Pregnant women with active acromegaly are potentially at risk because of their increased risk of glucose intolerance, diabetes mellitus, high blood pressure, and preeclampsia. Particularly, gestational diabetes may be more prevalent in acromegaly due to an insulin resistance state resulting from the anti-insulin effect of GH. However, only some cases of mild gestational diabetes, most of them controlled with dietary measures,9–11 are reported in the literature, while most patients with acromegaly do not experience clinically relevant metabolic or cardiovascular complications during pregnancy. However, Caron et al. noted a trend to an increased prevalence of gestational diabetes and high blood pressure in acromegalic women as compared to the overall French population. No differences were seen between patients with and without preconception control of GH/IGF-I.3 Interestingly, the occurrence of these complications was not associated with the type of medical treatment, as only one woman who developed gestational diabetes had been treated with a somatostatin analog during the first half of pregnancy.3,4 As regards newborns from women with acromegaly, no malformation has been documented, and birth weight was normal in 83 of the 95 babies reported in the Cheng review,4 in agreement with the premise of placental impermeability to GH and IGF-I.9 In conclusion, although acromegaly itself does not appear to significantly affect the course of pregnancy, prospective studies of larger populations should be conducted to conclusively assess the metabolic and cardiovascular consequences of GH/IGF-I excess during pregnancy for both the mother and fetus.

Dopamine analogs (DAs), particularly bromocriptine, have been shown to be safe during pregnancy.12 However, in the recent systematic review conducted by Cheng et al., a greater prevalence of macrosomic fetuses was seen in women treated with DAs as compared to untreated women, and the difference was borderline significant.4 However, this result needs to be confirmed in larger prospective studies. There are currently few conclusive data about SAs. All five subtypes of somatostatin receptors are expressed in the placenta, including SST4 (which shows little affinity for octreotide).13 Maffei et al. detected a very low number of somatostatin receptors in placental cell membrane and umbilical cord tissues, which suggests that the maternal–fetal barrier is able to exert a weak functional response to SAs.12 Although the fetus may be exposed to the drug in the first few weeks following conception, pregnancy is likely to continue without complications if treatment is discontinued after pregnancy is confirmed. In the few cases reported of women with acromegaly in whom treatment with SAs was continued during pregnancy, no maternal complication of fetal malformation was reported.8,13 However, delayed uterine growth was documented in the fetus of a woman treated with octreotide LAR throughout pregnancy.14 In fact, in the systematic review by Cheng, women treated with SAs during pregnancy were more likely to have low birth weight newborns as compared to untreated women.4 Maffei et al. documented transient reductions in uterine artery flow and systolic velocity after injections of short-acting octreotide in a pregnant woman with acromegaly.13 This may explain, at least partly, the association between delayed growth/microsomia and the previously mentioned use of SAs. The use of pegvisomant during pregnancy has been reported as being safe and effective in two cases.15,16 Fetal drug levels were minimal, suggesting low or no transplacental passage, while GH-V levels in maternal and cord blood were within the normal range.15 In conclusion, although the medical treatment of pregnant women with acromegaly is not associated with major side effects in the mother or fetus, drug discontinuation is recommended during pregnancy. If drugs are used, strict monitoring of fetal development is recommended.

To sum up, although no adequate scientific evidence is available about the management of acromegalic women during pregnancy, the following suggestions may be made: (a) it is important to control GH/IGF-I hypersecretion before pregnancy is planned; (b) medical treatment should be discontinued at least two months before a planned pregnancy or upon pregnancy diagnosis, because pregnancy does not aggravate acromegaly in most cases, and may even lead to a reduction in IGF-I levels and an improvement in associated symptoms, particularly in the first half of pregnancy; (c) in women with microadenoma, clinical signs suggesting a potential tumor growth (such as headache and/or vision disturbances) should be monitored every term; (d) in women with macroadenoma, strict clinical control and visual field examination are recommended every six weeks, because symptomatic macroadenoma growth may occur during pregnancy, particularly if previously untreated or if given drug treatment only; (e) in patients with evidence of tumor enlargement, in addition to ophthalmological monitoring, a control MRI may be considered in the second term. In these patients, a cesarean section to minimize the risk of pituitary apoplexy should be considered. If vision impairment is documented, urgent transsphenoidal resection is recommended; (f) all pregnant women with acromegaly should be monitored because of the risk of the occurrence of diabetes and gestational hypertension; (g) the available evidence does not support the maintenance or restart of medical treatment for acromegaly during pregnancy, because of the potential increase in the risk of impaired fetal development; and (h) lactation may be permitted in pregnant women with acromegaly, particularly in those with minimal or no residual tumor.

However, little experience is available, and prospective multicenter studies will be needed to clarify whether or not acromegalic mothers and their fetuses have an increased risk during and after pregnancy as compared to normal pregnant women.