INTRODUCTION — Periconceptional folic acid supplementation decreases the occurrence and recurrence of neural tube defects (NTDs). It is recommended for all women planning pregnancy or capable of becoming pregnant. Preconception patient education about the need for prophylaxis is important during medical wellness visits as many women are not aware of this recommendation until after they seek prenatal care or choose not to follow the recommendation because of cost or inconvenience [1,2]. Women who do not take supplements still consume some folic acid as folate is a natural component of a variety of foods, and grain products in many countries are fortified with folic acid.
This topic will discuss the role of folic acid supplementation for prevention of NTDs, dosing in women at average versus high risk of NTDs, potential pregnancy benefits unrelated to NTDs, potential risks of supplementation, and NTDs that occur despite supplementation. Prenatal screening and diagnosis of NTDs are reviewed separately. (See "Open neural tube defects: Risk factors, prenatal screening and diagnosis, and pregnancy management".)
FOLATE AND FOLIC ACID — Although the terms folate and folic acid are often used interchangeably, folate is a water-soluble B vitamin (B9) that occurs naturally in foods, and folic acid is the synthetic form of folate.
Sources — Folate (B9) occurs naturally in several foods, including beef liver, leafy vegetables, peas and beans, avocados, eggs, and milk (table 1) [3,4].
Folic acid is available in multivitamins, prenatal vitamins, and as a pure folic acid supplement. It is also added to fortify certain foods, including flour, pasta, breads, cereals, cornmeal, and rice, and it has been added to some oral estrogen-progestin contraceptive pills to ensure adequate baseline folate levels in the event of unplanned pregnancy from inconsistent/incorrect contraceptive use or conception soon after discontinuation.
Both folate and folic acid are reduced to their metabolically active form, L-5-methyltetrahydrofolate (L-5-methyl-THFL), during absorption across the intestinal mucosa; some hepatic metabolism also occurs [5]. The calcium salt of L-5-methyl-THFL is commercially available and included in some vitamin supplements instead of folic acid.
In healthy volunteers, folic acid supplements, dietary folate, and L-5-methyl-THFL supplements resulted in similar increases in plasma folate and red cell folate concentrations [5].
Food fortification — Fortification provides approximately 163 micrograms of folic acid per day to the target population in the United States, which may or may not be adequate to prevent neural tube defects (NTDs) without a vitamin supplement [6,7]. Models using blood folate concentrations to estimate the optimal folic acid dose suggest that 163 micrograms may be inadequate and that 400 micrograms per day may be needed; however, epidemiologic data have demonstrated significant reductions in NTD rates in countries where food fortification is at the same level as the United States and folic acid supplementation is not widespread [8-12].
The adequacy of current levels of food fortification is supported by a 2017 systematic review by the US Preventive Services Task Force (USPSTF) that noted studies of folic acid supplementation performed after 1998, when food fortification with folic acid became routine in the United States, have not demonstrated a protective association [13], suggesting that current levels of food fortification may be sufficient to prevent most folate-sensitive NTDs. It is also possible that misclassification and recall bias in post-food fortification studies reduced the magnitude of the effect associated with supplementation.
Given the limitations of the post-food fortification studies, in 2017 the USPSTF reaffirmed its 2009 recommendation that all women of reproductive age planning or capable of pregnancy take a supplement containing 0.4 to 0.8 mg of folic acid once per day to reduce their risk of having a child with an NTD [14]. (See 'Candidates' below.)
Causes of suboptimal levels — Varying degrees of folate deficiency may result from:
●Decreased intake due to:
•Low-carbohydrate diets, since bread and pasta are made of fortified grains [15].
•High consumption of foods designated as "organic," as they are exempt from folic acid fortification regulations.
•Anorexia, food insecurity, etc.
●Interference by some medications (eg, phenytoin, sulfasalazine, trimethoprim, methotrexate).
●Medical or surgical conditions associated with malabsorption (most commonly: inflammatory bowel disease and major intestinal resection or bypass; less commonly: documented celiac disease, significant liver disease, renal failure requiring dialysis, and ethanol abuse).
●Methylenetetrahydrofolate reductase (MTHFR) polymorphisms (eg, MTHFR 677C->T or 677TT).
Diagnosis of suboptimal levels — Normal serum/plasma and red cell folate levels by trimester are shown in the table (table 2). Red cell folate concentration is the most accurate assessment of folate status, although there are laboratory issues with reproducibility [16,17]. Red cell folate concentration reflects body stores of folate while serum/plasma folate reflects current concentrations in the circulation; it is not known whether one of these levels is more predictive of risk of NTDs than the other.
True folate deficiency is rare in the United States. However, suboptimal levels (ie, below the level for optimal prevention of NTDs) are common and defined by the World Health Organization as red cell folate <400 ng/mL (906 nmol/L) [18,19]. The serum/plasma threshold is not well-established. In one study, a serum/plasma level >11.3 ng/mL (25.5 nmol/L) was suggested for optimal NTD prevention in nonanemic, non-vitamin B-12-deficient, nonpregnant women [20]. In another study, a serum/plasma level >7.0 ng/mL (15.9 nmol/L) was suggested for pregnant women [6]. The discordancy may be related to hemodilution in pregnancy or to population differences in race/ethnicity and environmental factors in the two studies, or to chance.
One study estimated that 23 percent of women of childbearing age in the United States have suboptimal folate levels [21]. Given this high estimated prevalence, routine measurement of folate levels is not practical. Furthermore, it has not been proven to be an effective approach for reduction of NTDs. Instead, empiric folic acid supplementation is recommended for all women. (See 'Folic acid supplementation for prevention of neural tube defects' below.)
FOLIC ACID SUPPLEMENTATION FOR PREVENTION OF NEURAL TUBE DEFECTS
Evidence of efficacy — The body of evidence from randomized trials and large prospective and retrospective studies supports the efficacy of folic acid supplementation and dietary fortification for decreasing the occurrence and recurrence of neural tube defects (NTDs) [3,13,22-26]. For example, in a meta-analysis of randomized trials:
●For women with no previously affected pregnancy, daily folic acid supplementation (alone or in combination with other vitamins and minerals) reduced NTDs by 93 percent compared with no interventions/placebo or vitamins and minerals without folic acid (0/2471 versus 6/2391; relative risk [RR] 0.07, 95% CI 0.00-1.32; one trial, 4862 births) [22].
●When women with and without a previously affected pregnancy were included in the analysis, NTDs were reduced by 70 percent (12/3433 versus 42/3275; RR 0.31, 95% CI 0.17-0.58; five trials, 6708 births).
●When only women with a previously affected pregnancy were analyzed, NTDs were reduced by a similar amount (12/3433 versus 42/3275; RR 0.34, 95% CI 0.18-0.64; four trials, 1846 births).
Candidates — Most major national medical organizations and public health authorities recommend that all women of childbearing potential, not just those who are attempting to conceive, receive a once per day folic acid supplement [14,24,27,28]. This broad recommendation is based on the large number of unplanned pregnancies (as many as 50 percent of pregnancies in the United States are unplanned [29]) and closure of the neural tube very early in gestation, before many women know they are pregnant (neural tube closure occurs 26 to 28 days after conception [ie, by six weeks of gestation]).
Dose and administration
Universal prophylaxis for the general obstetric population — For most women, the standard folic acid supplement (multivitamin, prenatal vitamin) is 0.4 mg taken once per day, beginning at least one month prior to attempting conception and continuing throughout pregnancy. This dose should ensure adequate folate levels during organogenesis, which occurs primarily in the first trimester, and also later in pregnancy when folate is required to meet the growth and probably developmental needs of the fetus, and maternal needs [30-32]. All prenatal and many multivitamins contain at least 0.4 mg of folic acid.
Some guidelines recommend beginning folic acid supplementation at least one month before conception while others recommend beginning two to three months before conception, particularly if a previous offspring had an NTD (table 3). We recommend beginning supplementation at least one month before conception because we are not treating severe folate deficiency, folate is well absorbed, and it not stored in fat so excess intake is excreted. Serum levels will become normal almost as soon as supplements are started, but red cell folate levels will take three months to normalize because of RBC turnover.
High-dose prophylaxis for women at high risk of offspring with NTD — Women who are at higher risk of having a child with an NTD than the baseline population are candidates for higher (1 to 4 mg) dose folic acid supplementation (table 3). This dose should be initiated one to three months prior to conception and maintained through the first 12 weeks of gestation, after which the dose is reduced to 0.4 mg [30,33]. The choice of dose between 1 and 4 mg depends on the reason that the patient is high risk and is discussed below. (See 'Women who may benefit from higher dose folic acid supplementation' below.)
In the United States, the tolerable upper limit for folic acid intake in the general adult population is 1 mg. Folic acid supplementation at the 4 mg dose used for prophylaxis in women at high risk of having a child with an NTD is generally believed to be nontoxic in the short term [24], but the dose should be decreased after the first trimester since the reason for therapy (prevention of NTDs) is no longer relevant and the possibility of adverse fetal effects with long-term exposure cannot be excluded [34]. (See 'Epigenetic alterations' below.)
Women should be advised not to attempt to achieve high-dose supplementation by taking multiple multivitamins because they might ingest harmful levels of other vitamins, such as vitamin A. One prenatal vitamin per day and a 1 mg tablet of folic acid three to four times per day is a practical means of ingesting a total dose of 4 to 5 mg per day. Alternatively, the three to four 1 mg folic acid tablets/capsules can be taken at one time for patient convenience. One mg tablets/capsules of folic acid are widely available by prescription; 5 mg tablets/capsules are also available in some countries. The dose is reduced to at least 0.4 mg after 12 weeks of gestation.
Although expert consensus groups consistently recommend 4 mg per day as the maximum dose, one expert (Wald) has suggested a higher dose (5 mg) for this population since his mathematical model predicted this dose may reduce the risk of NTDs by approximately 85 percent [35,36]. By contrast, a 2015 Cochrane review suggested that the positive effect of folic acid on NTD incidence and recurrence is not affected by the specific folic acid dose (400 micrograms versus higher) or whether folic acid is given alone or with other vitamins and minerals [22].
Monitoring folate levels — We do not monitor folate levels. Although serum/plasma and red cell folate levels can be monitored, the utility of this practice is not known, and serum/plasma levels do not reflect total body saturation levels. No prospective studies have evaluated whether routinely monitoring levels during pregnancy improves outcomes.
Some suggest that women with an identified folate deficiency due to a known comorbidity (such as inflammatory bowel disease or bariatric surgery), rather than low dietary intake, should be monitored with monthly serum assessments to ensure adequate supplementation, but there is insufficient evidence to recommend for or against this practice. (See "Fertility and pregnancy after bariatric surgery", section on 'Micronutrient supplementation'.)
Women who may benefit from higher dose folic acid supplementation — Preconception patient education about the need for high-dose prophylaxis is critical as many women who have had a prior pregnancy with an NTD or who are otherwise high-risk may not be aware of the recommendation for high-dose folic acid until after they seek prenatal care [37].
The most robust data for the efficacy of higher dose folic acid supplementation are for women with a previously affected offspring [22,38]. More limited data support recommendations for higher dose folic acid supplementation in the specific other high-risk groups discussed below [39].
Either parent with a personal history of NTD or a previously affected offspring — Compared with families with no affected parents or siblings, the risk of NTD in offspring is increased at least 10-fold among women with previously affected offspring, a personal history of an NTD, a partner with an NTD, or a partner with an affected child with a previous partner (table 4).
These women should be offered periconceptional/first-trimester supplementation with high-dose (4 mg) folic acid (table 3). In women with a previously affected pregnancy, this dose reduced the risk of recurrent NTDs by approximately 70 percent in a seminal trial (6/593 versus 21/602; RR 0.28, 95% CI 0.12-0.71); in women who were not pregnant at randomization and complied with therapy, NTDs were reduced by 83 percent [38]. (See 'High-dose prophylaxis for women at high risk of offspring with NTD' above.)
Family history of an NTD in a second or third degree relative — The risk of an NTD in offspring is mildly increased if there is a family history of an NTD in one second- or third-degree relative. The risk is estimated to increase from 0.1 to 0.5 percent with no affected relative to 1 to 2 percent with an affected second-degree relative versus 0.5 to 1 percent with an affected third-degree relative [24].
We suggest 1 mg per day periconceptional/first-trimester folic acid dosing for this population, similar to the Society of Obstetricians and Gynaecologists of Canada's recommendations [24]. (See 'High-dose prophylaxis for women at high risk of offspring with NTD' above.)
Antiseizure medication therapy
●Valproic acid and carbamazepine – Women taking antiseizure medications associated with a high risk for NTDs in offspring, such as valproic acid and carbamazepine, should be transitioned to a treatment regimen associated with lower NTD risk prior to conception, if medically possible. If not possible, the optimal management of folic acid supplementation in this setting is unknown.
We suggest that women with epilepsy on valproate or carbamazepine who are planning to become pregnant take 4 mg per day periconceptional/first-trimester folic acid supplementation to reduce the risk of NTDs based on indirect data from studies in other high-risk women (ie, women with previously affected offspring, personal or partner history of NTD) [38]. Although a large study of congenital anomalies in live born children of mothers taking antiseizure medications showed no reduction in overall congenital anomalies with folic acid supplementation, even when stratified by folic acid dose (high-dose: odds ratio [OR] 1.82, 95% CI 1.30-2.56; low-dose or no folic acid: OR 1.94, 95% CI 1.21-3.13), pregnancy terminations were not analyzed, only six children had nervous system defects, and the majority of mothers initiated high-dose folic acid from the second month of pregnancy [40]. (See 'High-dose prophylaxis for women at high risk of offspring with NTD' above.)
●Other antiseizure medications – For women who are taking other antiseizure medications (eg, levetiracetam, lamotrigine) which have not been associated with as high a risk of NTD, and sexually active women of reproductive age who are not actively planning pregnancy, we suggest 0.4 mg per day folic acid. (See "Management of epilepsy during preconception, pregnancy, and the postpartum period", section on 'Folic acid supplementation'.)
In all cases, the patient's neurologist should be consulted as folic acid supplementation may reduce serum antiseizure medication levels below therapeutic levels [41].
Clinical guidelines regarding the dose of folic acid supplementation in women with epilepsy vary and are not definitive. For example:
●The American Academy of Neurology and American Epilepsy Society guidelines state that data are insufficient to determine whether doses higher than 0.4 mg offer greater protective benefits [42].
●The Society of Obstetricians and Gynaecologists of Canada (SOGC) recommends 1 mg of folic acid once per day for women taking medications with secondary teratogenic effects related to folate inhibition [24].
●The American College of Obstetricians and Gynecologists (ACOG) recommends 4 mg of folic acid once per day for women at high risk of having offspring with NTDs [33], and includes women taking antiseizure medications in this category [43].
Although the rationale for administering high-dose supplementation is that the relatively high risk of NTDs associated with some antiseizure medications is thought to be mediated by a decrease in serum folate levels, the effectiveness and appropriate dose of perinatal folic acid supplementation in women taking antiseizure medications have not been investigated in randomized trials, and observational studies have not shown a benefit [40,44]. (See "Risks associated with epilepsy during pregnancy and postpartum period", section on 'Valproate'.)
Folic acid supplementation may have additional benefits beyond reduction in NTDs, such as reduction in autistic traits [45]. (See 'Does folic acid supplementation improve other pregnancy outcomes?' below.)
Therapy with medications other than antiseizure medications that reduce folic acid activity — Medications other than antiseizure medications (eg, triamterene, trimethoprim, sulfasalazine) have been associated with reductions in available folic acid and thus may increase the risk of NTDs. These medications, which are uncommonly used in pregnant women, may inhibit folic acid absorption, reduce its activity, or have other interactive effects [46].
It is reasonable to offer increased periconceptional/first-trimester folic acid supplementation to women taking these medications. We suggest 1 mg per day folic acid, similar to SOGC recommendations [24]. (See 'High-dose prophylaxis for women at high risk of offspring with NTD' above.)
Maternal medical conditions associated with decreased folic acid — Several maternal medical conditions have been associated with reduced red cell folate levels, likely through reduced folic acid absorption or increased folic acid clearance. These include medical or surgical conditions associated with malabsorption, such as celiac disease, inflammatory bowel disease, and major intestinal resection or bypass (including some types of bariatric surgery). Less common conditions include advanced liver disease, renal failure requiring dialysis, and unhealthy alcohol use [24].
We suggest 1 mg per day folic acid periconceptional/first-trimester supplementation for women with these conditions, similar to SOGC's recommendations (table 3) [24]. (See 'High-dose prophylaxis for women at high risk of offspring with NTD' above.)
Preexisting diabetes — Women with preexisting (pregestational) diabetes are at increased risk of a pregnancy complicated by an NTD. For this reason, we suggest 1 mg per day periconceptional/first-trimester folic acid supplementation for these women; this dose is readily available, may be more effective than a lower dose, and has no additional harms or side effects. (See 'High-dose prophylaxis for women at high risk of offspring with NTD' above.)
Studies evaluating outcome with different folic acid doses have not been performed, and guidelines vary:
●ACOG recommends at least 0.4 mg per day folic acid for women with diabetes contemplating pregnancy, and opines that higher doses (0.8 to 1 mg) may be beneficial in high risk women, such as those with other risk factors for NTDs [47].
●The American Diabetes Association also suggests a minimum dose of at least 0.4 mg per day [48], which was effective in at least two case-control studies [49,50] and in at least one study in animals [51].
●The SOGC recommends 1 mg per day [24].
●The Endocrine Society suggests 5 mg/day beginning three months before discontinuing contraception or otherwise trying to conceive, and reducing the dose to 0.4 to 1.0 mg/day at 12 weeks of gestation through the completion of breastfeeding [52].
It is important to note that good periconceptional glucose control is the key factor for prevention of NTDs and other anomalies in these pregnancies. (See "Pregestational (preexisting) diabetes: Preconception counseling, evaluation, and management", section on 'Congenital malformations'.)
Other populations (obesity, MTHFR polymorphism) — We suggest not prescribing higher doses of folic acid supplementation for obese women and women with methylenetetrahydrofolate reductase (MTHFR) polymorphisms; we use routine universal prophylaxis dosing (0.4 mg per day) for these women, even though these conditions have been associated with an increased risk of NTDs. (See 'Universal prophylaxis for the general obstetric population' above.)
Testing for MTHFR polymorphisms is not recommended as routine folic acid supplementation at 0.4 mg per day will adequately increase red cell and serum folate concentrations whether or not the woman has a polymorphism [53,54]. Supplementation with an equimolar dose of 5-methyl tetrahydrofolate (5-MTHF), an alternative form of folic acid, has the advantage that it is not influenced by possible MTHFR gene mutations [55].
There are no prospective data that higher dose folic acid supplementation for obese women is more effective. At least some of the association between obesity and NTDs is likely due to unrecognized diabetes in these women; either 0.4 or 1 mg per day folic acid is a reasonable dose in women with diabetes, as discussed above.
DOES FOLIC ACID SUPPLEMENTATION IMPROVE OTHER PREGNANCY OUTCOMES? — Folic acid supplementation may have pregnancy benefits unrelated to prevention of neural tube defects (NTDs), but available data are insufficient to support a clear benefit.
Congenital malformations other than NTDs — A meta-analysis of randomized trials concluded that folic acid supplementation, alone or in combination with vitamins and minerals, does not have a clear effect on the frequency of other birth defects [22]. However, some cleft lip/palate, congenital heart defects, limb reduction defects, urinary tract defects, and congenital hydrocephalus may be folate-sensitive congenital malformations, based in part on the observation that the incidence of these congenital malformations has fallen following introduction of universal folic acid fortification or supplementation [24,56-61]. Animal studies also provide some experimental support for folic acid supplementation to reduce the risk of cleft lip/palate from concurrent exposure to procarbazine, a folic acid inhibitor [62].
We suggest a higher dose (1 mg per day) of periconceptional/first-trimester folic acid supplementation for women with a history of one of the following malformations in themselves or their partner, a prior offspring, or a first- or second-degree relative:
●Cleft lip/palate
●Congenital heart defects
●Limb reduction defects
●Urinary tract defects
●Congenital hydrocephalus
The benefit of this approach is based on low-quality data, but the birth defects are serious and the potential for harm from this dose of folic acid is low. The Society of Obstetricians and Gynaecologists of Canada also recommends 1 mg per day for these women [24]. The efficacy of this approach is unproven. (See 'High-dose prophylaxis for women at high risk of offspring with NTD' above.)
Conflicting results have been reported for reducing the risk of abdominal wall defects and pyloric stenosis. No reductions have been observed for hypospadias, undescended testes, or trisomy 21.
We suggest routine universal prophylaxis dosing (0.4 mg per day) for women with a personal or family history of these conditions rather than high-dose supplementation. (See 'Universal prophylaxis for the general obstetric population' above.)
Growth restriction, autism, hypertensive disorders of pregnancy — Meta-analyses have linked folic acid supplementation to a decreased risk of small for gestational age infants [63,64] and decreased risk of autism [65-67]. The included studies were low quality and the data insufficient to warrant a change in counseling or recommendations for folic acid supplementation.
The body of data does not indicate a consistent decreased or increased risk for hypertensive disorders of pregnancy (preeclampsia, gestational hypertension) [68,69], even at high doses (4 mg daily) [70].
We suggest routine universal prophylaxis dosing (0.4 mg per day) for women at increased risk for these disorders rather than high-dose supplementation. (See 'Universal prophylaxis for the general obstetric population' above.)
Spontaneous preterm birth — In a meta-analysis of randomized trials including over 5000 women with asymptomatic singleton gestations and no prior preterm birth, folic acid supplementation did not reduce the risk of preterm birth (<37 or <34 weeks) or preterm prelabor rupture of membranes compared with unsupplemented pregnancies [71].
We suggest routine universal prophylaxis dosing (0.4 mg per day) for these women rather than high-dose supplementation. (See 'Universal prophylaxis for the general obstetric population' above.)
Miscarriage — In a meta-analysis of randomized trials of vitamin supplementation for preventing miscarriage, folic acid supplementation (with or without multivitamins and/or iron) did not reduce the risk of early or late miscarriage compared with no folic acid supplementation [72]. In addition, a prospective cohort study of healthy folate-replete women attempting pregnancy after one or two previous pregnancy losses found that lower preconception serum folate levels were not associated with higher rates of anovulation, inability to conceive, or pregnancy loss [73].
We suggest routine universal prophylaxis dosing (0.4 mg per day) for these women rather than high-dose supplementation. (See 'Universal prophylaxis for the general obstetric population' above.)
POTENTIAL RISKS
Unrecognized vitamin B12 deficiency — In women with megaloblastic anemia (macrocytic anemia associated with multilobed neutrophils on the blood smear), it is important to rule out vitamin B12 deficiency before administering folic acid because treatment with folic acid may delay diagnosis of vitamin B12 deficiency and allow progression of neurologic abnormalities and some hematologic abnormalities. Causes of vitamin B12 deficiency are listed in the table (table 5). Taking folic acid as part of a multivitamin or prenatal vitamin with vitamin B12 reduces any potential risk. (See "Clinical manifestations and diagnosis of vitamin B12 and folate deficiency".)
Twinning — An association between rates of dichorionic twinning and distributions of methylenetetrahydrofolate reductase (MTHFR) mutations has led to speculation about a relationship between folic acid and multiple gestation. Some modeling studies, based on pooled results of randomized trials, suggested that folic acid supplementation to prevent neural tube defects (NTDs) resulted in a 45 percent increase in dizygotic twinning (odds ratio [OR] 1.45, 95% CI 1.06-1.98) [74,75]. However, large prospective studies of folic acid supplementation have reported a slight decrease in twins (OR 0.91, 95% CI 0.82-1.00) [76]. Studies of twinning using historical controls may be confounded by increased contemporary usage of fertility medications and assisted reproduction.
Epigenetic alterations — As folic acid plays a role in DNA methylation, there is a theoretical concern that maternal folic acid supplementation could lead to fetal epigenetic changes leading to long-term adverse effects [77]. One particular area of concern has centered on immune phenotypes that may alter childhood risk of atopic disease and reactive airway disease. However, epidemiologic studies have reported inconsistent findings on the association of maternal folic acid exposure or folate levels and increased incidence or severity of childhood respiratory outcomes and atopic disease [78-83].
Breast cancer — A 35-year follow-up study of women who participated in a placebo-controlled randomized trial of folic acid supplementation in pregnancy reported a nonsignificant increase in breast cancer mortality in women who received 0.2 or 5 mg folic acid supplementation once per day during pregnancy [84]. This result may well have been due to chance as the body of evidence is inconclusive [85-87]. (See "Overview of cancer prevention", section on 'Folic acid' and "Vitamin supplementation in disease prevention", section on 'Cancer'.)
At this time, no change in the recommendations for folic acid supplementation in pregnancy is appropriate, but further study is warranted.
Neurocognitive development — One review suggested that excessive maternal folic acid intake may be associated with adverse neurologic effects in offspring unrelated to the neural tube [34]. Studies on the effect of periconceptional/early pregnancy use of high-dose folic acid (≥1 mg per day) and neurocognitive development in offspring are conflicting [88,89]. Given the uncertainties, only women at highest risk of NTDs (table 3) should receive >1 mg per day of folic acid.
TREATMENT FAILURES — Adequate intake of folic acid will not prevent all primary or recurrent cases of neural tube defects (NTDs). The percentage of NTDs that is preventable with folic acid is unclear; estimates range from less than 50 to over 70 percent [90].
The frequency of recurrent NTDs despite high-dose folic acid prophylaxis (4 mg) remains as high as 1 percent [90-92]. This is likely due to autoantibodies to folate receptors and folate-independent pathways, such as aneuploidy, poorly controlled hyperglycemia, first-trimester hyperthermia, and specific genetic syndromes that include NTDs.
There are no formal recommendations regarding additional evaluation or intervention following a recurrence despite adequate folic acid supplementation. Because folate-resistant NTDs cannot always be identified with certainty, folic acid supplementation is recommended for all women. Glycemic control prior to conception in women with poorly controlled diabetes, use of anti-pyretics during first-trimester febrile illness, and avoidance of saunas/hot tubs are all reasonable precautions for prevention of first or recurrent NTDs. Other interventions, such as use of inositol, are under investigation [93].
SOCIETY GUIDELINE LINKS — Links to society and government-sponsored guidelines from selected countries and regions around the world are provided separately. (See "Society guideline links: Nutrition and supplements in pregnancy".)
INFORMATION FOR PATIENTS — UpToDate offers two types of patient education materials, "The Basics" and "Beyond the Basics." The Basics patient education pieces are written in plain language, at the 5th to 6th grade reading level, and they answer the four or five key questions a patient might have about a given condition. These articles are best for patients who want a general overview and who prefer short, easy-to-read materials. Beyond the Basics patient education pieces are longer, more sophisticated, and more detailed. These articles are written at the 10th to 12th grade reading level and are best for patients who want in-depth information and are comfortable with some medical jargon.
Here are the patient education articles that are relevant to this topic. We encourage you to print or e-mail these topics to your patients. (You can also locate patient education articles on a variety of subjects by searching on "patient info" and the keyword(s) of interest.)
●Basics topic (see "Patient education: Vitamin B12 deficiency and folate (folic acid) deficiency (The Basics)")
Fact sheets for patients can be found on the following websites:
●Centers for Disease Control and Prevention
●United States Department of Health and Human Service
SUMMARY AND RECOMMENDATIONS
●The body of evidence supports the efficacy of folic acid supplementation and dietary fortification to decrease the occurrence and recurrence of neural tube defects (NTDs) by at least 70 percent. (See 'Evidence of efficacy' above and 'Food fortification' above and 'Either parent with a personal history of NTD or a previously affected offspring' above.)
●We recommend periconceptional/first-trimester folic acid supplementation to reduce the occurrence and recurrence of NTDs (Grade 1A), in agreement with most guidelines. (See 'Folic acid supplementation for prevention of neural tube defects' above.)
•For most women of reproductive potential, we suggest one multivitamin containing 0.4 mg of folic acid once per day beginning at least one month prior to conception and continuing through the first trimester (Grade 2B). (See 'Universal prophylaxis for the general obstetric population' above.)
Most major national medical organizations and public health authorities recommend that all women of childbearing potential, not just those who are attempting to conceive, receive a folic acid supplement once per day because a large number of unplanned pregnancies occur and the neural tube closes very early in gestation, before many women know they are pregnant. (See 'Candidates' above.)
•For women with a previous pregnancy affected by an NTD or with an NTD in either parent, we suggest 4 mg of folic acid once per day beginning at least one month prior to conception and continuing through the first trimester (Grade 2C). The dose is decreased to 0.4 mg per day after the first trimester. (See 'Either parent with a personal history of NTD or a previously affected offspring' above and 'High-dose prophylaxis for women at high risk of offspring with NTD' above.)
•The optimal periconceptional/first-trimester folic acid dose for women in other risk groups is unclear. We suggest the following (Grade 2C) (see 'Women who may benefit from higher dose folic acid supplementation' above):
-Family history of NTD in a first- or second-degree relative – 1 mg
-Women on valproic acid or carbamazepine – 4 mg
-Women taking other antiseizure medications – 0.4 mg
-Women taking medications other than antiseizure medications that have been associated with reductions in available folic acid (eg, triamterene, trimethoprim, sulfasalazine) – 1 mg
-Women with medical conditions associated with reduced red cell folate levels – 1 mg
-Women with pregestational diabetes – 1 mg
●Measurement of maternal folate levels before or after supplementation is not recommended. (See 'Diagnosis of suboptimal levels' above.)
●In the absence of vitamin B12 deficiency, there are no clear harms from folic acid supplementation. (See 'Potential risks' above.)
●In women with megaloblastic anemia (macrocytic anemia associated with multilobed neutrophils on the blood smear), it is important to rule out vitamin B12 deficiency before administering folic acid as treatment with folic acid may delay diagnosis of vitamin B12 deficiency and allow progression of neurologic abnormalities and some hematologic abnormalities. Causes of vitamin B12 deficiency are listed in the table (table 5). Taking folic acid as part of a multivitamin or prenatal vitamin with vitamin B12 reduces any potential risk. (See 'Unrecognized vitamin B12 deficiency' above.)
●Folic acid supplementation will not prevent all NTDs, such as those related to chromosomal abnormalities and other non-folate-related mechanisms. (See 'Treatment failures' above.)
●Some cleft lip/palate, congenital heart defects, limb reduction defects, urinary tract defects, and congenital hydrocephalus may be folate-sensitive congenital malformations, but evidence is of low quality. We suggest 1 mg per day periconceptional/first-trimester folic acid supplementation for women with a history of one of these malformations in themselves or their partner, a prior offspring, or a first- or second-degree relative (Grade 2C). (See 'Congenital malformations other than NTDs' above.)
ACKNOWLEDGMENTS — The UpToDate editorial staff acknowledges Lauri Hochberg, MD, and Joanne Stone, MD, who contributed to an earlier version of this topic review.
1 : 2012 Update on global prevention of folic acid-preventable spina bifida and anencephaly.
2 : Strategies for Preventing Folate-Related Neural Tube Defects: Supplements, Fortified Foods, or Both?
3 : Common congenital anomalies: Environmental causes and prevention with folic acid containing multivitamins.
4 : Common congenital anomalies: Environmental causes and prevention with folic acid containing multivitamins.
5 : Folic acid and L-5-methyltetrahydrofolate: comparison of clinical pharmacokinetics and pharmacodynamics.
6 : Folate levels and neural tube defects. Implications for prevention.
7 : Folic acid intake among U.S. women aged 15-44 years, National Health and Nutrition Examination Survey, 2003-2006.
8 : Neural tube defects and maternal folate intake among pregnancies conceived after folic acid fortification in the United States.
9 : Folic acid intake and spina bifida in the era of dietary folic acid fortification.
10 : Global Birth Prevalence of Spina Bifida by Folic Acid Fortification Status: A Systematic Review and Meta-Analysis.
11 : Impact of folic acid fortification of flour on neural tube defects: a systematic review.
12 : Minimum effective dose of folic acid for food fortification to prevent neural-tube defects.
13 : Folic Acid Supplementation for the Prevention of Neural Tube Defects: An Updated Evidence Report and Systematic Review for the US Preventive Services Task Force.
14 : Folic Acid Supplementation for the Prevention of Neural Tube Defects: US Preventive Services Task Force Recommendation Statement.
15 : Low carbohydrate diets may increase risk of neural tube defects.
16 : Preventing neural tube defects: the importance of periconceptional folic acid supplements.
17 : Results of an international round robin for serum and whole-blood folate.
18 : Results of an international round robin for serum and whole-blood folate.
19 : Results of an international round robin for serum and whole-blood folate.
20 : Defining the plasma folate concentration associated with the red blood cell folate concentration threshold for optimal neural tube defects prevention: a population-based, randomized trial of folic acid supplementation.
21 : U.S. women of childbearing age who are at possible increased risk of a neural tube defect-affected pregnancy due to suboptimal red blood cell folate concentrations, National Health and Nutrition Examination Survey 2007 to 2012.
22 : Effects and safety of periconceptional oral folate supplementation for preventing birth defects.
23 : Global Birth Prevalence of Spina Bifida by Folic Acid Fortification Status: A Systematic Review and Meta-Analysis.
24 : Pre-conception Folic Acid and Multivitamin Supplementation for the Primary and Secondary Prevention of Neural Tube Defects and Other Folic Acid-Sensitive Congenital Anomalies.
25 : Folic acid supplementation and neural tube defect recurrence prevention.
26 : Prenatal multivitamin supplementation and rates of congenital anomalies: a meta-analysis.
27 : Prenatal multivitamin supplementation and rates of congenital anomalies: a meta-analysis.
28 : Policy statement on folic acid and neural tube defects.
29 : Declines in Unintended Pregnancy in the United States, 2008-2011.
30 : Declines in Unintended Pregnancy in the United States, 2008-2011.
31 : Impact of continuing folic acid after the first trimester of pregnancy: findings of a randomized trial of Folic Acid Supplementation in the Second and Third Trimesters.
32 : Gene-specific DNA methylation in newborns in response to folic acid supplementation during the second and third trimesters of pregnancy: epigenetic analysis from a randomized controlled trial.
33 : Practice Bulletin No. 187: Neural Tube Defects.
34 : The adverse effects of an excessive folic acid intake.
35 : Quantifying the effect of folic acid.
36 : Folic acid and the prevention of neural-tube defects.
37 : Supplement use and other characteristics among pregnant women with a previous pregnancy affected by a neural tube defect - United States, 1997-2009.
38 : Prevention of neural tube defects: results of the Medical Research Council Vitamin Study. MRC Vitamin Study Research Group.
39 : Periconceptional folic acid and risk for neural tube defects among higher risk pregnancies.
40 : Congenital Anomalies in Children of Mothers Taking Antiepileptic Drugs with and without Periconceptional High Dose Folic Acid Use: A Population-Based Cohort Study.
41 : Effect of folic acid supplementation on congenital malformations due to anticonvulsive drugs.
42 : Practice parameter update: management issues for women with epilepsy--focus on pregnancy (an evidence-based review): vitamin K, folic acid, blood levels, and breastfeeding: report of the Quality Standards Subcommittee and Therapeutics and Technology Assessment Subcommittee of the American Academy of Neurology and American Epilepsy Society.
43 : Practice parameter update: management issues for women with epilepsy--focus on pregnancy (an evidence-based review): vitamin K, folic acid, blood levels, and breastfeeding: report of the Quality Standards Subcommittee and Therapeutics and Technology Assessment Subcommittee of the American Academy of Neurology and American Epilepsy Society.
44 : Folic acid use and major congenital malformations in offspring of women with epilepsy: a prospective study from the UK Epilepsy and Pregnancy Register.
45 : Association of Folic Acid Supplementation During Pregnancy With the Risk of Autistic Traits in Children Exposed to Antiepileptic Drugs In Utero.
46 : Folic acid antagonists during pregnancy and the risk of birth defects.
47 : ACOG Practice Bulletin No. 201: Pregestational Diabetes Mellitus.
48 : 14. Management of Diabetes in Pregnancy: Standards of Medical Care in Diabetes-2021.
49 : Lack of periconceptional vitamins or supplements that contain folic acid and diabetes mellitus-associated birth defects.
50 : The impact of folic acid intake on the association among diabetes mellitus, obesity, and spina bifida.
51 : Folic acid supplementation diminishes diabetes- and glucose-induced dysmorphogenesis in rat embryos in vivo and in vitro.
52 : Diabetes and pregnancy: an endocrine society clinical practice guideline.
53 : Response of serum and red blood cell folate concentrations to folic acid supplementation depends on methylenetetrahydrofolate reductase C677T genotype: results from a crossover trial.
54 : Methylenetetrahydrofolate reductase 677C-->T variant modulates folate status response to controlled folate intakes in young women.
55 : Folic acid versus 5- methyl tetrahydrofolate supplementation in pregnancy.
56 : Effect of Folic Acid Food Fortification in Canada on Congenital Heart Disease Subtypes.
57 : Prevalence of severe congenital heart disease after folic acid fortification of grain products: time trend analysis in Quebec, Canada.
58 : A Meta-Analysis of the Relationship Between Maternal Folic Acid Supplementation and the Risk of Congenital Heart Defects.
59 : Folic acid-containing supplement consumption during pregnancy and risk for oral clefts: a meta-analysis.
60 : First-Trimester Maternal Folic Acid Supplementation Reduced Risks of Severe and Most Congenital Heart Diseases in Offspring: A Large Case-Control Study.
61 : Maternal Periconceptional Folic Acid Supplementation and Risk for Fetal Congenital Heart Defects.
62 : Is it possible to prevent cleft palate by prenatal administration of folic acid? An experimental study.
63 : Effect of folic acid supplementation on preterm delivery and small for gestational age births: A systematic review and meta-analysis.
64 : Effectiveness of folic acid supplementation in pregnancy on reducing the risk of small-for-gestational age neonates: a population study, systematic review and meta-analysis.
65 : New Perspective on Impact of Folic Acid Supplementation during Pregnancy on Neurodevelopment/Autism in the Offspring Children - A Systematic Review.
66 : The association between maternal use of folic acid supplements during pregnancy and risk of autism spectrum disorders in children: a meta-analysis.
67 : Review and meta-analysis found that prenatal folic acid was associated with a 58% reduction in autism but had no effect on mental and motor development.
68 : Folic acid alone or multivitamin containing folic acid intake during pregnancy and the risk of gestational hypertension and preeclampsia through meta-analyses.
69 : Effect of folic acid supplementation during pregnancy on gestational hypertension/preeclampsia: A systematic review and meta-analysis.
70 : Effect of high dose folic acid supplementation in pregnancy on pre-eclampsia (FACT): double blind, phase III, randomised controlled, international, multicentre trial.
71 : Folic acid supplementation and preterm birth: results from observational studies.
72 : Vitamin supplementation for preventing miscarriage.
73 : Preconception folate status and reproductive outcomes among a prospective cohort of folate-replete women.
74 : Modelling the potential impact of population-wide periconceptional folate/multivitamin supplementation on multiple births.
75 : Use of multivitamins and folic acid in early pregnancy and multiple births in Sweden.
76 : Folic acid supplements during early pregnancy and likelihood of multiple births: a population-based cohort study.
77 : Nutrition During Pregnancy Impacts Offspring's Epigenetic Status-Evidence from Human and Animal Studies.
78 : Association of folic acid supplementation during pregnancy and infant bronchiolitis.
79 : Folate and asthma.
80 : The association between mother and child MTHFR C677T polymorphisms, dietary folate intake and childhood atopy in a population-based, longitudinal birth cohort.
81 : Maternal use of folic acid supplements during pregnancy, and childhood respiratory health and atopy.
82 : Folic acid use in pregnancy and the development of atopy, asthma, and lung function in childhood.
83 : Prenatal folic acid and risk of asthma in children: a systematic review and meta-analysis.
84 : Taking folate in pregnancy and risk of maternal breast cancer.
85 : Folic acid fortification remains an urgent health priority.
86 : Folic acid supplement use and breast cancer risk in BRCA1 and BRCA2 mutation carriers: a case-control study.
87 : Effects of folic acid supplementation on overall and site-specific cancer incidence during the randomised trials: meta-analyses of data on 50,000 individuals.
88 : Effect of maternal high dosages of folic acid supplements on neurocognitive development in children at 4-5 y of age: the prospective birth cohort Infancia y Medio Ambiente (INMA) study.
89 : Effect of high doses of folic acid supplementation in early pregnancy on child neurodevelopment at 18 months of age: the mother-child cohort 'Rhea' study in Crete, Greece.
90 : Preventing folate-related neural tube defects: Problem solved, or not?
91 : Reduction in neural-tube defects after folic acid fortification in Canada.
92 : Reduction in neural-tube defects after folic acid fortification in Canada.
93 : Preventive and Therapeutic Role of Dietary Inositol Supplementation in Periconceptional Period and During Pregnancy: A Summary of Evidences and Future Applications.