Safety of TNF-α inhibitors during IBD pregnancy: a systematic review Academic research paper on "Clinical medicine"

BMC Medicine

RESEARCH ARTICLE Open Access

Safety of TNF-a inhibitors during IBD pregnancy: a systematic review

Abstract

Background: Tumor necrosis factor (TNF)-a inhibitors are increasingly being used in inflammatory bowel disease (IBD). Because this chronic intestinal disorder often affects women of fertile age, it is essential to assess the effect of biologies on pregnancy outcome.

Methods: We performed a systematic review of the English-language literature to investigate if treatment with TNF-a blockers during pregnancy in women with IBD increases the risk of spontaneous abortions, preterm delivery, stillbirth, low birth weight, congenital malformations, or risk of infections in the offspring. Of 552 articles and abstracts reviewed, 58 articles or abstracts with unique content were identified and included in this systematic review. However, most presentations were case reports or case series supplied by a limited number of observational studies. No randomized controlled studies were available.

Results: TNF-a inhibitors do not seem to affect either outcome of pregnancy in mothers with IBD, or the outcome in the offspring (congenital malformations and immunosuppression). Further, recent data have not identified any increased risk of infections in the first year of life in the offspring of mothers who received biologics, even in combination with immunomodulators (thiopurines).

Conclusions: From the present systematic review, no association was found between administration of TNF inhibitors for IBD during pregnancy and adverse pregnancy outcome or congenital abnormalities. Further, no increased relative risk of infections has been reported in the first year of life in offspring of mothers who received biologics. Biologics should be discontinued during pregnancy solely if the IBD is in remission using the same stopping criteria as for patients with IBD in general, as uncontrolled activity of IBD may expose the mother and child to a risk greater than those only potentially coming from the use of TNF-a inhibitors. In such cases, inoculation of the offspring with live vaccines is contraindicated until the biologic agent is no longer detectable in the child's circulation.

Keywords: Biologics, Crohn's disease, IBD, Lactation, Pregnancy, Ulcerative colitis

Ole Haagen Nielsen1*, Edward V Loftus Jr2 and Tine Jess3

Background

Biologics are effective and increasingly used in the treatment of inflammatory bowel disease (IBD), of which Crohn's disease (CD) and ulcerative colitis (UC) are the two main types. As the peak incidence of IBD overlaps with the prime reproductive years, information on the effects of biologics on pregnancy outcome (including fetal harm) is essential in order to give appropriate advice to women of childbearing age who require treatment for IBD.

* Correspondence: ohn@dadlnet.dk

department of Gastroenterology, MedicalSection, Herlev Hospital, University of Copenhagen, Copenhagen, Denmark Full list of author information is available at the end of the article

Bio Med Central

In general, women with IBD are advised to conceive at quiescent stages of their disease, as this reduces the risk of obstetric complications (for example, preterm delivery and low birth weight) [1-5]. Effective control of disease activity using a wide range of medications, including bio-logics, is vitally important during pregnancy [6,7].

The most commonly used biologics in IBD are infliximab (IFX), a chimeric IgG1 monoclonal antibody; adalimumab (ADA), a human monoclonal IgG1 antibody; and certolizumab pegol (CZP), a pegylated Fab fragment of a humanized IgG4 isotype monoclonal antibody [8]. Recently, golimumab (GLM), also a human monoclonal IgG1 antibody, has been added to the list.

©2013 Nielsen et al.; licensee BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.Org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

These four biologic agents are all classified as 'category B' drugs by the US Food and Drugs Administration (FDA) [9], meaning that animal reproduction studies have not shown any risk to the fetus, but there are no adequate and well-controlled studies in pregnant women.

In the clinical scenarios of a woman with IBD on biologic therapy becoming pregnant, or when biologic treatment is being considered in a pregnant woman with active IBD, decisions are made on a case-by-case basis because the short-term and long-term implications of exposure to biologic agents have not yet been investigated systematically. Although no comparative effectiveness data exist to support the strategy, it has been common practice at many IBD centers to continue bio-logics through the second trimester of pregnancy [10], as the transplacental transfer of IgG begins around week 20 and increases thereafter, especially during the third trimester [11]. In accordance with this practice, IFX and ADA are discontinued around week 30 of pregnancy [12], and in patients with active IBD, it has been suggested to bridge therapy with glucocorticoids to control disease activity until delivery [13-16]. This approach has the benefit of minimizing the break from treatment with biologic agents and perhaps decreasing the risk of im-munogenicity [8] (that is, the risk of hypersensitivity reactions or loss of response once the biologic is reintroduced post-partum). However, CZP may differ from the other tumor necrosis factor (TNF)-a blockers used in IBD, as it is a Fab fragment of a monoclonal antibody, which is not transported across the placenta and therefore, it may not be necessary to discontinue this drug in the third trimester [17].

However, at present there are no definitive conclusions concerning what could be one of the most important therapeutic decision-making settings from the viewpoint of risk-benefit analysis. Thus, the decision whether to use bio-logics during pregnancy might be regarded as an example in which it is considered most prudent to err on the side of caution, especially as it is still unknown what levels in the serum of TNF inhibitors used to treat a mother with IBD will be safe or harmful for the fetus or newborn.

The aim of this study was to perform a systematic review of the available literature on the risk of adverse birth outcomes related to IBD after maternal exposure to IFX, ADA, or CZP, in order to improve evidence-based informed choice and clinical decision-making during pregnancy, especially in the third trimester. Data about use of GLM in IBD pregnancies are currently unavailable, as it has only recently been approved for UC.

Methods

Ethics approval

This study was an analysis of published data, which did not require ethics committee approval.

Search strategy

A systematic review was performed according to the guidelines established by the Meta-analysis of Observational Studies and Epidemiology Group (MOOSE criteria) [18]. The databases searched (January 1998 to May 2013) were MedLine, EMBASE, the Cochrane Library, and the homepages of the FDA and the European Medicines Agency (EMA), using the combinations of the following Medical Subject Heading (MeSH) search terms: (inflammatory bowel disease OR inflammatory bowel diseases OR Crohn's disease OR ulcerative colitis) AND biologics OR biologic products OR infliximab OR adalimumab OR golimumab OR certolizumab. This was again combined with either pregnancy OR newborn OR lactation OR breast feeding OR infant. No authors were contacted.

Selection criteria

We wanted to include all randomized controlled trials, observational studies, case series, and case reports evaluating pregnancy outcomes of women with IBD treated with TNF-a inhibitors (IFX, ADA, GLM, or CZP) during any trimester of pregnancy, including the 90 day periconceptional period. Outcome assessment included miscarriages (spontaneous abortions), pre-term delivery, stillbirth, low birth weight, and/or congenital malformations, and if data were available, it also included assessment of infections in the offspring. Only abstracts or articles published in English were considered. Figure 1 shows the flowchart of the study screening process.

Data extraction

Two authors (OHN and TJ) independently identified candidate articles from the results of the initial search, based on the title and abstract. Subsequently, both authors independently reviewed the full text of candidate articles to identify interventions and assess study quality. In cases of any discrepancies between the independent searchers, these were resolved in consensus with the third author (EVL).

The reference lists of relevant articles were hand-searched to identify additional studies. Further, abstracts from the meetings of American Gastroenterological Association (Digestive Disease Week), American College of Gastroenterology, and the European Crohn's and Colitis Organisation from 1998 to May 2013 were searched manually for relevant abstracts based on the aforementioned search terms.

Summarization of data

The search yielded a total of 58 studies (36 articles and 22 abstracts) that met the inclusion criteria (Table 1). The studies comprised 33 case reports, 21 case series,

Studies retrieved through electronic and subsequent hand search (n=552)

First pass review of studies (n=478)

Second pass review of studies (n=429)

Detailed evaluation of studies n=94

Studies included in final analysis (n=58)

Figure 1 Flowchart of the study screening process.

and 4 prospective studies with or without control groups. No controlled randomized studies were identified. The total number of pregnant women with IBD who were exposed to anti-TNF agents was at least 1,533 (one study with 289 pregnancies included other diseases and did not specify the number of women with IBD [19]). The bias of the present study was that only non-English studies were excluded.

Results

Infliximab

In the early days of biologic treatment for IBD, IFX was reported to be associated with adverse pregnancy outcomes in some case reports [20,21], but not in others [22-27], and in case series where IFX was administered throughout pregnancy to maintain remission in IBD, no harm to the fetus/child was reported [16,19,28-34]. Furthermore, larger and subsequent studies did not report any increased risk for adverse events compared with un-exposed IBD pregnancies [12,17,35-49]. In a study on pregnancies exposed to IFX, Zelinkova et al. observed one adverse event (polydactyly), actually reported on two occasions [12,50]. In this particular case, the mother of the infant had also received methotrexate (MTX) 2

months prior to conception [12,50]. MTX is a drug classified as 'X' by the FDA; that is, a drug for which studies in animals or humans have shown fetal abnormalities and/or for which there is positive evidence of human fetal risk, based on adverse reaction data from investiga-tional or marketing experience, and for which the risks involved in use of the drug in pregnant women clearly outweigh the potential benefits [9]. However, polydactyly is an uncommon disorder; it is not usually seen as the only complication to MTX treatment, but is more often present together with other abnormalities [50].

The first series studying intentional IFX administration throughout pregnancy examined outcomes in 10 women with active CD, and all ended in live births [32]. Of these 10 births, there were 3 cases of premature birth and 1 case with low birth weight, findings that were not unexpected in women with CD that was sufficiently severe to require IFX treatment. No congenital abnormalities were observed 6 months post-partum [32].

The four largest studies providing data on the safety of IFX in an IBD population are from the Therapy Resource Evaluation Assessment Tool (TREAT) registry [36], a pregnancy safety database maintained by the manufacturer of IFX [49], the Pregnancy in Inflammatory Bowel Disease and Neonatal Outcomes (PIANO) registry [51] and the Groupe d'Etude Thérapeutique des Affections Inflammatoires du Tube Digestif (GETAID) collaboration [52].

The TREAT registry is a prospective study of North American patients with CD. As of February 2010, there were 6,273 patients in the registry, and 142 pregnancies with IFX exposure were reported. The risk of fetal malformations was no higher than in the general population [36], and a more detailed analysis of pregnancies in the TREAT registry is under way [36].

The IFX Safety Database is a retrospective data-collection instrument set up by the manufacturer of IFX (Centocor, now Janssen Biotech) to study women with rheumatoid arthritis or CD exposed to IFX before or during pregnancy. There were 96 women with direct exposure to IFX who gave birth to 100 children; however, in most case, IFX treatment was discontinued in the first trimester of pregnancy. The rates of adverse outcomes were not different from that expected in the general population [49].

Preliminary data from the US national prospective PIANO registry has recently been disclosed [53]. A total of 1,232 women with IBD were enrolled as of April 1, 2013, of whom 357 women received biologics, including during the third trimester, and an additional 109 women received a combination of thiopurines and biologics [53]. Adverse pregnancy outcomes such as spontaneous abortions, preterm birth, low birth weight, and congenital abnormalities were evaluated. A slightly higher relative risk

Excluded due to non-English language (n=74)

Excluded due to no relevance, e.g., other diseases or animals (n=49)

Exclusion of reviews and articles without patient cases (n=335)

Studies excluded due to:

-Repeated patient description (n=36)

Author Year Anti TNF Stage of pregnancy Study type

James [25] 2001 FX P(J2) Case report

Srinivasan [21] 2001 FX PC/P(JD Case report

Bank et al [24] 2002 FX P(T1-T2) Case report

Burt et al [27] 2003 FX PC Case report

Katz et al [49] 2004 FX 53/96 PC; 58/96 P(T1); 6/96 unknown Case series from Inflixim Safety Database (82 CD, UC, 10 RA, 3 unknown); women, 72 births

Mahadevan et al [32] 2005 FX 9/10 PC; 8/10 P(T2); 8/10 P(T3); 7/10 PP Case series (n = 10 worr

Tursi [34] 2006 FX PC/P(T1-T3)/PP Case report

Xirouchakis et al [64] 2006 FX PC/P(JD Case report

Vasiliauskas et al [16] 2006 FX (10 mg/kg body weight) PC/P(T1 -T3) Case report

Mahadevan et al [28] 2007 FX p(Ti-T3) Case series (n = 5)

Malgarinos et al [29] 2007 FX PC/P(T1 -T3) Case report

Angelucci et al [26] 2008 FX P(J1) Case report

Palmer et al [20] 2008 FX P (T2-T3) Case report

Stengel et al [33] 2008 FX PC/P(T1 -T3) Case report

Kane et al [68] 2009 FX 2 PC/P(T1-T3), 1 P(T2) Case series (3 women)

Hou et al [14] 2009 FX PC/p(J1-T3) Case report

Aral et al [23] 2010 FX P (T2-T3) Case report

Epping et al [66] 2010 FX PC/P(T1 -T3) Case report

Angelucci et al [65] 2010 FX PC/P(JD Case report

Correia et al [30] 2010 FX PC/P(T1 -T3) 2 case reports

Molnâr et al [47] 2010 FX PC/P(T1 -T3) Case report

Cheent et al [63] 2010 FX (10 mg/kg body weight) PC/P(T1 -T3) Case report

Aratari et al [44] 2011 FX P(J2) Case report

Mode of delivery

Outcome of pregnancies

Unknown Unknown

Unknown

C-section Unknown

8/10 C-section, 2/10 Vaginal

Unknown

Vagina

Vagina

4 vaginal/1 C-section Unknown C-section Unknown

C-section

2 vaginal, 1 C-section

Vagina

Unknown

Unknown

C-section

C-section

Unknown

Vagina

C-section

Normal, healthy, full term

Premature, preterm, LBW. Adverse outcome: intracerebral and intrapulmonary bleeding followed by death 3 days later (metronidazole + azathioprine + 5-ASA was also administered in pregnancy for treatment of flare and fistulae)

Normal, healthy, full term (correspondence with authors)

Normal, healthy, preterm (36 weeks)

64/96 were live births (1 preterm death at 24 week, 1 full-term with tetralogy of Fallot, 1 perinatal sepsis, 1 intestinal malrotation, 1 developmental delay); 4 pregnancies ended with twins. 14/96 were miscarriages, 18/96 were therapeutic terminations

3/10 were preterm, 1/10 were LBW, 2/10 were neonatal illnesses, which resolved. Al normal at follow-up

Normal, healthy, preterm (36 weeks)

Normal, healthy, full term

Normal, healthy, full term

Normal, healthy, full term

Normal, healthy, preterm

Normal, healthy, full term

ntra-uterine fetal death due to placenta abruption or ¡ntra-uterine infection

Normal, healthy, full term

3 normal, healthy, full term

Normal, healthy, full term

Normal, healthy, full term

Normal, healthy, full term

Normal, healthy, preterm (31 weeks)

Normal, healthy; 1 preterm (31 weeks)

Normal, healthy, full term

Healthy, full term, no malformations

Healthy, preterm (37 weeks)

Abdul Wahab et al [40] 2011 FX P(T2-T3) Case report

Kozeluhova [41] 2011 FX PC/P(T1 -T3) Case report

Chaparro et al [45] 2011 FX PC/P(T1 -T3) Case report

Naganuina et al [67] 2011 FX PC/P(T1 -3) Case series (3 women)

Steenholdt et al [22] 2012 FX PC/P(T1 -T2) Case report

Arguelles-Arias et al [42] 2012 FX PC/P(T1 -T3) Case series (12 women)

Lichtenstein et al [36] 2012 FX 142 reported pregnancies Case series (analysis of data from TREAT registry)

Snoeckx et al [38] 2013 FX PC/P(T1 -T3) Case series (556 pregnancies)

Vesga et al [80] 2005 ADA PC/P(T1-T3)/PP Case report

Coburn et al [77] 2006 ADA P(T2; T3) Case report

Mishkin et al [79] 2006 ADA PC/P(T1 -T3) Case report

Chamberí et al [75] 2006 ADA PC/P(JD Case series (5 women)

Bosworth et al [71 ] 2007 ADA PC/P(T1 -T3) Case report

Johnson et al [72] 2009 ADA PC/P(T1 -T3) Case-controlled study 34 women and 45 controls (OTIS)

Jürgens et al [78] 2010 ADA PC/P(JD Case report

Ben-Horin et al [74] 2010 ADA PC/P(T1 -3) Case report

Abdul Wahab et al [73] 2011 ADA PC/P(T1 -T3) Case report

Mahadevan et al [76] 2011 ADA PC/P(T1 -T3) Case series (5 women)

Kane et al [31] 2009 CZP Unknown (UCB data on file) Case series (16 women)

Mahadevan et al [85] 2009 CZP P(T2; T3)/PP Case report

Oussalah et al [86] 2009 CZP PC/P(T1; T3) Case report

Steinberg et al [84] 2010 CZP P (T2-T3) Case report

Mahadevan et al [87] 2012 CZP PC/P(T1 -T3) Case series (139 pregnancies including 17 with rheumatoid arthritis)

Slama et al [19] 2010 I FX/ADA PC/P(T1 -T3) Case series (289 pregnancies including other diseases than IBD)

Unknown Unknown C-section Unknown

Unknown

8 vaginal, 4 C-sections Unknown

Unknown

C-section

Unknown

Vagina

Unknown

C-section

Unknown

Vagina Vagina C-section

2 vaginal 3 C-sections Unknown

Unknown Vagina

C-section Unknown

Unknown

Normal, healthy, full term

Normal, healthy, full term

Normal, healthy, full term

All healthy, full term, 1 low birth weight, no malformations

Normal, healthy, full term

12 healthy children

The vast majority of babies (924%) were healthy with no defects or other adverse events

There were 58 miscarriages, 38 elective abortions, 7 stillbirths, and 453 live births

Normal, healthy, full term

Normal, healthy, full term

Normal, healthy, full term

All full-term live births. No malformations

Normal, healthy, full term

29 live-born (1 with undescended testicle + 1 with microencephaly); 5 spontaneous abortions. Two major structural defects in control group

Healthy, full term

Healthy, full term

Twins, normal, healthy, full term

Healthy (one infant developed pulmonary edema, but recovered fully)

4 healthy, full term; 1 small for gestational age; and 2 lost to follow-up. 8 induced abortions amd 1 spontaneous abortion

Healthy, full term, no malformations

Normal, healthy, full term. Adverse outcome in 1 case: bleeding 7 days post-partum, secondary to cotyledon retention

Healthy, full term, no malformations

21 miscarriages, 15 elective abortions, and 103 live births (2 with congenita abnormalities: 1 with mild unilateral hydronephrosis and 1 with vesicouretic reflux)

No increased risk of adverse pregnancy outcome compared with unexposed IBD pregnancies

Dunne et al. [46]

Schnitzler et al. [54]

I FX/ADA

I FX/ADA

Machkova et al. [43]

Habalet al. [37] Traussnigg et al. [39] Zelinkova Z et al. [12]

Casanova et al. [48]

Seirafi et al. [52]

2012 I FX/ADA

2013 I FX/ADA 2013 I FX/ADA 2013 I FX/ADA

IFX/ADA/CZP

PC/P(T1-T3)

PC and/or P(T1) and/or P(T2)

PC/P(T1-T3)

PC/P(T1-T3)

PC/P(T1-T3)

PC/P(T1-T3) (T1-T2 ADA only)

PC/P(T1-T3)

2011 IFX/ADA/CZP PC/P(T1-T3)

Mahadevan et al. [51 ] 2012 IFX/ADA/CZP PC/P(T1-T3)

Casanova et al. [35]

Mahadevan et al. [17]

2013 IFX/ADA/CZP PC/P(T1-T3)

2013 IFX/ADA/CZP

PC/P(T1-T3)

15 case series (15 women)

Case-controlled study (35 women with 42 pregnancies (35 IFX + 7 ADA) versus 101 pregnancies before IBD/ treatment and 56 matched pregnancies in healthy controls)

Case series (33 pregnancies in 31 women)

Case series (29 pregnancies in 21 women) Case series (14 pregnancies in 13 women) Case series (31 pregnancies in 28 women)

Case-controlled retrospective study (30 pregnancies in treated mothers versus 110 unexposed IBD pregnancies)

Case series (85 women)

Unknown

Unknown

Unknown

Unknown Unknown Unknown

Unknown

Unknown

Case-controlled study (291 women without, and 79 with immunomodulators)

Unknown

Case series (66 pregnancies)

Case series (31 women)

Unknown

15 vaginal, 16 C-section

9 terminated pregnancies at study end. All live births were healthy, with two sets

of twins

10 abortions (1 trisomy 18, 1 elective), 1 stillbirth (umbilicalstrangulation), 32 live births: 8/32 premature, 6/32 low birth weight. Allchildren were born healthy but one child with necrotizing enterocolitis died at 13 days of age (mother required treatment for severe asthma and CD during T3)

5/33 pregnancies ongoing. 24/28 healthy children (4/24 preterm), 3/24 spontaneous abortions, and 1/24 provoked abortion

27 normal, healthy, full term;2 miscarriages 13 normal, healthy, full term; 1 miscarriage

28 live births (27 normal, healthy, full term; 1 child born to a mother treated with concomitant methotrexate periconceptually had polydactyly);3 miscarriages

Prevalence of unfavorable delivery outcome (spontaneous abortion, preterm delivery, low birth weight and malformations) were higher in the control group

6/85 were miscarriages, 47/85 were live births (30/85 ongoing), 8/49 were preterm, 3/49 were deaths (two in utero/one very premature),7/46 live births had neonatal complications (1 infection, 3 respiratory distress syndrome, 6 LBW <2500 g, 1 HELLP syndrome

No increased risk apart from higher risk of spontaneous abortion and C-section in group treated with biologics alone, and higher risk of preterm birth and infections int offspring at 12 months in combined thiopurine group verus biologics-alone group or unexposed IBD pregnancies

55 normal, healthy full term;, 4 preterm;6 miscarriages;1 congenitalabnormality (severalcardiac malformations)

All 33 children (2 sets of twins) were normal, healthy, fullterm

Abbreviations: 5-ASA 5-aminosalicylic acid, ADA adalimumab; C-section cesarean section, CZP certolizumab pegol, HELLP a syndrome characterized by hemolysis, elevated liver enzymes, and low platelet count (that is, a variant/complication of pre-eclampsia), IBD inflammatory bowel disease, IFX infliximab, LBW low birth weight, PC periconceptual (that is, use within 90 days before conception), PP post-partum, P(T1-T3) (pregnancy with trimester where biologics were reported to be administered), MTX methotrexate, TNF tumor necrosis factor, TREAT Therapy Resource Evaluation Assessment Tool.

(RR) for preterm birth was found for women on combination therapy (2.4; 95% confidence interval (CI) 1.3 to 4.3), which was, however, not found for those on bio-logics only (0.8; 95% CI, 0.5 to 1.3). No elevation in the risk of spontaneous abortion, low birth weight, or congenital abnormalities was observed for biologics, either alone or in combination with thiopurines. Earlier reports (May 2012) had indicated that there was a higher rate of infections in the offspring [51], but the RR at month 12, adjusted for premature birth, was shown in April 2013 to be 0.9 (95% CI 0.7 to 1.1) for biologics alone, and 1.0 (95% CI 0.7 to 1.3) for those on combined therapy. When results for CZP were excluded, the values were 0.9 (95% CI 0.8 to 1.2) and 1.0 (95% CI 0.7 to 1.3), respectively [53]. In addition, breast feeding was not associated with any risk of infection or impairment of height or weight. The limitation on the preliminary data was that not all infants had reached the age of 12 months, and the observation will continue until the age of 4 years for all of the offspring [53].

The French GETAID consortium prospectively recorded pregnant women with IBD during a 2 year period (2009 to 2010), and preliminary data analysis of 127 pregnancies in 120 women was reported in 2010 [52]. Of these 120 women, 54 women had received biologic therapy for their IBD. Birth outcomes of the women on biologics did not differ from those in the unexposed IBD population, suggesting an absence of any excess risk linked to anti-TNF-a therapy.

Schnitzler et al. [54] conducted an observational study of 35 pregnancies under direct exposure to IFX until week 20 of pregnancy, 53 pregnancies with indirect exposure to IFX (women treated with IFX prior to pregnancy), 7 pregnancies with direct exposure to ADA, and 56 matched pregnancies in healthy women. Several patients experienced a flare of disease in the third trimester. However, exposure to anti-TNF-a preparations was not associated with a higher incidence of adverse pregnancy outcomes [54]. The paper concluded that pregnancy outcomes after exposure to TNF inhibitors did not differ from those of women with IBD who were not exposed to anti-TNF treatment, but were worse than in healthy women [54]. Further, a literature review including women with rheumatic disorders or CD with direct exposure to IFX at any time during pregnancy did not find any increase in undesirable pregnancy or fetal outcome [55].

However, in contrast to studies providing evidence of the safety of anti-TNF-a preparations during pregnancy, a review of more than 120,000 adverse events voluntarily reported to the FDA after drug exposure revealed 61 congenital abnormalities in 41 children of 40 mothers exposed to TNF-a blockers for various indications, including IBD [56]. Of these, 22 mothers were exposed to

etanercept (a biologic agent not efficacious for IBD [57]), and 19 were exposed to IFX. Of the 41 children, 24 (59%) had abnormalities thought to be part of the VACTERL (vertebral abnormalities, anal atresia, cardiac defects, tracheoesophageal, renal and limb abnormalities) spectrum. The findings led the authors to conclude that the use of TNF-a blockers should be avoided during pregnancy. However, this study was subsequently criticized for significant methodological flaws [58,59], including selection bias, lack of a control group, and the fact that only one of the infants (the etanercept group only) had a clustering of three or more abnormalities included in the VACTERL spectrum [60]. Furthermore, the review did not take into account the total number of women exposed to anti-TNF-a agents or any confounding by severity of the underlying disease. Finally, the most common defects reported in this review were cardiac defects, which are observed in the general population as well [58,59].

Like other IgG antibodies, IFX is transferred across the placenta with the help of an Fc receptor neonatal (FcRn) molecule responsible for the transfer of immuno-globulins from the mother to the neonate [11]. The transfer occurs partly in the second, and mainly in the third trimester [31]. This finding has led many clinicians to discontinue IFX in the third trimester when the highest level of transfer occurs [61], in the belief that detectable serum IFX in the neonate might lead to clinically relevant immunosuppression. Moreover, the use of biologics in the second and third trimesters has been questioned [12]. However, Zelinkova et al. [12,50] showed that even though two patients discontinued IFX treatment as early as in week 26 of pregnancy, the infants still had detectable amounts of IFX in their serum samples after delivery. Low levels of IFX have been detected up to 6 months post-partum in the serum of infants whose mothers have received this drug up to delivery [16]. IFX was undetectable in the infant at delivery only in one case, where the mother discontinued drug therapy at week 21, suggesting that discontinuation of drug therapy might be considered earlier than the beginning of the third trimester [50].

Because of this presence of IFX in the circulation after delivery, the use of live-virus vaccines (for example, varicella, measles, mumps, rubella, rotavirus, intranasal influenza, and bacillus Calmette-Guerin; BCG) is contra-indicated in patients receiving biologic therapy and their children [62]. A case report described a fatal incident of an infant who was exposed to IFX during gestation and who received a BCG vaccine at 3 months; this infant died of disseminated BCG infection [63]. Thus, the most recent recommendation from the World Congress of Gastro-enterology consensus statement on vaccinations in infants exposed to biologic therapy in utero recommend delay of

all live-virus vaccines until after biologic molecules are no longer detectable in the child's blood [62].

In this systematic review, identifying 17 case reports related to IFX [14,16,20,22,23,29,30,33,34,40,41,45,47,63-66], 13 case series [12,17,19,28,32,37-39,42,43,46,67,68], 2 uncontrolled cohort studies [19,36, and 2 controlled cohort studies [48,69] (Table 2), we found the prevalence of pregnancy complications, including preterm delivery, stillbirth, low birth weight, miscarriages, or congenital malformations in children exposed to IFX throughout pregnancy is limited, even after exposure to biologics throughout the third trimester. However, the use of IFX up to week 30 of gestation results in fetal intra-uterine exposure to high IFX levels (up to three-fold higher than in the maternal peripheral blood), which may raise concerns about the long-term effects of IFX on these children, including effects on their immune system [50].

Adalimumab

The clinical data for the safety of ADA during pregnancy in women with IBD are more limited than for IFX, but in animals, it appears that ADA does not increase obstetric risks and has no teratogenic effects [70]. In humans, data on ADA and pregnancy primarily concerns patients with diseases other than IBD, such as rheumatoid arthritis and psoriasis.

For IBD, 21 case reports and series with more than 300 children exposed showed no increased risk of adverse pregnancy outcome or congenital malformations associated with ADA treatment during pregnancy compared with pregnancies in unexposed women with IBD [12,17,19,35,37,39,43,46,48,51,52,54,71-80], even if ADA was administered in the third trimester [17,19,35,37,39, 43,46,48,51,52,71-74,76,77,79,80]. The Organization of Teratology Information Specialists reported on a group of 34 women treated with ADA for various indications in a prospective study, and another 133 ADA-exposed women in a case series. There was no difference in pre-term deliveries, stillbirths, spontaneous abortions or congenital malformations in the group treated with ADA compared with either the general population or a control group with the same disease but not exposed to ADA [62,81]. In line with these observations, Schnitzler et al. did not find a higher incidence of adverse pregnancy outcomes in seven women treated with ADA compared with unexposed women with IBD, although the power of that study was limited [54].

An ongoing cohort study evaluating ADA in pregnancy compared 80 live offspring born to 94 ADA-exposed women with CD, 53 live offspring of 58 women with CD not exposed to ADA, and 78 of 87 women from a non-diseased comparison group. The frequency of congenital abnormality in the three groups was 9.6%, 5.4%, and 5.0%, respectively [72] (P>0.05 between all groups).

Like IFX, ADA is transferred across the placenta in the third trimester of pregnancy [31,76], and accordingly, it has been recommended at many IBD centers that ADA should be discontinued in the third trimester (that is, week 30), even though data, as mentioned before, do not support this theory [82].

Osting et al. carried out a review of TNF-a blockers (ADA and eternacept only) administered during pregnancy from 1999 to 2009 using the Organization of Tetratology Information Specialists (OTIS) prospective registry, and concluded that 7 to 10% of children had congenital abnormalities [83]. However, the underlying disease activity might be a confounding factor with greater effect on the risk of congenital abnormalities than the biologic treatment per se.

Golimumab

Because GLM was approved only recently (May 2013) by the FDA for treatment of the UC, data are not yet available for this drug in relation to IBD pregnancies.

Certolizumab pegol

Because CZP lacks the Fc portion of the antibody, which is crucial for the main transfer of immunoglobulins across the placenta, the transfer of CZP to the offspring is low, but a small transfer of Fab fragments is seen [31]. In a group of 10 women receiving CZP during pregnancy, with the final dose 1 to 4 weeks before delivery, CZP was detectable at minimal levels in the infants' circulation [17]. Overall, CZP is transferred across the placenta to a much lower degree than IFX or ADA [17].

Compared with the other two TNF inhibitors approved for CD, the human data on pregnancy outcomes in mothers treated with CZP during pregnancy are more limited. In three case reports where CZP injections were administered during the third trimester, healthy infants were delivered at full term [84-86], and in a case series of 16 pregnancies of CZP-treated mothers, all children were healthy [31]. In a recent case series with 139 pregnancies, 17 were in mothers with rheumatoid arthritis; of these 139 pregnancies, 103 ended in live birth (2 with congenital abnormalities; see Table 1), 21 in spontaneous miscarriage, and 15 in elective termination [87], results that are similar to those reported in the general population [87]. Based on these findings and the low placental transfer of CZP, the drug appears to be safe to use throughout pregnancy [17]. One of the reports observed uterine bleeding in the mother at 7 days post-partum; whether this can be ascribed to the CZP treatment remains to be established [86].

Evaluation of the identified studies

In the studies included in this systematic review, more than 1,426 live births occurred among all the women

Table 2 Studies reporting exact numbers, odds ratios, or relative risks for various birth outcomes in women with IBD exposed to TNF-a blockers compared with unexposed controls with IBD

Author Patients with IBD exposed to TNF-a blockers Controls Spontaneous abortions or stillbirths Preterm delivery Low birth weight Abnormalities/major birth defects/malformations Infections during the first 12 months of life

Johnson et al. [72] 34a 55b 5/34 versus 3/55; OR 2.99 (95% CI0.67 to 13.41) - - 2/34 versus 2/53; OR 1.59 (0.21 to 11.9) -

Schnitzler et al. [54] 42 78 9/42 versus 12/78; OR 1.5 (0.57 to 3.92) 8/32 versus 8/65; OR 2.38 (0.80 to 7.06) 6/32 versus 9/65; OR 1.44 (0.46 to 4.46) 1/42 versus 1/78; OR 1.87 (0.11 to 30.8) -

Casanova et al. [48] 202c 110 20/202 versus 19/110; OR 0.53 (0.27 to 1.04) 8/202 versus 13/110; OR 0.31 (0.12 to 0.77) 12/202 versus 11/110; OR 0.57 (0.24 to 1.33) 2/202 versus 0/110; (no OR or CI) -

Mahadevan et al. [51] 79c 291/326 RR 1.29 (0.79 to 2.11); Biologies alone:; RR 2.56 (1.07 to 4.12) RR 1.83 (1.01 to 3.31); Biologics alone:; RR 0.89 (0.54 to 1.47) RR 1.35 (1.01-1.80); Biologies alone:; RR 0.89 (0.70-1.12)

Abbreviations: CI confidence interval, IBD inflammatory bowel disease, OR odds ratio, RR relative risk, TNF tumor necrosis factor. aPatients with Crohn's disease, psoriasis, rheumatoid arthritis, and other forms of arthritis. bControls were unexposed patients with rheumatoid arthritis. cTNF-a blockers and/or thiopurines or other immunomodulators.

exposed to IFX, ADA, or CZP. The number of congenital abnormalities associated with live births reported did not point to any pattern of specific birth defects (Table 1). There were 128 miscarriages, 81 elected abortions (presumably 'under-reported'), 12 stillbirths, and 33 preterm births reported (Table 1).

Owing to considerable variation in study designs, selection of controls, and the definition and selection of outcomes in the identified studies, we were unable to conduct a meta-analysis. However, it appears clear from Table 2 that for all outcomes except congenital abnormalities, the OR or RR did not point systematically towards a negative or positive effect of TNF-a inhibitors. A slightly increased risk of congenital abnormalities in women with IBD exposed to TNF-a inhibitors compared with unexposed pregnant women with IBD seemed to be suggested from the few studies with controls (Table 2), but the CIs were very broad. Moreover, this observation should be weighed against the fact that the vast majority of case reports did not report congenital abnormalities, although it is thought that such 'positive' cases are more likely to be described and published than negative ones. Lastly, the meta-analysis by Cornish et al. [1] including 3,907 women with IBD, showed that an underlying increased risk of the studied outcomes already exists (stillbirths: OR 1.48 (95% CI 0.89 to 2.47); preterm delivery: OR 1.87 (1.52 to 2.31); low birth weight: OR 2.10 (1.38 to 3.19); and congenital abnormalities: OR 2.37 (1.47 to 3.82)) independent of treatment, compared with 320,531 pregnant non-IBD controls.

Discussion

When summarizing the existing data in this systematic review, no association between treatment with TNF-a inhibitors for IBD in pregnancy and adverse pregnancy outcomes such as spontaneous abortions, preterm deliveries, stillbirth, low birth weight, congenital malformations, and/ or infections, was found, even after administration of TNF-a blockers in the third trimester. In studies combining biologics with thiopurines (which often occurs because of the favorable results of the Study of Immunomodulator Naive Patients in Crohn's disease (SONIC) [88] and UC SUCCESS (a study similar to the SONIC trial) [89] studies in CD and UC, respectively), there was no increased risk of infections in newborns compared with an unexposed control group.

Ideally, any woman with IBD intending a pregnancy should have counseling with her gastroenterologist and obstetrical provider well in advance of conception, and this counseling should cover the medical treatment options and the risks associated with active disease during pregnancy. Pregnancy should if possible be planned, and the IBD should be controlled before conception. Further, the importance of adherence to treatment and

prevention of relapse during pregnancy should be stressed, and the patient should be monitored as a high-risk pregnancy. However, in real-world situations, this is not always the case, but it is important for the physician to discuss with each patient with IBD the risk versus benefit ratio of medical therapy, including TNF-a inhibitors, for disease control during pregnancy.

Embryo-fetal perinatal developmental toxicity studies performed in cynomolgus monkeys receiving doses of TNF-a inhibitors several hundred times the recommended human dose did not reveal any evidence of teratogenic or other deleterious effects [90], such as adverse pregnancy or maternal outcomes [91]. Because IFX does not cross-react with TNF-a in species other than humans and chimpanzees, other animal reproduction studies have not been conducted with this drug. Thus, to date there is no evidence that TNF blockers are associated with embryotoxicity, teratogenicity, or increased pregnancy loss compared with pregnancies unexposed to biologics, either in rheumatology [92], or in a recent retrospective IBD multicenter study [35].

The present systematic literature review reveals that many reports on biologic treatment in pregnancy lack information on the total number of women exposed to treatment, disease activity, co-morbidities, and/or concomitant medications. In some cases, it is therefore difficult to establish whether instances of fetal harm are due to medications or to the severity of the underlying illness [20,21]. Furthermore, many of the studies intending to assess the effect of TNF-a inhibitors per se were confounded by the fact that many patients are on multiple medications. Finally, it should be kept in mind that biologics are more commonly used in patients with more severe disease activity, which accordingly might influence the pregnancy outcome data presented [1], especially if patients are not compared with pregnant women with a similar degree of IBD disease severity treated with other medications. As an example, the unfavorable outcome described by Srinivasan [21] may potentially be due to the underlying severity of IBD or to other medications.

The aggravation of underlying disease might be more detrimental to the viability of pregnancy than the apparently low risk of continuing biologic therapies, and the results from this systematic review do not support the practice of stopping biologic treatment of the expectant mother after week 30 because of a theoretical risk of infections or congenital abnormalities in the offspring. The data presented here suggest that the rates of congenital malformations and adverse birth events are similar to the rates in the background population of pregnant women, or at least of women with IBD in general [1]. Further, there is no increased risk of infections in the offspring of mothers on biologic treatment during

pregnancy. However, it should be emphasized that immunosuppression of the offspring contraindicate the use of live vaccines until the biologic agent is no longer detectable in the child's circulation, because of the risk of fatal infections [63,93,94].

Limitations of the study

Limitations of studies identified in this systematic review included small sample sizes and paucity of studies with control groups. Future studies assessing the outcome of pregnancies exposed to IFX or other biologics during conception and pregnancy should be prospective in nature, and should assess comparable women with IBD with or without the relevant exposure as a control group to draw firm conclusions. Data on potential con-founders, especially maternal age, disease activity, and co-medications, should also be recorded. Furthermore, long-term follow-up studies of children exposed to biologic medications in the uterus should be carried out, especially as no long-term data exist on outcomes in children related to the development of diseases such as asthma or autoimmune diseases.

Conclusions

There is a growing body of evidence suggesting that biologic agents are of low risk in pregnancy. Although it is difficult to prove absolute safety, this systematic review suggests that women who inadvertently become pregnant while taking TNF-a inhibitors can be reassured that continuation of pregnancy does not appear to impose an increased risk to either themselves or their baby. The limited clinical results available suggest that the benefit of biologic agents in attaining response and maintaining remission in pregnant women with IBD might outweigh the risk of pregnancy complications due to flare-ups (for example, spontaneous abortions, prematurity, low birth weight or stillbirth), and the theoretical risk of drug exposure to the fetus [34]. However, the long-term implications of fetal exposure to therapeutic monoclonal antibodies on the child's developing immune system are still unknown.

Therefore, biologics should be discontinued during pregnancy only if the IBD of the pregnant patient is in remission using stopping criteria for patients with IBD in general, and the intentional use of biologics throughout pregnancy should be considered in situations where the disease is active at the end of the second trimester, as a documented benefit of TNF-a inhibitors for active inflammatory and fistulizing IBD is unprecedented. Further prospective studies are essential to elucidate the risk of combination therapy on the neonatal immune system.

Abbreviations

ADA: Adalimumab; BCG: Bacillus Calmette-Guerin; CD: Crohn's disease; CZP: Certolizumab pegol; EMA: European Medicines Agency; FcRn: Fe

receptor neonatal; FDA: Food and Drug Administration; GLM: Golimumab; IBD: Inflammatory boweldisease; IFX: Infliximab; MTX: Methotrexate; TNF: Tumor necrosis factor; UC: Ulcerative colitis.

Competing interests

TJ and OHN have nothing to disclose. EVL has consulted for Abbott Labs, UCB Pharma, and Janssen Biotech, and has received research support from Abbott Labs, UCB Pharma, and Janssen Biotech. However, allauthors declare they have not been supported from any organization for the submitted work; have had no financialrelationships with any organizations that might have an interest in the submitted work in the previous 3 years; and have no other relationships or activities that could appear to have influenced the submitted work.

Authors' contributions

OHN conceived the study; TJ and OHN extracted the data; TJ, OHN, and EVL analysed the data, interpreted the results, and drafted the manuscript; and T and OHN extracted the data. EVL is the guarantor. Allauthors read and approved the finalmanuscript.

Acknowledgements

This study received no externalfunding.

Author details

department of Gastroenterology, MedicalSection, Herlev Hospital, University of Copenhagen, Copenhagen, Denmark. 2Division of Gastroenterology & Hepatology, Mayo Clinic, Rochester, MN, USA. 3Department of Epidemiology Research, Statens Serum Institute, National Health Surveillance and Research, Copenhagen, Denmark.

Received: 27 November 2012 Accepted: 1 July 2013 Published: 31 July 2013

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doi:10.1186/1741 -7015-11-174

Cite this article as: Nielsen et al.: Safety of TNF-a inhibitors during IBD pregnancy: a systematic review. BMC Medicine 2013 11:174.

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