Frozen Embryo Transfer (FET) cycles have increased ever since the first pregnancy from IVF using cryopreserved embryos was reported in 1983 (Trounson and Mohr, 1983). While frozen-thawed embryo transfer was initially developed to perform embryo transfer in oocyte donation cycles (Legro et al., 1993), it subsequently evolved towards an elective technique for patients with supernumerary embryos and an increased risk of developing ovarian hyperstimulation syndrome (Devroey et al., 2011). Nowadays, FET cycles are also used in cases with late-follicular progesterone elevation (Bosch et al., 2010; Roque et al., 2015; Healy et al., 2016), embryo-endometrial asynchrony (Shapiro et al., 2008), recurrent implantation failure (Magdi et al., 2017), and pre-implantation genetic diagnosis/screening. This evolution of utility in the FET landscape also reflects itself in the currently available data for FET usage, with a 93% increase of the procedure between 2013 and 2018 (“Fertility treatment 2018: trends and figures | HFEA,” https://www.hfea.gov.uk/about-us/publications/research-and-data/fertility-treatment-2018-trends-and-figures/).
A thorough look at the current FET protocols is important to gain more insight towards an optimal FET strategy. FET can take place in either a natural cycle or in an artificial cycle (Mackens et al., 2017). According to a recent Cochrane meta-analysis (Ghobara et al., 2017) there is no evidence to support the use of one regimen in preference to another. Nonetheless, taking into account the minimal cycle monitoring related to such practice, i.e. hormonal analyses and ultrasound scans of the endometrium, and the applicability to even women without regular bleeding, the protocol of exogenous oestrogen and progesterone administration is widely used for endometrial preparation (Younis et al., 1996). However, this approach has some disadvantages such as costs, inconvenience, prolonged treatment (especially in case of pregnancy) and potential side-effects associated with oestrogen supplementation, i.e. increased thrombotic risk and preeclampsia (von Versen-Höynck et al., 2019; Conrad et al., 2022). In fact, several observational studies have already hinted towards an increased risk of pre-eclampsia when using HRT for endometrial preparation (Sazonova et al., 2012; Ishihara et al., 2014; Opdahl et al., 2015), and a large systematic review (Roque et al., 2019) confirmed these findings with statistical significance. A relationship between the duration of oestrogen priming of the endometrium and the increased occurrence of hypertensive disorders was suggested by Roque et al. 2019 (Roque et al., 2019), while Shi et al. 2018 (Shi et al., 2018) found no differences in the occurrence of hypertensive disorders between eFET and fresh ET when eFET was performed in a natural cycle. On the other hand, oestrogen stimulation in FET-HRT activates thrombotic risk markers and a restriction in the use of unnecessary hormone exposure is important, as described recently by Dalsgaard et al., (2022). Moreover, still cycle cancellation due to spontaneous ovulation is an uncontrollable phenomenon that can always occur, especially when the oestrogen preparation takes long time, therefore the rationale for a shorter time to oestrogen exposure could potentially lead to less spontaneous ovulations and easier programming of the FET cycle. Contrasting results do exist, however, further emphasizing the need for additional exploration of this subject (Chen et al., 2016).
Nowadays, most FET-HRT protocols opt for the 14-day period of oestrogen supplementation to mimic the natural proliferative phase of the menstrual cycle (Conrad et al., 2017). However, scarce evidence has shown that 5 to 7 days is sufficient for endometrial proliferation (Conrad et al., 2017). Recently, Sekhon et al. (Sekhon et al., 2019), Joly et al. (Joly et al., 2023) and (Jiang et al., 2022) demonstrated in retrospective cohort studies including more than thousand patients, that the length of E2 supplementation is linked neither to implantation rate, nor live birth rate and cumulative live birth rate; as well as the level of oestradiol on the day of start of progesterone, (Mackens et al., 2020).
Besides the very open debate about the ideal length of the E2 supplementation and considering recent results showing that this has no effects on the FET outcome, we should consider another important issue of the FET cycle, which is the delayed time to pregnancy. A recent study on patients’ perspectives regarding elective FET (eFET) revealed that the postponement of embryo transfer is an important deciding factor in the choice of eFET versus fresh embryo transfer (Stormlund et al., 2019). Considering these important results, reducing time-to-pregnancy (TTP) in the FET-HRT protocol would therefore increase patient comfort when choosing eFET over fresh ET. Given the totally arbitrary decision to perform 14 days of oestrogen endometrial preparation in a FET-HRT, and the emerging evidence that the duration of oestrogen exposure does not affect success rates and given the real need to shorten time to pregnancy for patients facing IVF; the main objective of this pilot study is to evaluate the feasibility of a short endometrial preparation in FET-HRT cycles with the administration of 7 consecutive days of oestrogen priming prior to P4 initiation, by comparing clinical pregnancy rates with the standard of care (14 days of oestrogen priming).