Catecholamine response to ultrasonographically guided percutaneous blood sampling in fetal sheep

Betamethasone dose and formulation for induced lung maturation in fetal sheep

OBJECTIVE

We hypothesized that maternal treatments with betamethasone acetate induce fetal lung maturation comparably to the betamethasone phosphate+betamethasone acetate used clinically.

STUDY DESIGN

Ewes with singleton pregnancies were treated with single doses of 0.25-mg/kg or 0.5-mg/kg betamethasone acetate, 4 doses of 0.25-mg/kg betamethasone phosphate, a single dose of 0.5-mg/kg betamethasone acetate+0.25-mg/kg betamethasone phosphate, 2 doses of 0.25-mg/kg betamethasone acetate+0.25-mg betamethasone phosphate or vehicle beginning 48 hours before preterm delivery. Fetal lung maturation was evaluated.

RESULTS

All treatments induced lung maturation relative to vehicle controls. The relatively insoluble betamethasone acetate resulted in low maternal blood betamethasone and no detectable fetal blood betamethasone in 2 of 3 fetuses, but it induced fetal lung maturation comparable to the 2-dose betamethasone acetate+betamethasone phosphate or 4 doses of betamethasone phosphate.

CONCLUSION

A single maternal dose of betamethasone acetate effectively induces fetal lung maturation in sheep with minimal fetal exposure.

Cardiovascular and endocrine responses to cutaneous electrical stimulation after fentanyl in the ovine fetus

OBJECTIVE

The purpose of this study was to determine whether physical stimulation is stressful to the ovine fetus, as judged from physiologic changes that are similar to those reported for other stressors (such as hypoxia); whether any stress response could be blocked by clinically used doses of fentanyl; and whether fentanyl alone had any potentially deleterious physiologic effects in the fetus.

STUDY DESIGN

We investigated the effect of fentanyl analgesia on the cardiovascular and endocrine response to cutaneous electrical stimulation in the late gestation (>125 days) ovine fetus (n=7 fetuses). Chronically implanted catheters and blood flow probes were used to measure fetal arterial blood pressure, heart rate, carotid and femoral blood flow, pH, Po(2), Pco(2), lactate, cortisol, and beta-endorphin levels before, during, and for 1 hour after 5 minutes of cutaneous electrical stimulation to the lip, forelimb, and abdomen, in a crossover design. Clinically used 30 or 150 microg doses of fentanyl (which approximated 10 or 50 microg/kg estimated fetal weight) or saline solution were given intravenously to the fetus 2 minutes before stimulation.

RESULTS

When compared with the control, stimulation caused a significant rise in fetal heart rate (P=.003; mean maximal rise, 48.6+/-14.0 beats/min, 0-10 minutes after the start of stimulation) but caused no change in any other parameters studied. Neither dose of fentanyl attenuated the changes in heart rate that were observed in response to stimulation alone. Fentanyl alone significantly increased fetal heart rate, carotid blood flow, and lactate and cortisol levels and significantly decreased pH and Po(2).

CONCLUSION

Cutaneous electrical stimulation in the fetal sheep causes an increase in heart rate, which fentanyl does not block. Fentanyl itself has significant effects on the cardiovascular and endocrine system, which might adversely affect the fetus.

Pharmacokinetics of betamethasone after maternal or fetal intramuscular administration

OBJECTIVE

The purpose of this study was to determine the pharmacokinetics of betamethasone in maternal and fetal circulations after maternal or fetal intramuscular administration.

STUDY DESIGN

Ewes that bore single fetuses underwent surgery at approximately 96 days of pregnancy for the implantation of fetal and maternal vascular catheters. At approximately 103 days, five ewes were injected intramuscularly with betamethasone (0.5 mg/kg body weight) or five fetuses received ultrasound-guided intramuscular injections of betamethasone (0.5 mg/kg estimated fetal weight). Maternal and fetal blood samples were collected serially for the measurement of plasma betamethasone concentrations.

RESULTS

Fetal injection caused higher peak fetal betamethasone concentrations (341.2+/-23.7 nmol/L) than maternal injection (37.6+/-3.7 nmol/L; P<.001) and greater cumulative betamethasone exposure. The half-life of betamethasone in the fetal circulation was shorter after fetal injection (1.1+/-0.3 hours) than after maternal injection (8.5+/-2.0 hours; P=.006).

CONCLUSION

The duration of fetal and maternal exposure to betamethasone can be minimized by direct fetal intramuscular administration that, in sheep, affords lung maturation without adverse effects on fetal growth.

Uising WinBUGS to fit nonlinear mixed models with an application to pharmacokinetic modelling of insulin response to glucose challenge in sheep exposed antenatally to glucocorticoids

Many chronic diseases of adulthood, such as hypertension and diabetes, are now believed to have at least some of their origins before birth. Extensive studies in animal models have identified antenatal exposure to excess glucocorticoids as a leading candidate for the physiological cause of fetal compromise. The resulting adverse intra-uterine environment appears to "program" the individual for higher risk of subsequent disease. We present an analysis of blood glucose and insulin concentrations collected during glucose tolerance tests at 6 and 12 months postnatal age in a cohort of sheep that were treated antenatally with injections of betamethasone (a synthetic glucocorticoid) which, when injected into the mother, cross the placenta to the fetus. A simple pharmacokinetic model, essentially a modification of the single compartment model with first-order absorption and elimination, is developed to describe the time course of glucose concentration and the associated insulin response. The resulting nonlinear mixed model is implemented in a Bayesian framework using the Markov chain Monte Carlo technique Gibbs Sampling via the software package BUGS. This sampling process allows inferences to be made directly about derived quantities with an immediate physical interpretation, such as the maximum insulin concentration in response to glucose challenge. At 6 months postnatal age, sheep treated with antenatal injections of synthetic glucocorticoids had raised insulin concentration in comparison to controls after bolus administration of glucose. This effect persisted to 12 months postnatal age only in the sheep that received multiple doses of glucocorticoids. Moreover, the raised insulin concentration in sheep that received direct injections of synthetic glucocorticoid as fetuses is accompanied by better glucose clearance than in those sheep that received only saline injections, a phenomenon that is not observed in the animals that received maternal injections. It is argued that the fitting of an appropriate statistical model to complex physiological data does not necessarily proclude a result that has a clear interpretation for clinical scientists.

Differential effects of maternal betamethasone and cortisol on lung maturation and growth in fetal sheep

OBJECTIVES

We asked whether maternal or fetal cortisol treatments induced fetal lung maturation and growth restriction compared with betamethasone and whether medroxyprogesterone (MPA) influenced lung maturation.

STUDY DESIGN

Pregnant sheep were randomized to receive MPA or saline solution at 100 days of gestation. At 117 days of pregnancy, ewes were randomized to receive maternal or fetal treatments with 0.5 mg/kg betamethasone, four injections of hydrocortisone given over 4.5 hours or saline solution. Body weight and lung maturation were evaluated at 125 days.

RESULTS

Maternal betamethasone decreased in birth weight by 16% and induced lung maturation. Fetal cortisol or betamethasone induced only lung maturation. Maternal cortisol caused neither growth restriction nor lung maturation. MPA did not alter lung function in control lambs or in betamethasone-treated preterm lambs.

CONCLUSIONS

Maternal cortisol treatments had no apparent effects on the fetus, suggesting that growth restriction caused by betamethasone may result from unidentified effects on the maternal-placental unit.

The effects of overcoming experimental bladder outflow obstruction in fetal sheep

OBJECTIVE

To develop an ovine model of fetal bladder outflow obstruction and to investigate the effect on the kidney of surgical relief of the obstruction in the prenatal period.

METHODS

Ultrasound examination and amniocentesis were performed on 68 date-bred pregnant ewes at day 57 of pregnancy (term = 150 days). Fetal gender was determined using a molecular technique to identify single male fetuses. The urethra and urachus were ligated at hysterotomy on 20 of these fetuses at 75 days' gestation. Comparisons were made with six controls that did not undergo operation. Changes that occurred in fetal urinary tract appearance were detected using serial ultrasound examinations. Seven obstructed cases chosen at random had further prenatal surgery on day 94 to decompress the obstructed urinary tract by vesicostomy. The animals were killed at 110 days' gestation and post-mortem studies were performed.

RESULTS

Fourteen days after surgical obstruction, there were increases in the summed renal lengths (33 mm vs. 28 mm, p = 0.003) and renal pelvis anteroposterior (A-P) diameters (8 mm vs. 5.5 mm, p = 0.02). In the group allocated to receive surgical decompression, 9 days' relief of obstruction resulted in significant reductions in summed renal lengths (30 mm vs. 41 mm, p = 0.024; controls 31 mm) and renal pelvis A-P diameters (5.8 mm vs. 8.9 mm, p = 0.012; controls < 2 mm). Postmortem histological examination in the surgical decompression group revealed an estimated number of glomeruli similar to controls and greater than in the obstructed cases.

CONCLUSION

Surgical relief of fetal bladder outflow obstruction in ovine mid-pregnancy results in improved renal appearance on ultrasonic and histopathological examinations.

Is prenatal glucocorticoid administration another origin of adult disease?

1. The intra-uterine environment is now believed to play a major role in the origin of many adult diseases. Illnesses in which there is significant 'programming' before the time of birth include hypertension, diabetes, coronary heart disease and stroke. Acting on a genetic predisposition, intra-uterine triggers appear to programme the individual's metabolism and endocrine milieu and, after birth, these risk factors are then either amplified or minimized by environmental influences. The triggers operative during fetal life that have been studied most extensively are undernutrition and glucocorticoid exposure. 2. Over the past decade, a series of studies in sheep have focused on the perinatal and life-long consequences of glucocorticoid exposure in mid- to late-pregnancy. These studies in the sheep model have shown that maternal injections with glucocorticoids, in a manner similar to clinical treatment for women at risk of preterm birth, enhance fetal lung maturation, but were also associated with developmental and other functional alterations that are of concern. With weekly doses to the mother, there is restricted fetal growth, delayed myelination of the central nervous system, altered blood pressure soon after birth and increased insulin response to glucose challenge in early adulthood. If the glucocorticoids are given to the fetus by ultrasound-guided intramuscular injection, rather than to the mother, the effects on lung maturation are similar, but growth is spared and blood pressure after birth is unaltered. Increased insulin response to glucose challenge occurs in early adulthood with glucocorticoid by either route and is independent of growth restriction. 3. The findings in experimental animals are supported by studies of children in the Western Australian Preterm Infant Follow-up Study. Multivariate analyses have shown that increasing the number of glucocorticoid exposures, for the purpose of enhancing lung maturation prior to preterm birth, is associated with reduced birthweight and behavioural disorders at 3 years of age. 4. The results of these animal and clinical studies provide further support for a role of prenatal glucocorticoid exposure in triggering predisposition to adult disease. Further exploration of these models is expected to uncover the mechanisms and lead to effective strategies that may underpin clinical interventions.

Repeated ultrasound guided fetal injections of corticosteroid alter nervous system maturation in the ovine fetus

INTRODUCTION

Recent studies in sheep have shown that repeated maternal injections of betamethasone are associated with adverse effects within the nervous system. Repeated fetal injections of betamethasone achieve serial improvements in preterm lung function in sheep and are a possible alternative to repeated maternal therapy. We have evaluated the effect of repeated fetal administration of betamethasone on nervous system maturation in an ovine model.

METHODS

Date-mated ewes (n = 48) were randomized to receive ultrasound-guided fetal injections of betamethasone or saline between days 104 to 124 of gestation and were delivered by cesarean section on day 125 or 145 (term = 150). Optic and sciatic nerves were prepared for light and electronmicroscopy. Eye diameters were measured and transverse sections of retinae were evaluated. Data were analyzed using a mixed model analysis of variance.

RESULTS

Repeated fetal administration of corticosteroid did not significantly affect optic nerve myelination but resulted in significant delays in sciatic axonal growth (p < 0.02) and retinal maturation (p < 0.04). The process of performing repeated fetal injections also significantly affected some retinal parameters.

CONCLUSION

Repeated fetal administration of betamethasone alters some aspects of nervous system maturation in sheep. It is premature to plan trials of repeated fetal corticosteroid therapy in humans.

Programming effects in sheep of prenatal growth restriction and glucocorticoid exposure

Our aim was to determine the postnatal effects of single and repeated glucocorticoid injections during late gestation. Repeated (104, 111, 118, 125 days) or single (104 days) injections of betamethasone or saline were given to the ewe or by ultrasound guided injection to the fetus (term 150 days). Lambs were born spontaneously and studied at 3 and 6 mo and 1 yr of age. Arterial pressure was measured at each age, and we performed intravenous glucose tolerance tests at 6 mo and 1 yr. Repeated maternal, but not single maternal or fetal, betamethasone injections prolonged gestation, reduced weight at birth and 3 mo, and was associated with low arterial pressure at 3 mo but not at 6 mo and 1 yr. Glucose metabolism was altered in all betamethasone treatment groups, regardless of the number or route of injections. Our data demonstrate that glucocorticoid-induced fetal growth restriction is associated with a transient reduction in postnatal arterial pressure, but glucocorticoid exposure with or without growth restriction alters glucose metabolism.

Antenatal glucocorticoids and growth: single versus multiple doses in animal and human studies

In recent years, many clinicians have prescribed repeated courses of glucocorticoids to pregnant women at risk of early preterm birth. The published literature has provided reassurance from randomized controlled trials that single-course treatment improves postnatal lung function without deleterious consequences, but we do not yet have data from randomized trials designed specifically to investigate the effects of repeated courses. Data from animal studies have, for many years, provided evidence that prenatal exposure to glucocorticoids restricts fetal growth and, more recently, has suggested a role in programming the individual to adult disease. Multivariate analyses from non-randomized cohorts have also suggested associations between repeated treatments and reduced birth weight, but we await results from randomized controlled trials currently in progress to provide more definitive answers. Regardless of any effect on growth, the possibility that adult health and disease may be programmed by fetal exposure to glucocorticoids will ensure our need to balance the ability of these agents to improve newborn survival with the potential consequences in later life.

Maternal, but not fetal, administration of corticosteroids restricts fetal growth

OBJECTIVE

Previous studies have shown that repeated doses of corticosteroids given to pregnant sheep improve postnatal lung function, but restrict fetal growth. Repeated administration of corticosteroids directly to the fetus also enhances postnatal lung function. The purpose of the present study was to investigate and characterize the relative effects on growth of repeated maternal and fetal treatments by study of body, organ, and placental weights.

METHODS

Date-bred pregnant sheep were given intramuscular betamethasone or saline to either the mother or fetus on three occasions at weekly intervals commencing at 104 days gestation, followed by cesarean section at 125 days. Twenty-two animals which had received three doses of betamethasone were compared with 21 which had received a single dose at 104 days and with 12 saline-treated controls.

RESULTS

Repeated maternal doses of betamethasone resulted in reductions in birthweight and weights of the placenta and major organs. Direct fetal injection did not affect birthweight, placental weight, placental/ birthweight ratio, or weights of the major organs with the exception of the liver.

CONCLUSIONS

Administration of repeated doses of betamethasone directly to the sheep fetus does not produce the growth-restricting effects induced by maternal administration and does not affect the placental/birthweight ratio.

Antenatal betamethasone therapy augments isoproterenol and prostaglandin E2-mediated relaxation of preterm ovine pulmonary veins

Antenatal glucocorticoid therapy improves pulmonary function in preterm newborns. We have determined the effect of antenatal glucocorticoid therapy on isoproterenol and prostaglandin (PG) E2-mediated relaxation in preterm ovine pulmonary veins after birth. Ovine fetuses (121 and 126 d of gestation; term = 150 d) received an ultrasound guided intramuscular injection of betamethasone, 0.5 mg/kg, or saline. Lambs were delivered 15 or 48 h later, ventilated for 3 h, and killed. Isolated fourth generation pulmonary veins were suspended in organ chambers filled with modified Krebs-Ringer solution (95% O2, 5% CO2) at 37 degrees C, and their isometric tension was recorded. During contractions to U46619, isoproterenol and PGE2 induced greater relaxations of pulmonary veins of betamethasone-treated lambs than those of control. Forskolin, an activator of adenylate cyclase, caused greater relaxation in veins of betamethasone-treated lambs than in those of controls. A greater relaxation of veins treated with betamethasone than that of control veins also occurred in the presence of isobutylmethylxanthine, an inhibitor of phosphodiesterases. All vessels relaxed similarly to 8-bromo-cAMP, a cell membrane-permeable analog of cAMP. When stimulated with isoproterenol, PGE2, and forskolin, adenylate cyclase activity of crude membrane preparations of pulmonary veins treated with betamethasone was greater than that of controls. These results demonstrate that antenatal betamethasone therapy potentiates isoproterenol and PGE2-mediated relaxation of pulmonary veins of preterm lambs; an enhanced adenylate cyclase activity explain in part the effect of antenatal glucocorticoid therapy on pulmonary veins of preterm lambs.

Prenatal glucocorticoid and T4 effects on lung morphology in preterm lambs

Prenatal glucocorticoid plus T4 treatment of fetal sheep results in improvements in oxygenation, gas exchange, lung mechanics, and lung volumes after preterm delivery. We have evaluated the morphometric changes in the lungs of lambs exposed to betamethasone and T4 48 h before preterm delivery at 121 and 135 d gestation and related those changes to the physiologic improvements in lung function. The lungs used for the morphometric studies were from lambs with postnatal physiologic responses similar to those of the entire group of lambs reported previously (16). At both 121 and 135 d gestation, lung gas volumes and fixed tissue volumes increased, the percent of collapsed (nonaerated) parenchyma decreased, and the percent of perilobular connective tissue decreased with both gestational age and prenatal hormone exposure. Alveolar size, as estimated by mean linear intercept length, did not change with gestation or hormone exposure, but there was a decrease in alveolar wall thickness with advancing gestation and at each gestation with hormone exposure. The major anatomic effect of prenatal hormone exposure was a decrease in alveolar wall thickness and an increase in aerated parenchyma, effects that were consistent with the physiologic improvements in postnatal lung function.

Cardiac flow after fetal blood sampling in normally grown and growth-retarded fetuses

The objective of this study was to evaluate the effect of fetal blood sampling on cardiac flow velocity waveforms. Flow velocity waveforms were measured from the ascending aorta and pulmonary artery immediately before and after fetal blood sampling in 29 normally grown and 12 growth-retarded fetuses. The latter group was characterized by abnormal Doppler indices in the umbilical artery and middle cerebral artery suggestive of uteroplacental insufficiency as the causative factor of the impaired growth. The flow velocity parameters studied were the peak velocity, the time to peak velocity, and the left and right cardiac output and their ratio. In normally grown fetuses, the peak velocity and right and left cardiac output values increased significantly after fetal blood sampling, while no significant changes were observed in the other indices considered. The gestational age at the time of the procedure was positively related to the amplitude of these changes. In growth-retarded fetuses, fetal blood sampling did not induce any significant increase in cardiac output or peak velocities, while in more than 50 per cent of the fetuses these Doppler indices decreased. The amplitude of the decrease was significantly related to the severity of acidosis in the umbilical vein. In conclusion, the cardiac haemodynamic response to fetal blood sampling differs between normally grown and growth-retarded fetuses. This difference may explain the higher rate of complications occurring in the latter group of fetuses after blood sampling.