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Prenatal GC therapy is routinely used to improve infant outcome after preterm birth, although a number of questions regarding its clinical use could not be answered with available experimental and clinical literature (1). Crowley et al. (2) indicate that prenatal GC therapy is optimally effective if the treatment-to-delivery interval is 24 h to 7 d (3). Many fetuses at risk of preterm delivery do not deliver within 7 d of initial GC treatment. As a result, obstetricians are frequently administering repetitive courses of maternal GC therapy at 7-d intervals to achieve a maximal fetal response in pregnancies with early preterm labor (<32 wk) (4, 5), although there are no randomized controlled trial data to support this practice.

Despite the widespread use of antenatal corticosteroid therapy in obstetric practice, little is known about the effects of synthetic GC on the fetal tissues. Some effects of prenatal GC use on lung structure (6), somatic growth, brain maturation (7), and adrenocorticoid function (8) after repeated GC treatments can persist until delivery at term. At this time, having overcome the immediate issue of LM and survivability, the improvement of treatment protocols continues. Therefore, questions currently being asked are directed at the side effects from such treatment, in particular, from repeated dosing, which have already stated that it has not been sufficiently addressed. Studies from the 1970s demonstrated decreased fetal growth and weight in rats (9, 10), rabbits (11), and humans (12) after antenatal corticosteroid use. However, few studies compared the effect of both BETA and DEX on fetal LLBW (13).

The aim of this study was to investigate in vivo effects of single or repetitive doses of BETA and DEX administered to pregnant mice near the end of the last third of the gestation period on fetal LM and LLBW of their pups.

MATERIALS AND METHODS

Animals.

All procedures were approved and performed under the guidelines of the Animal Care and Use Committee of Cumhuriyet University School of Medicine. Experiments were carried out on Swiss albino female mice (26–33 g body weight) maintained in individual cages under controlled temperature (21–23°C), a relative humidity of 60–65%, and day light, and fed ad libitum. Each mouse was assigned an identification pairing number before mating. Attempts at conception were undertaken for up to 5 consecutive days (one estrus cycle). The timed conception was identified as gestational d 0 by the presence of a copulatory plug during a 2-h exposure (0900–1100 h) with the male. The pregnant females were then housed individually throughout gestation.

At 13 d gestation, the gravid mice (n = 180) were randomly assigned to one of the six treatment groups: SB, RB, SD, RD, SS, and RS groups. Each group was then divided into three sets of 10 mice randomly. We recorded body weights of all mice at 0 and 16.5 d gestation. Mice with a litter size smaller than two were excluded.

Fetal treatments.

We used mouse model of Stewart et al.(14). to investigate the effect of BETA and DEX on LM and LLBW of mouse pups. Doses of BETA and DEX from previous studies of Stewart et al. (14) and Christiensen et al. (15), respectively, were given as single or repetitive doses of BETA or DEX. We used BETA (Celestone Chronodose; Eczacibasi Pharmaceuticals Co., Istanbul, Turkey) and DEX (Deksamet; Biosel Pharmaceuticals Co., Istanbul, Turkey) formulations, used in animal and human investigations, composed of an equivalent molar weight mixture of the sodium phosphate and acetate forms (16, 17). The 6 mg/mL solution of BETA and 8 mg/mL solution of DEX were diluted with 0.9% sodium chloride solution to prepare a 0.1-mg dose in 0.25 mL. These doses of BETA and DEX have been shown to accelerate fetal lung maturity without impairing fetal survival or weight gain (15) are the most common formulations used clinically.

Each mouse received either saline (0.9% sodium chloride) or BETA or DEX as a 0.25-mL dose drawn into 1-mL syringes. A 25-gauge needle was used for subcutaneous injection into the nuchal fold. We administered single dose of BETA, DEX, and saline solution at 0900 h at 14 d gestation in the SB, SD, and SS groups, respectively, and repetitive doses of BETA, DEX, or saline solution twice daily (0900 h/2100 h) at 14 and 15 d gestation in the RB, RD, and RS, respectively.

Postnatal measurements.

In the first set of all the groups, the gravid mice (n = 60) were killed by cervical dislocation at 16.5 d gestation. The pups, removed by immediate hysterotomy, were placed on a filter paper moistened at 37°C. Lung maturity was evaluated with a previously established technique designed to characterize breathing effort by the study of Christensen et al. (15). Each pup's breathing motion was observed for 1 min by the same investigator (T.G.), who was blinded to the treatment. We used a scoring assignment according to the respiratory pattern: 0, no breathing; 1, gasping; 2, gasping/labored breathing; 3, labored breathing; 4, labored breathing/unlabored breathing; 5, unlabored breathing. Gasping was characterized as isolated breathing with the mouth opened and the neck extended. Labored breathing involved abdominal and extremity movement, whereas unlabored breathing required chest motion only. After BS test, the pups of the first set were killed for evaluation.

Beginning at 18.5 d gestation, the gravid mice in the second and third sets were checked twice daily for the presence or absence of any litters and we waited for their delivery in term gestation. The mice in the second set of all the groups were redivided into three subsets randomly (including four, three, and three mice) and we killed their pups for evaluation on postnatal d 1, 3, and 5, respectively. The pups of third set of all the groups were killed for evaluation on postnatal d 90. The amount of live and dead births per litter, LLBW, the lung/body weight ratio, and the sex of pups were determined at the appropriate time according to the set and subsets of all the groups.

Statistical analysis.

The effect of antenatal treatment on prenatal and postnatal parameters was examined by one- or two-way GLM univariate ANOVA. Where the difference between treatment groups was significant, post hoc pair-wise comparisons between study groups were performed using Tukey HSD multiple comparisons test. With a special feature of this post hoc test, the study groups were classified into homogeneous subsets and these subsets were shown from “a” to “f” letters where appropriate in data presentations. Sex ratio of pups in study groups was compared by χ2 test. Statistical significance was accepted at p < 0.05.

RESULTS

We found no significant difference in maternal weights at 0 d gestation among study groups (Table 1). Although the maternal weight increases during pregnancy, at 16.5 d gestation, mice exposed to BETA and DEX, especially in the RD group, had significantly lower maternal weight compared with the saline groups, respectively (p < 0.05;Table 1). There was no significant difference in the sex ratio and live litter size among the study groups, although the live litter size was lower in RD group (p > 0.05;Table 1). The death litter size of RD group was significantly higher than that of the other groups (p < 0.05;Table 1).

Table 1 Maternal weight and live and dead litter size of all the study groups
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Comparison of the BS of the first set of study groups were performed after pups' sex and study group were given as two factors in the ANOVA test; and the factor of study group only presented significant effect on the BS (p < 0.05;Fig. 1). Later, BS of female and male pups were compared separately. The BS of female and male pups was significantly higher in the four treatment groups compared with the saline groups (p < 0.05). There was significantly higher BS of female and male pups in the repetitive GC-exposed groups than the single GC-exposed groups (p < 0.05). The BS of female and male pups in the SB and RB groups was significantly higher than that of the SD and RD groups, respectively (p < 0.05). In the four treatment groups, the male pups had higher BS than that of the female ones (p > 0.05), but it did not reach statistical significance.

Figure 1
figure 1

BS of male and female pups delivered at 16.5 d gestation in the first set (n = 10) of the six study groups. There was no significant difference between the male and female sets (p > 0.05); however, the male and female sets were analyzed separately and it was found that there were significant differences among the sets within the female and male groups (p < 0.05). For the female sets, the letters a, b, c, and d were used to designate significance. Sets with the same letter were not significantly different; sets with different letters were significantly different (p < 0.05). Similarly, the letters e, f, g, and h were used for the male group with the same interpretation. Comparison of sets used the Tukey HSD multiple comparison test. Data are presented as mean ± SD.

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Figures 2 and 3 illustrate LLBW of female and male pups, respectively, in the first sets and the subsets of the second sets of study groups. Table 2 presents LLBW of female and male pups in the third sets of study groups. Table 3 shows lung/body weight ratio of female and male pups in all the sets of study groups. Although we found no significant difference in these findings with respect to sex, they were usually higher in male pups. These findings generally were significantly lower in SB and SD groups, and RB and RD groups than those of the SS and RS groups, respectively (p < 0.05). When pups exposed to the single and repetitive doses of DEX, these findings usually were significantly lower than those of pups given the single and repetitive doses BETA, respectively (p < 0.05). The LLBW of male pups in RB and RD groups were significantly lower than those of male pups in saline groups at birth (p < 0.05). These reductions was persisted into the young adult period (postnatal d 90); however, this was not shown in the females except in liver weight.

Figure 2
figure 2

LLBW of female pups in first and second sets of all the study groups. Data were presented as mean ± SEM. *SB and SD vs SS, ¶RB and RD vs RS, †SD vs SB, and ‡RD vs RB, p < 0.05.

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Figure 3
figure 3

LLBW of male pups in first and second sets of all the study groups. Data were presented as mean ± SEM. *SB and SD vs SS, ¶RB and RD vs RS, †SD vs SB, and ‡RD vs RB, p < 0.05.

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Table 2 LLBW of female and male pups on postnatal d 90
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Table 3 Lung/body weight ratio of female and male pups of all the study groups
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DISCUSSION

This study examined the effects of multiple fetal exposures to BETA and DEX at approximately 75% of gestation on postnatal LM and fetal and neonatal growth in doses determined for simulation of those used clinically for fetal LM. Repetitive exposures to GC, especially BETA, given twice daily at 14 and 15 d gestation improved postnatal LM in prematurely delivered pups at 16.5 d gestation. Repeated doses of GC, especially DEX, decreased maternal body weight measured at 16.5 d gestation and LLBW. Their effect on weight reduction persisted on postnatal d 90. Male pups had increased LM and LLBW than female ones but this difference was not reached statistical significance.

Both BETA and DEX appear to be ideal corticosteroids for enhancing fetal maturation when they are given between 24 and 34 wk gestation. These drugs are similar in structure and function, have an approximate plasma half-life of 3–5 h and long biologic half-life of 36–54 h, and cross the placenta in biologically active forms (18). Both clinical and in vitro evidence suggest that corticosteroid-induced biologic effects on the fetal lung persist up to 7 d after their use (17, 19). Both BETA and DEX cross the placenta and are not inactivated to a major extent by placental enzymes. The only difference between them is the orientation of a methyl group on position 16. Although it is hard to explain that such a small difference between two molecules could have considerable results, the biologic effects of photoisomerization of the bilirubin molecule show how a change in orientation can alter its effects. These drugs modulate the rate of differentiation of numerous fetal organs, including lung studied in detail (20), heart, liver, skin, gut, and kidney (17, 21, 22). There is now growing evidence from a number of studies on different species that fetal exposure to excess GC at critical stages of development also can have lifelong effects on several systems. Antenatal treatment with either BETA or DEX at the recommended doses provides similar physiologic stress level of GC activity in fetal plasma sufficient to provide a near-maximal occupancy of receptors and induction of target proteins.

We found that the lung weight was significantly lower after antenatal exposure to repetitive doses of BETA or DEX rather than their single doses. When comparing the two treatment groups, it was observed that DEX markedly reduced the lung weight more than BETA. The reduced lung/body weight ratios further demonstrate the relative loss of lung tissue mass. This reduced weight, evident in both sexes, was not reversible and persisted in the young adults, although the relative lung/body weight ratios tended to normalize. The reduced lung weight after exposure to the single dose of BETA was reversed in the young adults, but their effect after repetitive use persisted. These findings are in accord with the study of Stewart et al. (14). Willet et al. (23) reported that the most striking effect of antenatal use of BETA was a marked reduction in alveolar number by inhibiting alveolar septation in animals treated at 118 or 119 d gestation when alveolar formation is already underway in fetal sheep. In the study of Corroyer et al. (24), newborn rats were given a 4-d treatment with DEX (0.1–0.01 μg/g body weight DEX sodium phosphate daily on d 1–4), or saline. Morphologically, this treatment caused a significant thinning of the septa and an acceleration of LM on d 4. They suggested that GC may accelerate LM by influencing cell cycle control mechanisms, mainly through impairment of G1 cyclin/CDK complex activation. Although Stewart et al. (19) found no long-term differences beyond the immediate perinatal period in the growth and development of BETA- or placebo-exposed mouse pups, Okajima et al. (25) evaluated the influences of antenatal DEX administration on neonatal lung development in rats. They administered DEX (0.4 mg/kg maternal body weight per day) on the 21st d or on the 20th and 21st d of gestation in Sprague Dawley rats. After natural deliveries, the lungs of the pups 1–60 d of age were obtained and processed for morphometric analysis. They found that both groups presented a lower numerical density of alveoli and a larger mean alveolar radius in 60-d-old pups.

The effect of corticosteroids on the liver weight was similar to that on lungs. In general, DEX caused a greater reduction in liver weight than BETA. Several mechanisms for these reductions have been suggested. This mechanism of growth impairment associated with corticosteroid therapy is thought to be related to reduced biosynthesis of DNA and RNA as well as prolonged inhibition of mitosis and cellular activity (12, 26). This reduced weight also may result, in part, from impaired function of the placenta after treatment, but may also be a direct effect of corticosteroids on fetal tissues (27). A previous study showed that there were no differences between BETA and control group in brain, lung, kidney, and adrenal weights in rhesus monkeys (28). However, the mean liver weight of the BETA-treated fetuses was significantly greater than that of the control group. They suggested that the increased liver weight is caused by an elevation in liver glycogen content, however, the specific mechanism is not known (28). Previous studies in fetal sheep have found fetal growth retardation after BETA treatment at 104 d gestation (68% of gestation) but not after later in gestation (29). Antenatal corticosteroids routinely have caused growth retardation in fetal rodents (30, 31). These species have short gestations and rapid fetal growth, and a single treatment will impact significantly.

We found that the body weight of male pups exposed to the repetitive doses of BETA and DEX was lower than those of male pups administered saline solution. The reduction in body weights persisted into the young adult period (postnatal d 90); however, this was not shown in the females. We speculate that the cause of this reduction may be the androgen hormone. Androgens have been found to delay fetal LM, while stimulating fetal lung growth (32). They have concluded the following: (1) the sex difference is due to androgen exposure in utero, (2) androgens promote lung growth, and (3) androgens block both mesenchymal and epithelial maturation.

Our study is limited by its design; because the preterm period of mouse gestation is shorter than that of human pregnancy, it is not possible to use the repetitive doses of GC in intervals recommended for humans. In addition, we did not measure the concentration of BETA and DEX in blood and investigated organs. Caution is necessary when extrapolating from animal models to human clinical medicine, but it is important to point out that the general sequence of growth of organs shows no species differences between laboratory animals and humans. Moreover, it is impossible to conduct a randomized controlled trial of repetitive use of antenatal GC in humans.

Our findings provide experimental support for repetitive treatment courses of antenatal GC for prevention of respiratory distress syndrome in premature infants. However, possible benefits from repetitive dosing must be weighed against increased risks for adverse effects. Exposure to exogenous GC decreases the activity of placental 11β-HSD type 2, which allows increased passage of high maternal GC to the fetus by inhibiting the natural “protective” placental barrier to GC, reduced birth weight, and programmed permanently elevated GC levels throughout the adult life of the newborn (3336).

We conclude that DEX is less potent than BETA in accelerating fetal lung maturity while causing a greater reduction in fetal LLBW. Repeated administration of GC, especially DEX, should be avoided because of their permanent effect on fetal and neonatal growth. BETA may be preferred in clinical situations requiring imminent preterm labor. In view of these known problems of prolonged GC exposure, retreatment should perhaps be reserved for pregnancies with active labor, recurring more than 1 wk after the last BETA administration, with high risk of delivering an infant at 32 wk gestation. Some aspects of the use of antenatal GC, especially in a repetitive manner, may require reconsideration in humans.