Advanced maternal age

Advanced maternal age, in a broad sense, is the instance of a woman being of an older age at a stage of reproduction, although there are various definitions of specific age and stage of reproduction.[1] It is a result of female childbearing postponement. The variability in definitions regarding age is in part explained by the effects of increasing age occurring as a continuum rather than as a threshold effect.[1]

In Western, Northern, and Southern Europe, first-time mothers are on average 26 to 29 years old, up from 23 to 25 years at the start of the 1970s. In a number of European countries (Spain), the mean age of women at first childbirth has now even crossed the 30 year threshold.[2]

This process is not restricted to Europe. Asia, Japan and the United States are all seeing average age at first birth on the rise, and increasingly the process is spreading to countries in the developing world like China, Turkey and Iran. In the U.S., the average age of first childbirth was 26 in 2013.[3]

Advanced maternal age is associated with adverse reproductive effects such as increased risk of infertility,[4] and that the children will have chromosomal abnormalities.[5] The corresponding paternal age effect is less pronounced.[6][7]

In present generations it is more common to have children at an older age. Several factors may influence the decisions of mothers when having their first baby. Such factors include educational, social and economic status.

History

Having children later was not exceptional in the past, when families were larger and women often continued bearing children until the end of their reproductive age. What is so radical about this recent transformation is that it is the age at which women give birth to their first child which is becoming comparatively high, leaving an ever more constricted window of biological opportunity for second and subsequent children, should they be desired. Unsurprisingly, high first-birth ages and high rates of birth postponement are associated with the arrival of low, and lowest-low fertility.

This association has now become especially clear, since the postponement of first births in a number of countries has now continued unabated for more than three decades, and has become one of the most prominent characteristics of fertility patterns in developed societies. A variety of authors (in particular Lesthaeghe) have argued that fertility postponement constitutes the ‘hallmark’ of what has become known as the second demographic transition.

Others have proposed that the postponement process itself constitutes a separate 'third transition'.[8] On this latter view, modern developed societies exhibit a kind of dual fertility regime, with the majority of births being concentrated either among very young or increasingly older mothers. This is sometimes known as the 'rectangularisation' of fertility patterns.

Examples

In the USA, the average age at which women bore their first child advanced from 21.4 years old in 1970, to 25 years old in 2006.[9]

Effects

Decreased fertility

Cumulative percentage and average age for women reaching subfertility, sterility, irregular menstruation and menopause.[10]

A woman's fertility peaks in the early and mid twenties, after which it starts to decline, with advanced maternal age causing an increased risk of female infertility.

According to Henri Leridon, PhD, an epidemiologist with the French Institute of Health and Medical Research, of women trying to get pregnant, without using fertility drugs or in vitro fertilization:[4]

Risk of birth defects

The risk of having a Down syndrome pregnancy in relation to a mother's age.

A woman's risk of having a baby with chromosomal abnormalities increases with her age. Down syndrome is the most common chromosomal birth defect, and a woman's risk of having a baby with Down syndrome is:[5]

Other effects

Advanced maternal age is associated with adverse outcomes in the perinatal period, which may be caused by detrimental effects on decidual and placental development.[11]

The risk of the mother dying before the child becomes an adult increases by more advanced maternal age, such as can be demonstrated by the following data from France in 2007:[12]

Maternal age at childbirth 25 30 35 40 45
Risk of mother not surviving until child's 18th birthday (in %)[12] 1.0 1.6 2.6 3.8 5.5

Advanced maternal age continues to be associated with a range of adverse pregnancy outcomes including low birth weight, pre-term birth, stillbirth, unexplained fetal death, and increased rates of Caesarean section.

On the other hand, advanced maternal age is associated with a more stable family environment, higher socio-economic position, higher income and better living conditions, as well as better parenting practices,[12] but it is more or less uncertain whether these entities are effects of advanced maternal age, are contributors to advanced maternal age, or common effects of a certain state such as personality type.

Changes in interpregnancy interval

Kalberer et al.[13] have shown that despite the older maternal age at birth of the first child, the time span between the birth of the first and the second child (= interpregnancy interval) decreased over the last decades. If purely biological factors were at work, it could be argued that interpregnancy interval should have increased, as fertility declines with age, which would make it harder for the woman to get a second child after postponed birth of the first one. This not being the case shows that sociologic factors (see above) prime over biological factors in determining interpregnancy interval.

With technology developments cases of post-menopausal pregnancies have occurred, and there are several known cases of older women carrying a pregnancy to term, usually with in vitro fertilization of a donor egg. A 61-year-old Brazilian woman with implantation of a donor egg expected her first child September 2011.[14]

Ovarian aging

As women age, they experience a decline in reproductive performance leading to menopause. This decline is tied to a decline in the number of ovarian follicles. Although about 1 million oocytes are present at birth in the human ovary, only about 500 (about 0.05%) of these ovulate, and the rest are wasted (ovarian follicle atresia). The decline in ovarian reserve appears to occur at a constantly increasing rate with age,[15] and leads to nearly complete exhaustion of the reserve by about age 51. As ovarian reserve and fertility decline with age, there is also a parallel increase in pregnancy failure and meiotic errors resulting in chromosomally abnormal conceptions.

Titus et al.[16] have proposed an explanation for the decline in ovarian reserve with age. They showed that as women age, double-strand breaks accumulate in the DNA of their primordial follicles. Primordial follicles are immature primary oocytes surrounded by a single layer of granulosa cells. An enzyme system is present in oocytes that normally accurately repairs DNA double-strand breaks. This repair system is referred to as homologous recombinational repair, and it is especially active during meiosis. Meiosis is the general process by which germ cells are formed in eukaryotes, and it appears to be an adaptation for efficiently removing damages in germ line DNA by homologous recombinational repair (see Origin and function of meiosis also[17]). Human primary oocytes are present at an intermediate stage of meiosis, that is prophase I (see Oogenesis). Titus et al.[16] also showed that expression of four key DNA repair genes that are necessary for homologous recombinational repair (BRCA1, MRE11, Rad51 and ATM) decline in oocytes with age. This age-related decline in ability to repair double-strand damages can account for the accumulation of these damages, which then likely contributes to the decline in ovarian reserve.

Women with an inherited mutation in the DNA repair gene BRCA1 undergo menopause prematurely,[18] suggesting that naturally occurring DNA damages in oocytes are repaired less efficiently in these women, and this inefficiency leads to early reproductive failure. Genomic data from about 70,000 women were analyzed to identify protein-coding variation associated with age at natural menopause.[19] Pathway analyses identified a major association with DNA damage response genes, particularly those expressed during meiosis and including a common coding variant in the BRCA1 gene.

See also

Notes

  1. 1 2 Effect of advanced age on fertility and pregnancy in women at UpToDate. Author: Ruth C Fretts. Section Editor: Louise Wilkins-Haug. Deputy Editor: Vanessa A Barss. This topic last updated: Dec 3, 2012.
  2. "Archived copy" (PDF). Archived from the original (PDF) on 2014-12-22. Retrieved 2014-05-27.
  3. http://www.cdc.gov/nchs/fastats/births.htm
  4. 1 2 3 Leridon, H. (2004). "Can assisted reproduction technology compensate for the natural decline in fertility with age? A model assessment". Human Reproduction. 19 (7): 1548–1553. doi:10.1093/humrep/deh304. PMID 15205397.
  5. 1 2 Morris, JK; Mutton, DE; Alberman, E (2002). "Revised estimates of the maternal age specific live birth prevalence of Down's syndrome.". Journal of medical screening. 9 (1): 2–6. PMID 11943789.
  6. H. Tournaye, "Male Reproductive Ageing," in Bewley, Ledger, and Nikolaou, eds., Reproductive Ageing, Cambridge University Press (2009), ISBN 9781906985134 (accessed 15 November 2013)
  7. Kidd SA, Eskenazi B, Wyrobek AJ (2001). "Effects of male age on semen quality and fertility: a review of the literature". Fertil Steril. 75 (2): 237–48. doi:10.1016/S0015-0282(00)01679-4. PMID 11172821.
  8. Kohler, H. P.; Billari, F. C.; Ortega, J. A. (2002). "The emergence of lowest-low fertility in Europe during the 1990s". Population and Development Review. 28 (4): 641–680. doi:10.1111/j.1728-4457.2002.00641.x.
  9. Mathews, TJ. "Delayed Childbearing: More Women Are Having Their First Child Later in Life" (PDF). 2009. CDC. Retrieved 26 August 2013.
  10. te Velde, E. R. (2002). "The variability of female reproductive ageing". Human Reproduction Update. 8 (2): 141–154. doi:10.1093/humupd/8.2.141. ISSN 1355-4786.
  11. Nelson, S. M.; Telfer, E. E.; Anderson, R. A. (2012). "The ageing ovary and uterus: New biological insights". Human Reproduction Update. 19 (1): 67–83. doi:10.1093/humupd/dms043. PMC 3508627Freely accessible. PMID 23103636.
  12. 1 2 3 Schmidt, L.; Sobotka, T.; Bentzen, J. G.; Nyboe Andersen, A.; on behalf of the ESHRE Reproduction Society Task Force (2011). "Demographic and medical consequences of the postponement of parenthood". Human Reproduction Update. 18 (1): 29–43. doi:10.1093/humupd/dmr040. PMID 21989171.
  13. Kalberer U, Baud D, Fontanet A, Hohlfeld P, de Ziegler D. Birth records from Swiss married couples analyzed over the past 35 years reveal an aging of first-time mothers by 5.1 years while the interpregnancy interval has shortened. Fertil Steril. 2009 Dec;92(6):2072-3.
  14. "Woman, 61, pregnant". The Sydney Morning Herald. 27 September 2011.
  15. Hansen KR, Knowlton NS, Thyer AC, Charleston JS, Soules MR, Klein NA (2008). "A new model of reproductive aging: the decline in ovarian non-growing follicle number from birth to menopause". Hum. Reprod. 23 (3): 699–708. doi:10.1093/humrep/dem408. PMID 18192670.
  16. 1 2 Titus S, Li F, Stobezki R, Akula K, Unsal E, Jeong K, Dickler M, Robson M, Moy F, Goswami S, Oktay K (2013). "Impairment of BRCA1-related DNA double-strand break repair leads to ovarian aging in mice and humans". Sci Transl Med. 5 (172): 172ra21. doi:10.1126/scitranslmed.3004925. PMID 23408054.
  17. Harris Bernstein, Carol Bernstein and Richard E. Michod (2011). Meiosis as an Evolutionary Adaptation for DNA Repair. Chapter 19 pages 357-382 in “DNA Repair” (Inna Kruman editor). InTech Open Publisher. DOI: 10.5772/25117 ISBN 978-953-307-697-3 http://www.intechopen.com/books/dna-repair/meiosis-as-an-evolutionary-adaptation-for-dna-repair
  18. Rzepka-Górska I, Tarnowski B, Chudecka-Głaz A, Górski B, Zielińska D, Tołoczko-Grabarek A (2006). "Premature menopause in patients with BRCA1 gene mutation". Breast Cancer Res. Treat. 100 (1): 59–63. doi:10.1007/s10549-006-9220-1. PMID 16773440.
  19. Day FR, Ruth KS, Thompson DJ, et al. (2015). "Large-scale genomic analyses link reproductive aging to hypothalamic signaling, breast cancer susceptibility and BRCA1-mediated DNA repair". Nat. Genet. 47 (11): 1294–303. doi:10.1038/ng.3412. PMC 4661791Freely accessible. PMID 26414677.

References

Further reading

External links

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