Adrenal function in preterm infants: ACTH may not be the sole regulator of the fetal zone

Steroid Metabolomic Signature in Term and Preterm Infants

Adrenal function is essential for survival and well-being of preterm babies. In addition to glucocorticoids, it has been hypothesized that C19-steroids (DHEA-metabolites) from the fetal zone of the adrenal gland may play a role as endogenous neuroprotective steroids. In 39 term-born (≥37 weeks gestational age), 42 preterm (30-36 weeks) and 51 early preterm (<30 weeks) infants 38 steroid metabolites were quantified by GC-MS in 24-h urinary samples. In each gestational age group, three distinctive cluster were identified by pattern analysis (k-means clustering). Individual steroidal fingerprints and clinical phenotype were analyzed at the 3rd day of life. Overall, the excretion rates of C21-steroids (glucocorticoid precursors, cortisol, and cortisone metabolites) were low (<99 μg/kg body weight/d) whereas the excretion rates of C19-steroids were up to 10 times higher. There was a shift to higher excretion rates of C19-steroids in both preterm groups compared to term infants but only minor differences in the distribution of C21-steroids. Comparable metabolic patterns were found between gestational age groups: Cluster 1 showed mild elevation of C21- and C19-steroids with the highest incidence of neonatal morbidities in term and severe intraventricular hemorrhage in early preterm infants. In cluster 2 lowest excretion in general was noted but no clinically unique phenotype. Cluster 3 showed highest elevation of C21-steroids and C19-steroids but no clinically unique phenotype. Significant differences in steroid metabolism between clusters are only partly reflected by gestational age and disease severity. In early preterm infants, higher excretion rates of glucocorticoids and their precursors were associated with severe cerebral hemorrhage. High excretion rates of C19-steroids in preterm infants may indicate a biological significance.

The Androgen Metabolome of Preterm Infants Reflects Fetal Adrenal Gland Involution

CONTEXT

The human adrenal cortex changes with fetal-neonatal transition from the fetal to the adult organ, accompanied by changes in the steroid metabolome.

OBJECTIVE

As it is unclear how the observed developmental changes differ between preterm and full-term neonates, we investigated whether the involution of the fetal adrenals is following a fixed time course related to postmenstrual age or whether it is triggered by birth. Furthermore, the fetal and postnatal androgen metabolome of preterm infants was characterized in comparison to term babies.

METHODS

This was a prospective, longitudinal, 2-center study collecting spot urines of preterm and term infants during the first 12 to 18 months of life. Steroid metabolites were measured from spot urines by gas chromatography-mass spectrometry. Data relating were modeled according to established pre- and postnatal pathways.

RESULTS

Fetal adrenal involution occurs around term-equivalent age in preterm infants and is not triggered by premature birth. Testosterone levels are higher in preterm infants at birth and decline slower until term compared to full-term babies. Dihydrotestosterone levels and the activity of the classic androgen biosynthesis pathway are lower in premature infants as is 5α-reductase activity. No difference was found in the activity of the alternate backdoor pathway for androgen synthesis.

CONCLUSION

Human adrenal involution follows a strict timing that is not affected by premature birth. By contrast, prematurity is associated with an altered androgen metabolome after birth. Whether this reflects altered androgen biosynthesis in utero remains to be investigated.

Impact of Gestational and Postmenstrual Age on Excretion of Fetal Zone Steroids in Preterm Infants Determined by Gas Chromatography-Mass Spectrometry

CONTEXT

Fetal zone steroids (FZSs) are excreted in high concentrations in preterm infants. Experimental data suggest protective effects of FZSs in models of neonatal disease.

OBJECTIVE

We aimed to characterize the postnatal FZS metabolome of well preterm and term infants.

METHODS

Twenty-four-hour urinary FZS excretion rates were determined in early preterm (<30 weeks' gestation), preterm (30-36 weeks), and term (>37 weeks) infants. Pregnenolone and 17-OH-pregnenolone metabolites (n = 5), and dehydroepiandrosterone sulfate and metabolites (n = 12) were measured by gas chromatography mass spectrometry. Postnatal concentrations of FZSs were compared with already published prenatal concentrations in amniotic fluid.

RESULTS

Excretion rates of total FZSs and most of the single metabolites were highest in early preterm infants. In this group, excretion rates approach those of term infants at term equivalent postmenstrual age. Preterm infants of 30-36 weeks had more than half lower median excretion rates of FZSs than early preterm infants at the same time of postmenstrual age. Postnatal concentrations of FZSs were partly more than 100-fold higher in all gestational age groups than prenatal concentrations in amniotic fluid at midgestation.

CONCLUSION

The excretion rates of FZSs as a proxy of the involution of the fetal zone of the most immature preterm infants approached those of term infants at term equivalent. In contrast, the fetal zone in more mature preterm infants undergoes more rapid involution. These data in exclusively well neonates can serve as a basis to investigate the effects of illness on the FZS metabolome in future studies.

Fetal Zone Steroids and Estrogen Show Sex Specific Effects on Oligodendrocyte Precursor Cells in Response to Oxidative Damage

Oxygen causes white matter damage in preterm infants and male sex is a major risk factor for poor neurological outcome, which speculates the role of steroid hormones in sex-based differences. Preterm birth is accompanied by a drop in 17β-estradiol (E2) and progesterone along with increased levels of fetal zone steroids (FZS). We performed a sex-based analysis on the FZS concentration differences in urine samples collected from preterm and term infants. We show that, in preterm urine samples, the total concentration of FZS, and in particular the 16α-OH-DHEA concentration, is significantly higher in ill female infants as compared to males. Since we previously identified Nup133 as a novel target protein affected by hyperoxia, here we studied the effect of FZS, allopregnanolone (Allo) and E2 on differentiation and Nup133 signaling using mouse-derived primary oligodendrocyte progenitor cells (OPCs). We show that the steroids could reverse the effect of hyperoxia-mediated downregulation of Nup133 in cultured male OPCs. The addition of FZS and E2 protected cells from oxidative stress. However, E2, in presence of 16α-OH-DHEA, showed a negative effect on male cells. These results assert the importance of sex-based differences and their potential implications in preterm stress response.

Cortisol production in preterm infants with or without late-onset adrenal insufficiency of prematurity: A prospective observational study

BACKGROUND

Immature adrenocortical function in preterm infants may cause inadequate production of cortisol under stress, resulting in adrenal insufficiency of prematurity (AOP). The objective of this study is to compare cortisol production in preterm infants with and without late-onset AOP.

METHODS

Of 27 preterm infants born at less than 32 weeks gestation, cortisol production was analyzed in those who did (patients, group P) and did not (controls, group C) eventually develop late-onset AOP. Blood samples were prospectively collected every two weeks after birth, and steroid hormone concentrations in the pathway to cortisol production were measured retrospectively.

RESULTS

We restricted the initial subjects to infants with gestation less than 29 weeks to adjust for confounding factors, culminating in matched infants in groups P (n = 8) and C (n = 11). The cortisol concentrations did not differ between the groups before AOP onset (P = 0.20), but the total concentrations of precursors for cortisol were higher in group P (P < 0.0001). The total concentrations of precursors in group C were inversely correlated with postmenstrual age (ρ = -0.38, P < 0.01). The pattern of changes in total concentrations of precursors differed between the groups (P < 0.05).

CONCLUSION

Adrenal cortex maturity in preterm infants develops in parallel with postmenstrual age. Infants with late-onset AOP have undeveloped maturation of adrenocortical function after birth.

CLINICAL TRIAL REGISTRATION

UMIN000022453.

Adrenal function of extremely premature infants in the first 5 days after birth

Background There is limited data on adrenal function in the early days after birth in extremely premature infants. The relationship between plasma adrenocorticotrophic (ACTH) and cortisol hormone is central to the integrity of the hypothalamic-pituitary-adrenal (HPA) axis yet there are no studies examining this relationship in prematurity. Methods The aim of this study was to examine the relationship between early morning plasma cortisol and ACTH concentrations during the first 5 days after birth in infants born at less than 28 weeks' gestation and to identify any independent factors that determine plasma cortisol levels in these infants during extreme prematurity. We prospectively studied early morning plasma ACTH and cortisol concentrations in infants born below 28 weeks' gestation during the first 5 days of birth. Plasma cortisol was measured without extraction, using DPC Immulite® 2000 using a solid phase 2 site chemiluminescent immunometric assay. ACTH was measured using a radioimmunoassay. Spearman's correlation was used to examine the relationship between cortisol and ACTH. Multiple regression analysis was used to examine the relationship between plasma cortisol and clinical risk index for babies (CRIB) score, antenatal dexamethasone, mode of delivery and gestation. Results There were 95 infants (53 males) of mean gestation 25.3 ± 1.3 standard deviation (SD) (range 23-27 + 6) weeks. The mean birth weight was 809 ± 17.0 g. The mean plasma cortisol was 400.5 ± 42.6 nmol/L and the mean plasma ACTH was 4.5 ± 0.9 pmol/L. Early morning plasma cortisol correlated significantly with gestation (R = 0.4, p = 0.005). Early morning plasma ACTH did not correlate with early morning plasma cortisol (R = -0.12, p = 0.7). Multiple regression analysis showed that gestation was the only independent determinant of early morning plasma cortisol concentration (beta coefficient = -0.4, p = 0.04). Conclusions The relationship between early morning plasma ACTH and plasma cortisol is either not established or is impaired in infants of less than 28 weeks' gestation in the first 5 days after birth. The plasma cortisol level is mainly determined by gestation and is not directly related to illness severity, antenatal steroids or plasma ACTH in these infants in the first 5 days after birth.

The response of C19- and some C21-steroids during Synacthen and insulin tolerance test

Testing of the adrenal function with ACTH 1-24 (Synacthen test) or insulin (insulin tolerance test-ITT) is commonly used. The question of ongoing debate is the dose of Synacthen. Moreover, it may be important from the physiological point of view besides measurement of cortisol levels and 17α-hydroxy-progesterone to know also the response of other steroids to these test. The plasma levels of 24 free steroids and their polar conjugates were followed after stimulation of 1 μg, 10 μg and 250 μg of ACTH 1-24 and after insulin administration in thirteen healthy subjects. The study aimed to describe a response of steroid metabolome to various doses of ACTH 1-24 and to find the equivalency of these tests. The additional ambition was to contribute to understanding of physiology of these stimulation tests and suggest an additional marker for HPA axis evaluation. No increase of most conjugated steroids and even decrease of some of them during all of the Synacthen tests and ITT at 60th min were observed. The levels of steroid conjugates decreased in ITT but did not during all of the Synacthen tests by 20 min of each test. Testosterone and estradiol did not increase during the Synacthen tests or ITT as expected. The results suggest that the conjugated steroids in the circulation can serve as reserve stock for rapid conversion into free steroids in the first minutes of the stress situation. Various doses of ACTH 1-24 used in the Synacthen tests implicate earlier or later occurrence of maximal response of stimulated steroids. The equivalent dose to ITT and standard 250 μg of ACTH 1-24 seemed to be dose of 10 μg ACTH 1-24 producing the similar response in all of the steroids in the 60th min of the test.

DHEA in Prenatal and Postnatal Life: Implications for Brain and Behavior

Dehydroepiandrosterone (DHEA) and its sulfated congener (DHEAS) are the principal C₁₉ steroid produced by the adrenal gland in many mammals, including humans. It is secreted in high concentrations during fetal life, but synthesis decreases after birth until, in humans and some other primates, there is a prepubertal surge of DHEA production by the adrenal gland-a phenomenon known as adrenarche. There remains considerable uncertainty about the physiological role of DHEA and DHEAS. Moreover, the origin of the trophic drives that determine the waxing and waning of DHEA synthesis are poorly understood. These gaps in knowledge arise in some measure from the difficulty of understanding mechanistic determinants from observations made opportunistically in humans and primates, and have stimulated a search for other suitable species that exhibit adrenarche- and adrenopause-like changes of adrenal function. DHEA and DHEAS are clearly neuroactive steroids with actions at several neurotransmitter receptors; indeed, DHEA is now known to be also synthesized by many parts of the brain, and this capacity undergoes ontogenic changes, but whether this is dependent or independent of the changes in adrenal synthesis is unknown. In this chapter we review key contributions to this field over the last 50+ years, and speculate on the importance of DHEA for the brain, both during development and for maturation and aging of cerebral function and behavior.

Potential role of increased oxygenation in altering perinatal adrenal steroidogenesis

BACKGROUND

At birth, the large fetal adrenal involutes rapidly, and the patterns of steroidogenesis change dramatically; the event(s) triggering these changes remain largely unexplored. Fetal abdominal viscera receive hypoxic blood having a partial pressure of oxygen of only ~2 kPa (20-23 mm Hg); perinatal circulatory changes change this to adult values (~20 kPa). We hypothesized that transition from fetal hypoxia to postnatal normoxia participates in altering perinatal steroidogenesis.

METHODS

We grew midgestation human fetal adrenal cells and human NCI-H295A adrenocortical carcinoma cells in 2% O2, then transitioned them to 20% O2 and quantitated steroidogenic mRNAs by quantitative PCR and microarrays.

RESULTS

Transitioning fetal adrenal cells from hypoxia to normoxia increased mRNAs for 17α-hydroxylase/17,20 lyase (P450c17), 3β-hydroxysteroid dehydrogenase (3βHSD2), and steroidogenic acute regulatory protein (StAR). We repeated the protocol with NCI-H295A cells acclimated to hypoxia for 15 d, quantitating 31,255 transcripts by microarray. Using an arbitrary 1.5-fold difference, 1 d of normoxia increased 4 transcripts and decreased 56, whereas 2 d of normoxia increased 62 transcripts and decreased 105. P450c17, 3βHSD2, and StAR were ranked among the top eight increased transcripts.

CONCLUSION

These data suggest that the hypoxic/normoxic transition at birth contributes to perinatal changes in adrenal steroidogenesis.

21-hydroxylase deficiency in the neonate - trends in steroid anabolism and catabolism during the first weeks of life

Deficiency of 21-hydroxylase provides an in vivo model of intrauterine induction of enzymes participating in steroid anabolism and catabolism. Quantitative data for 93 steroid metabolites in urine from 111 patients and 7 controls (25 samples) were compared over the first six weeks of life. Net flux through the key anabolic enzymes was examined by comparison of the totals of steroids derived from the intermediates prior to and following each enzymatic step. Metabolic relationships were established on structural grounds and by Pearson correlation. The relative importance of each catabolic route was evaluated after summing metabolites classified according to their structure as fetal, neonatal, and classical (adult) type. Hierarchical cluster analysis identified the structure at C3-C5 as a key distinguishing feature of the major catabolic streams and demonstrated a split point in metabolic pattern in patients at 7 days. Changes with time in steroid metabolism, larger in patients than in controls, could be interpreted as reflecting increased cortisol demand post partum, the clinical onset of salt-wasting and a transition in catabolism from fetal to postnatal life. Faster involution of the fetal zone and pronounced enhancement of steroid production in zona fasciculata and zona glomerulosa were indicated in patients. Predominant at birth were 'planar' fetal-type 5α-reduced metabolites, adapted to placental excretion, which gave way to additionally hydroxylated neonatal-type metabolites, facilitating renal excretion. Classical metabolism made gains over the study period. Overproduction of steroids in utero in 21-hydroxylase deficiency would have induced fetal catabolic pathways dependent on 5α-reduction. A progressive increase of steroids likely to arise from 5α-reductase type 2 activity, again more distinct in disease, was observed. We demonstrate that the key intermediates in the hypothetical 'backdoor' pathway of androgen synthesis are part of a broader catabolic network and should not be examined in isolation.

Development and function of the human fetal adrenal cortex: a key component in the feto-placental unit

Continuous efforts have been devoted to unraveling the biophysiology and development of the human fetal adrenal cortex, which is structurally and functionally unique from other species. It plays a pivotal role, mainly through steroidogenesis, in the regulation of intrauterine homeostasis and in fetal development and maturation. The steroidogenic activity is characterized by early transient cortisol biosynthesis, followed by its suppressed synthesis until late gestation, and extensive production of dehydroepiandrosterone and its sulfate, precursors of placental estrogen, during most of gestation. The gland rapidly grows through processes including cell proliferation and angiogenesis at the gland periphery, cellular migration, hypertrophy, and apoptosis. Recent studies employing modern technologies such as gene expression profiling and laser capture microdissection have revealed that development and/or function of the fetal adrenal cortex may be regulated by a panoply of molecules, including transcription factors, extracellular matrix components, locally produced growth factors, and placenta-derived CRH, in addition to the primary regulator, fetal pituitary ACTH. The role of the fetal adrenal cortex in human pregnancy and parturition appears highly complex, probably due to redundant and compensatory mechanisms regulating these events. Mounting evidence indicates that actions of hormones operating in the human feto-placental unit are likely mediated by mechanisms including target tissue responsiveness, local metabolism, and bioavailability, rather than changes only in circulating levels. Comprehensive study of such molecular mechanisms and the newly identified factors implicated in adrenal development should help crystallize our understanding of the development and physiology of the human fetal adrenal cortex.

Effect of antenatal betamethasone use on adrenal gland size and endogenous cortisol and 17-hydroxyprogesterone in preterm neonates

AIM

To assess the effect of antenatal betamethasone use on adrenal gland size and adrenal hormones in preterm neonates who had gestational ages of 27-36 weeks.

INFANTS AND METHODS

Sixty-six neonates divided into two groups: betamethasone group, whose mothers received betamethasone 12 mg two times 24 h apart, and no betamethasone group, whose mothers did not receive any steroid agent during the antenatal period. Serum 17-hydroxyprogesterone (17-OHP) levels and cortisol levels were measured during the first six hours of life. In addition, adrenal gland length and width were determined on the first day of life. Hormone tests and ultrasonographic evaluation were repeated on the fifth day of life.

RESULTS

We found statistically significant reductions in 17-OHP and cortisol levels at birth in corticosteroid-exposed neonates (p < 0.05). There was no significant difference between the study groups with regard to adrenal gland length and width (p > 0.05).

CONCLUSIONS

This study demonstrates that betamethasone use in preterm neonates reduces endogenous 17-OHP and cortisol levels; however, it has no effect on adrenal gland size.

Relationships between adrenocorticotropic hormone and cortisol are altered during clustered nursing care in preterm infants born at extremely low gestational age

BACKGROUND

Little is known about the effects of clustered nursing care on hypothalamic pituitary axis (HPA) responses in preterm infants in the neonatal intensive care unit.

AIMS

To examine facial responses, adrenocorticotropic hormone (ACTH) and cortisol levels, and the relationship between ACTH and cortisol in preterm infants in two gestational age groups (extremely low gestational age [ELGA: < or =28 weeks]; very low gestational age [VLGA: 29-31 weeks]) under basal conditions and in response to routine nursing procedures.

STUDY DESIGN

Within subjects' cross-over design in random order.

SUBJECTS

Ninety preterm infants with no postnatal steroid exposure were studied at 32+/-1 weeks postconceptional age.

OUTCOME MEASURES

Facial actions, ACTH and cortisol levels were measured after a 30 minute rest period and in response to routine clustered nursing care (CC). Changes in facial actions were analyzed using repeated measures ANOVA. MANOVA or Mann-Whitney U tests were used to determine differences in ACTH and cortisol between gestational age groups. Spearman rank correlations were used to examine relationships between perinatal variables and facial, ACTH and cortisol levels.

RESULTS

All infants had significantly increased facial responses to CC (p=0.001). Infants having experienced higher numbers of skin breaking procedures 24 h before basal assessment had higher basal cortisol levels (r=0.30, p=0.01). In response to CC, ELGA infants showed no correlation between ACTH and cortisol levels; VLGA infants showed a strong, positive correlation (r=0.62, p=0.02).

CONCLUSION

The pattern of relationship between ACTH and cortisol differs depending on gestational age at birth in response to clustered nursing care. Prior pain alters responsiveness and HPA dysregulation is apparent in ELGA infants.

Parturition itself is the basis for fetal adrenal involution

CONTEXT

Newborn infants show a postnatal decline in androgen levels as the fetal adrenal glands involute.

HYPOTHESIS

Placental factors up-regulate dehydroepiandrosterone sulfate (DHEA-S) generation. Hence, regardless of age, parturition will result in fetal adrenal involution and decline in DHEA-S levels.

SUBJECTS AND METHODS

Premature neonates (n = 30) with gestational age 26-35 wk were studied. Adrenal volume by ultrasonography and serum DHEA-S, cortisol, and androstendione levels were followed weekly between d 1 and 28 of life.

RESULTS

Serum DHEA-S was high on d 1 of life, declining rapidly regardless of gestational age during the first week of life (P < 0.001), and serum androstenedione and cortisol levels followed a similar pattern. Androstenedione levels showed a rise as of d 21 of life in boys but not in girls. The adrenals decreased in ultrasonographic volume from d 1 to 14 of life (P < 0.001), regardless of gestational age.

CONCLUSIONS

Involution of the adrenal is faster than previously reported and, regardless of gestational age, occurs within the first week of life in terms of hormone secretion and within 2 wk in adrenal size. Involution involves a decline in DHEA-S but also in androstenedione and cortisol secretion, with a change in enzymatic activity. Males and females differ in their androstenedione levels and enzymatic activity. Parturition itself is the basis for fetal adrenal involution, supporting a key role for placental factors in maintaining the fetal adrenal and generating adrenal androgens.

Persistent high activity of the fetal adrenal cortex in preterm infants: is there a clinical significance?

BACKGROUND

In preterm infants, the activity of the fetal adrenal cortex continues until term. Dehydroepiandrosterone sulphate can block the synthesis of surfactant in vitro. The incidence of pulmonary disease is higher in male than in female preterm infants.

OBJECTIVE

To investigate the relationship between urinary excretion of fetal zone steroids (3beta-OH-5-ene-steroids) and the severity of lung disease in preterm infants with respect to gender.

PATIENTS AND METHODS

3beta-OH-5-ene-steroids were profiled by gas chromatography-mass spectrometry in 24-h urinary samples in 61 preterm infants of less than 30 weeks gestational age.

RESULTS

The incidence of respiratory distress syndrome treated with surfactant in females (n = 30) was 47% and in males (n = 31) 71%, p = 0.07. Medians of total excretion rates of fetal zone steroids (microg/kg/d) in female (male) preterm infants were at day 1: 1,317 (895); day 2: 3,154 (7,723), p = 0.03; day 3: 5,502 (9,494), p = 0.08; day 5: 7,140 (10,407); week 2: 8,731 (9,720); week 3: 8,571 (10,079); week 4: 7,620 (7,825). Regression analysis did not reveal a significant influence of maximum excretion rates of fetal zone steroids or gender on the incidence of respiratory distress syndrome treated with surfactant.

CONCLUSIONS

Excretion rates of fetal zone steroids were 4-fold higher than previously reported indicating a persistent high activity of the fetal adrenal zone in preterm infants. Excretion rates of fetal zone steroids were significantly higher in male preterm infants compared to females at day 2 (trend at day 3) but did not have a significant influence on the incidence of respiratory distress syndrome.

C19‐5‐ene Steroids in Nature

Dehydroepiandrosterone (DHEA), produced from cholesterol in the adrenals, is the most abundant steroid in our circulation. It is present almost entirely as the sulfate ester, but the free steroid is the form that serves as a precursor of estrogens and androgens, as well as 7- and 16-oxygenated derivatives. Mammalian tissues reduce the 17-keto Group of DHEA to produce androstenediol-a weak estrogen and full-fledged androgen. Its androgen activity is not inhibited by the anti-androgens commonly used to treat prostate cancer. It is probably responsible for the growth of therapy-resistant prostate cancer. DHEA is hydroxylated at the 7 alpha position, and this derivative is oxidized by 11 beta-hydroxysteroid dehydrogenase to form 7-keto DHEA. The latter is reduced by the same dehydrogenase to form 7 beta-hydroxy DHEA. When fed to rats, each of the latter three steroids induce the formation of two thermogenic enzymes in the liver. The late-term human fetus produces relatively large amounts of 16 alphahydroxy DHEA, which serves the mother as a precursor of estriol.

Maturity of the adrenal cortex in very preterm infants is related to gestational age

To study the maturity of the adrenal cortex in preterms born before 33 wk of gestation, basal levels of cortisol and cortisone and the cortisol and 17-hydroxyprogesterone (17-OHP) response to 1 microg/kg adrenocorticotropic hormone stimulation were measured in 24 appropriate-for-gestational age preterm infants (26-33 wk; 690-1985 g). Gestational age influenced the response of cortisol, 17-OHP, and the ratio between cortisol/17-OHP in the studied infants. In preterms born <30 wk of gestation, levels of cortisol, and the ratio between cortisol/17-OHP were lower compared with preterms born between 30 and 33 wk. Levels of cortisone were higher in preterms born <30 wk, suggesting a lower activity of 11 beta-hydroxysteroid dehydrogenase that may be related to maturity as well. These findings indicate that the adrenal cortex function in preterm infants is closely related to the duration of gestation and may be important in neonatal morbidity.

Development of the hypothalamic-pituitary-adrenal axis in the fetus and preterm infant

The development of the hypothalamic-pituitary-adrenal (HPA) axis in the human fetus is a complex process. The feto-placental unit may be responsible for important maturational processes in vital organ systems in the fetus. A late gestational cortisol surge may be important in fetal maturation, particularly maturation of the lungs. Several striking differences exist between the function of the HPA axis in the fetus and in adults, such as a relative deficiency of 3beta-hydroxysteroid dehydrogenase in the fetal adrenal cortex. With the transition from intrauterine to extra-uterine life several changes occur in the function of the HPA axis. In infants born before term, the function of the HPA axis may still be immature at both the central and adrenal level. This immaturity of the HPA axis may be important in the development of neonatal morbidity. The present review describes the development of the HPA axis in the fetus and in preterm infants and discusses the possible role of HPA immaturity in the development of neonatal morbidity.

The hypothalamic pituitary axis in the fetus and newborn

Glucocorticoid receptor activation in the fetal lung triggers maturation necessary for extra-uterine life. Antenatal treatment with betamethasone and dexamethasone has lowered severity of respiratory distress in very low birth weight infants, and dexamethasone given postnatally has resulted in short-term improvement in chronic lung disease. Recently, however, surfactant therapy has diminished the differential benefit of antenatal glucocorticoid treatment, and it has been difficult to show that postnatal dexamethasone therapy improves survival. Treated infants may have reduced weight gain, adrenal suppression, increased incidence of intestinal perforation and infection, and long-term developmental and metabolic problems. Recent data suggest that the fetal hypothalamic/pituitary/adrenal axis is active early and is precisely structured for an intricate sequence of specifically fetal developmental events, which may be deranged by dexamethasone therapy. We consider data suggesting that persistence of the fetal pattern in some premature infants constitutes adrenal insufficiency, and that therapy at stress replacement doses with less potent glucocorticoids might avoid side effects seen with traditional regimens.