Reduced oxygen concentration during human IVF culture improves embryo utilization and cumulative pregnancy rates per cycle

Aafke P A Van Montfoort, Eus G J M Arts, Lydia Wijnandts, Alexander Sluijmer, Marie-José Pelinck, Jolande A Land, Jannie Van Echten-Arends, Aafke P A Van Montfoort, Eus G J M Arts, Lydia Wijnandts, Alexander Sluijmer, Marie-José Pelinck, Jolande A Land, Jannie Van Echten-Arends

Abstract

Study question: Do different oxygen levels during human IVF embryo culture affect embryo utilization, cumulative IVF success rates per cycle and neonatal birthweight?

Summary answer: After 2 days of culture, a lower oxygen level (5%) leads to more good-quality embryos and more embryos that can be cryopreserved, and thereby to a higher cumulative live birth rate per cycle when compared to embryo culture in 20% oxygen, while birthweights are similar.

What is known already: Several studies have compared IVF outcome parameters after embryo culture in a more physiological level of 5% oxygen and the atmospheric level of 20%. Although there is consensus that embryo development improves in 5% oxygen, effects on pregnancy and live birth rates are mainly seen in blastocyst, but not cleavage-stage transfers. A major drawback of these studies is that only fresh embryo transfers were included, not taking additional frozen-thawed transfers from these cycles into account. This might have underestimated the effects of oxygen level, especially in cleavage-stage embryo transfers. Furthermore, little is known about the effect of oxygen level during culture on birthweight.

Study design size duration: This is a cohort study in 871 consecutive patients who had an IVF cycle between January 2012 and December 2013, and 5-7 years follow-up to allow transfer of frozen-thawed embryos. Based on daily availability of positions in the incubators, all oocytes and embryos of one cycle were allocated to one of the three incubators with traditional ambient oxygen levels (6% CO2 and 20% O2 in air), or to a fourth incubator that was adjusted to have low oxygen levels of 5% (6% CO2, 5% O2 and 89% N2). Embryos were cultured under 5 or 20% oxygen until Day 2 or 3, when embryos were transferred or cryopreserved, respectively. Clinical and other laboratory procedures were similar in both groups.

Participants/materials setting methods: To compare embryo characteristics and (cumulative) pregnancy outcomes between the two oxygen groups, for each patient only the first cycle in the study period was included in the analysis, resulting in 195 cycles in the 5% group (1627 oocytes) and 676 in the 20% oxygen group (5448 oocytes). Embryo characteristics were analysed per cycle and per embryo and were corrected for maternal age, cycle rank order, fertilization method (IVF or ICSI) and cause of subfertility. Perinatal data from the resulting singletons (n = 124 after fresh and 45 after frozen-thawed embryo transfer) were collected from delivery reports from the hospitals or midwife practices.

Main results and the role of chance: In the 5% oxygen group, there were significantly more embryos of good quality (45.8 versus 30.9% in the 20% group, adjusted odds ratio (OR) [95% CI] = 1.9 [1.6-2.4]). This did not result in higher live birth rates per cycle, but after fresh transfers more good-quality spare embryos could be cryopreserved (46.1 versus 29.7%, adjusted OR [95% CI] = 2.0 [1.7-2.5]).After a follow-up period of 5-7 years, in which 82.4% of the cryopreserved embryos from the 5% oxygen group and 85.4% from the 20% oxygen group were thawed, the percentage of patients with at least one live birth resulting from the study cycle was significantly higher in the low oxygen group (adjusted OR [95% CI] = 1.5 [1.01-2.2]). In 124 live born singletons from fresh embryo transfers and in 45 from transfers of cryopreserved embryos, birthweight was similar in both oxygen groups after correction for confounding factors.

Limitations reasons for caution: This is a retrospective study, and treatment allocation was not randomised. The study was not powered for a predefined birthweight difference. With the number of live births in our study, small differences in birthweight might not have been detected. The selection of embryos to be cryopreserved was based on embryo morphology criteria that might be different in other clinics.

Wider implications of the findings: Improved embryo utilization by more cryopreservation leading to higher cumulative live birth rates per cycle favours the use of 5% instead of 20% oxygen during human IVF embryo culture. This study also demonstrates that for comparison of different IVF treatment regimens, the cumulative outcome, including transfers of fresh and frozen-thawed embryos, is to be preferred instead of analysis of fresh embryo transfers only.

Study funding/competing interests: No external funding was received for this study. None of the authors has a conflict of interest to declare.

Trial registration number: NA.

Keywords: birthweight; embryo culture techniques; embryo utilization; fertilization in vitro; oxygen; pregnancy rate.

© The Author(s) 2020. Published by Oxford University Press on behalf of the European Society of Human Reproduction and Embryology.

Figures

Figure 1
Figure 1
Flowchart depicting the inclusion of 965 patients and the selection to arrive at 871 cycles for the analyses. Only the patient’s first cycle performed after the start of the study was included. This was not necessarily the first cycle for the patient. Allocation to culture in 5% or 20% oxygen was based on daily available positions in the incubators.

References

    1. Bahceci M, Ciray HN, Karagenc L, Ulug U, Bener F. Effect of oxygen concentration during the incubation of embryos of women undergoing ICSI and embryo transfer: a prospective randomized study. Reprod Biomed Online 2005;11:438–443.
    1. Barker DJ. The developmental origins of adult disease. J Am Coll Nutr 2004;23:588S–595S.
    1. Bolnick A, Awonuga AO, Yang Y, Abdulhasan M, Xie Y, Zhou S, Puscheck EE, Rappolee DA. Using stem cell oxygen physiology to optimize blastocyst culture while minimizing hypoxic stress. J Assist Reprod Genet 2017;34:1251–1259.
    1. Bontekoe S., Mantikou E., van Wely M., Seshadri S., Repping S. and Mastenbroek S.. Low oxygen concentrations for embryo culture in assisted reproductive technologies. Cochrane Database Syst Rev 2012;7:CD008950.
    1. Castillo CM, Horne G, Fitzgerald CT, Johnstone ED, Brison DR, Roberts SA. The impact of IVF on birthweight from 1991 to 2015: a cross-sectional study. Hum Reprod 2019;34:920–931.
    1. Catt JW, Henman M. Toxic effects of oxygen on human embryo development. Hum Reprod 2000;15:199–206.
    1. Christianson MS, Zhao Y, Shoham G, Granot I, Safran A, Khafagy A, Leong M, Shoham Z. Embryo catheter loading and embryo culture techniques: results of a worldwide web-based survey. J Assist Reprod Genet 2014;31:1029–1036.
    1. Santos MJ, Gamiz P, Albert C, Galan A, Viloria T, Perez S, Romero JL, Remohi J. Reduced oxygen tension improves embryo quality but not clinical pregnancy rates: a randomized clinical study into ovum donation cycles. Fertil Steril 2013;100:402–407.
    1. De Munck N, Janssens R, Segers I, Tournaye H, Van de Velde H, Verheyen G. Influence of ultra-low oxygen (2%) tension on in-vitro human embryo development. Hum Reprod 2018.
    1. Waal E, Mak W, Calhoun S, Stein P, Ord T, Krapp C, Coutifaris C, Schultz RM, Bartolomei MS. In vitro culture increases the frequency of stochastic epigenetic errors at imprinted genes in placental tissues from mouse concepti produced through assisted reproductive technologies. Biol Reprod 2014;90:22.
    1. Dumoulin JC, Meijers CJ, Bras M, Coonen E, Geraedts JP, Evers JL. Effect of oxygen concentration on human in-vitro fertilization and embryo culture. Hum Reprod 1999;14:465–469.
    1. Feil D, Lane M, Roberts CT, Kelley RL, Edwards LJ, Thompson JG, Kind KL. Effect of culturing mouse embryos under different oxygen concentrations on subsequent fetal and placental development. J Physiol 2006;572:87–96.
    1. Fischer-Brown A, Crooks A, Leonard S, Monson R, Northey D, Rutledge JJ. Parturition following transfer of embryos produced in two media under two oxygen concentrations. Anim Reprod Sci 2005;87:215–228.
    1. Fischer B, Bavister BD. Oxygen tension in the oviduct and uterus of rhesus monkeys, hamsters and rabbits. J Reprod Fertil 1993;99:673–679.
    1. Gaspar RC, Arnold DR, Correa CA, da Rocha CV Jr, Penteado JC, Del Collado M, Vantini R, Garcia JM, Lopes FL. Oxygen tension affects histone remodeling of in vitro-produced embryos in a bovine model. Theriogenology 2015;83:1408–1415.
    1. Gomes Sobrinho DB, Oliveira JB, Petersen CG, Mauri AL, Silva LF, Massaro FC, Baruffi RL, Cavagna M, Franco JG Jr. IVF/ICSI outcomes after culture of human embryos at low oxygen tension: a meta-analysis. Reprod Biol Endocrinol 2011;9:143.
    1. Houghton FD, Thompson JG, Kennedy CJ, Leese HJ. Oxygen consumption and energy metabolism of the early mouse embryo. Mol Reprod Dev 1996;44:476–485.
    1. Iwata H, Minami N, Imai H. Postnatal weight of calves derived from in vitro matured and in vitro fertilized embryos developed under various oxygen concentrations. Reprod Fertil Dev 2000;12:391–396.
    1. Karagenc L, Sertkaya Z, Ciray N, Ulug U, Bahceci M. Impact of oxygen concentration on embryonic development of mouse zygotes. Reprod Biomed Online 2004;9:409–417.
    1. Kasterstein E, Strassburger D, Komarovsky D, Bern O, Komsky A, Raziel A, Friedler S, Ron-El R. The effect of two distinct levels of oxygen concentration on embryo development in a sibling oocyte study. J Assist Reprod Genet 2013;30:1073–1079.
    1. Katz-Jaffe MG, Linck DW, Schoolcraft WB, Gardner DK. A proteomic analysis of mammalian preimplantation embryonic development. Reproduction 2005;130:899–905.
    1. Kea B, Gebhardt J, Watt J, Westphal LM, Lathi RB, Milki AA, Behr B. Effect of reduced oxygen concentrations on the outcome of in vitro fertilization. Fertil Steril 2007;87:213–216.
    1. Kirkegaard K, Hindkjaer JJ, Ingerslev HJ. Effect of oxygen concentration on human embryo development evaluated by time-lapse monitoring. Fertil Steril 2013;99:738–744e734.
    1. Kirkegaard K, Sundvall L, Erlandsen M, Hindkjaer JJ, Knudsen UB, Ingerslev HJ. Timing of human preimplantation embryonic development is confounded by embryo origin. Hum Reprod 2016;31:324–331.
    1. Kovacic B, Sajko MC, Vlaisavljevic V. A prospective, randomized trial on the effect of atmospheric versus reduced oxygen concentration on the outcome of intracytoplasmic sperm injection cycles. Fertil Steril 2010;94:511–519.
    1. Li W, Goossens K, Van Poucke M, Forier K, Braeckmans K, Van Soom A, Peelman LJ. High oxygen tension increases global methylation in bovine 4-cell embryos and blastocysts but does not affect general retrotransposon expression. Reprod Fertil Dev 2016;28:948–959.
    1. Ma YY, Chen HW, Tzeng CR. Low oxygen tension increases mitochondrial membrane potential and enhances expression of antioxidant genes and implantation protein of mouse blastocyst cultured in vitro. J Ovarian Res 2017;10:47.
    1. Maas K, Galkina E, Thornton K, Penzias AS, Sakkas D. No change in live birthweight of IVF singleton deliveries over an 18-year period despite significant clinical and laboratory changes. Hum Reprod 2016;31:1987–1996.
    1. Maheshwari A, McLernon D, Bhattacharya S. Cumulative live birth rate: time for a consensus? Hum Reprod 2015;30:2703–2707.
    1. Mantikou E., Jonker M. J., Wong K. M., van Montfoort A. P., de Jong M., Breit T. M., Repping S. and Mastenbroek S.. Factors affecting the gene expression of in vitro cultured human preimplantation embryos. Hum Reprod 2016;31:298–311.
    1. Meintjes M, Chantilis SJ, Douglas JD, Rodriguez AJ, Guerami AR, Bookout DM, Barnett BD, Madden JD. A controlled randomized trial evaluating the effect of lowered incubator oxygen tension on live births in a predominantly blastocyst transfer program. Hum Reprod 2009;24:300–307.
    1. Morin SJ. Oxygen tension in embryo culture: does a shift to 2% O2 in extended culture represent the most physiologic system? J Assist Reprod Genet 2017;34:309–314.
    1. Nastri CO, Nobrega BN, Teixeira DM, Amorim J, Diniz LM, Barbosa MW, Giorgi VS, Pileggi VN, Martins WP. Low versus atmospheric oxygen tension for embryo culture in assisted reproduction: a systematic review and meta-analysis. Fertil Steril 2016;106:95–104e117.
    1. Peng H, Shi W, Zhang W, Xue X, Li N, Li W, Shi J. Better quality and more usable embryos obtained on day 3 cultured in 5% than 20% oxygen: a controlled and randomized study using the sibling oocytes. Reprod Sci 2016;23:372–378.
    1. Peng ZF, Shi SL, Jin HX, Yao GD, Wang EY, Yang HY, Song WY, Sun YP. Impact of oxygen concentrations on fertilization, cleavage, implantation, and pregnancy rates of in vitro generated human embryos. Int J Clin Exp Med 2015;8:6179–6185.
    1. Quinn P, Harlow GM. The effect of oxygen on the development of preimplantation mouse embryos in vitro. J Exp Zool 1978;206:73–80.
    1. Rinaudo PF, Giritharan G, Talbi S, Dobson AT, Schultz RM. Effects of oxygen tension on gene expression in preimplantation mouse embryos. Fertil Steril 2006;86:1252–12651265 e1251-1236.
    1. Thompson JG, Simpson AC, Pugh PA, Donnelly PE, Tervit HR. Effect of oxygen concentration on in-vitro development of preimplantation sheep and cattle embryos. J Reprod Fertil 1990;89:573–578.
    1. Visser GH, Eilers PH, Elferink-Stinkens PM, Merkus HM, Wit JM. New Dutch reference curves for birthweight by gestational age. Early Hum Dev 2009;85:737–744.
    1. Waldenstrom U, Engstrom AB, Hellberg D, Nilsson S. Low-oxygen compared with high-oxygen atmosphere in blastocyst culture, a prospective randomized study. Fertil Steril 2009;91:2461–2465.
    1. Wale PL, Gardner DK. Time-lapse analysis of mouse embryo development in oxygen gradients. Reprod Biomed Online 2010;21:402–410.
    1. Wale PL, Gardner DK. Oxygen regulates amino acid turnover and carbohydrate uptake during the preimplantation period of mouse embryo development. Biol Reprod 2012;87.
    1. Wale PL, Gardner DK. Oxygen affects the ability of mouse blastocysts to regulate ammonium. Biol Reprod 2013;89.
    1. Wale PL, Gardner DK. The effects of chemical and physical factors on mammalian embryo culture and their importance for the practice of assisted human reproduction. Hum Reprod Update 2016;22:2–22.
    1. Zandstra H, Van Montfoort AP, Dumoulin JC. Does the type of culture medium used influence birthweight of children born after IVF? Hum Reprod 2015;30:530–542.
    1. Zandstra H, Brentjens L, Spauwen B, Touwslager RNH, Bons JAP, Mulder AL, Smits LJM, van der Hoeven M, Golde RJT, Evers JLH et al. . Association of culture medium with growth, weight and cardiovascular development of IVF children at the age of 9 years. Hum Reprod 2018;33:1645–1656.

Source: PubMed

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