MS has not been proven to affect female fertility.32 However, the proportion of women with no children is higher among women who eventually develop MS than among those who do not. Two epidemiological studies report lower incidence of MS among people (both women and men) who had children within the previous 5 years.28,31 The apparent protective effect of maternity/paternity was not seen in parents whose children had been born 10 years previously.28,31 This, combined with the fact that both women and men have a lower incidence of MS in the 5 years following a child's birth, suggests that pregnancy in itself is not a protective factor against MS. Alternative explanations for the apparently higher incidence of MS in people with no children may be preclinical MS acting to reduce fertility or influence family planning decisions.

Several studies have shown that fertility treatments increase the risk of relapses in women with MS, with relapse rates increasing during treatment and in the 3 months after in vitro fertilisation.33–36 This has been associated with use of gonadotropin-releasing hormone agonists.35,36 These drugs increase the number of cells producing IL-8, IL-12, IFN-γ, and TGF-β, which may have a proinflammatory effect and increase the levels of circulating vascular endothelial growth factor and chemokine CXCL-12, promoting transmission of peripheral blood mononuclear cells across the blood-brain barrier.36 This may explain the increased rate of MS relapses during fertility treatment. A role may also be played by sudden changes in oestrogen levels (as occurs during pregnancy and the postpartum period) and discontinuation of MS treatment during fertility treatment.

Familial aggregation is an epidemiological feature of MS. Children with one parent with MS have been shown to have a 2% likelihood of developing MS at some point in their lives.37 The risk increases to 6%-12% when both parents have MS (conjugal MS),38,39 suggesting that the risk of developing MS is determined by genetic factors inherited from both parents.

Some studies have found an association between the risk of developing MS and the month of birth (with risk of MS being slightly greater for people born in spring, and lower for those born in autumn), especially in cases of familial MS.40 This suggests that MS pathogenesis involves an interaction between genetic and climate-related environmental factors. However, subsequent studies have shown that these results were biased by geographical and seasonal differences in birth rates.41

Several studies suggest an inverse correlation between vitamin D levels and the risk of MS.42 Furthermore, women whose mothers consumed large amounts of vitamin D during pregnancy have been observed to have a lower risk of MS.43 Although the safety of vitamin D supplements has not been evaluated, these data suggest that pregnant women with low vitamin D levels should receive supplementation43 to maintain normal serum levels of 1,25-dihydroxyvitamin D (50-125nmol/L).44

Corticosteroids are classified under pregnancy risk category C by the USA Food and Drug Administration (FDA). These drugs should be avoided during the first trimester: corticosteroid use during the first 3 months of pregnancy has been associated with such foetal malformations as cleft palate.54 High-dose methylprednisolone is relatively safe for the treatment of MS relapses during the second and third trimesters, but should be limited to the treatment of disabling relapses. Although methylprednisolone is metabolised in the placenta before reaching the foetus, it may cause mild leukocytosis and immunosuppression in neonates.

MS treatment during pregnancy should be adapted to each patient's needs, considering such variables as age, disease progression, clinical and radiological stability, previous relapses, disability, the risks of discontinuing treatment, the risks of maintaining treatment, and the patient's preferences.

The available information on the effects of disease-modifying treatment on pregnancy comes mainly from personal experiences. Due to the scarcity of data on the safety of this treatment for pregnant women, effective contraception during treatment is highly recommended.

Patients should follow the indications of the summary of product characteristics of each drug; patients are discouraged from using most of these drugs during pregnancy. In exceptional cases where treatment is maintained during pregnancy, the drug should be prescribed off-label and patients should sign informed consent forms.

IFN-β is classified under FDA pregnancy risk category C. In experimental animals receiving higher doses than humans, the abortive effects of the drug have shown to increase in a dose-dependent manner during the first trimester. Small amounts of IFN-β are excreted into breast milk. Contraception should be used during treatment with the drug. Women with MS who plan to become pregnant should discontinue treatment with IFN-β.

The literature includes around 1000 cases of patients taking IFN-β during pregnancy. However, in most cases the drug was administered only during the first weeks of the first trimester, since treatment was discontinued after pregnancy was confirmed.55–60 Two studies analysing a small number of patients with MS who became pregnant while receiving IFN-β-1a60 and IFN-β-1b55 report a higher than expected frequency of miscarriages. However, subsequent studies with larger samples have not been able to confirm these results.57 These studies report a low incidence of foetal malformations (similar rates to those found in the general population); the incidence of malformations did not follow a coherent pattern. However, insufficient data are available to rule out an association between treatment with IFN-β and rare foetal abnormalities.56,57

Some of the series of pregnant women treated with IFN-β show a slight increase in the number of preterm births and low birth weight.61 These findings have not been confirmed by the results of other series. IFN-β should not be introduced during pregnancy; treatment discontinuation is common practice among women planning to become pregnant.62

Glatiramer acetate is classified under FDA pregnancy risk category B. Its safety profile is more favourable, as no alterations associated with the drug have been observed in animal models. The molecule cannot cross the placenta or be excreted into breast milk due to its high molecular weight. Studies of pregnant women receiving glatiramer acetate, including over 400 patients, have shown the safety of the drug and report normal rates of foetal malformations.55,58,63,64 However, given the low number of pregnant women treated with the drug, the risk of foetal malformations cannot be ruled out; glatiramer acetate should therefore be used with caution.

Little information is available on the use of other drugs, including natalizumab,65,66 fingolimod,67 dimethyl fumarate,68 and alemtuzumab,69 during pregnancy.

Natalizumab is classified in FDA pregnancy risk category C. The drug is associated with increased incidence of miscarriage in animals.70 Patients should discontinue natalizumab and allow a 3-month wash-out period before conception. The drug crosses the placenta during the second trimester and small amounts are excreted into breast milk. Natalizumab has occasionally been administered during the third trimester to patients with highly active MS, resulting in such haematological alterations as thrombocytopaenia and haemolytic anaemia in 8 of every 9 live births (Hellwig, personal communication).

Teriflunomide is classified in FDA pregnancy risk category X. The drug has been found to be teratogenic in animal models and is therefore contraindicated during pregnancy.71 It has a long plasma half-life, but colestyramine can be co-administered to accelerate elimination in women planning to conceive.52,71

Fingolimod is a pregnancy risk category C drug.72 Animal studies have shown that the drug crosses the placenta, has teratogenic effects, and is excreted into breast milk. Treatment discontinuation and a 2-month wash-out period are recommended.

Dimethyl fumarate is classified in pregnancy risk category C. It has been found to be toxic to the foetus and to cause testicular problems, low birth weight, and behavioural alterations in experimental animals.

Mitoxantrone, an FDA pregnancy risk category D drug, should be discontinued during pregnancy due to its potential teratogenicity.53 The drug may also cause infertility, premature ovarian failure, and amenorrhoea, especially in women older than 35.73

The disease should be stable before patients attempt to conceive. In patients with highly active relapsing-remitting MS, discontinuation of disease-modifying treatment prior to conception may be associated with an increased risk of relapses.74 Little is known about the effects of disease-modifying treatments for MS on male fertility and paternity.61 In a study by Hellwig et al.,75 MS treatment (mainly glatiramer acetate and IFN-β) was found to have no effect on patients’ children.

Teriflunomide can be detected at low concentrations in semen. Some regulatory agencies recommend that male patients receiving teriflunomide use contraception and follow an accelerated elimination procedure if they wish to conceive. According to the European Medicines Agency, the risk of embryo-foetal toxicity due to treatments administered to male patients is low.71

The available information on symptomatic treatment for MS is insufficient to provide evidence-based guidance on the use of these drugs during pregnancy, except for antiepileptic drugs.76 Baclofen,77 oxybutynin,78 amantadine,79 and clonazepam,80 some of the symptomatic drugs frequently used in MS, are classified under pregnancy risk categories B, C, or D.81 Discontinuation of symptomatic treatment before conception is generally recommended. If treatment is not discontinued, patients should receive the minimum effective dose for the shortest possible time.

No significant differences have been observed between women with MS and the general population in gestational age and birth weight, duration of the mother's hospital stay after delivery, frequency of assisted vaginal delivery, and frequency of caesarean delivery.82–85 The decision to use a specific technique during delivery remains with the obstetrician, although a higher rate of induced labours has been observed in women with a higher degree of disability.84 Anaesthesia is not contraindicated in patients with MS.86,87

When MS is highly active, disease-modifying treatment should be resumed as early as possible to minimise occurrence of postpartum relapses. Methylprednisolone and IV immunoglobulins do not seem to be effective for preventing postpartum relapses, although further controlled studies with larger samples are necessary to confirm this hypothesis.88–90

Studies into the progression of MS during the postpartum period suggest that breastfeeding has no impact on the relapse rate.43,91,92 Several recent studies have suggested that breastfeeding may have a protective effect against relapses.58,92 However, these findings result from a selection bias: the disease followed a more benign course in most of the study participants. Disease-modifying treatment is usually discontinued during breastfeeding since drugs may be excreted into breast milk. The decision to continue taking a disease-modifying drug immediately after delivery has to be weighed against the potential benefits of breastfeeding. For postpartum relapses requiring high-dose methylprednisolone, breastfeeding should be temporarily suspended until 12 to 48hours after administration of the last dose of methylprednisolone.53