, the transfer in the same 13 placentas peaked after 10 min at 35% before falling back to a steady-state transfer of approximately 29% from 30 min. However, the time course pattern was quite variable from placenta to placenta for both barusiban and antipyrine, which may make the mean time course misleading. By contrast, for any given placenta, the time course patterns of barusiban and antipyrine were similar to each other. Therefore, the area under the curve (AUC) of the time course was a more representative quantification of the placental transfer, which was 1246 ± 437%·min for barusiban vs. 3511 ± 988%·min for antipyrine (P < 0.0001, r2 = 0.8922), and the AUC ratio of barusiban to antipyrine was 36 ± 11% (95% confidence interval: 30–43%).
Discussion
In the present study, three different model systems were investigated. The rabbit is a standard model used to test reproductive toxicology [26] and the cynomolgus monkey, a large non-clinical model with a similar placental barrier to the human. The ex vivo human cotyledon model provides an insight into the actual clinical transfer.
Following barusiban administration in rabbits, only a limited amount crossed the placental barrier, reaching a level in the fetal blood and plasma of approximately 5% of the corresponding maximum on the maternal side. In most of the fetal tissues investigated, the barusiban concentrations were generally much lower than in the blood/plasma, in many cases below the limit of reliable quantification. Similarly, on intravenous barusiban infusion for 2 h to pregnant cynomolgus monkeys, limited placental transfer occurred, ref lected in the fetal plasma and amniotic f luid containing only 6.4–12.8 and 1.7–2.3% of the peak maternal plasma concentration, respectively. Again, in the perfused human placenta model, only approximately 11% barusiban diffusion or transport into the fetal circulation occurred, which was significantly lower compared to a peak of 35% for the small-molecule control antipyrine (P < 0.0001).
The level of barusiban transfer was similar in the cynomolgus monkey and human cotyledon perfusion model compared with in vivo atosiban transfer, a non-apeptide of slightly higher molecular weight, reported in pregnant women at term of 12% [11]. The human cotyledon ex vivo barusiban transfer of approximately 11% was clearly below that reported in humans for the smaller tocolytics MgSO4, nifedipine, fenoterol, and ritodrine hydrochloride, which ranged from 26% up to approximately 100% [4–10].
The tissue distribution pattern of barusiban in the rabbit fetuses was similar to that observed in a quantitative whole-body autoradiography (QWBA) study in the marmoset (unpublished data). Additionally, in both species, the radioactivity in fetal brain was normally below the limit of quantification (12 pmoles/g tissue for the marmoset).
The lower transfer of barusiban from maternal to fetal blood in the rabbit compared with the cynomolgus monkey and human cotyledon model may reflect species-specific placental barrier structure between the maternal and fetal compartments. Cynomolgus monkey and human placentas are hemomonochorial, with a single placental cell layer separating the maternal blood from fetal blood vessels [27, 28]. These displayed similar barusiban placental transfer in the present study, with approximately 9% of the maternal barusiban in the cynomolgus monkey and approximately 11% for the ex vivo human cotyledon reaching the fetal side. By contrast, this transfer was lower at approximately 5% in the rabbits, which have a hemodichorial placenta at term, with a double cell layer separating the maternal blood from fetal blood vessels [27]. While earlier in gestation the presence of the inverted yolk sack in the rabbit, which is absent in primates and humans [40], may contribute to drug transport or accumulation, this is no longer present at term in the current study. However, this structure would have to be taken into consideration when using this model to assess drug transfer earlier in gestation. Furthermore, in the rat, with a triple placental trophoblastic cell layer (hemotrichorial; one layer of cytotrophoblasts contacting the maternal blood and two layers of syncytiotrophoblasts) [27], barusiban in a QWBA study was below the limit of quantitation (40 pmoles/g) at all sampling times in the fetuses (unpublished data). A similar effect of placental barrier structure on transfer was observed for atosiban, which reached 12% in humans, but could not be detected in sheep, this animal with an epitheliochoral placenta of multiple cell layers between the maternal and fetal blood [11, 41].
Commonly used tocolytics are small-molecule drugs that were developed for clinical conditions other than preterm labor [42], for example, MgSO4, to treat/prevent low blood magnesium, arrhythmias, and acute asthma; ritodrine in asthma; fenoterol in asthma and chronic obstructive pulmonary disease; and nifedipine as an antihypertensive. Atosiban was the first drug specifically developed to treat preterm labor, which is approved in the EU and numerous countries globally, although not in the USA. It is a mixed V1AR/OTR antagonist and mainly acts in reproductive tissues, avoiding systemic adverse effects; however, it can still affect the vascular V1AR [43]. The concentration of V1A binding sites is high in human uterine tissues, particularly in the decidua, in all such tissues being approximately 50–60% of the level of oxytocin binding sites [44]. Barusiban, a new oxytocin antagonist, displayed considerably higher affinity in ligand-binding assays [18] and greater potency in functional, cell-based reporter gene assays for the human OTR than the human V1AR (unpublished data). A selective action of this new analogue on oxytocin responses, without influencing the uterine V1AR, was demonstrated in term-pregnant human myometrium [18]. Barusiban displayed concentration-dependent inhibition of oxytocin-induced contractions in both isolated human preterm and term myometrial strips, the effect at least as potent as atosiban [24]. Furthermore, in pregnant cynomolgus monkeys stimulated with oxytocin, barusiban displayed improved tocolytic potency and longer duration of action compared to atosiban [31]. Therefore, barusiban is a potential future alternative for atosiban, particularly with its greater affinity for the OTR than the V1AR compared with atosiban.
Any drug that can cross the placental barrier may pose a potential risk in fetal development. Therefore, the present study was performed for pharmacokinetic safety reasons, with placental transfer of barusiban investigated in two animal models together with a human placental cotyledon model. Low transfer of barusiban in all three models and the limited accumulation in the rabbit fetal tissues were found. Furthermore, the amount of barusiban applied to the rabbits and cynomolgus monkeys was approximately 20 and two times greater, respectively, than the highest therapeutic dose [33] to ensure high but well-tolerated maternal exposure, to see any potential transfer, and to identify potential fetal target organs. Barusiban was applied in the perfusate to the human cotyledon at a concentration corresponding to the maximum serum concentrations in clinical trials on intravenous administration of a 10-mg bolus, the maximum amount applied [33]. Therefore, considering the low barusiban transfer in all three models and the limited accumulation in the rabbit fetal tissues, at the therapeutic level, limited amounts of barusiban would be expected in the fetal tissues. Rasmussen et al. [45] reported that there were no barusiban-related effects in the mother or offspring on treating pregnant cynomolgus monkeys with up to 2.5 mg barusiban/kg body weight/day from day 85 of gestation until delivery. Detailed examination of the offspring over a 9-month postnatal period found no barusiban-related effects on developing organ systems or on behavior. Moreover, Thornton et al. [33] in a clinical study reported a very low level of fetal and neonatal adverse events with maternal barusiban, which did not differ from those observed on placebo treatment, and their frequency of occurrence did not alter with increasing maternal barusiban dosage. In the same study, barusiban did not result in any difference in physical or mental development in the offspring at a 1-year follow-up.
Maternal barusiban placental transfer needs to be determined in the clinical situation to confirm a limited transfer to human fetal blood. This would show how closely the transfer levels seen both in vivo in the cynomolgus, with a similar placental barrier structure, and ex vivo with the isolated human cotyledon reflect human maternal transfer. Consequently, this would indicate whether they are good models, as already shown, for example, for other drugs in the cotyledon model [35], to be used in further, more extensive studies of barusiban as well as in the future to test other potential peptide tocolytics. Future clinical trials of barusiban, including in comparison with other tocolytics, will elucidate any fetal side effects, which appear to be unlikely for barusiban based on current knowledge.
There were several limitations to the study. In the explorative rabbit study, the number of rabbits was limited, and not all fetuses were examined. Furthermore, only a limited number of time points were investigated, with available fetal blood/plasma samples restricted at the earlier time points and of amniotic fluid throughout. The cynomolgus study was restricted to three animals for ethical reasons, and in the fetuses, only plasma barusiban levels at a single time point were investigated and not the tissue distribution.
Conclusions
The limited placental transfer of barusiban in both animal studies and in isolated human placenta suggests that in maternal therapy, there would be restricted fetal exposure. This contrasts with the greater transfer determined here of the small-molecule antipyrine and of small-molecule tocolytic treatments in the literature. Because the placental barrier structure may influence the level of tocolytic transfer, care must be taken in extrapolating from the transfer levels observed in animal studies to the clinical situation. The similarity of barusiban transfer in the cynomolgus, with its comparable fetal development to humans, with the human placental single cotyledon reflects the previously reported ability of the latter ex vivo model to accurately predict in vivo human drug transfer and thus be useful in assessing pharmaceutical drug candidates to be administered during pregnancy in women.
Acknowledgments
We would like to thank the involved study directors and monitors, Covance Laboratories and R. Harrison, I. Osterburg, and M.B. Petersen. This manuscript was prepared by Robert Blakytny PhD, a freelance medical writer, who was supported by Ferring Pharmaceuticals A/S.