Uniform Aneuploidy Research Articles

Human embryos with segmental aneuploidies display delayed early development: a multi-centre morphokinetic analysis.

ObjectivesTo assess if segmental aneuploid embryos display unique morphokinetic patterns DesignRetrospective multicentre study including a total of 7,027 embryos cultured between 2016 and 2021 in 3 European IVF centres. Analysis was performed on aggregated multicentre data and separately for data from each centre. Embryos with no more than 4 chromosomal alterations were considered in the analysis, resulting in 3,040 euploids, 2,818 whole-chromosome and 697 segmental aneuploids. Overall, the dataset contained 3,742 distinct euploid-segmental sibling pairs. SubjectsStandard morphokinetic features were annotated using various time-lapse systems. Blastocysts were subjected to comprehensive chromosomal screening via PGT-A. ExposureMorphokinetic patterns were compared among euploid, whole-chromosome aneuploid, and segmental aneuploid embryos. Main outcomes measuresMorphokinetic timings across groups were compared using statistical analysis and associations with cleavage features were assessed. Multi-centre and centre-specific multivariate logistic regression models were calibrated, and their predictive performance was evaluated on independent test set data using Area-Under-ROC curve metrics. ResultsSegmental aneuploid embryos cleaved significantly slower than their euploid siblings across the first three cell cycles, with a delay reaching the blastocyst stage of development. Specifically during these early cell cycles, segmental aneuploid embryos were also shown to be significantly slower than their aneuploid siblings . A logistic model based on morphokinetic data from the multicentre dataset and regressed against type of aneuploidy displayed modest predictive performance on an independent test set (train-AUROC=0.58; test-AUROC=0.57). Predictive performance improved based on data from a single centre displaying adequate predictive performance on an independent test set from the same centre (train-AUROC=0.74; test-AUROC=0.64). However, the predictive value diminished when tested on data from other centres (AUROC=0.52-0.55). Finally, the presence of multinucleation and blastomere exclusion at cleavage stage, were associated with segmental aneuploidies. The combination of morphokinetic features and these discrete embryo morphological features into the logistic regression model (train AUROC=0.71) provided an improved prediction of segmental aneuploidy, supporting future investigations using more comprehensive annotation systems. ConclusionThe developed predictive framework might help improve decision-making in PGT-A cycles, helping in the evaluation of embryos showing segmental aneuploidy and distinguishing which embryos are more likely to not have lethal uniform aneuploidies for transfer.

Time will tell: time-lapse technology and artificial intelligence to set time cut-offs indicating embryo incompetence.

Can more reliable time cut-offs of embryo developmental incompetence be generated by combining time-lapse technology (TLT), artificial intelligence, and preimplantation genetics screening for aneuploidy (PGT-A)? Embryo developmental incompetence can be better predicted by time cut-offs at multiple developmental stages and for different ranges of maternal age. TLT is instrumental for the continual and undisturbed observation of embryo development. It has produced morphokinetic algorithms aimed at selecting embryos able to generate a viable pregnancy, however, such efforts have had limited success. Regardless, the potential of this technology for improving multiple aspects of the IVF process remains considerable. Specifically, TLT could be harnessed to discriminate developmentally incompetent embryos: i.e. those unable to develop to the blastocyst stage or affected by full-chromosome meiotic aneuploidies. If proven valuable, this application would prevent the non-productive use of such embryos, thereby improving laboratory and clinical efficiency and reducing patient stress and costs due to unnecessary embryo transfer and cryopreservation. The training dataset involved embryos of PGT-A cycles cultured in Embryoscope with a single media (836 euploid and 1179 aneuploid blastocysts and 1874 arrested embryos; 2013-2020). Selection criteria were ejaculated sperm, own (not donated) fresh oocytes, trophectoderm biopsy and comprehensive-chromosome-testing to diagnose uniform aneuploidies. Out-of-sample (30% of training), internal (299 euploid and 490 aneuploid blastocysts and 680 arrested embryos; 2021-2022) and external (97 euploid, 110 aneuploid and 603 untested blastocysts and 514 arrested embryos, 2018 to early 2022) validations were conducted. A training dataset (70%) was used to define thresholds. Several models were generated by fitting outcomes to each timing (tPNa-t8) and maternal age. ROC curves pinpointed in-sample classification values associated with 95%, 99% and 99.99% true-positive rate for predicting incompetence. These values were integrated with upper limits of maternal age ranges (<35, 35-37, 38-40, 41-42, and >42 years) in logit functions to identify time cut-offs, whose accuracy was tested on the validation datasets through confusion matrices. For developmental (in)competence, the best performing (i) tPNa cut-offs were 27.8 hpi (error-rate: 0/743), 32.6 hpi (error rate: 0/934), 26.8 hpi (error rate: 0/1178), 22.9 hpi (error-rate: 1/654, 0.1%) and 17.2 hpi (error rate: 4/423, 0.9%) in the <35, 35-37, 38-40, 41-42, and >42 years groups, respectively; (ii) tPNf cut-offs were 36.7 hpi (error rate: 0/738), 47.9 hpi (error rate: 0/921), 45.6 hpi (error rate: 1/1156, 0.1%), 44.1 hpi (error rate: 0/647) and 41.8 hpi (error rate: 0/417); (iii) t2 cut-offs were 50.9 hpi (error rate: 0/724), 49 hpi (error rate: 0/915), 47.1 hpi (error rate: 0/1146), 45.8 hpi (error rate: 0/636) and 43.9 hpi (error rate: 0/416); (iv) t4 cut-offs were 66.9 hpi (error rate: 0/683), 80.7 hpi (error rate: 0/836), 77.1 hpi (error rate: 0/1063), 74.7 hpi (error rate: 0/590) and 71.2 hpi (error rate: 0/389); and (v) t8 cut-offs were 118.1 hpi (error rate: 0/619), 110.6 hpi (error rate: 0/772), 140 hpi (error rate: 0/969), 135 hpi (error rate: 0/533) and 127.5 hpi (error rate: 0/355). tPNf and t2 showed a significant association with chromosomal (in)competence, also when adjusted for maternal age. Nevertheless, the relevant cut-offs were found to perform less well and were redundant compared with the blastocyst development cut-offs. Study limits are its retrospective design and the datasets being unbalanced towards advanced maternal age cases. The potential effects of abnormal cleavage patterns were not assessed. Larger sample sizes and external validations in other clinical settings are warranted. If confirmed by independent studies, this approach could significantly improve the efficiency of ART, by reducing the workload and patient impacts (extended culture and cleavage stage cryopreservation or transfer) associated with embryos that ultimately are developmentally incompetent and should not be considered for treatment. Pending validation, these data might be applied also in static embryo observation settings. This study was supported by the participating institutions. The authors have no conflicts of interest to declare. N/A.

Effects of ovarian stimulation on embryo euploidy: an analysis of 12874 oocytes and 3106 blastocysts in cycles with preimplantation genetic testing for monogenic disorders.

Does ovarian stimulation and the ovarian response affect embryo euploidy? Ovarian stimulation and the ovarian response in women undergoing preimplantation genetic testing for monogenic disorders (PGT-M) cycles did not affect the rates of blastocyst euploidy. Whether or not ovarian stimulation in IVF-embryo transfer has potential effects on embryo euploidy is controversial among studies for several reasons: (i) heterogeneity of the study populations, (ii) biopsies being performed at different stages of embryo development and (iii) evolution of the platforms utilized for ploidy assessment. Patients who undergo PGT-M cycles typically have no additional risks of aneuploidy, providing an ideal study population for exploring this issue. A retrospective cohort study including embryos undergoing PGT-M was conducted at a single academically affiliated fertility clinic between June 2014 and July 2021. A total of 617 women with 867 PGT-M cycles involving 12874 retrieved oocytes and 3106 trophectoderm biopsies of blastocysts were included. The primary outcome of the study was median euploidy rate, which was calculated by dividing the number of euploid blastocysts by the total number of biopsied blastocysts for each cycle. Secondary outcomes included the median normal fertilization rate (two-pronuclear (2PN) embryos/metaphase II oocytes) and median blastulation rate (blastocyst numbers/2PN embryos). Comparable euploidy rates and fertilization rates were observed across all age groups, regardless of variations in ovarian stimulation protocols, gonadotropin dosages (both the starting and total dosages), stimulation durations, the inclusion of human menopausal gonadotrophin supplementation, or the number of oocytes retrieved (all P > 0.05). Blastulation rates declined with increasing starting doses of gonadotropins in women aged 31-34 years old (P = 0.005) but increased with increasing gonadotrophin starting doses in women aged 35-37 years old (P = 0.017). In women aged 31-34, 35-37, and 38-40 years old, blastulation rates were significantly reduced with increases in the number of oocytes retrieved (P = 0.001, <0.001, and 0.012, respectively). Limitations include the study's retrospective nature and the relatively small number of patients of advanced age, especially patients older than 40 years old, leading to quite low statistical power. Second, as we considered euploidy rates as outcome measures, we did not analyze the effects of ovarian stimulation on uniform aneuploidy and mosaicism, respectively. Finally, we did not consider the effects of paternal characteristics on embryo euploidy status due to the fact that blastocyst aneuploidy primarily originates from maternal meiosis. However, sperm factors might have an effect on embryo development and the blastulation rate, and therefore also the number of blastocysts analyzed. The exclusion of patients with severe teratozoospermia and the fact that only ICSI was used as the insemination technique for women undergoing PGT-M contributed to minimize the effect of paternal factors. Ovarian stimulation and response to stimulation did not affect blastocyst euploidy rates in women undergoing PGT-M cycles. However, in women aged 31-40 years old, there was a significant decline in blastulation rates as the number of retrieved oocytes increased. This study was supported by the National Natural Science Foundation of China (Grant No. 81701407, 82301826); the National Key Research and Development Program of China (2022YFC2702901, 2022YFC2703004); China Postdoctoral Science Foundation (2022M710261), and China Postdoctoral Innovation Talent Support Program (BX20220020). There is no conflict of interest. N/A.

Aligning genotyping and copy number data in single trophectoderm biopsies for aneuploidy prediction: uncovering incomplete concordance.

To what extent can genotype analysis aid in the classification of (mosaic) aneuploid embryos diagnosed through copy number analysis of a trophectoderm (TE) biopsy? In a small portion of embryos, genotype analysis revealed signatures of meiotic or uniform aneuploidy in those diagnosed with intermediate copy number changes, and signatures of presumed mitotic or putative mosaic aneuploidy in those diagnosed with full copy number changes. Comprehensive chromosome screening (CCS) for preimplantation genetic testing has provided valuable insights into the prevalence of (mosaic) chromosomal aneuploidy at the blastocyst stage. However, diagnosis of (mosaic) aneuploidy often relies solely on (intermediate) copy number analysis of a single TE biopsy. Integrating genotype information allows for independent assessment of the origin and degree of aneuploidy. Yet, studies aligning both datasets to predict (putative mosaic) aneuploidy in embryos remain scarce. A single TE biopsy was collected from 1560 embryos derived from 221 couples tested for a monogenic disorder (n = 218) or microdeletion-/microduplication syndrome (n = 3). TE samples were subjected to both copy number and genotyping analysis. Copy number and SNP genotyping analysis were conducted using GENType. Unbalanced chromosomal anomalies ≥10 Mb (or ≥20 Mb for copy number calls <50%) were classified by degree, based on low-range intermediate (LR, 30-50%), high-range intermediate (HR, 50-70%) or full (>70%) copy number changes. These categories were further subjected to genotyping analysis to ascertain the origin (and/or degree) of aneuploidy. For chromosomal gains, the meiotic division of origin (meiotic I/II versus non-meiotic or presumed mitotic) was established by studying the haplotypes. The level of monosomy (uniform versus putative mosaic) in the biopsy could be ascertained from the B-allele frequencies. For segmental aneuploidies, genotyping was restricted to deletions. Of 1479 analysed embryos, 24% (n = 356) exhibited a whole-chromosome aneuploidy, with 19% (n = 280) showing full copy number changes suggestive of uniform aneuploidy. Among 258 embryos further investigated by genotyping, 95% of trisomies with full copy number changes were identified to be of meiotic origin. For monosomies, a complete loss of heterozygosity (LOH) in the biopsy was observed in 97% of cases, yielding a 96% concordance rate at the embryo level (n = 248/258). Interestingly, 4% of embryos (n = 10/258) showed SNP signatures of non-meiotic gain or putative mosaic loss instead. Meanwhile, 5% of embryos (n = 76/1479) solely displayed HR (2.5%; n = 37) or LR (2.6%; n = 39) intermediate copy number changes, with an additional 2% showing both intermediate and full copy number changes. Among embryos with HR intermediate copy number changes where genotyping was feasible (n = 25/37), 92% (n = 23/25) showed SNP signatures consistent with putative mosaic aneuploidy. However, 8% (n = 2/25) exhibited evidence of meiotic trisomy (9%) or complete LOH in the biopsy (7%). In the LR intermediate group, 1 of 33 (3%) genotyped embryos displayed complete LOH. Furthermore, segmental aneuploidy was detected in 7% of embryos (n = 108/1479) (or 9% (n = 139) with added whole-chromosome aneuploidy). These errors were often (52%) characterized by intermediate copy number values, which closely aligned with genotyping data when examined (94-100%). N/A. The findings were based on single TE biopsies and the true extent of mosaicism was not validated through embryo dissection. Moreover, evidence of absence of a meiotic origin for a trisomy should not be construed as definitive proof of a mitotic error. Additionally, a genotyping diagnosis was not always attainable due to the absence of a recombination event necessary to discern between meiotic II and non-meiotic trisomy, or the unavailability of DNA from both parents. Interpreting (intermediate) copy number changes of a single TE biopsy alone as evidence for (mosaic) aneuploidy in the embryo remains suboptimal. Integrating genotype information alongside the copy number status could provide a more comprehensive assessment of the embryo's genetic makeup, within and beyond the single TE biopsy. By identifying meiotic aberrations, especially in presumed mosaic embryos, we underscore the potential value of genotyping analysis as a deselection tool, ultimately striving to reduce adverse clinical outcomes. L.D.W. was supported by the Research Foundation Flanders (FWO; 1S74621N). M.B., K.T., F.V.M., S.J., A.V.T., V.S., D.S., A.D., and S.S. are supported by Ghent University Hospital. B.M. was funded by Ghent University. The authors have no conflicts of interest.

P-539 Chaotic blastocysts in preimplantation genetic testing for aneuploidies: prevalence, characterization and re-biopsy results

Abstract Study question Are we excluding blastocysts with favorable reproductive potential when embryos are designated as chaotic by Preimplantation Genetic Testing for Aneuploidies (PGT-A)? Summary answer The re-biopsy of chaotic blastocysts can rescue embryos with favorable reproductive potential only when there are ≥5 chromosomes displaying intermediate copy number values (CNV). What is known already An embryo is deemed as chaotic when multiple aneuploidies (5, 6 or more) are detected in the biopsied cells of the trophectoderm. Such embryos are classified as aneuploid, therefore their transfer is not recommended. There is evidence that chaotic embryos may result from the biopsy of apoptotic cells, cellular fragments and, more broadly, DNA degraded by multiple factors. Studies involving the re-biopsy and re-testing of a limited number of chaotic embryos have found a relevant percentage of euploid results. Moreover, there has been published a case report of a healthy live birth after the transfer of a chaotic embryo. Study design, size, duration This is a retrospective study of 1,442 cycles of PGT-A performed in twenty-two in vitro fertilization (IVF) clinics from November 2017 to December 2023. A total of 5,801 blastocysts were biopsied and analyzed in a single reference laboratory using Next-Generation Sequencing. Ninety-three chaotic blastocysts donated from patients who provided informed consent were thawed for re-biopsy in two IVF clinics. The subsequent re-analysis was performed in the same PGT laboratory using the same methodology. Participants/materials, setting, methods This study assessed the prevalence of chaotic embryos in all included cycles. Chaotic embryos were considered those with ≥5 chromosomes showing CNV below 1.75 or above 2.25. We sub-classified these embryos into pure chaotic (≥5 uniform aneuploidies), mixed chaotic (≥5 alterations considering uniform aneuploidies and chromosomes with intermediate CNV) and mosaic chaotic (≥5 chromosomes with intermediate CNV). Re-biopsies of 69 chaotic blastocysts were compared to the initial PGT-A results. Main results and the role of chance The prevalence of chaotic embryos was 4.3% (251/5,801); 13.5% (n = 34) pure, 53.0% (n = 133) mixed and 33.5% (n = 84) mosaic. After thawing 93 embryos, the survival rate was 74.2%. The 69 embryos that survived underwent re-biopsy yielding the following PGT-A results: 24.6% (n = 17) euploid, 37.7% (n = 26) chaotic, 26.1% (n = 18) aneuploid non-chaotic, 7.2% (n = 5) mosaic and 4.4% (n = 3) non informative. Nevertheless, outcomes varied substantially when the analysis was conducted based on the sub-category of chaotic embryos. In the pure category (n = 11), 72.7% (n = 8) showed identical results to the initial biopsy while 27.3% (n = 3) were aneuploid non-chaotic confirming at least one aneuploidy identified at the initial biopsy. Among the mixed category (n = 24), 54.2% (n = 13) were also mixed chaotic, and 45.8% (n = 11) were aneuploidy non-chaotic. All re-biopsies in this category also manifested at least one common aneuploidy with the initial biopsy or its opposite (trisomy/monosomy). In the mosaic category (n = 31), 54.8% (n = 17) were euploid, 16.1% (n = 5) were mosaic chaotic, 16.1% (n = 5) were mosaic non-chaotic and 12.9% (n = 4) were aneuploid non-chaotic. The concordance with the initial biopsy in terms of aneuploid result was 100% in the pure and mixed chaotic categories. However, over half of the embryos initially categorized as mosaic chaotic were, in fact, euploid. Limitations, reasons for caution Implantation, miscarriage and live birth rates are not explored. These outcomes are crucial for understanding the clinical significance of euploid embryos initially deemed as chaotic. The survival rate of chaotic embryos should be considered as it is lower than the survival rate of vitrified blastocysts reported in most IVF laboratories. Wider implications of the findings Previous research has suggested that re-biopsy can rescue embryos from PGT-A cycles given that a chaotic result has reduced predictive value. However, our current study reveals that not all chaotic embryos are suitable for re-biopsy, as 100% of pure and mixed chaotic blastocysts were aneuploid when re-tested. Trial registration number Not applicable

O-301 Progesterone Primed Ovarian Stimulation (PPOS) for DuoStim combined with PGT-A in poor prognosis patients: a valuable strategy

Abstract Study question Is PPOS rather than conventional GnRH-antagonist a valid strategy in DuoStim protocols? Summary answer PPOS-DuoStim and conventional-DuoStim showed similar mean euploid blastocyst rate (EBR) per inseminated metaphase-II (MII) oocytes. What is known already DuoStim (double stimulation in the same ovarian cycle) is an efficient strategy to increase the number of oocytes retrieved and embryos obtained in the shortest possible timeframe. PPOS is based on the use of exogenous oral progesterone to prevent LH surge during ovarian stimulation (OS). The effectiveness and safety of PPOS have been consistently reported across the last years, supporting it as a clinically-valuable OS protocol. To date, no evidence exists about PPOS application in DuoStim protocols and its association with oocyte competence, defined as EBR per MII-oocytes. Study design, size, duration Retrospective study involving 138 PPOS-DuoStim and 138 matched conventional-DuoStim patients treated at a single clinic between 2021 and 2022 and collecting ≥1 MII-oocyte after both stimulations. Matching was based on maternal age (40.3±2.7 years), number of oocytes collected after the I-stimulation (5.8±3.6 years), and sperm quality (66% normozoospermic). The primary outcome was the EBR per MII-oocytes. All intermediate embryological and clinical outcomes were also compared. Sub-analyses among I- and II-Stimulations were also conducted. Participants/materials, setting, methods DuoStim entailed the same protocol in I- and II-Stimulations with FSH 300IU/day+LH 150IU/day, 5 days spanning the two stimulations and GnRH-agonist to trigger ovulation. The only difference between PPOS-DuoStim and conventional-DuoStim was the administration of medrossiprogesterone acetate10mg/day orally from the first day of stimulation versus flexible GnRH-antagonist from the day the follicles reached a diameter of 13-14 mm. The same laboratory procedures were applied: ICSI, trophectoderm biopsy, comprehensive-chromosome-testing to report uniform aneuploidies and vitrified-warmed single-embryo-transfers. Main results and the role of chance The patients in the two groups were comparable for ovarian reserve markers, BMI, and duration of infertility. All data were comparable in conventional-DuoStim and PPOS-DuoStim (Mann-Whitney U tests were conducted): (i) overall fertilization rate per inseminated MII-oocytes were 73.1±23.2% versus 76.8±17.8% (p = 0.143), (ii) overall blastulation rate per 2PN-zygotes were 46.6±30.4% versus 45.7±25.1%(p = 0.797), (iii) overall euploidy rates per biopsied blastocysts were 24.1±30.9% versus 25.4±31.3%(p = 0.956), (iv) EBR per inseminated MII-oocytes were 9.6±17% versus 9.2±12.7% (p = 0.735). The data among only I- and II-stimulations were also similar. When comparing I- versus II-stimulations, paired t-tests highlighted longer II-stimulations (11±1.9 vs11.6±1.9 days, p = 0.001), resulting in larger cohorts of MII-oocytes (4.3±2.8 vs 5.2±3.3, p &amp;lt; 0.001) with comparable EBR per MII-oocytes (9.7±20.2% vs 11.6±16.2%, p = 0.233), thereby eliciting larger cohorts of euploid blastocysts (0.5±0.07 vs 0.7±0.09, p = 0.005). These data were confirmed also among conventional-DuoStim and PPOS-DuoStim study arms only. From a cycle perspective, among the 138 conventional-DuoStim couples, 31 (22%), 44 (32%) and 59 (43%) obtained ≥1 euploid blastocyst after I-stimulation, II-stimulation and overall, respectively. The same figures among the 138 PPOS-DuoStim were 36 (26%), 44 (32%) and 63 (46%), respectively. No statistical difference was reported (Fisher’s exact test=0.716). Limitations, reasons for caution Retrospective single center design. The current sample size should be doubled in order to reach a 80%-power with a 5%-α to exclude a 5% two-sided difference in the primary outcome. Patients’ compliance and discomfort, as well as clinical, gestational, and perinatal outcomes and cost-effectiveness analyses are needed. Wider implications of the findings PPOS is valuable in unconventional-OS protocols entailing freeze-all, like DuoStim with PGT-A. Future studies should assess if PPOS-DuoStim, by decreasing the number of injections and scans, may improve patient compliance and decrease OS discomfort. Any putative impact on follicular recruitment and oocyte yield should also be determined. Trial registration number not applicable

O-155 Limited utility of mosaicism reporting in PGT-A: independent confirmation from a European multisite, double-blinded analysis including 4293 embryo transfers following the first US experience

Abstract Study question Are results showing limited clinical utility of mosaicism reporting in PGT from a blinded mosaic embryo transfer American study, confirmed in a European setting? Summary answer Even between different patient populations and clinical settings, putative mosaicism reporting has limited clinical utility for embryo selection when co-evaluated with other clinical/embryological factors. What is known already Intermediate chromosomal copy number (ICN) results in NGS-based PGT-A are commonly interpreted as embryo mosaicism. A recent prospective, non-selection study in America showed that reporting mosaicism would not significantly improve embryo selection. At odds with this, results suggesting that embryo selection based on putative mosaicism can improve clinical outcomes continue to be reported, possibly reflecting limitations in accurate mosaicism identification or retrospective analysis biases. This study replicates the design of previously reported American study, using the same PGT-A assay, examining the predictive value of whole-chromosome ICN (wICN) and segmental ICN (sICN) following concurrent copy-number and genotyping-PGT in a European setting. Study design, size, duration A multisite double-blinded study involving 14 European IVF clinics was conducted from April 2022 to July 2023, including 3365 patients and 4293 single embryo transfers. Embryos, reported as negative for uniform aneuploidies, including those with wICN or sICN, were chosen for transfer based solely on standard developmental and morphological evaluation. Primary outcome measure was live birth rate defined as any pregnancy reaching the 24th week of gestation (LBR). Participants/materials, setting, methods Trophectoderm biopsies were analysed using a validated targeted-NGS assay with approximately 5000 loci across the genome, providing both quantitative and genotyping information to support aneuploidy classification. Putative mosaicism was inferred from ICN deviations from the expected two copies for autosomes and partly supported by corresponding SNP B-allele frequency patterns. Related clinical and embryological variables were analysed in a multivariate analysis and a Random Forrest regression used to model the clinical utility of putative mosaicism. Main results and the role of chance Of the embryos transferred, 6.8% (293/4293) were wICN only; 6.2% (269/4293) were sICN only and 0.5% (23/4293) were a combination of wICN and sICN. The detected ICN ranged from 23%-84% with no overrepresentation of any individual chromosomes. The LBR of embryos in the control group (without ICN), sICN and wICN were 46.8% (1736/3708; 95%CI:45.2-48.4%), 36.4% (98/269; 95%CI:30.9-42.3%) and 39.2% (115/293; 95%CI:33.8-44.9%) respectively. The miscarriage rate for control, sICN and wICN were 12.9% (257/1993; 95%CI:11.5-14-4%), 19.7% (24/122; 95%CI:13.6-27-6%) and 16.7% (23/138; 95%CI:11.4-23.8%), respectively. Logistic regression (P = 0.05) showed that the presence of sICN (OR: 0.7; 95%CI: 0.54-0.9) and wICN (OR: 0.62; 95%CI: 0.36-1.07) were modestly but significantly associated with LBR along with other embryological and clinical factors including embryo morphology (OR: 0.89; 95%CI: 0.84-0.96), day of biopsy (OR: 0.65;95%CI: 0.56-0.75), previous ET failures (OR: 0.79; 95%CI: 0.71-0.88) that were more strongly associated. No significant effect was observed of any specific intermediate CN cut-off on the association with LBR. Random Forrest regression, considering all correlating variables, showed a LBR prediction (AUC) equal to 0.578 without putative mosaicism and AUC of 0.583 with putative mosaicism included, a negligible increase considering the low incidence of mosaicism in our clinical setting along with its modest predictive value. Limitations, reasons for caution Follow-up prenatal and post-natal data at this time was not available, hence conclusions about these outcomes wasn’t possible. Despite the overall large sample size, the analysis of specific effects at different ICN values lacked sufficient power. Furthermore, this study’s data is platform-specific and cannot be translated to other PGT-A assays. Wider implications of the findings Although putative mosaicism was associated with modestly impaired pregnancy rate, two independent studies now confirm that reporting mosaicism has limited impact when prospectively selecting embryos for transfer based on standard embryological parameters. Considering the established downsides, including potential embryo disposal, the practice of mosaicism reporting in PGT is questionable. Trial registration number Not applicable

P-189 Can artificial intelligence outperform traditional non-invasive assessments in prioritizing euploid blastocysts for transfer? A retrospective intra-cohort analysis of 786 PGT-A cycles

Abstract Study question Are Artificial Intelligence (AI)-powered tools more efficient than traditional non-invasive assessments to prioritize euploid blastocysts for transfer? Summary answer Only one third of cycles yielded ≥3 blastocysts with different diagnoses. In these cycles, AI and traditional grading prioritized euploid embryos with comparable performance. What is known already While embryo morphology and developmental pace to blastocyst are associated with chromosomal and reproductive competence, their evaluation remains subjective and lacks reproducibility. The introduction of Time-lapse technology (TLT) in IVF has provided valuable insights into preimplantation development but has not enhanced embryologists’ reproducibility. Recently, AI models integrated with TLT offered the potential for automating and standardizing assessments. Whole-chromosome testing for uniform aneuploidies still is the strongest predictor of embryo (in)competence. In fact, if transferred, &amp;gt;98% of aneuploid blastocysts fail to result in a live-birth. AI tools strive to non-invasively predict blastocyst (an)euploidy, yet their clinical utility requires intra-cohort testing. Study design, size, duration Retrospective blinded analysis of 786 PGT-A cycles (maternal-age:38.9; years:2013-2020; 2184 blastocysts). For static assessment, 3 embryologists used Gardner’s grading at the time of biopsy (t-biopsy). For morphodynamic assessment, time of blastocyst-expansion (tEB) and embryo-area (embA at tEB) were also annotated. For AI assessment, scores were generated with three commercially-available models. All approaches were compared for their effectiveness in ranking euploid blastocyst(s) as top-quality among cohorts with ≥3 blastocysts and ≥1 euploid and ≥1 aneuploid (N = 279/786,35.5%). Participants/materials, setting, methods Embryologists ranked AA-blastocysts as top-quality (score=1), CC-blastocysts as worst-quality (score=9), prioritizing trophectoderm over ICM, with t-biopsy as third criterion. Morphodynamic assessments followed the same hierarchy but using tEB and embA in place of t-biopsy. For AI, higher scores corresponded to higher priority. For all assessments, coefficients of variation (CV=SD/mean) were calculated to assess data dispersion within cohorts with ≥3 blastocysts (N = 363/786,46.2%). Intra-cohort CVs were tested for their association with the likelihood of prioritizing euploid blastocysts. Main results and the role of chance Intra-cohort CVs were 0.71±0.35, 0.28±0.14, 0.58±0.26, and 0.56±0.34 for Gardner’s score, AI model-1, -2, and -3, respectively. Spearman’s correlations between Gardner’s score and AI model-1, -2, and -3 Intra-cohort CVs were 0.32, 0.34, and 0.14, respectively. AI model-1 and -2 were strongly correlated (0.63), but poorly with model-3 (0.21 and 0.22). Euploid blastocysts were prioritized in 163 cohorts by static assessments (N = 163/279,58.4%), 179 (64.2%) by morphodynamic, 174 (62.4%), 190 (68.1%), and 145 (52%) by AI model-1, -2, and -3. A maternal age-adjusted 0.1-larger Gardner’s grading intra-cohort CV correlated with higher likelihood of prioritizing euploid over aneuploid blastocysts (multivariate-OR:1.1, 95%CI:1.03-1.19, adjusted-p=0.005). No association was reported with AI models intra-cohort CVs. Notably, blastocysts affected from aneuploidies compatible with implantation were prioritized over euploid in 59 cohorts (N = 59/279,21.1%) by static assessment, 54 (19.4%) by morphodynamic, 52 (18.6%), 48 (17.2%), and 54 (19.4%) by AI model-1, -2, and -3. A maternal age-adjusted 0.1-larger Gardner’s grading intra-cohort CV correlated with lower likelihood of prioritizing aneuploid blastocysts compatible with implantation over euploid (multivariate-OR:0.9, 95%CI:0.83-0.98, adjusted-p=0.010). No association was reported with AI models intra-cohort CVs. Limitations, reasons for caution While representing the real-life scenario of a large PGT-A program, this study is a single center retrospective analysis in advanced maternal age women with a limited number of cycles with ≥3 blastocysts showing both euploid and aneuploid. Other AI-powered models exist, some specifically trained to predict euploidy. Wider implications of the findings Trophectoderm biopsy and testing aim to prevent the transfer of chromosomally-abnormal blastocysts. Although traditional/AI-based grading correlate with euploidy, their goal is prioritizing embryos for transfer, irrespective of the IVF setting (with or without PGT-A). Future research should concentrate on emphasizing live-birth prediction over misleadingly considering them as non-invasive PGT-A surrogates. Trial registration number None

P-647 Association between PCOS phenotype-D and euploid blastocyst rate per cohort of inseminated oocytes: a matched case-control study versus idiopathic infertile women

Abstract Study question Is there any association between PCOS phenotype-D and oocyte competence defined as euploid blastocyst rate (EBR) per cohort of inseminated oocytes? Summary answer Although higher fertilization and blastulation rates were reported in PCOS phenotype-D women versus idiopathic infertile patients, the EBR per cohort of inseminated oocytes was comparable. What is known already Several studies report poorer oocyte quality and cumulative-live-birth-rate (CLBR) in hyperandrogenic PCOS phenotypes, as defined according to the Rotterdam criteria. Increased androgen concentrations in follicular fluids are indeed associated with elevated serum-LH levels, which can block dominant follicle development inducing atresia and negatively impact fertilization rates and embryo development. Limited evidence exists in phenotype-D PCOS patients, namely women characterized by oligomenorrhea, ovarian PCO morphology and absence of hyperandrogenism. Here, we report the embryological and clinical outcomes in these women during ICSI cycles with preimplantation genetic testing for aneuploidies (PGT-A) at the blastocyst stage. Study design, size, duration Retrospective propensity score matched (PSM) case-control study. Among PGT-A cycles conducted by naïve patients with own oocytes (2013-2021), we excluded FNA/TESE. 58 phenotype-D PCOS patients were identified according to the Rotterdam criteria. These patients were matched for maternal age, number of cumulus-oocyte-complexes (COCs), and sperm quality, with 58 patients with idiopathic infertility, regular cycles, normal ovarian morphology, and no sign of clinical hyperandrogenism. The primary outcome was EBR per cohort of inseminated oocytes. Participants/materials, setting, methods GnRH-antagonist ovarian stimulation, ICSI, blastocyst biopsy, qPCR/NGS-analysis to assess uniform aneuploidies and vitrified-warmed single blastocyst transfers were conducted. The PCOS and control groups were similar for age (35.6±3.0 versus 36.0±3.9 years), COCs (23.1±6.7 versus 23.5±7.6), sperm factor, primary/secondary infertility, hormonal values, BMI (23.8±5.3 versus 22.0±2.8), and duration of infertility (3.6±2.2 versus 3.6±2.0 years). All intermediate embryological and clinical outcomes were assessed as secondary endpoints. Linear/logistic regressions adjusted for confounders were conducted to confirm statistically-significant differences. Main results and the role of chance No difference was reported in maturation rates, but women with PCOS showed better fertilization rates per cohort of inseminated oocytes (76.9±15.2% versus 67.3±20.4%, Mann-Whitney-U-test&amp;lt;0.01), and blastulation rates per cohort of 2PN-zygotes (52±20.4% versus 43.7±20.7%, Mann-Whitney-U-test=0.03). Eventually, PCOS patients obtained more blastocysts than controls (5.8±3.1 versus 4.5±2.9, Mann-Whitney-U-test=0.02), despite similar numbers of metaphase-II oocytes in the groups (16.5±6.1 versus 16.5±7.0). All differences remained significant after adjusting for maternal age and sperm factor. Nevertheless, the euploidy rates per cohort of biopsied blastocysts were similar, thus involving comparable EBR per cohort of inseminated oocytes (21.7±14.1% versus 17.2±16%, Mann-Whitney-U-test=0.12). More patients obtained ≥1 euploid blastocyst in the PCOS versus the control group (N = 56/58, 96% versus N = 47/58, 81%, Fisher’s-exact-test=0.02), independently from maternal age, semen quality, and number of inseminated oocytes (Odds-Ratio: 6.5, 95%CI:1.3-33.7, p = 0.03). Lastly, all clinical outcomes per first vitrified-warmed euploid transfer were similar, thereby involving comparable LBRs (N = 28/54, 51.9% versus N = 26/47, 55.3% in the PCOS and control groups, p = 0.8; Odds-Ratio adjusted for blastocyst quality and day: 1.19, 95%CI:0.5-2.7, p = 0.68). Limitations, reasons for caution Although clinical hyperandrogenism was absent in both groups, biochemical hyperandrogenism was not assessed. Nonetheless, this pilot study paves the way for future more detailed investigations. 24% of cycles in the PCOS group were not concluded, therefore a CLBR comparison would be biased and was not reported. Wider implications of the findings The lower developmental competence in the control group suggests oocyte quality issues, other than chromosomal, underlying their “unexplained infertility” condition. In phenotype-D PCOS women, IVF is effective. Since &amp;gt;50% of this subgroup of women had already failed multiple ovulation-induction and/or intrauterine-insemination attempts, an early referral to IVF deserves further investigations. Trial registration number Not applicable

O-293 Mastering consistency: a similar training allows to standardize embryo transfer performance, but experience does not involve further improvements

Abstract Study question Is there any variation in the live birth rate (LBR) per vitrified-warmed single euploid blastocyst transfer (SEBT) among clinicians trained at the same IVF center? Summary answer The LBR per SEBT (overall: 53%) remained consistent among equally trained transfer operators (range: 48%-60%) regardless of the number of prior procedures performed. What is known already The number of ART treatments and practitioners has increased over the years. To ensure high standards, an efficient quality control system should monitor and standardize operators’ performance by leveraging statistically-sound key-performance-indicators (KPIs). The embryo transfer procedure is a clinically relevant step, particularly susceptible to variations among clinicians, irrespective of their experience. However, the outcome of “LBR per transfer” is influenced by various confounders, such as embryo stage, morphology, reproductive history, uterine conditions, and others. Our objective was to assess potential differences among transfer practitioners who underwent the same training at a single IVF center in the least biased scenario possible. Study design, size, duration Retrospective single center study. Out of 8663 transfers performed by 4 operators (all trained by operator-1) between 2013 and 2021, we selected 421 first vitrified-warmed transfers with day5 euploid blastocysts whose morphology was &amp;gt;Gardner’s BB-grade in non-obese women, thereby excluding all main confounders on our primary outcome (= LBR per SEBT across different operators). The study was powered to exclude a 18%-decrease (β = 0.8, α = 0.05) in the LBR versus operator-1 (ratio comparator:control=1:2). Participants/materials, setting, methods We conducted ICSI, blastocyst biopsy without day3 zona-drilling, and aneuploidy testing to exclude full-chromosome uniform aneuploidies. All blastocysts were transferred ∼2 hours after warming. Uterine assessment was conducted to exclude putative conditions associated with lower LBR. Endometrial preparation protocol (modified-natural cycle versus hormone-replacement-therapy), maternal age at transfer, experience of prior implantation(s) (yes/no), the embryologists involved in the transfer procedure, were assessed as putative further confounders. All significant differences were confirmed through regression analyses. Main results and the role of chance The overall LBR per vitrified-warmed SEBT was 53.4% (N = 225/421). Operator-1 conducted 3960 transfer procedures during the study period, with 167 eligible for this study, achieving a 55.7% LBR (N = 93/167). Operator-2,-3, and -4 respectively conducted 2533, 1087, and 1083 procedures during the study period, with 134, 62, and 58 eligible for this study. Their LBRs were 50% (N = 67/134, p-value versus operator-1=0.2), 48.4% (N = 30/62, p-value=0.2), and 60.3% (N = 35/58, p-value=0.3). Multivariate logistic regression analysis, adjusted for endometrial preparation protocol and embryologists involved in the transfer procedure, confirmed the absence of an association (Operator-2 vs. 1 multivariate-OR: 0.83, 95%CI 0.5-1.39, adjusted-p=0.49; Operator-3 vs. 1 multivariate-OR: 0.75, 95%CI 0.40-1.40, adjusted-p=0.37; Operator-4 vs. 1 multivariate-OR: 1.40, 95%CI 0.72-2.70, adjusted-p=0.32). Importantly, the number of prior transfer procedures conducted by each clinician during the study period also showed no association with the primary outcome (OR = 1.0, p-value=0.82). From an IVF center perspective, the LBR per SEBT remained stable across the 9-year study period, showing minimal non-significant fluctuations. These outcomes describe an IVF center where equally-trained clinicians adopt the same standard-operating-procedures to manage vitrified-warmed embryo transfers. In this context, the LBR per SEBT represents an ideal KPI to assess the learning curve of operators in training. Limitations, reasons for caution Over 2500 SEBTs are required to rule out a 5%-decrease in the LBR. Yet, such a substantial number is better suited for comparing centers’ rather than practitioners’ performance. It would be intriguing to investigate potential differences among operators who underwent different training regimens but operate within the same clinic. Wider implications of the findings No correlation exists between the number of prior embryo transfer procedures conducted and further improvements, therefore initial operators’ training is crucial for standardizing their performance. LBR per SEBT is a strong KPI, though poorly-actionable in the short-term. It’s better suited for center comparisons, prompting internal procedure reviews when differences arise. Trial registration number not applicable

O-127 Blastocyst expansion speed assay: a putative artificial intelligence-powered tool for embryo selection. Retrospective study involving 2184 blastocysts and 786 PGT-A cycles

Abstract Study question Is blastocyst expansion-speed, examined through Artificial-Intelligence (AI) between time of blastulation (tB) and time of expanding blastocyst (tEB), associated with embryo blastulation and reproductive competence? Summary answer Blastocyst expansion-speed-assay (ESA) was significantly associated with euploidy and live-birth rates, being discordant with clinical embryologists’ ranking in 50% of embryonic cohorts. What is known already Blastocyst expansion is one of the earliest morphogenetic events in mammalian development. It is essential for the establishment of the blastocyst layout and requires trophectoderm integrity. Several studies suggested that expansion is a valuable feature for ranking and prioritizing blastocysts for transfer based on their developmental competence. Time-lapse technology (TLT) implementation in IVF allows a deeper understanding of blastocyst expansion dynamics. In this study, we combined TLT and AI to develop a blastocyst-ESA and investigate its association with embryo blastulation and reproductive competence. Study design, size, duration Retrospective study including 2184 blastocysts cultured in EmbryoScope incubators during 786 PGT-A cycles across 2013-2020. Videos were analyzed through an AI-powered tool (CHLOETM, Fairtility). The expansion-speed was calculated as [(Δ embryo proper area at tEB – embryo proper area at tB) / (Δ tEB - tB)]. ESA was tested for its association with embryo quality, euploidy and live-birth rate (LBR) in 548 vitrified-warmed single euploid transfers. A simulation of ESA putative clinical effectiveness was conducted. Participants/materials, setting, methods ICSI, trophectoderm biopsy of fully-expanded blastocysts without day3 zona-drilling, and qPCR/NGS to assess full-chromosome uniform aneuploidies were performed. tB and tEB, expressed as hours-post-insemination (hpi), embryo proper area (in µm2) at both these stages, and blastocyst quality (EQ-Score from 0 to 1) were all automatically recorded through CHLOE. Possible confounders (e.g., maternal age, male factor, and cause of infertility) were considered. Regression analyses were conducted to adjust the data. Main results and the role of chance The average ESA was 705±458 µm2/hour. Higher ESA was associated with higher EQ-Score. Euploid blastocysts showed higher ESA than aneuploid (761±465 µm2/hour versus 667±449 µm2/hour; p &amp;lt; 0.01). ESA was also associated with LBR per euploid blastocyst transfer (LB: 873±438 µm2/hour versus 736±467 µm2/hour; p &amp;lt; 0.01). Of note, maternal age showed no association with ESA. Multivariate regressions outlined a + 5.1%-increase in the chance of euploidy and a + 6.3%-increase in chance of LB, every +100 µm2/hour-increase in ESA. ESA and embryologists were discordant in grading top-quality embryos in each cohort in 50% of the cases. In 59% of the 352 cohorts where both euploid and aneuploid blastocysts were obtained, ESA would have ranked the former embryos as top-quality. In the 216 cycles with ≥2 euploid blastocysts obtained and ≥1 transferred, ESA would have prioritized (i) a competent embryo in 46% of the cases, (ii) an incompetent embryo in 20%, but (iii) in 33% its value could not be assessed (i.e., the top embryo according to ESA has not been transferred yet). When compared to the embryologists, ESA would have been (i) equally-effective in 49% of the cases, (ii) more effective in 12-24%, and (iii) less effective in 5%-26%. Limitations, reasons for caution Retrospective single-center study. Both continuous and sequential media were used, although they were not associated with the outcomes under investigation. To assess the clinical value of ESA, a prospective study among first transfers is warranted. Wider implications of the findings ESA is an automated, unbiased, and easily-applicable measurement that certainly deserves further appraisal. If validated in prospective studies, AI-based selection algorithms could include this assessment to increase their predictive power. Trial registration number None

P-046 Ejaculatory abstinence: is there any association with embryo developmental competence? A Retrospective Study in time-lapse incubators

Abstract Study question Is ejaculatory abstinence (EA) associated with fertilization and blastocyst development in ICSI cycles with embryo culture in time-lapse incubators? Summary answer There is no association between length of EA and fertilization, blastocyst development or morphology. What is known already Semen analysis is pivotal in medically assisted reproduction (MAR), serving as a significant indicator of male partners’ health. The period of EA is a relevant factor that can affect sperm quality. Numerous studies described EA association with clinical outcomes, while its impact on embryological results remains inconclusive. Recent meta-analyses, despite a conflicting literature, highlighted positive effects of shorter abstinence periods. A recent study suggested that prolonged abstinence might reduce fertilization rate in ICSI cycles without time-lapse imaging, thereby reducing usable zygotes’ rate Study design, size, duration Retrospective study including all oocytes (N = 7164) from 1148 ICSI cycles (N = 902 couples) cultured in time-lapse incubators at a single IVF center between January 2020 and December 2022. Only non-donor fresh gametes were included (Mean Maternal age: 38.5±4 years; Paternal Age: 41±5.6 years). The primary embryological outcomes were fertilization rate and type, and blastocyst development per inseminated oocyte and per 2PN-zygote. Secondary outcomes were euploidy, day of blastocyst development and Gardner’s morphology. Participants/materials, setting, methods Semen analysis was conducted according to WHO. All oocytes were cultured up to day7 in EmbryoScope or GERI incubators with continuous media and refresh in day5 (if needed). If requested, PGT-A was performed to assess full-chromosome uniform aneuploidies. Univariate and multivariate logistic regressions were conducted. Possible confounders were assessed among ovarian stimulation, maternal, paternal, sperm, and IVF cycles characteristics. Associations were confirmed with Generalized estimating equations (GEE) to account for repeated measurements among oocytes’ cohort. Main results and the role of chance Logistic regressions and GEE were conducted to assess associations between possible confounders and blastocyst development per inseminated metaphase-II oocyte. Maternal age, sperm concentration, and motility A+B were associated. The same confounders were reported on blastocyst development among 2PN-zygotes. The days of EA (1-8 days) did not show any association with fertilization (p = 0.198) or blastocyst development per metaphase-II oocyte (p = 0.495). No association was reported with abnormal fertilization, neither combining all abnormalities in a single group, nor clustering them as 1PN, 3PN, 3.1PN, and multi-PN. An increasing trend was reported in blastocyst development among 2PN-zygotes according to the length of EA (1-day: 17/37,45.9%; 2-days: 190/424,44.8%; 3-days: 1405/2574,54.6%; 4-day: 746/1410,52.9%; 5-days: 450/827,54.4%; 6-days: 70/133,52.6%; 7-days: 46/101,45.5%; 8-days: 85/162,52.5%), but this was not significant in a multivariate logistic regression (p = 0.887). Length of EA showed no association with euploidy (p = 0.424), nor with day of development (p = 0.966) and Gardner’s inner cell mass (p = 0.204) or trophectoderm (p = 0.428) morphology. Limitations, reasons for caution This study is inherently limited by its retrospective design. The limited number of cycles included was balanced using time-lapse incubators to improve the accuracy of fertilization check and benefit from an undisturbed embryo culture environment. Artificial Intelligence will be implemented to automate developmental timings’ annotation and objectify embryo quality assessment. Wider implications of the findings The length of EA seems not associated with embryological outcomes, adding to the controversy on this topic. Here, we included only ICSI cycles with blastocyst culture conducted in time-lapse to enhance the quality of the evidence. Larger datasets and diverse settings are now required, especially enriched with poor prognosis patients. Trial registration number not applicable

Healthy Live Births after the Transfer of Mosaic Embryos: Self-Correction or PGT-A Overestimation?

The implementation of next generation sequencing (NGS) in preimplantation genetic testing for aneuploidy (PGT-A) has led to a higher prevalence of mosaic diagnosis within the trophectoderm (TE) sample. Regardless, mosaicism could potentially increase the rate of live-born children with chromosomic syndromes, though available data from the transfer of embryos with putative PGT-A mosaicism are scarce but reassuring. Even with lower implantation and higher miscarriage rates, mosaic embryos can develop into healthy live births. Therefore, this urges an explanation for the disappearance of aneuploid cells throughout development, to provide guidance in the management of mosaicism in clinical practice. Technical overestimation of mosaicism, together with some sort of "self-correction" mechanisms during the early post-implantation stages, emerged as potential explanations. Unlike the animal model, in which the elimination of genetically abnormal cells from the future fetal lineage has been demonstrated, in human embryos this capability remains unverified even though the germ layer displays an aneuploidy-induced cell death lineage preference with higher rates of apoptosis in the inner cell mass (ICM) than in the TE cells. Moreover, the reported differential dynamics of cell proliferation and apoptosis between euploid, mosaic, and aneuploid embryos, together with pro-apoptosis gene products (cfDNA and mRNA) and extracellular vesicles identified in the blastocoel fluid, may support the hypothesis of apoptosis as a mechanism to purge the preimplantation embryo of aneuploid cells. Alternative hypotheses, like correction of aneuploidy by extrusion of a trisomy chromosome or by monosomic chromosome duplication, are even, though they represent an extremely rare phenomenon. On the other hand, the technical limitations of PGT-A analysis may lead to inaccuracy in embryo diagnoses, identifying as "mosaic" those embryos that are uniformly euploid or aneuploid. NGS assumption of "intermediate copy number profiles" as evidence of a mixture of euploid and aneuploid cells in a single biopsy has been reported to be poorly predictive in cases of mosaicism diagnosis. Additionally, the concordance found between the TE and the ICM in cases of TE biopsies displaying mosaicism is lower than expected, and it correlates differently depending on the type (whole chromosome versus segmental) and the level of mosaicism reported. Thus, in cases of low-/medium-level mosaicism (<50%), aneuploid cells would rarely involve the ICM and other regions. However, in high-level mosaics (≥50%), abnormal cells in the ICM should display higher prevalence, revealing more uniform aneuploidy in most embryos, representing a technical variation in the uniform aneuploidy range, and therefore might impair the live birth rate.

The morphokinetic signature of mosaic embryos: evidence in support of their own genetic identity

To provide full morphokinetic characterization of embryos ranked with different degrees of chromosomal mosaicism. Retrospective cohort study. University-affiliated private invitro fertilization clinic. We analyzed 1,511 embryos from 424 intracytoplasmic sperm injection cycles by culturing embryos in a time-lapse imaging system and performing next-generation sequencing. We assessed 106 mosaic embryos. None. Comparison of chromosomal, morphological, and morphokinetic characteristics of blastocysts classified as euploid, aneuploid, low-degree mosaic (30% to <50% aneuploid cells in trophectoderm biopsy), and high-degree mosaic (50% to <70% aneuploid cells in trophectoderm biopsy). Statistical analysis was performed using χ2, Kruskal-Wallis, or analysis of variance tests according to data type and distribution. A two-way random effects model was used to calculate interoperator correlation of annotations, and a logistic mixed effects model was performed to evaluate the effect of confounders on morphokinetic timing. The mosaicism rate was ∼7% regardless of parental age. Mosaicism and uniform aneuploidies were not evenly distributed across chromosomes. The percentage of high-quality blastocysts significantly decreased from euploid (66.9%) to mosaic (52.8%) and aneuploid (47.7%). Aneuploid blastocysts significantly delayed development compared with euploid blastocysts in start of compaction (median, 84.72 hours postmicroinjection [hpm], interquartile range [IQR], 13.2; vs. median, 82.10 hpm, IQR, 11.5), start of blastulation (median, 101 hpm; IQR, 11.7; vs. median, 98.29 hpm, IQR, 10.5), and timing of blastocyst (median, 108.04 hpm, IQR, 11.50; vs. median, 104.71 hpm, IQR, 11.35). However, embryo morphokinetics were not correlated to the degree of mosaicism or to a mosaicism configuration that was apt for embryo transfer. Morphokinetic timing of mosaic embryos overlaps with that of euploid and aneuploid embryos, which may reflect their unique genetic and developmental identity. Although this suggests mosaic embryos are not simply a misdiagnosis by-product, further studies are needed to reveal the true identity of this particular type of embryo.

Characteristics of the IVF Cycle that Contribute to the Incidence of Mosaicism.

Highly sensitive next-generation sequencing (NGS) platforms applied to preimplantation genetic testing for aneuploidy (PGT-A) allow the classification of mosaicism in trophectoderm biopsies. However, the incidence of mosaicism reported by these tests can be affected by a wide number of analytical, biological, and clinical factors. With the use of a proprietary algorithm for automated diagnosis of aneuploidy and mosaicism, we retrospectively analyzed a large series of 115,368 trophectoderm biopsies from 27,436 PGT-A cycles to determine whether certain biological factors and in vitro fertilization (IVF) practices influence the incidence of overall aneuploidy, whole uniform aneuploidy, mosaicism, and TE biopsies with only segmental aneuploidy. Older female and male patients showed higher rates of high-mosaic degree and whole uniform aneuploidies and severe oligozoospermic patients had higher rates of mosaicism and only segmental aneuploidies. Logistic regression analysis identified a positive effect of female age but a negative effect of embryo vitrification on the incidence of overall aneuploid embryos. Female age increased whole uniform aneuploidy rates but decreased only segmental aneuploidy and mosaicism, mainly low-mosaics. Conversely, higher ovarian response decreased whole uniform aneuploidy rates but increased only segmental aneuploidies. Finally, embryo vitrification decreased whole uniform aneuploidy rates but increased mosaicism, mainly low-mosaics, compared to PGT-A cycles with fresh oocytes. These results could be useful for clinician’s management of the IVF cycles.

Clinical outcomes after the transfer of blastocysts characterized as mosaic by high resolution Next Generation Sequencing- further insights

ObjectiveTo determine the pregnancy outcome potential of euploid, mosaic and aneuploid embryos. DesignRetrospective study. SettingReference genetics laboratories. Patient(s)2654 PGT-A cycles with euploid characterized embryo transfers, 253 PGT-A cycles with transfer of embryos characterized as mosaic, and 10 PGT-A cycles with fully abnormal embryo transfers. Intervention(s)Blastocysts were assessed by trophectoderm (TE) biopsy followed by PGT-A via array CGH or NGS. Main outcome measure(s)Implantation, miscarriage, ongoing implantation rates (OIR), and karyotype if available, were compared between different embryo groups, and between the two PGT-A techniques. ResultsThe Ongoing Pregnancy Rate (OPR)/transfer was significantly higher for NGS-classified euploid embryos (85%) than for aCGH ones (71%) (p < 0.001), but the OPR/cycle was similar (63% vs 59%). NGS-classified mosaic embryos resulted in 37% OPR/cycle (p < 0.001 compared to euploid). Mosaic aneuploid embryos with <40% abnormal cells in the TE sample had an OIR of 50% compared to 27% for mosaics with 40–80% abnormal cells in the TE, and 9% for complex mosaic embryos. All the karyotyped ongoing pregnancies (n = 29) were euploid. Transfers of embryos classified as aneuploid via aCGH (n = 10) led to one chromosomally abnormal pregnancy. Conclusion(s)NGS-classified euploid embryos yielded higher OIRs but similar OPRs/cycle compared to aCGH. NGS-classified mosaic embryos had reduced potential to reach term, compared to euploid embryos. If they did reach term, those with karyotype results available were euploid. Embryos carrying uniform aneuploidies affecting entire chromosomes were mostly unable to implant after transfer, and the one that implanted ended up in a chromosomally abnormal live birth.

15.IMPACT OF MATERNAL AGE IN THE INCIDENCE OF UNIFORM AND MOSAIC ANEUPLOIDIES

Introduction Female fertility decreases with age and increases the incidence of aneuploidies mostly due to meiotic errors. The incidence of aneuploid embryos turn around 60% confirming the high abortion rates observed by the presence of chromosomal aneuploidies. Next generation sequencing (NGS) proved to be the most appropriate technology for aneuploidy testing in trophectoderm biopsies, with accurate results, high throughput and cost efficiency. However, the rates and levels of embryonic mosaicism are still a subject of discussion. It is known that they can lead to miscarriage and birth defects but the data linking advanced maternal age and mosaicism is limited. Thus, this study aims to assess the differences between the incidence of different levels of mosaicism and uniform aneuploidies in blastocyst biopsies according to maternal age to verify if they follow a similar pattern. Material & methods A total of 34,387 blastocyst biopsies were sent for PGT-A analysis between October and December 2018 from private assisted reproduction centers to our laboratory. NGS technology (ThermoFisher platform) combined with diagnosis a proprietary validated algorithm was used to optimize results. Patients were stratified by age in seven groups: 50% - 30% - Results 33,341 biopsies were informative with 6% (n=1997) of total mosaicism, 47% uniform aneuploidy (n= 15.670) and 47% euploid biopsies (n=15.674). Regarding the mosaicism rates, 65.3 % (n= 1305) were low mosaic degree, and 34.6% (n=692) were high mosaic degree. A significant decrease (p Conclusions The rate of euploid embryos decreased with advanced maternal age and aneuploidies increased, corroborating previous data from other studies. Regarding mosaicism different trends were observed for low mosaic degree, with a trend towards a decrease of low mosaic degree with maternal age, and high mosaic degree without an effect of maternal age.

11. HIGH CONSISTENCY IN EMBRYO ANEUPLOIDY TESTING OF UNIFORM, MOSAIC AND SEGMENTAL ANEUPLOIDIES WITH THE APPLICATION OF A VALIDATED ALGORITHM

Introduction Detection of mosaic embryos and degree of mosaicism is a hot topic in preimplantation genetic testing of aneuploidy (PGT-A). Several groups have reported healthy life births from mosaic embryos. A key point is the degree of mosaicism that can be detected in a trophectoderm biopsy and the impact of next generation sequencing (NGS) protocol and interpretation of sequencing data. The aim of this study was to determine the robustness of the diagnosis using a validated algorithm to establish the thresholds for mosaicism degree and the minimal resolution for de novo segmental aneuploidies. Material & methods NGS protocol combined automatic library preparation (IonChefTM system, ThermoFisher Scientific), and multiplexing for up to 96 samples (S5-XL sequencer; ThermoFisher). Pools of 4-6 cells with uniform and segmental aneuploidies (10-23 Mb) from cell lines with known karyotypes were employed for platform validation. For mosaicism validation, different proportions of gDNA (0-100%) from cell lines with whole chromosome aneuploidies were sequenced. Quality parameters were evaluated to determine the conditions for accurate detection. Biopsies were diagnosed as mosaic, if only one or two chromosomes fitted the mosaicism thresholds, without uniform aneuploidy for any other chromosome. After validation, results of 34,147 biopsies from 9 diagnostic laboratories using the same diagnostic algorithm were analysed (October 2018-December 2018). Results The minimal resolution for de novo segmental aneuploidies was established at 10 Mb, and the cut-off values for mosaicism detection at 30% and 70%. Biopsies were classified as: euploid ( Finally, we wanted to assess the incidence of mosaicism for chromosomes considered suitable for transfer after genetic and psychological counselling according to Gratti et al (2018). The percentage of low degree mosaicism for low risk chromosomes (1, 3, 4, 5, 10, 12, 19) was 1.1% and for chromosomes with moderate risk (2, 6, 7, 9, 11, 15, 17, 20, 22) was 1.5%. Conclusions High informativity rates were achieved using a high-throughout platform. The application of an internally validated algorithm for PGT-A showed high consistency among different laboratories, avoiding subjectivity and interindividual differences in the diagnosis, and minimizing the risks for overdiagnosis of mosaicism. Low mosaicism rates were identified and even lower if we consider only low mosaics for chromosomes suitable for transfer in the absence of euploid embryos and after proper genetic and psychological counselling. Reference Grati FR, Gallazzi G, Branca L, Maggi F, Simoni G, Yaron Y. An evidence-based scoring system for prioritizing mosaic aneuploid embryos following preimplantation genetic screening. Reprod Biomed Online. 2018 Apr;36(4):442-449.

Mosaicism: detection and clinical outcomes

Introduction It has been proposed that selecting euploid blastocysts to transfer via preimplantation genetic testing for aneuploidy (PGT-A) with the use of comprehensive chromosome screening (CCS) methods, could lead to significant improvements in IVF outcomes. However, questions have been raised related to the implantation potential of mosaic embryos, composed of a mixture of normal and chromosomally abnormal cells. The main aim of this study was to examine the developmental ability of mosaic blastocysts. Materials and methods Blastocysts were biopsied and processed with the use of NGS, followed by frozen embryo transfer. Trophectoderm (TE) biopsies were classified as mosaic if they had 20%–80% abnormal cells. Results Different aneuploidy types, including some complex forms, were capable of persisting to the blastocyst stage. Euploidy rates decreased dramatically with advancing female age, whereas uniform aneuploidy increased. Moreover, the transfer of mosaic diploid aneuploid blastocysts was associated with higher miscarriage and lower implantation rates, compared to embryos in which only euploid cells were detected in the TE biopsy. Conclusions Extensive analysis of the chromosome constitution of human blastocysts suggested that a significant proportion are chromosomally normal in every cell. These findings do not support the notion that mosaic chromosome abnormalities are a natural part of embryo development. Blastocysts with uniform aneuploidy present in the biopsied TE sample and, to a lesser extent, those with mosaic abnormalities were associated with poorer clinical outcomes, compared to euploid embryos.

The cytogenetic constitution of human blastocysts: insights from comprehensive chromosome screening strategies.

Embryos that are able to form blastocysts have succeeded in activating their genome and differentiating into two cell types-an external layer of trophectoderm cells, which will go on to form extra-embryonic tissues such as the placenta, and the inner cell mass, which will give rise to the embryo proper. Culturing embryos to the blastocyst stage has become an increasingly popular IVF practice over the past decade. Additionally, it has been proposed that the identification and transfer of euploid blastocysts could significantly improve IVF outcomes. Toward this end, comprehensive molecular cytogenetic methods have been developed. The application of such methods in both clinical and research contexts has yielded cytogenetic data from large numbers of blastocysts. Questions have been raised concerning the implantation potential of blastocysts diagnosed 'euploid' or 'aneuploid', and there has been particular debate over the detection and viability of embryos categorized as 'mosaic'-composed of a mixture of normal and aneuploid cells. This review aims to summarize data from studies using comprehensive molecular cytogenetic methods to examine blastocyst-stage embryos, describing current knowledge related to rates of euploidy, uniform aneuploidy and mosaicism. Issues associated with the developmental capacity of blastocysts of different cytogenetic constitutions will also be addressed. Guidelines on the clinical management of blastocysts with varying chromosome complements will be considered. Rates of euploidy, uniform aneuploidy (in which all cells have the same abnormal karyotype) and mosaicism were determined via a thorough literature search (PubMed). The keywords used in the search were as follows: preimplantation embryo development, blastocyst stage, embryonic aneuploidy, meiotic chromosome malsegregation, post-zygotic chromosome malsegregation, comprehensive chromosome screening, array comparative genomic hybridization, single-nucleotide polymorphism array, next-generation sequencing, embryo mosaicism and implantation of mosaic embryos. Relevant articles written in English and published up to March 2018 were reviewed. Different types of aneuploidy, including some complex forms, are capable of persisting to the blastocyst stage. As expected, euploidy rates decreased with advancing female age, whereas uniform aneuploidy increased. Analysis of multiple cells from individual blastocysts revealed that most of those classified 'abnormal' contained no euploid cells (due to meiotic errors arising in the gametes and therefore present in every cell), some having additional mosaic (post-fertilization, mitotic) errors. Blastocysts with a mix of normal and aneuploid cells were observed less frequently than other classes of embryo. The transfer of embryos with diploid-aneuploid mosaic biopsy specimens is reportedly associated with higher miscarriage and lower implantation rates, compared to embryos in which only euploid cells are detected. Detailed investigations into the chromosome constitution of human blastocysts suggest that a significant proportion is euploid in every cell, although the exact fraction is strongly influenced by female age. These findings do not support the notion that mosaic chromosome abnormalities are a natural part of embryo development. Mosaic aneuploidies, arising post-zygotically, were detected by various different comprehensive molecular cytogenetic methods, suggesting that the majority of these represent genuine findings. However, it remains possible that certain comprehensive molecular cytogenetic methods may carry a risk of mosaicism being incorrectly assigned, in a minority of samples, as a result of technical artifact. This may be a consequence of degraded DNA in the trophectoderm biopsy or other technical issues. According to published studies, blastocysts considered to have uniform aneuploidy and, to a lesser extent, those with mosaic abnormalities were associated with poorer clinical outcomes in comparison with euploid embryos.