Abstract

Introduction

During IVF treatment, the oxygen concentration in the incubator is an important determinant of the in vitro environment that an embryo encounters. The preimplantation embryo consumes oxygen at a relatively constant level from the one-cell through the morula stage, while at the blastocyst stage the consumption is considerably increased (Houghton et al., 1996). Oxygen plays a role in energy production, but in too high concentrations it may have a toxic effect by the formation of reactive oxygen species (Catt and Henman, 2000). While in vivo oxygen levels range from 1.5 to 8.7% in the fallopian tubes and uterus of several species (Fischer and Bavister, 1993), in most laboratories in vitro culture of human embryos was traditionally performed under atmospheric oxygen concentrations (~20%). The technologies available in the early days of IVF, and most likely also for financial reasons, led to the widespread implementation of incubators that used atmospheric air (i.e. 20% oxygen) (Wale and Gardner, 2016). Around the turn of the last century, more advanced incubators capable of creating an environment of 5% oxygen, which better resembles the natural environment for oocytes and embryos, were developed. Currently, in around 60% of the IVF cycles performed worldwide, the embryos are cultured under 5% oxygen (Christianson et al., 2014).

Over the years, many groups investigated the effect of the relatively high atmospheric oxygen concentration on the intrinsic properties of embryos in several species including human and found that high oxygen levels affect gene expression (Rinaudo et al., 2006; Mantikou et al., 2016), DNA methylation (Li et al., 2016), mitochondrial membrane potential (Ma et al., 2017), protein profiles (Katz-Jaffe et al., 2005) and embryo metabolism (Wale and Gardner, 2012; Wale and Gardner, 2013) (see Wale and Gardner, 2016, for a review on this topic). It is therefore not surprising that a high oxygen level also alters embryo development in humans (Dumoulin et al., 1999; Kovacic et al., 2010; Kirkegaard et al., 2013; Peng et al., 2016), in mouse (Quinn and Harlow, 1978; Karagenc et al., 2004; Wale and Gardner, 2010) and in sheep and cattle (Thompson et al., 1990).

The effect of oxygen level during embryo culture on pregnancy and live birth rates is less straightforward. Although most studies found an improvement in embryo quality when culturing embryos under 5% oxygen, pregnancy or live birth rates were not always better (Dumoulin et al., 1999; Bahceci et al., 2005; Kea et al., 2007; Meintjes et al., 2009; Waldenstrom et al., 2009; Kovacic et al., 2010; de los Santos et al., 2013; Peng et al., 2015). This discrepancy is partly explained by lack of power due to small sample sizes in some studies. When data are pooled in meta-analyses, the overall effect favours culture under 5% oxygen (Gomes Sobrinho et al., 2011; Bontekoe et al., 2012; Nastri et al., 2016). Another explanation for the inconsistent results among the studies could be due to the differences in duration of exposure, until cleavage or blastocyst stage. When data in the meta-analyses were stratified for duration of culture, there was no effect of oxygen on pregnancy or live birth rates after 2–3 days of culture. After culture to the blastocyst stage, however, culture under 5% oxygen resulted in improved ongoing pregnancy and live birth rates.

The discrepancy in the oxygen effect on pregnancy outcomes according to embryonic stage suggests that a longer exposure might be needed to observe an effect. However, as the embryo is more vulnerable to oxygen in the pre-compaction stage as compared to the post-compaction stage (Wale and Gardner, 2010; Kirkegaard et al., 2013), the duration might not be the problem. It is also possible that the morphology-based embryo scoring systems can better distinguish between a good- and lower-quality embryo at cleavage than at blastocyst stage, especially regarding cell number.

In an IVF programme with embryo culture either under high or low oxygen, the embryos that can cope best (i.e. the high-quality embryos) will be transferred, resulting in only small or no detectable effects of oxygen on pregnancy rates in fresh embryo transfer cycles. Better outcome parameters are embryo utilization rate and cumulative pregnancy rate after transfers of fresh and frozen-thawed embryos, since these reflect whether low oxygen moves overall embryo development to a more favourable side. The shift towards single fresh embryo transfer has made embryo cryopreservation and subsequent frozen-thawed embryo transfer of greater importance; therefore, now the additional pregnancies from these transfers can no longer be neglected and should be incorporated in the calculation of IVF success rates (Maheshwari et al., 2015). In most published studies, only fresh embryo transfers were taken into account, which might underestimate the effect of oxygen.

Another drawback of the published studies is that the data analyses have not always been carried out in a consistent and proper way. In studies in which patients were allocated to one of the two oxygen groups, embryo outcomes such as fertilization or cleavage have been analysed either as mean numbers or as mean proportions per cycle (Dumoulin et al., 1999; Waldenstrom et al., 2009), while in other papers the oocyte or embryo is the unit of analysis (Kea et al., 2007; de los Santos et al., 2013). This impedes a proper comparison. Furthermore, in a per embryo analysis it should be taken into account that oocytes and embryos from one patient do not reflect independent observations. This has not been done in any of the studies. Kirkegaard et al. showed that up to one-third of the variation in timing of embryo development is explained by patient characteristics (Kirkegaard et al., 2016). Failure to correct for this interdependency may lead to overestimation of potential effects.

In contrast to the numerous reports on the effects of different oxygen levels on embryo and pregnancy outcomes, the effects of oxygen levels on human offspring health are hardly investigated (Nastri et al., 2016), even though the effect of the preimplantation environment on offspring health is an emerging topic. In several studies, both in animals and in humans, certain IVF culture media or the protein source added to these media led to altered birthweights (Zandstra et al., 2015). This weight difference was found to be maintained at least until the age of 9 years (Zandstra et al., 2018). Birthweight is negatively related to the risk for adult diseases such as cardiovascular disease and diabetes (Barker, 2004). Whether this relation also accounts for IVF is not known yet, but the lower birthweight found in IVF children should raise awareness that the environment during very early life might have long-lasting effects.

Regarding the scarcity of data on oxygen concentration effects on cumulative pregnancy outcomes per started IVF cycle, the primary aim of our study was to investigate whether 5% oxygen as compared to 20% oxygen concentration leads to higher cumulative pregnancy rates per IVF cycle, if the data from additional transfers of cryopreserved embryos are included. In the 5- to 7-year follow-up period in this study, around 85% of the cryopreserved embryos were thawed and could be included in the analyses. The data are analysed on a per cycle and per embryo level separately, correcting for the interdependency between embryos from the same patient. Next to this, our secondary aim was to assess whether different oxygen concentrations during human embryo culture affect birthweight.

Materials and Methods

Study Design

Data for this retrospective cohort study were collected from patients who underwent an IVF cycle between January 2012 and December 2013 at the University Medical Centre Groningen (UMCG) (Fig. 1). Frozen embryo transfers from these cycles were included until December 2018, i.e. 7 years since the first and 5 years since the last oocyte retrieval in this study. Patients either had their full IVF cycle in the UMCG or were (part of) the clinical phase in the affiliated satellite clinic (Wilhelmina Hospital Assen (WZA)) or one of the transport clinics (Medical Center Leeuwarden (MCL) or Scheper Hospital Emmen (SZE)) and the laboratory phase at the UMCG. In the satellite clinic, only the ovarian stimulation is regulated and monitored, while all other procedures including oocyte retrieval, all laboratory procedures and embryo transfer are performed at the UMCG. In the transport clinics, all procedures up to and including the oocyte retrieval are performed, after which the oocytes within the follicular fluid are transported to the IVF laboratory at the UMCG, where all laboratory procedures, including embryo culture, and embryo transfer are performed. All clinical protocols were similar in all four hospitals. All laboratory procedures were always performed at the UMCG.

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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.

The study took place during a transition period in the UMCG, in which a change from culture with 20% oxygen to 5% oxygen was introduced in a stepwise manner. Three out of the four incubators were kept at the traditional ambient oxygen levels (Forma Scientific 3121 [Forma Scientific Inc., Marietta, OH, USA), 6% CO₂ and 20% O₂ in air], and one incubator was adjusted to have low oxygen levels of 5% [Sanyo MCO-18M (Sanyo, Osaka, Japan), 6% CO₂, 5% O₂ and 89% N₂]. Cycles were arbitrarily allocated to one of the four incubators, based on daily available positions, and all oocytes and embryos from that cycle were fertilized and cultured under 5 or 20% oxygen, respectively. Both type of incubators had eight workspaces and were used at equal intensity. All clinical and laboratory procedures were similar in both groups. Only cycles with at least one inseminated or injected oocyte were included, and cycles in which donor gametes were used or PGD or fertility preservation was performed were excluded.

To compare embryo and (cumulative) pregnancy outcomes between the two oxygen groups, only one cycle per patient was included in the analysis. This cycle was the patient’s first cycle performed after the start of the study in January 2012, but the cycle could have a higher rank order (Fig. 1).

At the start of their IVF treatment, all patients at the UMCG and affiliated clinics sign a universal consent form in which they allow the use of their data obtained during routine medical care from medical records for research purposes, under the condition that the patients’ identity remains untraceable and the data remain confidential. The Institutional Review Board of the UMCG approved the study (file no M19.225065).

Results

Study population

During the study period from January 2012 to December 2013, 871 out of the 965 consecutive patients could be included and underwent 1378 IVF or IVF/ICSI treatment cycles in which at least one oocyte was available for injection or insemination (Fig. 1). Only one cycle per patient was included in the analysis and this cycle was the patient’s first cycle performed after the start of the study in January 2012. One hundred ninety-five cycles from 195 patients were arbitrarily allocated based on daily available positions to the only incubator with 5% oxygen, and 676 cycles from 676 patients to one of the three incubators with 20% oxygen. The characteristics of the groups are shown in Table I and were comparable.

Table I

Patient characteristics at the time of inclusion in 871 women who participated in the study and whose embryos were cultured under 5% or 20% oxygen.

		5% O 2 (n =195)	20% O 2 (n =676)	P value
Maternal age (years)		33.9±4.0	34.0±4.5	NS
Duration of subfertility (years)		3.8±2.6	3.9±2.6	NS
COS cycle order	1 2 3 ≥4	114 (58.5%) 55 (28.2%) 19 (9.7%) 7 (3.6%)	378 (55.9%) 182 (26.9%) 83 (12.3%) 33 (4.9%)	NS
Fertilization method	IVF ICSI	52 (26.7%) 143 (73.3%)	198 (29.3%) 478 (70.7%)	NS
Subfertility	Primary subfertility* Secondary subfertility	123 (63.1%) 72 (36.9%)	380 (56.9%) 288 (43.1%)	NS
Cause of subfertility	Female factor Male factor Unexplained	49 (25.1%) 109 (55.9%) 37 (19.0%)	172 (25.4%) 362 (53.6%) 142 (21.0%)	NS
Clinic	UMCG WZA (Satellite) MCL, SZE (Transport)	118 (60.5%) 8 (4.1%) 69 (35.4%)	352 (52.1%) 42 (6.2%) 282 (41.7%)	NS

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Data are presented as mean±SD or as number (%).

^*For eight cases in the 20% group, primary or secondary subfertility was not known.

COS=controlled ovarian stimulation, UMCG=University Medical Centre Groningen, WZA=Wilhelmina Hospital Assen, MCL=Medical Centre Leeuwarden, SZE=Scheper Hospital Emmen.

NS=Not significant, P >0.05.

IVF outcomes

In Table II, the embryo characteristics and outcomes in both oxygen groups are shown. These characteristics are expressed and analysed per cycle and per embryo. In both analyses, there were significantly more embryos with 2PN that cleaved, and more embryos of good quality (2PN on Day 1 and four cells on Day 2, with less than 20% fragmentation and no multinucleated blastomeres) in the lower oxygen group. Therefore, more embryos could be cryopreserved, and a significantly higher embryo utilization rate was achieved in the lower compared to the higher oxygen group. These differences remained significant after correction for maternal age, cycle rank order, fertilization method (IVF or ICSI) and cause of subfertility. The mean number of embryos transferred per cycle was significantly lower in the 5% oxygen group (see Table II, analysis per cycle), while in the analysis per oocyte/embryo, the percentage of embryos that was transferred from the total number of embryos was similar in both groups (see Table II).

Table II

Embryo characteristics and outcomes after culture under either 5 or 20% oxygen, analysed by comparing averages per cycle by using linear regression analysis and by comparing the outcomes per oocyte/embryo by using GEE binary logistic models.

	5% O 2	20% O 2	P value	Adjusted P value 6
Analysis per cycle	n =195	n =676
Number of oocytes	8.3±5.1	8.1±5.0	NS	NS
Number of patients with >10 oocytes	64 (32.8%)	229 (33.9%)	NS	-
Number of patients with >20 oocytes	7 (3.6%)	25 (3.7%)	NS	-
Number of injected or inseminated oocytes	7.4±4.5	7.1±4.5	NS	NS
Fertilization rate1	62.4±26.5	62.7±26.7	NS	NS
Cleavage rate2	97.0±10.4	94.2±16.2	P <0.05	P <0.05
Good-quality embryo rate2,4	48.0±33.8	30.4±32.5	P <0.001	P <0.001
Number of embryos transferred3	1.2±0.4	1.3±0.5	P <0.05	P <0.05
Number of embryos cryopreserved3	2.1±2.3	1.4±2.0	P <0.001	P <0.001
Embryo utilization rate2,5	76.1±25.7	66.2±31.6	P <0.001	P <0.001
Number of thaw cycles with cryopreserved embryos	1.10±1.4	0.8±1.2	P =0.002	-
Analysis per oocyte/embryo	n =1627	n =5448	Crude GEE-OR [95% CI]	Adjusted GEE-OR [95% CI] 6
Number of injected or inseminated oocytes	1448/1627 (89.0%)	4779/5448 (87.7%)	1.1 [0.88–1.48]	1.2 [0.90–1.49]
Normal fertilization rate (2PN)	877/1448 (60.6%)	3031/4779 (63.4%)	0.9 [0.78–1.09]	0.9 [0.79–1.10]
Cleavage rate	849/877 (96.8%)	2865/3031 (94.5%)	1.8 [1.18–2.86]	1.8 [1.17–2.85]
Good-quality embryo rate	402/877 (45.8%)	936/3031 (30.9%)	2.0 [1.59–2.39]	1.9 [1.59–2.39]
Embryos transferred	226/877 (25.8%)	842/3031 (27.8%)	0.9 [0.76–1.05]	0.9 [0.76–1.06]
Embryos cryopreserved	404/877 (46.1%)	900/3031 (29.7%)	2.0 [1.66–2.47]	2.0 [1.67–2.49]
Embryo utilization rate	630/877 (71.8%)	1742/3031 (57.5%)	1.8 [1.50–2.20]	1.8 [1.50–2.20]

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Data are presented as mean±SD or as number (%).

¹Expressed as the proportion of the number of injected or inseminated oocytes.

²Expressed as the proportion of the number of two pronuclei (2PN) zygotes per cycle.

³Expressed as mean per cycle with zygotes.

⁴Defined as having 2PN on Day 1 and four blastomeres on Day 2 with less than 20% fragmentation and no multinucleated blastomeres.

⁵Defined as the proportion of zygotes per cycle that is transferred or cryopreserved as an embryo.

⁶The difference between the oxygen groups was corrected for maternal age, cycle rank order, cause of subfertility and fertilization method, except at number of oocytes and number of injected or inseminated oocytes where fertilization method was left out of the analysis.

NS=not significant, P >0.05.

GEE-OR=odds ratio derived from the general estimating equations (GEE) binary logistic models.

The improved average embryo quality did not affect the ongoing pregnancy and live birth rates in the fresh embryo transfer cycles (Table III). However, after including the frozen-thawed embryo transfer cycles, performed in 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 (see Supplementary Table SII), the percentage of patients with at least one ongoing pregnancy (26.2 versus 19.4% in the 5 and 20% groups, respectively) or one live birth (25.1 versus 18.8%) was significantly higher in the low oxygen group (Table III, adjusted odds ratio=1.5, both significant). Seven patients had two live births from one started fresh cycle (i.e. six times one live birth after transfer of a fresh embryo and one after transfer of frozen-thawed embryos and one time two live births after two consecutive frozen embryo transfers). At the end of the follow-up period, 75 patients (23 (18.1%) in the 5% group and 52 (16.3%) in the 20% group) still had embryos cryopreserved (Supplementary Table SII, range 1–11 embryos), of which 57 patients already had at least one live birth from the transfer of fresh or frozen-thawed embryos from this cycle.

Table III

Pregnancy outcomes in 195 cycles with embryo culture under 5% oxygen and 676 cycles with culture under 20% oxygen.

	5% O 2 (n =195)	20% O 2 (n =676)	P value	Adjusted OR 2 [95% CI]
After fresh embryo transfer
Biochemical pregnancy	50/195 (25.6%)	142/676 (21.0%)	NS	1.3 [0.90–1.90]
Implantation1	45/226 (19.9%)	135/842 (16.0%)	NS	1.3 [0.88–1.88]
Ongoing pregnancy	40/195 (20.5%)	104/676 (15.4%)	NS	1.4 [0.95–2.16]
Live birth	37/195 (19.0%)	100/676 (14.8%)	NS	1.4 [0.90–2.07]
Multiple pregnancy	2/37 (5.4%)	11/100 (11.0%)	NS	0.4 [0.08–2.05]
Cumulative after fresh and frozen-thawed embryo transfer
At least one ongoing pregnancy	51/195 (26.2%)	131/676 (19.4%)	0.04	1.5 [1.04–2.19]
At least one live birth	49/195 (25.1%)	127/676 (18.8%)	0.052	1.5 [1.01–2.17]

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Data are presented as number (%) or as mean±SD. NS=not significant, P >0.05.

¹Defined as the total number of foetal sacs divided by the total number of embryos transferred.

²The difference between the oxygen groups was corrected for maternal age, cycle rank order, cause of subfertility and fertilization method.

Perinatal outcomes

Data on the perinatal outcome parameters (gender, gestational age at birth and birthweight) was obtained from 100, 100 and 89%, respectively, of the 124 live born singletons after fresh embryo transfers. There was no difference in perinatal outcome between the 5 and 20% oxygen group regarding birthweight, birthweight corrected for gestational age at birth, gender and parity (Z score), gestational age at birth and gender (Table IV).

Table IV

Perinatal outcome in 124 and 46 singleton live births after fresh and frozen-thawed embryo transfers respectively, with embryo culture under either 5 or 20% oxygen.

After fresh embryo transfer		5% O2 (n =35)	20% O2 (n =89)	P value
Birthweight (grams)		3464±616	3421±538	NS
Z score1		0.29±1.0	0.19±1.0	NS
Gestational age at birth (weeks)		39.3±2.2	39.1±1.6	NS
Gender	Male	20 (57.1%)	51 (57.3%)	NS
	Female	15 (42.9%)	38 (42.7%)
After frozen-thawed embryo transfer		5% O2 (n =14)	20% O2 (n =32)
Birthweight (grams)		3513±778	3527±454	NS
Z score1		0.64±0.9	0.23±1.1	NS
Gestational age at birth (weeks)		37.5±5.9	39.7±1.3	NS
Gender	Male	7 (50.0%)	15 (46.9%)	NS
	Female	7 (50.0%)	17 (53.1%)

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Data are presented as mean±SD or as number (%).

¹ Z score indicates birthweight corrected for gender, parity and gestational age at birth.

NS=not significant, P >0.05.

There were 47 live births after the transfer of frozen-thawed embryos. One of these was a twin and 46 were singletons. From 38 (82.6%) live born singletons (11 in the 5% and 27 in the 20% oxygen group), birthweight data were obtained. Gender and gestational age were known for all live born singletons. The perinatal outcome parameters did not differ between the singletons in the 5 and 20% oxygen group (Table IV).

A multivariate regression analysis on birthweight and oxygen level while correcting for several potential confounding factors, such as gestational age at birth, gender, fertilization method (IVF or ICSI), number of transferred embryos, primiparity (yes or no), cause of subfertility and duration of subfertility, showed that birthweight was not related to oxygen level during embryo culture, neither after fresh nor frozen-thawed embryo transfer.

Discussion

The results from this study show that embryo culture under 5% oxygen level as compared to 20% for as little as 2 days already leads to a higher number of good-quality embryos, and thus more embryos suitable for cryopreservation. Consequently, the cumulative ongoing pregnancy and live birth rate after transfer of fresh and frozen embryos from one cycle was significantly higher in the 5% oxygen group as compared to the 20% group. The oxygen level did not affect birthweight of the resulting singletons.

The improved embryo quality in the 5% oxygen group was no surprise as a better embryo development in low oxygen has been shown before. Kirkegaard and colleagues compared human embryo development by using time-lapse monitoring and found that timing of the third cleavage division was delayed in culture under 20% oxygen as compared to 5% The timing of blastocyst stages was similar, however, suggesting stage-specific oxygen effects (Kirkegaard et al., 2013). These data confirm earlier time-lapse data in mice where continuous culture under 20% oxygen for 118 h delayed timing of the first, second and third cleavage divisions as well as blastocyst development(Wale and Gardner, 2010). A switch at 48 h from 20 to 5% oxygen level did not alter the outcomes, again suggesting a specific oxygen effect at pre-compaction stage that is not reversible.

The improved embryo quality in the 5% oxygen group indeed resulted in more suitable embryos for cryopreservation and better cumulative ongoing pregnancy and live birth rates. Reporting the cumulative pregnancy rates per cycle after transfer of fresh and frozen embryos, as assessed in our study, is to be preferred when comparing IVF treatments. So far, only a few studies had cumulative pregnancy rates as an endpoint, but have reported contradictory results. Kovacic et al. (2010) reported a significantly improved cumulative pregnancy rate after culturing under low oxygen, while De los Santos et al. (2013) did not find a difference in cumulative pregnancy rates between the 5 and 20% oxygen groups in ovum donation cycles. In both studies, it is unclear, however, how many embryos were still cryopreserved at the end of the study period and whether transfer of these embryos could have led to a divergence in cumulative live birth rate between the two oxygen groups.

Our study had a long follow-up time of 5–7 years in which 84.5% of all frozen embryos were thawed. At the end of the follow-up period, in the 5% group 23 patients still had 71 embryos cryopreserved and in the 20% group were 52 patients with 131 embryos. Twelve and 15 patients in the 5 and 20% groups, respectively, had not achieved a live birth in the fresh embryo transfer cycle in which remaining embryos had been cryopreserved and, although not very likely after 5–7 years, they might still return to our clinic for an additional transfer. However, a similar rate of patients achieving a live birth in each group will not change the outcome of the study. For example, if one-third of these patients would achieve a live birth, the four and five extra live births in the 5 and 20% groups would result in cumulative live birth rates of 27.2 and 19.5%, respectively (P =0.021).

Besides the long 5- to 7-year follow-up, another strength of this study is that the analyses of embryo outcomes were conducted both per cycle and per oocyte/embryo and that the analyses per oocyte/embryo were corrected for the interdependency of data from embryos from the same patient. In a per cycle analysis, the number of oocytes and embryos per cycle is not taken into account and therefore the interpretation of the outcomes is different. That outcomes can differ when analysed on a per cycle or per embryo level becomes apparent with the average number of embryos transferred. Per cycle, there were on average more embryos transferred in the 20% oxygen when compared to the 5% group, while at the embryo level there was no difference between the two groups regarding the percentage of embryos selected for transfer.

As this was a retrospective study, allocation to the two oxygen groups was not randomized. Furthermore, the selection of the embryos to be cryopreserved was based on morphological criteria, which might be different from those applied in other clinics, although cell number, degree of fragmentation and absence of multinucleation are widely used. Another limitation of this study is that besides the two different oxygen levels, two different types of incubators were also used. Therefore, we analysed data from the year preceding the transition from 20 to 5% oxygen and showed that in 20% oxygen the embryo outcome parameters were similar between the two incubator types.

Recently, it was suggested to reduce the oxygen level after day 3 to 2%, as this would mimic the decreasing oxygen gradient in the female reproductive tract from the tubes towards the uterus (Morin, 2017). However, in a recently published randomized controlled trial, no better blastulation and blastocyst utilization rates were achieved when compared to continuous culture under 5% (De Munck et al., 2018). Bolnick and colleagues suggested, based on culture of embryonic and trophoblastic stem cells, that 2% could be the optimal oxygen level for human embryo culture, although in order to optimize embryo culture at 2% oxygen, other elements of culture should be adjusted as well (Bolnick et al., 2017).

We found no differences in birthweights, and our results are comparable to those in two other studies that reported on human birthweight after culturing under two different oxygen conditions (Meintjes et al., 2009; Kasterstein et al., 2013). In these studies, however, the number of included live births was small (ranging from 6 to 26 per group) and no correction for possible confounding factors was done. In studies investigating trends in birthweight over time, one study found an increase in birthweight over time, especially after the implementation of bench top incubators with 5% oxygen (Castillo et al., 2019), while another study did not see an effect (Maas et al., 2016). However, in these kinds of retrospective analyses in which many patient, clinic and laboratory factors are subject to change over time, it is difficult, if not impossible, to pinpoint changes in birthweight to a specific item. In animal studies, opposing results have been found. Culture of bovine embryos in 5% as compared to 20% oxygen levels resulted in a reduced weight at birth (Fischer-Brown et al., 2005) and 14 days post-partum (Iwata et al., 2000), which might have been due to a reduced cotyledon surface area reported in the placentas of the 5% group (Fischer-Brown et al., 2005). Exposure of mouse embryos to 2% oxygen levels during the post-compaction stage only led to a reduced foetal weight at embryonic day 18 when compared to exposure to 7 or 20% oxygen and to an in vivo group (Feil et al., 2006). This reduction might also be caused by the reduced placental surface available for exchange that was reported in the 2% group. In another study in mice comparing the effect of culture under 5 and 20% oxygen, foetal weights were similar, but the increased number of resorption sites in the 20% oxygen group might have biased the results (Karagenc et al., 2004).

No difference in birthweight does not necessarily mean that health in the longer term is unaffected. It has been reported that atmospheric 20% oxygen during embryo culture affects repressive and permissive histone modifications in bovine blastocysts (Gaspar et al., 2015) and gene expression in mouse blastocysts (Rinaudo et al., 2006). Whether these epigenetic changes are adaptive or deregulatory, and whether these changes only alter the embryonic developmental potential or lead to long-term alterations in the offspring, is not yet known. On the other hand, in a study in mice in which IVF with two different oxygen levels and natural conception were compared, an increased frequency of stochastic epigenetic errors at imprinted genes in placental tissue was detected after IVF: there were, however, no differences in epigenetic errors between the oxygen levels (de Waal et al., 2014).

As far as we know, this study is the largest study reporting on 5 versus 20% oxygen levels during human embryo culture and birthweight. Despite the retrospective design of the study, correction for major confounding factors such as gender, gestational age at birth and parity was possible. However, information on other possible confounding factors, including pregnancy complications, parental weight and height and maternal smoking during pregnancy, were missing. Furthermore, this study was not powered for a predefined birthweight difference. It should therefore be kept in mind that with the number of live births in our study, small differences in birthweight might not have been detected.

In conclusion, after culturing embryos for 2 days under either 5 or 20% oxygen, the cumulative ongoing pregnancy rates and live birth rates per cycle were higher in the 5% group owing to more good-quality embryos available for cryopreservation and subsequent transfer. There was no difference in birthweights of the live born singletons. Our results support the implementation of 5% oxygen during culture instead of 20%, even for short culture protocols. Long-term follow-up of IVF offspring is needed to ascertain the safety of embryo culture in general, regardless of culturing under 5 or 20% oxygen.

Supplementary Material

Acknowledgements

References