Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-27T03:19:34.884Z Has data issue: false hasContentIssue false

The health outcomes of human offspring conceived by assisted reproductive technologies (ART)

Published online by Cambridge University Press:  18 April 2017

M. Chen
Affiliation:
Shanghai First Maternity and Infant Hospital, Tongji University School of Medicine, Shanghai, China
L. K. Heilbronn*
Affiliation:
Discipline of Medicine, University of Adelaide, Adelaide, SA, Australia Research Centre for Reproductive Health, Robinson Research Institute, University of Adelaide, Adelaide, SA, Australia
*
*Address for correspondence: Dr L. Heilbronn, Level 7, Nutrition and Metabolism, SAHMRI, North Terrace, Adelaide, SA 5000, Australia. (Email leonie.heilbronn@adelaide.edu.au)
Rights & Permissions [Opens in a new window]

Abstract

Concerns have been raised about the health and development of children conceived by assisted reproductive technologies (ART) since 1978. Controversially, ART has been linked with adverse obstetric and perinatal outcomes, an increased risk of birth defects, cancers, and growth and development disorders. Emerging evidence suggests that ART treatment may also predispose individuals to an increased risk of chronic ageing related diseases such as obesity, type 2 diabetes and cardiovascular disease. This review will summarize the available evidence on the short-term and long-term health outcomes of ART singletons, as multiple pregnancies after multiple embryos transfer, are associated with low birth weight and preterm delivery, which can separately increase risk of adverse postnatal outcomes, and impact long-term health. We will also examine the potential factors that may contribute to these health risks, and discuss underlying mechanisms, including epigenetic changes that may occur during the preimplantation period and reprogram development in utero, and adult health, later in life. Lastly, this review will consider the future directions with the view to optimize the long-term health of ART children.

Type
Review
Copyright
© Cambridge University Press and the International Society for Developmental Origins of Health and Disease 2017 

Assisted reproduction technologies (ART)

ART are defined as all treatments or procedures for initiating pregnancy that include the in vitro handling of both oocytes and sperm or embryos, predominantly in vitro fertilization (IVF), intracytoplasmic sperm injection (ICSI), gamete and embryo cryopreservation, preimplantation genetic diagnosis and preimplantation genetic screening.Reference Zegers-Hochschild, Adamson and de Mouzon 1 Briefly, the routine IVF procedure includes three steps: ovarian hyperstimulation, IVF and embryo culture, and embryo transfer. First, high doses of gonadotropins are administrated to induce development of multiple follicles. Then, the oocytes are retrieved from the ovaries using a transvaginal ultrasound-guided fine needle and inseminated with the prepared sperm in vitro to achieve fertilization. Embryos are cultured in a prepared medium in the incubator for 3 days to reach the eight-cell stage or 5 days to develop to the blastocyst stage. Finally, the embryos are transferred into the uterus or frozen for future transfer. Although IVF is beneficial for most of infertile couples with female infertility, unexplained infertility and some cases of male infertility, ICSI in which a single spermatozoon is injected into the oocyte cytoplasm is required to treat severe male infertility.

Since 1978, more than 5 million children have been born by ART treatment, mostly by IVF and ICSI.Reference Ferraretti, Goossens and Kupka 2 Concerns about the potential health implications of ART remain.Reference Schieve, Rasmussen and Buck 3 , Reference Sutcliffe and Ludwig 4 Increasing evidence shows ART treatment is associated with adverse perinatal outcomes, which are related to subfertility of patients, multiple pregnancies and ART technologies.Reference Sutcliffe and Ludwig 4 Reference Basatemur and Sutcliffe 9 As it is well accepted that multiple pregnancies, after multiple embryos transfer, are associated with low birth weight and preterm delivery,Reference Hart and Norman 10 which can also impact long-term health risks, this review will limit its focus to the health outcomes of ART singletons born from IVF and ICSI v. singletons from natural conception.

Obstetric and perinatal outcome in ART singleton pregnancies

As summarized in Table 1, singleton pregnancies after ART are associated with adverse obstetric and perinatal outcome as compared with spontaneous conception.Reference Sutcliffe and Ludwig 4 , Reference Pinborg, Wennerholm and Romundstad 11 , Reference Henningsen, Pinborg and Lidegaard 12 These outcomes include an increased risk of low birth weight, preterm birth, small for gestational age, stillbirth, perinatal mortality, admission to a neonatal intensive care unit, antepartum haemorrhage, hypertensive disorders of pregnancy, preterm rupture of membranes, gestational diabetes, induction of labour and caesarean section.Reference Wisborg, Ingerslev and Henriksen 8 , Reference Pinborg, Wennerholm and Romundstad 11 Reference Buckett, Chian and Holzer 17 It should be noted that vanishing twin pregnancies, which contribute to about 10% of IVF singletons pregnancies, increase perinatal risk in IVF singletons.Reference Pinborg, Lidegaard and Freiesleben 18 , Reference Pinborg, Lidegaard and la Cour Freiesleben 19 However, whether the procedure of IVF itself, or the underlying parental characteristics or genetics are the main contributors to this increase in obstetric and perinatal risk is not clear. Some studies have shown that IVF singletons have an increased risk of adverse perinatal outcome v. their non-IVF siblings.Reference Pinborg, Wennerholm and Romundstad 11 However, other studies have shown that perinatal outcomes from spontaneous conception are also poorer in subfertile women v. those with normal fertility,Reference Basso and Baird 20 , Reference Zhu, Obel and Hammer Bech 21 and that perinatal outcomes are comparable after IVF or natural conception in subfertile women.Reference Raatikainen, Kuivasaari-Pirinen and Hippelainen 22 A large recent study using siblingship analysis suggested that maternal characteristics such as subfertility and maternal age but not IVF treatment are associated with lower birth weight in IVF children.Reference Seggers, Pontesilli and Ravelli 23 This discrepancy in the literature requires further study in larger cohorts that control for as many confounders as possible, and also further pre-clinical study. When investigating risk, the type of ART procedure is not always reported, and may contribute to adverse perinatal outcomes. A recent study shows that frozen embryo transfer increases pregnancy rates, improves obstetric and perinatal outcomes, and reduces the risk of ovarian hyperstimulation syndrome in patients with polycystic ovary syndrome.Reference Chen, Shi and Sun 24 A meta-analysis of 11 studies supports this, reporting that singletons born after the transfer of frozen thawed embryos had better obstetric and perinatal outcome as compared with those after the transfer of fresh IVF embryos.Reference Maheshwari, Pandey and Shetty 25 The relative risks (RR) and 95% confidence intervals (CI) of antepartum haemorrhage (RR=0.67, 95% CI, 0.55–0.81), preterm birth (RR=0.84, 95% CI, 0.78–0.90), small for gestational age (RR=0.45, 95% CI, 0.30–0.66), low birth weight (RR=0.69, 95% CI, 0.62–0.76) and perinatal mortality (RR=0.68, 95% CI, 0.48–0.96) were lower in women who received frozen embryos.Reference Maheshwari, Pandey and Shetty 25 The characteristics for each study was shown in the review.Reference Maheshwari, Pandey and Shetty 25 This data suggests that suboptimal endometrial development, induced by hormone stimulation, may be a contributor to poorer perinatal outcome after IVF.Reference Chung, Coutifaris and Chalian 7 , Reference Henningsen, Pinborg and Lidegaard 12 A recent retrospective cohort study suggests natural cycle IVF may decrease the risk of low birth weight v. conventional stimulated IVF,Reference Mak, Kondapalli and Celia 26 but this is not reported universally.Reference LaMarca and Polyzos 27 The length of embryo culture is emerging as another potential confounder when considering perinatal outcomes, but consideration may also be required as to whether sequential or single-step culture media is employed.Reference Wirleitner, Vanderzwalmen and Stecher 28 Increasing evidence suggests the type of culture medium may also impact birth weight in IVF singletons.Reference Vergouw, Kostelijk and Doejaaren 29 , Reference Dumoulin, Land and Van Montfoort 30 Although some studies show that blastocyst transfer is associated with a higher cumulative live birth and pregnancy rates,Reference Glujovsky, Farquhar and Quinteiro Retamar 31 a recent meta-analysis of six studies suggest that blastocyst transfer may increase the risk of preterm birth in IVF singleton pregnancies.Reference Dar, Lazer and Shah 32 Taken together, it seems that parental characteristics, and ART procedures themselves contribute to the adverse perinatal outcomes of singleton pregnancies after ART. Careful further studies are warranted to determine whether cleavage embryo transfer, sequential media with blastocyst transfer, minimal stimulation protocols or natural IVF improve obstetric and perinatal outcomes, and the long-term health outcomes of this on ART children.

Table 1 Obstetric and perinatal outcome in in vitro fertilization (IVF) singleton pregnancies

ICSI, intracytoplasmic sperm injection; CI, confidence intervals; ART, assisted reproductive technologies; aOR, adjusted odds ratio; OR, odds ratio.

Birth defects in ART singleton pregnancies

Major malformations were defined as those causing functional impairment or requiring surgical correction,Reference Bonduelle, Liebaers and Deketelaere 33 , Reference Bonduelle, Wilikens and Buysse 34 whereas the others were considered minor malformations. The prevalence of major birth defects such as chromosomal and musculoskeletal defects diagnosed by 1 year of age is two-fold higher in infants conceived by IVF or ICSI than in naturally conceived infants born between 1993 and 1997 in Western Australia.Reference Hansen, Kurinczuk and Bower 35 Importantly, this study controlled for parental factors such as maternal age and parity, the gender of the infant and correlation between siblings. In Israel, the percentage of major malformations in infants conceived by ART in 1986–1994 and 1995–2002 was also double that of the general population during the same periods.Reference Merlob, Sapir and Sulkes 36 Similar reports have been observed in Spain,Reference Gutarra-Vilchez, Santamarina-Rubio and Salvador 37 France,Reference Tararbit, Houyel and Bonnet 38 CanadaReference El-Chaar, Yang and Gao 39 and the United StatesReference Reefhuis, Honein and Schieve 40 , Reference Boulet, Kirby and Reefhuis 41 (summarized in Table 2).

Table 2 Birth defects in in vitro fertilization (IVF) singleton pregnancies

ICSI, intracytoplasmic sperm injection; CI, confidence intervals; ART, assisted reproductive technologies; aOR, adjusted odds ratio; OR, odds ratio; aRR, adjusted relative risks; IUI, intrauterine insemination.

Large meta-analyses have been conducted and show that children born after ART have a 30–40% increased risk of birth defects compared with spontaneous conceptions.Reference Rimm, Katayama and Diaz 42 Reference Qin, Sheng and Wang 47 However, it is not entirely clear if the contributing factor is the ART procedure, or the underlying infertility itself. One Italian study of >7000 infants born after ART or ovulation induction suggested the increased prevalence of birth defects associated with non-spontaneous conception was largely due to confounding factors such as maternal age,Reference Parazzini, Cipriani and Bulfoni 48 which is associated with poorer oocyte quality, mitochondrial dysfunction, aneuploidy and epigenetic alteration.Reference Ge, Schatten and Zhang 49 A large Danish longitudinal study found singletons born of infertile couples who conceived naturally (time to pregnancy >12 months) or after infertility treatment including different types of ART or surgeries had a higher prevalence of congenital malformations compared with singletons born of fertile couples (time to pregnancy ⩽12 months).Reference Zhu, Basso and Obel 50 Notably, the prevalence of congenital malformations increased with increasing time to pregnancy, suggesting that infertility per se was an independent risk factor. On the other hand, amongst infertile couples, infertility treatment was associated with an increased prevalence of genital organ malformations in singletons compared with natural conception.Reference Zhu, Basso and Obel 50 Further, Davies et al.Reference Davies, Moore and Willson 15 compared risks of birth defects among pregnancies in women who received ART treatment, spontaneous pregnancies in women who had a previous birth with assisted conception and spontaneous pregnancies in women with or without a record of infertility. An increased risk of birth defects was significantly associated with infertility per se, independently of assisted conception. An increased risk of birth defects was also associated with assisted conception after the multivariate adjustment, however, this association was only observed in births conceived by ICSI but not by IVF, after adjustments.Reference Davies, Moore and Willson 15 In comparison, two meta-analysis reported the risk of birth defect was not significantly different between children conceived by IVF and ICSI.Reference Wen, Jiang and Ding 45 , Reference Massaro, MacLellan and Anderson 51

Ovulation induction alone has also been associated with increased risk of birth defects.Reference El-Chaar, Yang and Gao 39 , Reference Klemetti, Gissler and Sevon 52 Evidence shows that exogenous gonadotrophins may impair oocyte and embryo development as well as endometrial receptivity, increase chromosomal aneuploidy, alter epigenetic modifications, thus have detrimental effects on perinatal outcomes and long-term health.Reference Santos, Kuijk and Macklon 53 , Reference Vialard, Boitrelle and Molina-Gomes 54 In Finland, ART singleton girls from ovulation induction had more major heart anomalies than controls conceived naturally.Reference Klemetti, Gissler and Sevon 52 Similarly, the risks of birth defects were higher in ovulation induction v. natural conception, whereas the risk was even higher in IVF v. ovulation induction.Reference El-Chaar, Yang and Gao 39 Taken together, this data suggest that singletons conceived by ART procedures are at increased risk for birth defects. This is at least partly due to the underlying infertility, and parental characteristics, but may be further increased by ovulation induction and ART procedures.

Growth and development in ART singleton pregnancies

A number of studies have examined the growth patterns of ART children with conflicting resultsReference Wennerholm, Albertsson-Wikland and Bergh 55 Reference Olivennes, Kerbrat and Rufat 69 (summarized in Table 3). The majority of studies have not observed any differences in the growth of ART children v. naturally conceived children. For instance, recent prospective follow-up studies in the United States compared 969 singletons conceived by infertility treatment including ART and ovulation induction with or without intrauterine insemination with 2471 singletons conceived naturally, and found the growth and development of children up to 3 years of age was comparable.Reference Yeung, Sundaram and Bell 60 , Reference Yeung, Sundaram and Bell 70 Similar findings have been observed in ART children v. the general population up to 13 years of age in European countries.Reference Bonduelle, Wennerholm and Loft 61 , Reference Basatemur, Shevlin and Sutcliffe 62 , Reference Olivennes, Kerbrat and Rufat 69 A study in the United States also reported IVF young adults exhibited normal pubertal development.Reference Beydoun, Sicignano and Beydoun 71 A handful of studies have found ART children had impairedReference Kai, Main and Andersen 63 , Reference Koivurova, Hartikainen and Sovio 64 or enhanced childhood growth.Reference Miles, Hofman and Peek 65 Reference Green, Mouat and Miles 67 Notably, some studies recruited children born prematurely, small for gestational age, with low birth weight or from multiple pregnancies, which may confound the results and few of these studies have controlled for subfertility. Ceelen et al. examined the growth data from birth to 4 years of age in a small follow-up study that included 233 IVF children aged 8–18 years and 233 spontaneously conceived controls born to subfertile parents. They showed IVF children had significantly lower weight, height and BMI standard deviation scores (SDSs) at 3 months, and weight SDS at 6 months of age compared with controls. IVF children demonstrated a catch-up growth during late infancy (3 months to 1 year) v. controls, such that no differences were observed in weight, height and BMI after 1 year of age between groups.Reference Ceelen, van Weissenbruch and Prein 68 This is a small study, but potentially of concern, given evidence that rapid catch-up growth is associated with increased risk of disease later in life.Reference Ong and Loos 72 , Reference Ekelund, Ong and Linne 73

Table 3 Growth and development in assisted reproductive technologies (ART) singleton pregnancies

IVF, in vitro fertilization; ICSI, intracytoplasmic sperm injection; aOR, adjusted odds ratio; OR, odds ratio; IGF, insulin-like growth factor; BMI, body mass index.

A meta-analysis including four studies in singletons reported an increased risk of cerebral palsy for IVF children v. those conceived naturally.Reference Hvidtjorn, Schieve and Schendel 74 This risk may be largely due to multiple births, low birth weight and preterm births among ART children.Reference Ericson, Nygren and Olausson 75 Reference Zhu, Hvidtjorn and Basso 80 In Australia, an increased risk of cerebral palsy was observed in ART infants overall and for ART singletons, even after adjusting for parental and fetal factors.Reference Davies, Moore and Willson 15 Similarly, Zhu et al.Reference Zhu, Hvidtjorn and Basso 80 found that ART infants had an increased risk of cerebral palsy after controlling for preterm birth and multiplicity, and there was no association between parental subfertility and the risk of cerebral palsy, indicating that the increased risk of cerebral palsy for ART infants was due to the effect of ART treatment.

No differences were observed in the cognitive and motor development in large cohort studies between ART children and controls examined at 3 or 5 years of age who were recruited in Europe,Reference Ponjaert-Kristoffersen, Bonduelle and Barnes 81 Great BritainReference Carson, Kurinczuk and Sacker 82 , Reference Carson, Kelly and Kurinczuk 83 or the United States.Reference Yeung, Sundaram and Bell 70 Similarly, a systematic review of 59 studies reported that children born following ART are not at increased risk of severe cognitive impairment compared with naturally conceived children.Reference Middelburg, Heineman and Bos 84 There is also no increased risk of autism in singletons conceived by ART,Reference Grether, Qian and Croughan 85 Reference Lyall, Baker and Hertz-Picciotto 88 but studies including IVF multiple births and autism spectrum disorders have shown conflicting results.Reference Grether, Qian and Croughan 85 , Reference Lehti, Brown and Gissler 87 In contrast, Kissin et al.Reference Kissin, Zhang and Boulet 89 found that the incidence of autism diagnosis in ART-conceived children during the first 5 years of life was higher when ICSI was used compared with IVF. Notably, Belva et al. showed that 54 ICSI-conceived adults had significantly lower sperm concentration, lower total sperm count as well as lower total motile sperm count but comparable mean levels of follicle-stimulating hormone, luteinizing hormone, testosterone and inhibin B in comparison to 57 spontaneously conceived peers, possibly reflecting inherited fertility problems.Reference Belva, Bonduelle and Roelants 90 , Reference Belva, Roelants and De Schepper 91 Taken together, the available data on the growth and development of ART children is generally reassuring, although an increased risk of cerebral palsy has been observed. This needs to be confirmed in large studies focussing on ART singletons born at term with normal birth weight. In addition, more follow-up studies in adults are warranted to determine if ART is associated with increased risk of impaired cognitive development and psychological adjustment, later in life.

Cancer risk in ART singleton pregnancies

Concerns are turning towards the longer-term health implications of IVF. A number of studies have been undertaken to examine the cancer risk of children conceived by ART procedures (summarized in Table 4). Most of the earlier studies demonstrate that ART procedures are not associated with increased risk of cancers.Reference Bruinsma, Venn and Lancaster 92 Reference Lerner-Geva, Toren and Chetrit 95 For instance, one data linkage study that included 3528 ART singletons with a median follow-up period of 4 years showed that ART children did not have a significantly increased incidence of cancer.Reference Bruinsma, Venn and Lancaster 92 Similar results have been noted in the Netherlands over an average follow-up period of 6 yearsReference Klip, Burger and de Kraker 93 and in a meta-analysis of 11 cohort studies.Reference Raimondi, Pedotti and Taioli 96

Table 4 Cancer risk in assisted reproductive technologies (ART) singleton pregnancies

IVF, in vitro fertilization; HR, hazard ratio.

In the last decade, more studies have reported an increased risk of certain cancers in ART children. In Sweden, although there was no overall increase in cancer risk in >16,000 ART children compared with naturally conceived children, more cases of Langerhans histiocytosis were reported.Reference Kallen, Finnstrom and Nygren 97 After 5 years, the same group reported a moderately increased risk for all cancers in 26,692 children conceived by ART during the years 1982–2005.Reference Kallen, Finnstrom and Lindam 98 Notably, the increased cancer risk was associated with high birth weight, premature delivery and the presence of respiratory diagnoses as well as low Apgar score.Reference Kallen, Finnstrom and Lindam 98 A large retrospective Nordic population-based cohort study found ART children had an increased risk for central nervous system tumours and malignant epithelial neoplasms v. children born spontaneously between 1982 and 2007.Reference Sundh, Henningsen and Kallen 99 This cohort was matched for parity, year of birth and country, and controlled for maternal age, sex, gestational age and birth defects.Reference Sundh, Henningsen and Kallen 99 Similarly, ART was associated with an increased risk of hepatoblastoma and rhabdomyosarcoma, but not the overall risk of cancer in the United Kingdom.Reference Williams, Bunch and Stiller 100 This study also controlled for confounding factors such as sex, age at diagnosis, birth weight, singleton v. multiple birth, parity, parental age, type of assisted conception and cause of parental infertility. A meta-analysis, published in 2013, that included 25 cohort and case-control studies reported that children born after ART are at increased risk for all cancers (RR=1.33; 95% CI, 1.08–1.63), and specifically for leukaemias (RR=1.65; 95% CI, 1.35–2.01), neuroblastomas (RR=4.04; 95% CI, 1.24–13.18) and retinoblastomas (RR=1.62; 95% CI, 1.12–2.35). It should be noted that the majority of these studies did not control for confounders such as socioeconomic status, maternal smoking and perinatal health status, which may affect incidence.Reference Kallen, Finnstrom and Lindam 98 , Reference Schmidt, Schuz and Lahteenmaki 101 Further, it is unclear that whether the increased risk for cancers is related to underlying subfertility of the parent, or the ART procedure itself.Reference Hargreave, Jensen and Toender 102 More follow-up studies are needed to determine risk in children, as well as later in life.

Does ART increase the risk of chronic disease?

The long-term health implications of IVF are under-studied. Over the past decade, speculation is increasing that individuals conceived by ART may be at risk of developing metabolic syndrome, type 2 diabetes and cardiovascular disease, later in life.Reference Ceelen 103 Reference Chen, Wu and Zhao 107 To date these studies are small, and this evidence is not conclusive (summarized in Table 5). Discrepancies between studies may be due to differences in the ages investigated, study period, inclusion criteria of subjects, sample size, sampling of the comparison group, dietary intake and/or parental characteristics, as well as the ART technique employed. Ceelen et al. Reference Ceelen 103 reported an increase in body fat as assessed by skinfold thickness in IVF children who were matched for BMI. Post-pubertal IVF children in this study also had a trend towards increased body fat assessed by Dual-energy X-ray absorptiometry (DXA). Importantly, the control group studied were children who were born to subfertile parents and controlled for current size, birth weight, gestational age and parental characteristics.Reference Ceelen 103 Belva et al. reported pubertal ICSI singleton girls had increased central, peripheral and total adiposity assessed by circumferences, skinfolds and BMI, respectively, compared with naturally conceived controls. Furthermore, increased peripheral adiposity was observed in ICSI adolescent singleton boys with advanced pubertal stages v. controls.Reference Belva, Painter and Bonduelle 108 Conversely, one study reported no difference in fat percentage by DXA between IVF children and controls at 4–10 years of age.Reference Miles, Hofman and Peek 65 More studies in ART adults are required to assess the obesity incidence and the amount of liver and visceral fat which is clearly associated with increased risk of type 2 diabetes and cardiovascular diseases.Reference van Harmelen, Eriksson and Astrom 109

Table 5 Metabolic risk in assisted reproductive technologies (ART) singleton pregnancies

IVF, in vitro fertilization; ICSI, intracytoplasmic sperm injection

There is some suggestion that ART may also impair glucose metabolism in the offspring, potentially as a result of increased adiposity. Ceelen et al.Reference Ceelen, van Weissenbruch and Roos 104 reported IVF adolescents had elevated fasting glucose levels compared with controls, irrespective of any early life factors or parental characteristics. However, there was no significant difference in fasting insulin levels, and insulin sensitivity as measured by the homeostasis assessment model. Another study reported fasting glucose levels were higher among children aged 5–6 years old conceived through ovulation induction and ART compared with naturally conceived children from fertile couples.Reference Pontesilli, Painter and Grooten 110 Conversely,Reference Sakka, Loutradis and Kanaka-Gantenbein 105 there was no difference in weight, glucose, insulin, leptin, adiponectin, interleukin-6 or C-reactive protein in IVF children and controls. However, this study may be confounded by neonatal and parental factors. Another study reported IVF children were taller with significantly higher IGF1 serum levels.Reference Miles, Hofman and Peek 65 Reduced peripheral insulin sensitivity was also observed in a small cohort of IVF young adults by using gold standard assessment hyperinsulinemic-euglycemic clamp, without any significant differences in fasting glucose or insulin levels compared with naturally conceived young adults.Reference Chen, Wu and Zhao 107 However, only 14 IVF young adults were studied.

A number of studies suggest that ART may increase the risk of cardiovascular diseases. Celeen et al.Reference Ceelen, van Weissenbruch and Roos 104 reported that systolic and diastolic blood pressure levels were elevated in IVF children v. children conceived naturally from subfertile couples, after controlling for early life factors and parental characteristics. Sakka et al.Reference Sakka, Loutradis and Kanaka-Gantenbein 105 also reported that children born by IVF had significantly higher systolic and diastolic blood pressure than controls. Elevations in blood pressure in IVF conceived individuals are not universally detected.Reference Belva, Roelants and De Schepper 111

There is evidence that the process of ovarian induction may be a contributing factor to increases in blood pressure since systolic blood pressure and subscapular skinfold thickness were elevated in IVF children v. children conceived by natural IVF (without ovarian stimulation) and subfertile couples who conceived naturally.Reference Seggers and Haadsma 112 Blood pressure was also higher in children born to subfertile v. fertile couples.Reference Pontesilli, Painter and Grooten 110 In a more detailed investigationReference Scherrer, Rimoldi and Rexhaj 106 ART children displayed systemic and pulmonary vascular dysfunction, that could not be explained by subfertility or ovulation stimulation because vascular function was not altered in children conceived naturally after ovulation stimulation and in siblings of ART children who were conceived naturally.Reference Sakka, Margeli and Loutradis 113 Further, another group conducted a prospective cohort study and found signs of cardiovascular remodelling in ART fetuses, and ART infants as compared with controls conceived spontaneously.Reference Valenzuela-Alcaraz, Crispi and Bijnens 114 Right ventricular dysfunction has also been detected in children and adolescents conceived by ART.Reference von Arx, Allemann and Sartori 115 Taken together, ART treatment, ovulation induction and subfertility may all contribute to adverse cardiovascular outcome in childhood,Reference Pontesilli, Painter and Grooten 110 and further pre-clinical studies are necessary to resolve some of the discrepancies reported, as these enable better control of the confounding factors.

Few studies have examined the effects of ART on lipid metabolism. Sakka et al. Reference Sakka, Loutradis and Kanaka-Gantenbein 105 found that IVF children had significantly higher triglycerides, without differences in total cholesterol, high-density lipoprotein (HDL), low-density lipoprotein, uric acid, apolipoprotein-A1, apolipoprotein-B or lipoprotein(a) values.Reference Sakka, Loutradis and Kanaka-Gantenbein 105 Conversely, a group in New ZealandReference Miles, Hofman and Peek 65 , Reference Green, Mouat and Miles 67 found more favourable lipid profiles in a prepubertal IVF children with higher HDL levels and lower triglyceride levels than in controls. More prospective follow-up studies in ART adults are required to determine if ART treatment alters lipid profiles in the offspring.

ART may also alter thyroid function. Sakka et al.Reference Sakka, Malamitsi-Puchner and Loutradis 116 reported thyroid-stimulating hormone (TSH) levels were significantly higher in 106 IVF children v. 68 naturally conceived children aged 4–14 years. Seven IVF children, but no controls also had subclinical primary hypothyroidism. It is of note that four of these children were born prematurely with low birth weight, although statistically TSH levels was not associated with birth weight and gestational ages. Similarly, subclinical hypothyroidism was observed in 2–4-week-old IVF infants, born at term.Reference Onal, Ercan and Adal 117 A cross-sectional study in China found that the levels of thyroid hormones including T4, FT4 and TSH were significantly increased in singleton IVF v. naturally conceived newborns and children aged 3–10 years old. Notably, the levels of T4 and FT4 of IVF children positively correlated with maternal serum levels of oestradiol during the first trimester of pregnancy.Reference Lv, Meng and Lv 118 Further, no statistical difference was observed between IVF children born from frozen embryo transfer and naturally conceived individuals.Reference Lv, Meng and Lv 118 This suggests that a high oestradiol maternal environment, resulting from ovarian stimulation, may increase the risk of thyroid dysfunction in offspring born following IVF. Further study is necessary.

How does ART increase the risk of adverse outcome?

In humans, it is difficult to separate out the effects of ART procedures themselves with the underlying subfertility, paternal characteristics as well as postnatal environmental exposure. Furthermore, if increases in risk are the result of ART techniques, which of these processes increase risk? Animal models suggest that ART procedures contribute to altered fetal and placental growth and development.Reference Bloise, Feuer and Rinaudo 119 The developmental origins of health and disease hypothesisReference Barker 120 proposes that suboptimal periconceptional and perinatal environment can impair fetal and postnatal growth, followed by catch-up growth, predisposes offspring to increased risk of developing hypertension, obesity, type 2 diabetes and coronary heart disease in later life.Reference Eriksson, Forsen and Tuomilehto 121 Reference Forsen, Eriksson and Tuomilehto 123 Epigenetic is likely to be the reprogramming mechanism, but there may be other contributing factors including transcription changes, oxidative stress and mitochondrial dysfunction, and endoplasmic reticulum stress as reviewed elsewhere.Reference Rinaudo and Wang 124

Epigenetics is defined as heritable changes in gene expression without alterations in DNA sequence.Reference Waddington 125 Epigenetic modifications, including DNA methylation, histone modifications, micro-RNAs and higher-order packaging of DNA around nucleosomes, regulate the temporal and spatial gene expression patterns and are essential in embryonic, fetal and postnatal development.Reference Le Bouc, Rossignol and Azzi 126 DNA methylation is the most widely studied epigenetic mechanism and occurs through the enzymatic addition of a methyl group to the carbon-5 position of the cytosine of the cytosine–phosphate–guanine dinucleotide sequence. The methyl group interferes with the binding of particular transcription factors to DNA and attracts methyl-binding proteins that also regulate transcriptional repression.Reference Swales and Spears 127 Hence, gene expression is generally inhibited by DNA methylation, but is activated by DNA demethylation.Reference Dennis 128 DNA methylation also contributes to the preservation of chromosomal integrity and the inactivation of X-chromosome.Reference Laprise 129 There are two waves of DNA methylation and demethylation during gametogenesis and early preimplantation,Reference Reik and Walter 130 thus periconceptual manipulation of oocyte or blastocyst during IVF and ICSI treatment may impair the establishment of the DNA methylation in gametes and/or with the maintenance of DNA methylation within preimplantation embryos.Reference Laprise 129

In humans, there is evidence that ART procedures may alter epigenetic modifications during the preimplantation period of development. A high frequency of imprinted methylation errors was observed in ART human preimplantation embryos.Reference White, Denomme and Tekpetey 131 Altered DNA methylation and/or gene expression of a number of genes in the fetus, cord blood, placenta, neonatal bloodspots and buccal cell have been reported in ART children.Reference Katari, Turan and Bibikova 132 Reference Gomes, Huber and Ferriani 139 Notably, some of these genes whose expression altered by ART have been implicated in imprinting diseases and metabolic disorders such as obesity and type 2 diabetes. Song et al.Reference Song, Ghosh and Mainigi 133 showed ART itself results in significant differences in placental DNA methylation levels by using donor oocyte from fertile young women compared with fertile control groups. Another study suggests DNA methylation levels of 23 genes can explain around 80% of the variance in infant birth weight and six of these are associated with growth phenotypes in human or mouse models.Reference Turan, Ghalwash and Katari 140 Therefore, altered DNA methylation in ART offspring may contributes to low birth weight which is a marker of impaired fetal growth and adverse long-term health outcomes.

Animal models also support that ART alters epigenetic modifications in preimplantation embryos and offspring, thereby altering embryonic growth, fetal and placental growth, growth trajectory, increases risk of metabolic and cardiovascular diseases later in life, and shortens lifespan.Reference Chen, Wu and Zhao 107 , Reference Chen, Sun and Huang 141 Reference Rexhaj, Paoloni-Giacobino and Rimoldi 149 Metabolic profiling in mice serum and microarray analysis of pancreatic islets and insulin-sensitive tissues (liver, skeletal muscle and adipose tissue) indicated systemic oxidative stress and mitochondrial dysfunction, which is associated with increased expression of thioredoxin-interacting protein (TXNIP) and enrichment for H4 acetylation at the Txnip promoter in blastocysts and adipose tissue in adult mice.Reference Feuer, Liu and Donjacour 148 As TXNIP plays an important role in regulating peripheral glucose metabolism and integrating cellular nutritional and oxidative states with metabolic response, the data suggest that IVF results in epigenetic and gene expression changes in blastocysts that persist in adulthood.Reference Feuer, Liu and Donjacour 148 Rexhaj et al.Reference Rexhaj, Paoloni-Giacobino and Rimoldi 149 reported that ART mice offspring show endothelial dysfunction, increased arterial stiffness and arterial hypertension as well as shortened life span fed with a high-fat diet. Moreover, male ART mice transmit vascular dysfunction to their progeny and the methylation of imprinted genes such as H19 in the aorta is altered in ART mice and their progeny. Further, ART mice display increased DNA methylation of the promoter of the eNOS gene, decreased eNOS expression in the aorta and decreased plasma nitric oxide concentration. Importantly, all these alterations can be normalized by administration of the deacetylase inhibitor butyrate or addition of antioxidant melatonin to culture media, suggesting that altered epigenetic modification by ART causes vascular dysfunction in mice.Reference Rexhaj, Paoloni-Giacobino and Rimoldi 149 , Reference Rexhaj, Pireva and Paoloni-Giacobino 150

Placenta plays an important role in fetal development by transporting nutrients and oxygen, adapting morphologically and functionally to adverse environmental stress and minimizing their impact on the fetus.Reference Burton, Fowden and Thornburg 151 , Reference Sferruzzi-Perri and Camm 152 Placenta size can predict cardiovascular diseases and insulin resistance.Reference Barker, Bull and Osmond 153 , Reference Eriksson, Kajantie and Thornburg 154 ART may also impair placental development and function and thus fetal growth in utero.Reference Chen, Sun and Huang 141 , Reference Li, Chen and Tang 142 , Reference de Waal, Vrooman and Fischer 155 , Reference Bloise, Lin and Liu 156 Increased placental thickness and placental haematomas as well as pathological findings were reported in ART pregnancies.Reference Lalosevic, Tabs and Krnojelac 157 Reference Zhang, Zhao and Jiang 159 IVF impairs placental nutrient transport and metabolism in mice.Reference Chen, Sun and Huang 141 , Reference Tan, Zhang and Miao 144 , Reference Bloise, Lin and Liu 156 Placental weight and placental:fetal weight ratio was significantly higher in ART pregnancies than in naturally conceived pregnancies in humans and mouse models.Reference Bloise, Feuer and Rinaudo 119 , Reference de Waal, Vrooman and Fischer 155 , Reference Bloise, Lin and Liu 156 , Reference Daniel, Schreiber and Geva 160 , Reference Haavaldsen, Tanbo and Eskild 161 This was associated with reduced methylation levels and altered genomic imprinting and developmental gene expression by ART treatment in the placenta in mice and humans.Reference Katari, Turan and Bibikova 132 , Reference Turan, Katari and Gerson 138 , Reference Chen, Sun and Huang 141 , Reference Li, Chen and Tang 142 , Reference Tan, Zhang and Miao 144 , Reference de Waal, Vrooman and Fischer 155 These altered DNA methylation levels may impair a number of biological processes and functions during IVF placentation, including actin cytoskeleton organization, haematopoiesis, placental growth and vascularization, energy metabolism and nutrient transport.Reference Tan, Zhang and Miao 144 , Reference Choux, Carmignac and Bruno 162 Improper adaptive responses of placenta throughout pregnancy may result in adverse outcomes such as abortion, preeclampsia or intra-uterine growth restriction.Reference Choux, Carmignac and Bruno 162 Although successful placental adaptation leads to normal progress of the pregnancy, the memory of epigenetic adaptation mechanisms established during pregnancy increases the risk of developing metabolic diseases later in life.Reference Choux, Carmignac and Bruno 162 Taken together, impaired placental function and development due to altered DNA methylation may play a key role underlying the adverse outcomes in ART offspring. However, more studies are needed to examine whether other epigenetic mechanisms such as histone modifications and micro-RNAs during the development of preimplantation embryos are altered by ART.

Future directions to improve health of ART children

The perinatal outcomes in children born after ART have improved over time, mainly as a result of single embryo transfer and frozen thaw embryo transfer.Reference Henningsen, Gissler and Skjaerven 163 , Reference Hansen and Bower 164 As already practiced in many countries, single embryo transfer clearly reduces many of the risks associated with ART procedures, including improved perinatal outcomes, without compromizing live birth rates.Reference Hodgson and Wong 165 , Reference Pandian, Marjoribanks and Ozturk 166 The impact of hormone stimulation on perinatal and longer-term outcomes is under increasing scrutiny. The available evidence indicates that frozen embryo transfer may improve outcomes for both patients, and especially women with polycystic ovary syndrome and infants.Reference Chen, Shi and Sun 24 , Reference Evans, Hannan and Edgell 167 However, large well-controlled trials to determine if freeze-all protocols have benefits to the general infertile population and the later metabolic health in ART children are still needed. Further pre-clinical and large epidemiological studies from around the globe, that collect data to control for as many potential confounders as possible, are needed to compare ART techniques including frozen embryo transfer, stimulated v. unstimulated IVF cycles and the embryo culture lengths for not only the optimal perinatal outcomes, but for long-term health.

Conclusion

Concerns remain over the health and development of ART babies. Multiple pregnancies, due to multiple embryo transfer, increase the health risks, but ART singletons are also at increased risk of adverse obstetric and perinatal outcomes, increased risk for birth defects as compared with singletons conceived spontaneously. Further studies are needed to confirm if ART singletons have an increased risk of cancers, and cerebral palsy. Although accumulating data suggests that individuals conceived by ART may also have an increased risk of ageing-related chronic metabolic disorders, the evidence to date is obtained from pre-clinical studies, or small human cohorts. Thus large scale, well-controlled epidemiological studies are necessary. Greater work is also necessary to identify whether the increase in obstetric, perinatal and health impacts observed in ART children are the direct result of the ART procedure itself, or a result of the underlying subfertility of the parents. Although evidence suggests that altered DNA methylation and impaired placental development may contribute to the adverse outcomes in ART children, more studies are needed to examine whether altered epigenetic regulations are the underlying mechanism or the consequence of aberrant embryo development. As genetics and many parental characteristics cannot be altered, careful further study to identify the optimal ART procedures that maximize both perinatal and long-term health outcomes are necessary.

Acknowledgement

None.

Financial Support

LKH is supported by Australia Research Council Futures Fellowship.

Conflicts of Interest

None.

References

1. Zegers-Hochschild, F, Adamson, GD, de Mouzon, J, et al. The International Committee for Monitoring Assisted Reproductive Technology (ICMART) and the World Health Organization (WHO) revised glossary on ART terminology, 2009. Hum Reprod. 2009; 24, 26832687.Google Scholar
2. Ferraretti, AP, Goossens, V, Kupka, M, et al. Assisted reproductive technology in Europe, 2009: results generated from European registers by ESHRE. Hum Reprod. 2013; 28, 23182331.Google Scholar
3. Schieve, LA, Rasmussen, SA, Buck, GM, et al. Are children born after assisted reproductive technology at increased risk for adverse health outcomes? Obstet Gynecol. 2004; 103, 11541163.CrossRefGoogle ScholarPubMed
4. Sutcliffe, AG, Ludwig, M. Outcome of assisted reproduction. Lancet. 2007; 370, 351359.Google Scholar
5. Allen, VM, Wilson, RD, Cheung, A. Pregnancy outcomes after assisted reproductive technology. J Obstet Gynaecol Can. 2006; 28, 220250.Google Scholar
6. Ludwig, AK, Sutcliffe, AG, Diedrich, K, et al. Post-neonatal health and development of children born after assisted reproduction: a systematic review of controlled studies. Eur J Obstet Gynecol Reprod Biol. 2006; 127, 325.Google Scholar
7. Chung, K, Coutifaris, C, Chalian, R, et al. Factors influencing adverse perinatal outcomes in pregnancies achieved through use of in vitro fertilization. Fertil Steril. 2006; 86, 16341641.CrossRefGoogle ScholarPubMed
8. Wisborg, K, Ingerslev, HJ, Henriksen, TB. IVF and stillbirth: a prospective follow-up study. Hum Reprod. 2010; 25, 13121316.Google Scholar
9. Basatemur, E, Sutcliffe, A. Follow-up of children born after ART. Placenta. 2008; 29(Suppl. B), 135140.CrossRefGoogle ScholarPubMed
10. Hart, R, Norman, RJ. The longer-term health outcomes for children born as a result of IVF treatment: part I – general health outcomes. Hum Reprod Update. 2013; 19, 232243.Google Scholar
11. Pinborg, A, Wennerholm, UB, Romundstad, LB, et al. Why do singletons conceived after assisted reproduction technology have adverse perinatal outcome? Systematic review and meta-analysis. Hum Reprod Update. 2013; 19, 87104.CrossRefGoogle ScholarPubMed
12. Henningsen, AK, Pinborg, A, Lidegaard, O, et al. Perinatal outcome of singleton siblings born after assisted reproductive technology and spontaneous conception: Danish national sibling-cohort study. Fertil Steril. 2011; 95, 959963.Google Scholar
13. Pandey, S, Shetty, A, Hamilton, M, et al. Obstetric and perinatal outcomes in singleton pregnancies resulting from IVF/ICSI: a systematic review and meta-analysis. Hum Reprod Update. 2012; 18, 485503.CrossRefGoogle ScholarPubMed
14. Helmerhorst, FM, Perquin, DA, Donker, D, et al. Perinatal outcome of singletons and twins after assisted conception: a systematic review of controlled studies. BMJ. 2004; 328, 261.CrossRefGoogle Scholar
15. Davies, MJ, Moore, VM, Willson, KJ, et al. Reproductive technologies and the risk of birth defects. N Engl J Med. 2012; 366, 18031813.Google Scholar
16. McDonald, SD, Han, Z, Mulla, S, et al. Preterm birth and low birth weight among in vitro fertilization singletons: a systematic review and meta-analyses. Eur J Obstet Gynecol Reprod Biol. 2009; 146, 138148.Google Scholar
17. Buckett, WM, Chian, RC, Holzer, H, et al. Obstetric outcomes and congenital abnormalities after in vitro maturation, in vitro fertilization, and intracytoplasmic sperm injection. Obstet Gynecol. 2007; 110, 885891.Google Scholar
18. Pinborg, A, Lidegaard, O, Freiesleben, N, et al. Vanishing twins: a predictor of small-for-gestational age in IVF singletons. Hum Reprod. 2007; 22, 27072714.Google Scholar
19. Pinborg, A, Lidegaard, O, la Cour Freiesleben, N, et al. Consequences of vanishing twins in IVF/ICSI pregnancies. Hum Reprod. 2005; 20, 28212829.CrossRefGoogle ScholarPubMed
20. Basso, O, Baird, DD. Infertility and preterm delivery, birthweight, and caesarean section: a study within the Danish National Birth Cohort. Hum Reprod. 2003; 18, 24782484.Google Scholar
21. Zhu, JL, Obel, C, Hammer Bech, B, et al. Infertility, infertility treatment, and fetal growth restriction. Obstet Gynecol. 2007; 110, 13261334.Google Scholar
22. Raatikainen, K, Kuivasaari-Pirinen, P, Hippelainen, M, et al. Comparison of the pregnancy outcomes of subfertile women after infertility treatment and in naturally conceived pregnancies. Hum Reprod. 2012; 27, 11621169.Google Scholar
23. Seggers, J, Pontesilli, M, Ravelli, AC, et al. Effects of in vitro fertilization and maternal characteristics on perinatal outcomes: a population-based study using siblings. Fertil Steril. 2016; 105, 590598.e2.Google Scholar
24. Chen, ZJ, Shi, Y, Sun, Y, et al. Fresh versus frozen embryos for infertility in the polycystic ovary syndrome. N Engl J Med. 2016; 375, 523533.Google Scholar
25. Maheshwari, A, Pandey, S, Shetty, A, et al. Obstetric and perinatal outcomes in singleton pregnancies resulting from the transfer of frozen thawed versus fresh embryos generated through in vitro fertilization treatment: a systematic review and meta-analysis. Fertil Steril. 2012; 98, 368377.e1-9.Google Scholar
26. Mak, W, Kondapalli, LA, Celia, G, et al. Natural cycle IVF reduces the risk of low birthweight infants compared with conventional stimulated IVF. Hum Reprod. 2016; 31, 789794.Google Scholar
27. Sunkara SK, LaMarca, A, Polyzos, NP, et al. Live birth and perinatal outcomes following stimulated and unstimulated IVF: analysis of over two decades of a nationwide data. Hum Reprod, 2016.CrossRefGoogle Scholar
28. Wirleitner, B, Vanderzwalmen, P, Stecher, A, et al. Individual demands of human embryos on IVF culture medium: influence on blastocyst development and pregnancy outcome. Reprod BioMed Online. 2010; 21, 776782.Google Scholar
29. Vergouw, CG, Kostelijk, EH, Doejaaren, E, et al. The influence of the type of embryo culture medium on neonatal birthweight after single embryo transfer in IVF. Hum Reprod. 2012; 27, 26192626.Google Scholar
30. Dumoulin, JC, Land, JA, Van Montfoort, AP, et al. Effect of in vitro culture of human embryos on birthweight of newborns. Hum Reprod. 2010; 25, 605612.CrossRefGoogle ScholarPubMed
31. Glujovsky, D, Farquhar, C, Quinteiro Retamar, AM, et al. Cleavage stage versus blastocyst stage embryo transfer in assisted reproductive technology. Cochrane Database Syst Rev. 2016; (6), CD002118.Google Scholar
32. Dar, S, Lazer, T, Shah, PS, et al. Neonatal outcomes among singleton births after blastocyst versus cleavage stage embryo transfer: a systematic review and meta-analysis. Hum Reprod Update. 2014; 20, 439448.Google Scholar
33. Bonduelle, M, Liebaers, I, Deketelaere, V, et al. Neonatal data on a cohort of 2889 infants born after ICSI (1991-1999) and of 2995 infants born after IVF (1983-1999). Hum Reprod. 2002; 17, 671694.Google Scholar
34. Bonduelle, M, Wilikens, A, Buysse, A, et al. Prospective follow-up study of 877 children born after intracytoplasmic sperm injection (ICSI), with ejaculated epididymal and testicular spermatozoa and after replacement of cryopreserved embryos obtained after ICSI. Hum Reprod. 1996; 11(Suppl. 4), 131155, discussion 156-9.Google Scholar
35. Hansen, M, Kurinczuk, JJ, Bower, C, et al. The risk of major birth defects after intracytoplasmic sperm injection and in vitro fertilization. N Engl J Med. 2002; 346, 725730.Google Scholar
36. Merlob, P, Sapir, O, Sulkes, J, et al. The prevalence of major congenital malformations during two periods of time, 1986-1994 and 1995-2002 in newborns conceived by assisted reproduction technology. Eur J Med Genet. 2005; 48, 511.Google Scholar
37. Gutarra-Vilchez, R, Santamarina-Rubio, E, Salvador, J, et al. Birth defects in medically assisted reproduction pregnancies in the city of Barcelona. Prenat Diagn. 2014; 34, 327334.Google Scholar
38. Tararbit, K, Houyel, L, Bonnet, D, et al. Risk of congenital heart defects associated with assisted reproductive technologies: a population-based evaluation. Eur Heart J. 2011; 32, 500508.CrossRefGoogle ScholarPubMed
39. El-Chaar, D, Yang, Q, Gao, J, et al. Risk of birth defects increased in pregnancies conceived by assisted human reproduction. Fertil Steril. 2009; 92, 15571561.Google Scholar
40. Reefhuis, J, Honein, MA, Schieve, LA, et al. Assisted reproductive technology and major structural birth defects in the United States. Hum Reprod. 2009; 24, 360366.Google Scholar
41. Boulet, SL, Kirby, RS, Reefhuis, J, et al. Assisted reproductive technology and birth defects among liveborn infants in Florida, Massachusetts, and Michigan, 2000-2010. JAMA Pediatr. 2016; 170, e154934.Google Scholar
42. Rimm, AA, Katayama, AC, Diaz, M, et al. A meta-analysis of controlled studies comparing major malformation rates in IVF and ICSI infants with naturally conceived children. J Assist Reprod Genet. 2004; 21, 437443.Google Scholar
43. Hansen, M, Bower, C, Milne, E, et al. Assisted reproductive technologies and the risk of birth defects – a systematic review. Hum Reprod. 2005; 20, 328338.Google Scholar
44. McDonald, SD, Murphy, K, Beyene, J, et al. Perinatel outcomes of singleton pregnancies achieved by in vitro fertilization: a systematic review and meta-analysis. J Obstet Gynaecol Can. 2005; 27, 449459.Google Scholar
45. Wen, J, Jiang, J, Ding, C, et al. Birth defects in children conceived by in vitro fertilization and intracytoplasmic sperm injection: a meta-analysis. Fertil Steril. 2012; 97, 13311337.e1-4.Google Scholar
46. Hansen, M, Kurinczuk, JJ, Milne, E, et al. Assisted reproductive technology and birth defects: a systematic review and meta-analysis. Hum Reprod Update. 2013; 19, 330353.Google Scholar
47. Qin, J, Sheng, X, Wang, H, et al. Assisted reproductive technology and risk of congenital malformations: a meta-analysis based on cohort studies. Arch Gynecol Obstet. 2015; 292, 777798.Google Scholar
48. Parazzini, F, Cipriani, S, Bulfoni, G, et al. The risk of birth defects after assisted reproduction. J Assist Reprod Genet. 2015; 32, 379385.CrossRefGoogle ScholarPubMed
49. Ge, ZJ, Schatten, H, Zhang, CL, et al. Oocyte ageing and epigenetics. Reproduction. 2015; 149, R103R114.Google Scholar
50. Zhu, JL, Basso, O, Obel, C, et al. Infertility, infertility treatment, and congenital malformations: Danish national birth cohort. BMJ. 2006; 333, 679.Google Scholar
51. Massaro, PA, MacLellan, DL, Anderson, PA, et al. Does intracytoplasmic sperm injection pose an increased risk of genitourinary congenital malformations in offspring compared to in vitro fertilization? A systematic review and meta-analysis. J Urol. 2015; 193(Suppl.), 18371842.Google Scholar
52. Klemetti, R, Gissler, M, Sevon, T, et al. Children born after assisted fertilization have an increased rate of major congenital anomalies. Fertil Steril. 2005; 84, 13001307.Google Scholar
53. Santos, MA, Kuijk, EW, Macklon, NS. The impact of ovarian stimulation for IVF on the developing embryo. Reproduction. 2010; 139, 2334.Google Scholar
54. Vialard, F, Boitrelle, F, Molina-Gomes, D, et al. Predisposition to aneuploidy in the oocyte. Cytogenet Genome Res. 2011; 133, 127135.Google Scholar
55. Wennerholm, UB, Albertsson-Wikland, K, Bergh, C, et al. Postnatal growth and health in children born after cryopreservation as embryos. Lancet. 1998; 351, 10851090.Google Scholar
56. Brandes, JM, Scher, A, Itzkovits, J, et al. Growth and development of children conceived by in vitro fertilization. Pediatrics. 1992; 90, 424429.Google Scholar
57. Ludwig, AK, Katalinic, A, Thyen, U, et al. Physical health at 5.5 years of age of term-born singletons after intracytoplasmic sperm injection: results of a prospective, controlled, single-blinded study. Fertil Steril. 2009; 91, 115124.Google Scholar
58. Belva, F, Henriet, S, Liebaers, I, et al. Medical outcome of 8-year-old singleton ICSI children (born >or=32 weeks’ gestation) and a spontaneously conceived comparison group. Hum Reprod. 2007; 22, 506515.Google Scholar
59. Knoester, M, Helmerhorst, FM, Vandenbroucke, JP, et al. Perinatal outcome, health, growth, and medical care utilization of 5- to 8-year-old intracytoplasmic sperm injection singletons. Fertil Steril. 2008; 89, 11331146.Google Scholar
60. Yeung, EH, Sundaram, R, Bell, EM, et al. Infertility treatment and children’s longitudinal growth between birth and 3 years of age. Hum Reprod. 2016; 31, 16211628.Google Scholar
61. Bonduelle, M, Wennerholm, UB, Loft, A, et al. A multi-centre cohort study of the physical health of 5-year-old children conceived after intracytoplasmic sperm injection, in vitro fertilization and natural conception. Hum Reprod. 2005; 20, 413419.Google Scholar
62. Basatemur, E, Shevlin, M, Sutcliffe, A. Growth of children conceived by IVF and ICSI up to 12years of age. Reprod Biomed Online. 2010; 20, 144149.Google Scholar
63. Kai, CM, Main, KM, Andersen, AN, et al. Serum insulin-like growth factor-I (IGF-I) and growth in children born after assisted reproduction. J Clin Endocrinol Metab. 2006; 91, 43524360.Google Scholar
64. Koivurova, S, Hartikainen, AL, Sovio, U, et al. Growth, psychomotor development and morbidity up to 3 years of age in children born after IVF. Hum Reprod. 2003; 18, 23282336.Google Scholar
65. Miles, HL, Hofman, PL, Peek, J, et al. In vitro fertilization improves childhood growth and metabolism. J Clin Endocrinol Metab. 2007; 92, 34413445.Google Scholar
66. Makhoul, IR, Tamir, A, Bader, D, et al. In vitro fertilisation and use of ovulation enhancers may both influence childhood height in very low birthweight infants. Arch Dis Child Fetal Neonatal Ed. 2009; 94, F355F359.Google Scholar
67. Green, MP, Mouat, F, Miles, HL, et al. Phenotypic differences in children conceived from fresh and thawed embryos in in vitro fertilization compared with naturally conceived children. Fertil Steril. 2013; 99, 18981904.Google Scholar
68. Ceelen, M, van Weissenbruch, MM, Prein, J, et al. Growth during infancy and early childhood in relation to blood pressure and body fat measures at age 8-18 years of IVF children and spontaneously conceived controls born to subfertile parents. Hum Reprod. 2009; 24, 27882795.Google Scholar
69. Olivennes, F, Kerbrat, V, Rufat, P, et al. Follow-up of a cohort of 422 children aged 6 to 13 years conceived by in vitro fertilization. Fertil Steril. 1997; 67, 284289.Google Scholar
70. Yeung, EH, Sundaram, R, Bell, EM, et al. Examining infertility treatment and early childhood development in the upstate KIDS study. JAMA Pediatr. 2016; 170, 251258.Google Scholar
71. Beydoun, HA, Sicignano, M, Beydoun, MA, et al. Pubertal development of the first cohort of young adults conceived by in vitro fertilization in the United States. Fertil Steril. 2011; 95, 528533.Google Scholar
72. Ong, KK, Loos, RJ. Rapid infancy weight gain and subsequent obesity: systematic reviews and hopeful suggestions. Acta Paediatr. 2006; 95, 904908.Google Scholar
73. Ekelund, U, Ong, KK, Linne, Y, et al. Association of weight gain in infancy and early childhood with metabolic risk in young adults.J Clin Endocrinol Metab. 2007; 92, 98103.Google Scholar
74. Hvidtjorn, D, Schieve, L, Schendel, D, et al. Cerebral palsy, autism spectrum disorders, and developmental delay in children born after assisted conception: a systematic review and meta-analysis. Arch Pediatr Adolesc Med. 2009; 163, 7283.Google Scholar
75. Ericson, A, Nygren, KG, Olausson, PO, et al. Hospital care utilization of infants born after IVF. Hum Reprod. 2002; 17, 929932.CrossRefGoogle ScholarPubMed
76. Klemetti, R, Sevon, T, Gissler, M, et al. Health of children born as a result of in vitro fertilization. Pediatrics. 2006; 118, 18191827.Google Scholar
77. Stromberg, B, Dahlquist, G, Ericson, A, et al. Neurological sequelae in children born after in-vitro fertilisation: a population-based study. Lancet. 2002; 359, 461465.Google Scholar
78. Hvidtjorn, D, Grove, J, Schendel, DE, et al. Cerebral palsy among children born after in vitro fertilization: the role of preterm delivery – a population-based, cohort study. Pediatrics. 2006; 118, 475482.Google Scholar
79. Hvidtjorn, D, Grove, J, Schendel, D, et al. Multiplicity and early gestational age contribute to an increased risk of cerebral palsy from assisted conception: a population-based cohort study. Hum Reprod. 2010; 25, 21152123.CrossRefGoogle Scholar
80. Zhu, JL, Hvidtjorn, D, Basso, O, et al. Parental infertility and cerebral palsy in children. Hum Reprod. 2010; 25, 31423145.CrossRefGoogle ScholarPubMed
81. Ponjaert-Kristoffersen, I, Bonduelle, M, Barnes, J, et al. International collaborative study of intracytoplasmic sperm injection-conceived, in vitro fertilization-conceived, and naturally conceived 5-year-old child outcomes: cognitive and motor assessments. Pediatrics. 2005; 115, e283e289.Google Scholar
82. Carson, C, Kurinczuk, JJ, Sacker, A, et al. Cognitive development following ART: effect of choice of comparison group, confounding and mediating factors. Hum Reprod. 2010; 25, 244252.Google Scholar
83. Carson, C, Kelly, Y, Kurinczuk, JJ, et al. Effect of pregnancy planning and fertility treatment on cognitive outcomes in children at ages 3 and 5: longitudinal cohort study. BMJ. 2011; 343, d4473.Google Scholar
84. Middelburg, KJ, Heineman, MJ, Bos, AF, et al. Neuromotor, cognitive, language and behavioural outcome in children born following IVF or ICSI – a systematic review. Hum Reprod Update. 2008; 14, 219231.Google Scholar
85. Grether, JK, Qian, Y, Croughan, MS, et al. Is infertility associated with childhood autism? J Autism Dev Disord. 2013; 43, 663672.CrossRefGoogle ScholarPubMed
86. Hvidtjorn, D, Grove, J, Schendel, D, et al. Risk of autism spectrum disorders in children born after assisted conception: a population-based follow-up study. J Epidemiol Community Health. 2011; 65, 497502.Google Scholar
87. Lehti, V, Brown, AS, Gissler, M, et al. Autism spectrum disorders in IVF children: a national case-control study in Finland. Hum Reprod. 2013; 28, 812818.Google Scholar
88. Lyall, K, Baker, A, Hertz-Picciotto, I, et al. Infertility and its treatments in association with autism spectrum disorders: a review and results from the CHARGE study. Int J Environ Res Public Health. 2013; 10, 37153734.CrossRefGoogle ScholarPubMed
89. Kissin, DM, Zhang, Y, Boulet, SL, et al. Association of assisted reproductive technology (ART) treatment and parental infertility diagnosis with autism in ART-conceived children. Hum Reprod. 2015; 30, 454465.Google Scholar
90. Belva, F, Bonduelle, M, Roelants, M, et al. Semen quality of young adult ICSI offspring: the first results. Hum Reprod. 2016; 31, 28112820.Google Scholar
91. Belva, F, Roelants, M, De Schepper, J, et al. Reproductive hormones of ICSI-conceived young adult men: the first results. Hum Reprod. 2017; 32, 439446.Google Scholar
92. Bruinsma, F, Venn, A, Lancaster, P, et al. Incidence of cancer in children born after in-vitro fertilization. Hum Reprod. 2000; 15, 604607.CrossRefGoogle ScholarPubMed
93. Klip, H, Burger, CW, de Kraker, J, et al. Risk of cancer in the offspring of women who underwent ovarian stimulation for IVF. Hum Reprod. 2001; 16, 24512458.Google Scholar
94. Bergh, T, Ericson, A, Hillensjo, T, et al. Deliveries and children born after in-vitro fertilisation in Sweden 1982-95: a retrospective cohort study. Lancet. 1999; 354, 15791585.Google Scholar
95. Lerner-Geva, L, Toren, A, Chetrit, A, et al. The risk for cancer among children of women who underwent in vitro fertilization. Cancer. 2000; 88, 28452847.Google Scholar
96. Raimondi, S, Pedotti, P, Taioli, E. Meta-analysis of cancer incidence in children born after assisted reproductive technologies. Br J Cancer. 2005; 93, 10531056.Google Scholar
97. Kallen, B, Finnstrom, O, Nygren, KG, et al. In vitro fertilization in Sweden: child morbidity including cancer risk. Fertil Steril. 2005; 84, 605610.Google Scholar
98. Kallen, B, Finnstrom, O, Lindam, A, et al. Cancer risk in children and young adults conceived by in vitro fertilization. Pediatrics. 2010; 126, 270276.Google Scholar
99. Sundh, KJ, Henningsen, AK, Kallen, K, et al. Cancer in children and young adults born after assisted reproductive technology: a Nordic cohort study from the Committee of Nordic ART and Safety (CoNARTaS). Hum Reprod. 2014; 29, 20502057.Google Scholar
100. Williams, CL, Bunch, KJ, Stiller, CA, et al. Cancer risk among children born after assisted conception. N Engl J Med. 2013; 369, 18191827.Google Scholar
101. Schmidt, LS, Schuz, J, Lahteenmaki, P, et al. Fetal growth, preterm birth, neonatal stress and risk for CNS tumors in children: a Nordic population- and register-based case-control study. Cancer Epidemiol Biomarkers Prev. 2010; 19, 10421052.Google Scholar
102. Hargreave, M, Jensen, A, Toender, A, et al. Fertility treatment and childhood cancer risk: a systematic meta-analysis. Fertil Steril. 2013; 100, 150161.Google Scholar
103. Ceelen, M, et al. Body composition in children and adolescents born after in vitro fertilization or spontaneous conception. J Clin Endocrinol Metab. 2007; 92, 34173423.Google Scholar
104. Ceelen, M, van Weissenbruch, MM, Roos, JC, et al. Cardiometabolic differences in children born after in vitro fertilization: follow-up study. J Clin Endocrinol Metab. 2008; 93, 16821688.Google Scholar
105. Sakka, SD, Loutradis, D, Kanaka-Gantenbein, C, et al. Absence of insulin resistance and low-grade inflammation despite early metabolic syndrome manifestations in children born after in vitro fertilization. Fertil Steril. 2010; 94, 16931699.Google Scholar
106. Scherrer, U, Rimoldi, SF, Rexhaj, E, et al. Systemic and pulmonary vascular dysfunction in children conceived by assisted reproductive technologies. Circulation. 2012; 125, 18901896.Google Scholar
107. Chen, M, Wu, L, Zhao, J, et al. Altered glucose metabolism in mouse and humans conceived by IVF. Diabetes. 2014; 63, 31893198.Google Scholar
108. Belva, F, Painter, R, Bonduelle, M, et al. Are ICSI adolescents at risk for increased adiposity? Hum Reprod. 2012; 27, 257264.Google Scholar
109. van Harmelen, V, Eriksson, A, Astrom, G, et al. Vascular peptide endothelin-1 links fat accumulation with alterations of visceral adipocyte lipolysis. Diabetes. 2008; 57, 378386.Google Scholar
110. Pontesilli, M, Painter, RC, Grooten, IJ, et al. Subfertility and assisted reproduction techniques are associated with poorer cardiometabolic profiles in childhood. Reprod Biomed Online. 2015; 30, 258267.Google Scholar
111. Belva, F, Roelants, M, De Schepper, J, et al. Blood pressure in ICSI-conceived adolescents. Hum Reprod. 2012; 27, 31003108.Google Scholar
112. La Bastide-Van Gemert S, Seggers, J, Haadsma, ML, et al. Is ovarian hyperstimulation associated with higher blood pressure in 4-year-old IVF offspring? Part II: an explorative causal inference approach. Hum Reprod, 2013.Google Scholar
113. Sakka, SD, Margeli, A, Loutradis, D, et al. Gender dimorphic increase in RBP-4 and NGAL in children born after IVF: an epigenetic phenomenon? Eur J Clin Invest. 2013; 43, 439448.Google Scholar
114. Valenzuela-Alcaraz, B, Crispi, F, Bijnens, B, et al. Assisted reproductive technologies are associated with cardiovascular remodeling in utero that persists postnatally. Circulation. 2013; 128, 14421450.Google Scholar
115. von Arx, R, Allemann, Y, Sartori, C, et al. Right ventricular dysfunction in children and adolescents conceived by assisted reproductive technologies. J Appl Physiol (1985). 2015; 118, 12001206.Google Scholar
116. Sakka, SD, Malamitsi-Puchner, A, Loutradis, D, et al. Euthyroid hyperthyrotropinemia in children born after in vitro fertilization. J Clin Endocrinol Metab. 2009; 94, 13381341.Google Scholar
117. Onal, H, Ercan, O, Adal, E, et al. Subclinical hypothyroidism in in vitro fertilization babies. Acta Paediatr. 2012; 101, e248e252.Google Scholar
118. Lv, PP, Meng, Y, Lv, M, et al. Altered thyroid hormone profile in offspring after exposure to high estradiol environment during the first trimester of pregnancy: a cross-sectional study. BMC Med. 2014; 12, 240.Google Scholar
119. Bloise, E, Feuer, SK, Rinaudo, PF. Comparative intrauterine development and placental function of ART concepti: implications for human reproductive medicine and animal breeding. Hum Reprod Update. 2014; 20, 822839.Google Scholar
120. Barker, DJ. The developmental origins of adult disease. Eur J Epidemiol. 2003; 18, 733736.Google Scholar
121. Eriksson, JG, Forsen, T, Tuomilehto, J, et al. Effects of size at birth and childhood growth on the insulin resistance syndrome in elderly individuals. Diabetologia. 2002; 45, 342348.Google Scholar
122. Barker, DJ, Winter, PD, Osmond, C, et al. Weight in infancy and death from ischaemic heart disease. Lancet. 1989; 2, 577580.Google Scholar
123. Forsen, T, Eriksson, J, Tuomilehto, J, et al. The fetal and childhood growth of persons who develop type 2 diabetes. Ann Intern Med. 2000; 133, 176182.Google Scholar
124. Rinaudo, P, Wang, E. Fetal programming and metabolic syndrome. Annu Rev Physiol. 2012; 74, 107130.Google Scholar
125. Waddington, CH. The epigenotype. Endeavour. 1942; 1, 1820.Google Scholar
126. Le Bouc, Y, Rossignol, S, Azzi, S, et al. Epigenetics, genomic imprinting and assisted reproductive technology. Ann Endocrinol (Paris). 2010; 71, 237238.Google Scholar
127. Swales, AK, Spears, N. Genomic imprinting and reproduction. Reproduction. 2005; 130, 389399.Google Scholar
128. Dennis, C. Epigenetics and disease: altered states. Nature. 2003; 421, 686688.Google Scholar
129. Laprise, SL. Implications of epigenetics and genomic imprinting in assisted reproductive technologies. Mol Reprod Dev. 2009; 76, 10061018.Google Scholar
130. Reik, W, Walter, J. Genomic imprinting: parental influence on the genome. Nat Rev Genet. 2001; 2, 2132.Google Scholar
131. White, CR, Denomme, MM, Tekpetey, FR, et al. High frequency of imprinted methylation errors in human preimplantation embryos. Sci Rep. 2015; 5, 17311.Google Scholar
132. Katari, S, Turan, N, Bibikova, M, et al. DNA methylation and gene expression differences in children conceived in vitro or in vivo. Hum Mol Genet. 2009; 18, 37693778.Google Scholar
133. Song, S, Ghosh, J, Mainigi, M, et al. DNA methylation differences between in vitro- and in vivo-conceived children are associated with ART procedures rather than infertility. Clin Epigenetics. 2015; 7, 41.Google Scholar
134. Whitelaw, N, Bhattacharya, S, Hoad, G, et al. Epigenetic status in the offspring of spontaneous and assisted conception. Hum Reprod. 2014; 29, 14521458.Google Scholar
135. Estill, MS, Bolnick, JM, Waterland, RA, et al. Assisted reproductive technology alters deoxyribonucleic acid methylation profiles in bloodspots of newborn infants. Fertil Steril. 2016; 106, 629639.e10.Google Scholar
136. Lou, H, Le, F., Zheng, Y, et al. Assisted reproductive technologies impair the expression and methylation of insulin-induced gene 1 and sterol regulatory element-binding factor 1 in the fetus and placenta. Fertil Steril. 2014; 101, 974980.e2.CrossRefGoogle ScholarPubMed
137. Nelissen, EC, Dumoulin, JC, Daunay, A, et al. Placentas from pregnancies conceived by IVF/ICSI have a reduced DNA methylation level at the H19 and MEST differentially methylated regions. Hum Reprod. 2013; 28, 11171126.Google Scholar
138. Turan, N, Katari, S, Gerson, LF, et al. Inter- and intra-individual variation in allele-specific DNA methylation and gene expression in children conceived using assisted reproductive technology. PLoS Genet. 2010; 6, 114.Google Scholar
139. Gomes, MV, Huber, J, Ferriani, RA, et al. Abnormal methylation at the KvDMR1 imprinting control region in clinically normal children conceived by assisted reproductive technologies. Mol Hum Reprod. 2009; 15, 471477.Google Scholar
140. Turan, N, Ghalwash, MF, Katari, S, et al. DNA methylation differences at growth related genes correlate with birth weight: a molecular signature linked to developmental origins of adult disease? BMC Med Genomics. 2012; 5, 10.Google Scholar
141. Chen, S, Sun, FZ, Huang, X, et al. Assisted reproduction causes placental maldevelopment and dysfunction linked to reduced fetal weight in mice. Sci Rep. 2015; 5, 10596.Google Scholar
142. Li, B, Chen, S, Tang, N, et al. Assisted reproduction causes reduced fetal growth associated with downregulation of paternally expressed imprinted genes that enhance fetal growth in mice. Biol Reprod. 2016; 94, 45.Google Scholar
143. Young, LE, Fernandes, K, McEvoy, TG, et al. Epigenetic change in IGF2R is associated with fetal overgrowth after sheep embryo culture. Nat Genet. 2001; 27, 153154.Google Scholar
144. Tan, K, Zhang, Z, Miao, K, et al. Dynamic integrated analysis of DNA methylation and gene expression profiles in in vivo and in vitro fertilized mouse post-implantation extraembryonic and placental tissues. Mol Hum Reprod. 2016; 22, 485498.Google Scholar
145. Farin, PW, Piedrahita, JA, Farin, CE. Errors in development of fetuses and placentas from in vitro-produced bovine embryos. Theriogenology. 2006; 65, 178191.Google Scholar
146. Wright K, Brown, L, Brown, G, et al. Microarray assessment of methylation in individual mouse blastocyst stage embryos shows that in vitro culture may have widespread genomic effects. Hum Reprod, 2011.Google Scholar
147. Le F, Wang, LY, Wang, N, et al. In vitro fertilization alters growth and expression of Igf2/H19 and their epigenetic mechanisms in the liver and skeletal muscle of newborn and elder mice. Biol Reprod, 2013.Google Scholar
148. Feuer, SK, Liu, X, Donjacour, A, et al. Use of a mouse in vitro fertilization model to understand the developmental origins of health and disease hypothesis. Endocrinology. 2014; 155, 19561969.Google Scholar
149. Rexhaj, E, Paoloni-Giacobino, A, Rimoldi, SF, et al. Mice generated by in vitro fertilization exhibit vascular dysfunction and shortened life span. J Clin Invest. 2013; 123, 50525060.Google Scholar
150. Rexhaj, E, Pireva, A, Paoloni-Giacobino, A, et al. Prevention of vascular dysfunction and arterial hypertension in mice generated by assisted reproductive technologies by addition of melatonin to culture media. Am J Physiol Heart Circ Physiol. 2015; 309, H1151H1156.Google Scholar
151. Burton, GJ, Fowden, AL, Thornburg, KL. Placental origins of chronic disease. Physiol Rev. 2016; 96, 15091565.Google Scholar
152. Sferruzzi-Perri, AN, Camm, EJ. The programming power of the placenta. Front Physiol. 2016; 7, 33.Google Scholar
153. Barker, DJ, Bull, AR, Osmond, C, et al. Fetal and placental size and risk of hypertension in adult life. BMJ. 1990; 301, 259262.Google Scholar
154. Eriksson, JG, Kajantie, E, Thornburg, KL, et al. Mother’s body size and placental size predict coronary heart disease in men. Eur Heart J. 2011; 32, 22972303.Google Scholar
155. de Waal, E, Vrooman, LA, Fischer, E, et al. The cumulative effect of assisted reproduction procedures on placental development and epigenetic perturbations in a mouse model. Hum Mol Genet. 2015; 24, 69756985.Google Scholar
156. Bloise, E, Lin, W, Liu, X, et al. Impaired placental nutrient transport in mice generated by in vitro fertilization. Endocrinology. 2012; 153, 34573467.Google Scholar
157. Lalosevic, D, Tabs, D, Krnojelac, D, et al. Histological characteristics of placentas from assisted reproduction programs. Med Pregl. 2003; 56, 521527.Google Scholar
158. Joy, J, Gannon, C, McClure, N, et al. Is assisted reproduction associated with abnormal placentation? Pediatr Dev Pathol. 2012; 15, 306314.Google Scholar
159. Zhang, Y, Zhao, W, Jiang, Y, et al. Ultrastructural study on human placentae from women subjected to assisted reproductive technology treatments. Biol Reprod. 2011; 85, 635642.Google Scholar
160. Daniel, Y, Schreiber, L, Geva, E, et al. Do placentae of term singleton pregnancies obtained by assisted reproductive technologies differ from those of spontaneously conceived pregnancies? Hum Reprod. 1999; 14, 11071110.Google Scholar
161. Haavaldsen, C, Tanbo, T, Eskild, A. Placental weight in singleton pregnancies with and without assisted reproductive technology: a population study of 536,567 pregnancies. Hum Reprod. 2012; 27, 576582.Google Scholar
162. Choux, C, Carmignac, V, Bruno, C, et al. The placenta: phenotypic and epigenetic modifications induced by assisted reproductive technologies throughout pregnancy. Clin Epigenetics. 2015; 7, 87.Google Scholar
163. Henningsen, AA, Gissler, M, Skjaerven, R, et al. Trends in perinatal health after assisted reproduction: a Nordic study from the CoNARTaS group. Hum Reprod. 2015; 30, 710716.Google Scholar
164. Hansen, M, Bower, C. The impact of assisted reproductive technologies on intra-uterine growth and birth defects in singletons. Semin Fetal Neonatal Med. 2014; 19, 228233.Google Scholar
165. Miller LM, Hodgson, R, Wong, TY, et al. Single embryo transfer for all? Aust N Z J Obstet Gynaecol, 2016.Google Scholar
166. Pandian, Z, Marjoribanks, J, Ozturk, O, et al. Number of embryos for transfer following in vitro fertilisation or intra-cytoplasmic sperm injection. Cochrane Database Syst Rev. 2013; CD003416.Google Scholar
167. Evans, J, Hannan, NJ, Edgell, TA, et al. Fresh versus frozen embryo transfer: backing clinical decisions with scientific and clinical evidence. Hum Reprod Update. 2014; 20, 808821.Google Scholar
168. Sazonova, A, Kallen, K, Thurin-Kjellberg, A, et al. Obstetric outcome after in vitro fertilization with single or double embryo transfer. Hum Reprod. 2011; 26, 442450.Google Scholar
Figure 0

Table 1 Obstetric and perinatal outcome in in vitro fertilization (IVF) singleton pregnancies

Figure 1

Table 2 Birth defects in in vitro fertilization (IVF) singleton pregnancies

Figure 2

Table 3 Growth and development in assisted reproductive technologies (ART) singleton pregnancies

Figure 3

Table 4 Cancer risk in assisted reproductive technologies (ART) singleton pregnancies

Figure 4

Table 5 Metabolic risk in assisted reproductive technologies (ART) singleton pregnancies