PGD/PGS
Debate: Is it now unethical not to screen out an aneuploidy embryo in IVF?
Speakers BIO:
Sjoerd Repping, The Netherlands
Master's
University: University of Amsterdam
October 1998, cum laude Main subject: Medical Biology (genetics / immunology)
Doctorate
University: University of Amsterdam, Faculty of Medicine
October 2003, cum laude Supervisors: prof. F. van der Veen, prof. N.J. Leschot (UvA), prof. D.C. Page, dr. S. Rozen (MIT, USA)
Title of thesis: Reproductive Fitness of the Human Y Chromosome
Courses
Executive Leadership Harvard, 2014
Financial Management AMC, 2009
Animal welfare /article 9 UvA, 1998
Radiation hygiene / level 5b UvA, 1997
Andreas Schmutzler, Germany
The International School of Medicine was founded in 2008. It is managed by Dr.med. Andreas Schmutzler, a German gynaecologist and lawyer, head of the Kiel University IVF programme,
Overview
For: Preimplantation genetic diagnosis (PGD) is a widespread method in artificial reproductive technology (ART), globally applied in about half of all countries, with primarily preimplantation genetic screening (PGS), with 1% (Europe) to 5% (USA) of all cases. It is the most interesting and most promising technique now, demands a cooperation of clinics, embryology and genetics and requires an ethical balancing of conviction and responsibility.
PGS has five aims: increase birth rates, decrease rates of multiple pregnancies, miscarriages, malformations and senseless therapies. All theses aims are reachable, primarily based on new findings of randomized controlled trials published since 2012 and branded as “PGS 2.0”, based primarily on the combination of blastocyst biopsy and array CGH.
The clinician has to detect the primary aim of the patient, balance its chances and risks, extrapolate from the scientific findings and the possibilities of his treatment center and make a decision, together with the patient, primarily based on his clinical intuition. E.g., it can be ethically correct to shorten time to pregnancy by compromising the cumulative pregnancy chance of oocyte retrieval. The clinician must discuss this with all patients.
Against: The aim of preimplantation genetic screening (PGS) is to select out embryos that are aneuploid. The reason to do so has generally been to increase the chance of live birth in couples undergoing IVF/ICSI. However, data that supports the notion that PGS increases live birth rates is lacking. In fact, PGS using day 3 biopsy and FISH results in a significant reduction in live birth rates. For novel technologies using day 5 biopsy and array based or NGS analysis, well designed trials are lacking. Simple reasoning demonstrates that no selection method will ever increase live birth rates per started cycle; at best, it could reduce time to pregnancy but at what cost? If one proposes that PGS should be applied to prevent the (unethical) birth of aneuploid offspring, there is sufficient data to demonstrate that PGS is neither sensitive nor specific enough to do so, while there is sufficient data to demonstrate that this will be at the cost of lowering live birth rates.
Aneuploidy in embryos: variability between centers, between patients and between cycles of the same patients
Overview
Chromosome abnormalities may be affected by hormonal stimulation and / or laboratory conditions. In this study we analyzed data from egg donor cycles that underwent PGS in different centers. Confounding factors such as fertility indication, paternal age, maternal age, and others were eliminated. We found a strong indication that different fertility centers have different aneuploidy rates, and even different doctors from the same center.
Comprehensive Chromosome Screening in IVF: Enhancing Outcomes while reducing the Burden of Care
Speaker BIO:
Rutgers University-New Brunswick
Robert Wood Johnson Medical School, Fellowship in Reproductive Endocrinology and Infertility
2013 – 2016
University of North Carolina at Chapel Hill
Obstetrics and Gynecology Residency Program
2009 – 2013
-Chief Resident (Education)
-American College of Surgeons Certificate of Merit for Teaching
-Whitehead Resident Teaching Award
University of Virginia
Doctor of Medicine (MD), Medicine
2006 – 2009
-Mulholland Society (President)
-Algernon Sydney Sullivan Award
-Raven Society
-Alpha Omega Alpha
-Gold Humanism Honor Society
The College of William and Mary in Virginia
The College of William and Mary in Virginiav Bachelor's degree, Biology/Biological Sciences, General
2001 – 2005
-Summa Cum Laude
-Inter Fraternity Council (President)
-Beta Theta Pi Fraternity (President)
-One-in-Four (President)
-Sullivan Award
-Phi Beta Kappa
Clinically evaluating NGS and its extra information
Speaker BIO:
Dagan Wells has been involved in preimplantation genetic diagnosis (PGD) and research into human gametes and embryos for over two decades. After studying at University College London, he relocated to the USA, working with Reprogenetics, one of the world’s largest providers of PGD. Dagan established a research laboratory at Yale University, before returning to the UK. He is now an Associate Professor at the University of Oxford. Dagan’s work has led to the publication of more than 150 papers, patents and multiple research grants and prizes. He serves on the Editorial Board of several journals and also directs Reprogenetics-UK, an independent laboratory offering state-ofthe-art PGD services to IVF clinics throughout the UK and internationally.
Overview
There is growing use of next generation sequencing (NGS) in diverse fields of scientific research and clinical diagnostics. In the context of preimplantation genetic diagnosis (PGD), NGS has quickly transitioned from a research technique to a frontline clinical methodology, employed for the detection of aneuploidy in human preimplantation embryos. The rapid speed of adoption has been driven by a desire to lower the costs of comprehensive chromosome screening and by the perception that NGS offers the best chance of facilitating this of any method currently available. Additionally, NGS has the potential to provide a number of extra benefits, such as revealing the DNA sequence of individual genes and quantifying levels of mitochondrial DNA in embryo biopsy specimens. At present several NGS methods are available for the genetic assessment of human embryos, utilizing different sequencing platforms and/or alternative DNA amplification strategies. Depending on the technique, there may be differences in cost per sample, throughput, speed, quantity and quality of the DNA sequence data produced. There is little doubt that NGS represents an exciting opportunity for PGD laboratories to improve patient care. However, future developments, such as routine whole genome sequencing, will raise significant ethical questions and should be debated as a matter of urgency.
Single gene diagnosis and aneuploidy detection using karyomapping
Speaker BIO:
Tony Gordon
After obtaining a PhD in Carcinogenesis research at the University of Nottingham in 1995, Dr Gordon worked for 7 years at the Institute of Cancer Research (London, UK) in Molecular Cytogenetics investigating pediatric sarcomas. In early 2006 Dr Gordon joined a software start-up, BlueGnome, to start their CytoChip microarray product line. In 2008 Dr Gordon started the 24sure pre-implantation genetic screening (PGS) microarray product line within BlueGnome. Currently 24sure been used to analyse the copy number content of over 300,000 embryo biopsies and has been shown by randomized control clinical trials to improve IVF outcomes. In 2012 BlueGnome was sold to Illumina for $88M. In 2013 Dr Gordon joined Genesis Genetics, the leading global company for PGD and PGS. Dr Gordon is the Managing Director for Genesis Genetics USA, plus Laboratory Director for Genesis Genetics UK laboratories. Dr Gordon is also a UK State Registered Clinical scientist, with nearly 20 years’ experience of clinical diagnostics. .
Development and current best practice for translocations
Speaker BIO:
Dr. Francesco Fiorentino, is founder and CEO of GENOMA, a private molecular genetics laboratory which is now one of the world's largest, fully integrated, specialized provider of genetics services. Dr. Fiorentino is a molecular biologist, internationally recognized in the fields of reproductive genetics, for its leadership in Preimplantation Genetic Diagnosis (PGD) and for its pioneering work in infertility and genetics. He is also well known as one of the pioneers in the creation of the specialties of reproductive and prenatal genetics and was the impetus behind development of many important concepts and techniques that have become standard in these important fields.
Dr. Fiorentino began his career at the the Italian Police Department- Forensic Science Service (FSS), Rome - Italy, where he spent 3 years performing research and investigation on forensic genetics, coordinating the DNA analysis unit.
Dr. Fiorentino later established GENOMA Laboratory, where he initiated a highly successful preimplantation genetic diagnosis (PGD) program, which has grown exponentially since its inception becoming one of the worldwide leaders in both in quality and volume.
Dr. Fiorentino is actively involved in PGD and the study of human oocytes and embryos, since almost two decades. His laboratory has a strong translational emphasis and is actively involved in the development of new techniques for improving the success rates of in vitro fertilization (IVF) treatment. Dr. Fiorentino’s research also aims to create novel PGD methods that are more comprehensive and more reliable than those in current use.
During his PGD activity, Dr. Fiorentino conceived and implemented the innovation of using Minisequencing technique for mutation detection on single cells, a procedure that is now widely used by most of the PGD centers.
Dr. Fiorentino and his group began clinical trials of array-comparative genomic hybridization (arrayCGH), a comprehensive chromosome screening method, aimed at revealing which of the embryos produced during an in vitro fertilisation (IVF) treatment cycle has the greatest potential for producing a child. The clinical application of this approach has been associated with some of the highest IVF pregnancy rates ever recorded and is now widely practiced worldwide.
Recently, he was responsible for the development and the first clinical application of Next Generation Sequencing (NGS) technology in Preimplantation Genetic Screening (PGS), for reliably screening the entire chromosome complement in embryos.
Dr. Fiorentino research work has been noted for its novelty and has frequently produced advances that have been translated from the research lab into clinical practice. His research has led to the publication of more than 40 peer-review papers and book chapters and has generated a great deal of media interest.
History of PGD and PGS
A Brief History of Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening
Jason Franasiak, MD, FACOG
Richard T. Scott, Jr, MD, FACOG, HCLD
Reproductive Medicine Associates of New Jersey
Rutgers, Robert Wood Johnson Medical School
Introduction
The development and enhancement of in vitro fertilization (IVF) over the last 35 years has resulted in dramatic improvements in the treatment of infertility. At present, IVF provides both the most successful and often the most cost effective approach to the care of most infertile couples [1][2].
In the short time since the first IVF birth in 1978 [3], our greater understanding of embryo development had allowed for the development of new technologies which can be implemented to enhance embryo selection. The primary goal is to distinguishing those embryos that are reproductively competent and are capable of producing a healthy child from those that cannot. The drive to select healthy embryos and avoid failed pregnancy attempts, miscarriages, and the need for pregnancy termination led to the first applications of preimplantation genetic diagnosis (PGD) in 1990 [4].
The concept of PGD is not a new one. Indeed, in a 1937 manuscript in the New England Journal of Medicine, Dr. John Rock predicted that human IVF, gender selection, and gestational carriers would be utilized in reproductive science [5]. He stated that one day science will allow for parents to obtain sons or daughters "according to specification", foreshadowing the ability to screen out detrimental disease states with PGD.
The first description of PGD came years later published by the great Dr. Robert Edwards and Dr. Richard Gardner in a 1967 Nature manuscript. In it he described the use of PGD for sexing of rabbit blastocysts [6]. Further work in animal models continued, including Marilyn Monk's work in 1987 demonstrating PGD in a murine model for Lesch-Nyan syndrome [7]. The development and implementation of several techniques in human embryology were instrumental in the application of PGD in human reproduction. First, Leeanda Wilton pioneered the cleavage stage biopsy in 1986. Then, in 1988, two additional approaches to obtaining genetic material from embryos were described with Yuri Verlinsky describing polar body biopsy and Audrey Muggleton-Harris describing trophectoderm biopsy.
The first applications for PGD came in testing monogenic disorders and sex-linked disorders. This was made possible by Elana Kontogianni's work in 1989 which showed PCR for the Y chromosome was possible from a blastomere. Focusing on X-chromosome linked diseases, amplification and detection of Y-chromosome specific repeat sequences allowed for selection of embryos that were female and thus not at risk of carrying the disease. These early approaches gave way to technologies that allowed for the detection of gene mutations on autosomes and sex chromosomes enabling clinicians to select embryos that do not harbor the mutation for embryo transfer.
The success of PGD to predict embryos which did not have genetic disease led to attempts to apply the technology more widely as a selective tool to all embryos in a particular cohort and identify those embryos with normal chromosome complements and thus a higher chance of success on a per cycle basis [8–16]. This practice became known as preimplantation genetic screening (PGS). A prominent goal in this case was to decrease the reliance on high embryo transfer order to achieve high success rates. This is an important given that the practice vastly increases the prevalence of multiple gestations, which are associated with high maternal and neonatal morbidity as compared to singletons [12].
The contribution of embryonic aneuploidy to the inefficiency of human reproduction is well established [17–19] and it seemed intuitive that assessment of the ploidy status of each embryo within the developing cohort would allow selection of only euploid embryos and would ultimately improve IVF outcomes [20]. While this premise was always valid, early attempts at embryonic aneuploidy screening were suboptimal [21,22]. The early techniques entailed molecular analysis that lacked sufficient precision to be clinically meaningful. More recently, application of newer and more powerful molecular technologies have overcome some of the early limits and produced meaningful improvements in clinical outcomes.
Applications for Genetic Testing of Embryos
The impetus to develop PGD in the clinical realm was to identify only unaffected children prior to implantation and thus eliminate the need for pregnancy termination after a diagnosis was made at a later time in the pregnancy. The first clinical application of preimplantation genetic testing was published in 1990 by Handyside et. al. detailing two couples at risk for transmission of X-linked mental retardation and anderoleukodystrophy [4]. Analysis of a blastomere at the 6-8 cell stage with polymerase chain reaction (PCR) analysis which amplified a Y chromosome specific repeat sequence allowed for transfer of female embryos.
While PGD was initially applied to a small subset of disorders with a high likelihood (25-50%) of being present, over the subsequent 15 years its use expanded. Testing for genetic disorders with low penetrance and late-onset became more common and the list of disorders tested expanded to include over 100 conditions, although the most frequent were cystic fibrosis and hemoglobinopathies [23].
The circumstances under which PGD is now utilized include an extensive list of sex-linked and autosomal single gene disorders, HLA typing, and translocations. This expansion is due in part to the way in which patients eligible for PGD are identified. Originally, couples were identified due to a history of a poor pregnancy outcome or a strong family history of disease. Now, expanded carrier screening has become more widely utilized and in many circumstances allows for detection of a transmissible genetic anomaly before it has been phenotypically apparent in patients.
Aneuploidy Screening
Utilization of PGS for aneuploidy screening was initially borne out of a desire to improve pregnancy rates in patients with advanced reproductive age. While antenatal diagnosis for aneuploidy was utilized to decrease the live birth rates of fetuses with an extra chromosome 21, 18, or 13, PGS was meant to look more widely at chromosomes to better select competent embryos and improve reproductive success for patients undergoing IVF on a per cycle basis.
The first papers evaluating human embryo chromosomes were published by Angell et. al. in 1983. They evaluated 3 8-cell embryos with 11 metaphase spreads and discovered that 2/3 of them were aneuploidy [24]. This led them the conclusion that these anomalies were the type "in early embryonic loss and probably contribute to the high failure rate after embryo transfer." This led to further work in 1986 by Angell et. all, where evidence was found of nondisjunction, resulting in trisomy, monosomy, and nullosomy; structural abnormalities; haploidy; and triploidy [25]. Additionally, they noted, importantly, that these lethal chromosome complements could not be distinguished morphologically from those with normal chromosome complements. Thus began attempts to accurately count chromosomes for the purpose of PGS that would span the subsequent decades.
FISH was initially employed with various combinations of chromosomes. However, this method was always limited by the inability to simultaneously screen for all 24 chromosomes [22]. FISH typically screened the seven chromosomes most frequently seen in miscarriage specimens (chromosomes 13, 16, 18, 21, 22, X and Y) analyzing only one or two blastomeres [26,27]. Five trials examining the impact of chromosomal screening in patients with advanced maternal age [26–28] and four trials in relatively good prognosis patients failed to show benefit when screening with FISH [29–32]. This is due in part to the limited interrogation of chromosomes and in part to the technical challenges associated with FISH for PGS.
The development of technologies for single cell whole genome amplification (WGA) allowed for analysis of all 24 chromosomes [33–35]. The first platform characterized was metaphase comparative genomic hybridization (mCGH) by Wells et. al. [36]. The mCGH proved to be quite time consuming and many other platforms utilizing WGA have evolved at a rapid pace in the past several years including, array CGH (aCGH) [37,38,16], single nucleotide polymorphism (SNP) arrays [8,39,40], oligonucleotide CGH [41] and more recently next generation sequencing (NGS) [42]. An additional method, which enables 24 chromosome evaluation without requiring whole genome amplification, is quantitative real time (qPCR) [43].
These methods which interrogate all 24 chromosomes have resulted in improvement in implantation rates and live birth rates, decreased miscarriage rate, and has changed practice patterns to allow for elective single embryo transfer without sacrifice of high success rates for patients.
Summary
Since PGD's inception in 1990, the utilization worldwide has increased and indications for its use have expanded. Originally, the goal of PGD was to detect and eliminate embryos that contained monogenic sex-liked disorders. The development of PGS followed with the original goal of increasing pregnancy success rates on a per cycle basis. Both PGD and PGS now have expanded roles in reproductive medicine. PGD allows for the identification of numerous autosomal and sex-linked disorders, many of which are now identified through expanded carrier screening. PGS allows for not only improved success on a per cycle basis, but also empowers reduced transfer order while maintaining high success rates. This reduced transfer order without sacrificing outcomes allows for a significant reduction of multiple gestations, which improves obstetric and neonatal outcomes and reduce the cost of care.
References
1 Reindollar, R.H. et al. (2010) A randomized clinical trial to evaluate optimal treatment for unexplained infertility: the fast track and standard treatment (FASTT) trial. Fertil. Steril. 94, 888–899
2 Goldman, M.B. et al. (2014) A randomized clinical trial to determine optimal infertility treatment in older couples: the Forty and Over Treatment Trial (FORT-T). Fertil. Steril. 101, 1574–1581.e2
3 Steptoe, P.C. and Edwards, R.G. (1978) Birth after the reimplantation of a human embryo. Lancet 2, 366
4 Handyside, A.H. et al. (1990) Pregnancies from biopsied human preimplantation embryos sexed by Y-specific DNA amplification. Nature 344, 768–70
5 (1937) Conception in a Watch Glass. N. Engl. J. Med. 217, 678–678
6 Edwards, R.G. and Gardner, R.L. (1967) Sexing of live rabbit blastocysts. Nature 214, 576–577
7 Monk, M. et al. (1987) Preimplantation diagnosis of deficiency of hypoxanthine phosphoribosyl transferase in a mouse model for Lesch-Nyhan syndrome. Lancet Lond. Engl. 2, 423–425
8 Treff, N.R. et al. (2010) Accurate single cell 24 chromosome aneuploidy screening using whole genome amplification and single nucleotide polymorphism microarrays. Fertil Steril 94, 2017–21
9 Treff, N.R. et al. (2011) Single nucleotide polymorphism microarray-based concurrent screening of 24-chromosome aneuploidy and unbalanced translocations in preimplantation human embryos. Fertil Steril 95, 1606–12 e1–2
10 Scott, R.T. et al. (2008) Microarray based 24 chromosome preimplantation genetic diagnosis (mPGD) is highly predictive of the reproductive potential of human embryos:a prospective blinded non-selection trial. Fertil Steril 90, 22
11 Scott, R.T. et al. (2012) Comprehensive chromosome screening is highly predictive of the reproductive potential of human embryos: a prospective, blinded, nonselection study. Fertil Steril 97, 870–5
12 Forman, E.J. et al. (2014) Obstetrical and neonatal outcomes from the BEST Trial: single embryo transfer with aneuploidy screening improves outcomes after in vitro fertilization without compromising delivery rates. Am. J. Obstet. Gynecol. 2014 Feb;210(2):157.e1-6.
13 Forman, E.J. et al. (2013) In vitro fertilization with single euploid blastocyst transfer: a randomized controlled trial. Fertil Steril. 2013 Jul;100(1):100-7.e1.
14 Wells, D. and Delhanty, J.D. (2000) Comprehensive chromosomal analysis of human preimplantation embryos using whole genome amplification and single cell comparative genomic hybridization. Mol Hum Reprod 6, 1055–62
15 Fragouli, E. et al. (2008) Comprehensive molecular cytogenetic analysis of the human blastocyst stage. Hum Reprod 23, 2596–608
16 Fishel, S. et al. (2010) Live birth after polar body array comparative genomic hybridization prediction of embryo ploidy-the future of IVF? Fertil Steril 93, 1006e7–1006e10
17 Hassold, T. and Hunt, P. (2001) TO ERR (MEIOTICALLY) IS HUMAN: THE GENESIS OF HUMAN ANEUPLOIDY. Nat. Rev. Genet. 2, 280–291
18 Fragouli, E. and Wells, D. (2011) Aneuploidy in the human blastocyst. Cytogenet Genome Res 133, 149–59
19 Hassold, T. and Hunt, P. (2009) Maternal age and chromosomally abnormal pregnancies: what we know and what we wish we knew. Curr Opin Pediatr 21, 703–8
20 Munne, S. et al. (1995) Embryo morphology, developmental rates, and maternal age are correlated with chromosome abnormalities. Fertil Steril 64, 382–91
21 Mastenbroek, S. et al. (2007) In vitro fertilization with preimplantation genetic screening. N Engl J Med 357, 9–17
22 Fritz, M.A. (2008) Perspectives on the efficacy and indications for preimplantation genetic screening: where are we now? Hum Reprod 23, 2617–21
23 Kuliev, A. and Verlinsky, Y. (2005) Preimplantation diagnosis: a realistic option for assisted reproduction and genetic practice. Curr. Opin. Obstet. Gynecol. 17, 179–183
24 Angell, R.R. et al. (1983) Chromosome abnormalities in human embryos after in vitro fertilization. Nature 303, 336–338
25 Angell, R.R. et al. (1986) Chromosome studies in human in vitro fertilization. Hum. Genet. 72, 333–339
26 Staessen, C. et al. (2004) Comparison of blastocyst transfer with or without preimplantation genetic diagnosis for aneuploidy screening in couples with advanced maternal age: a prospective randomised controlled trial. Hum Reprod 19, 2849–58
27 Hardarson, T. et al. (2008) Preimplantation genetic screening in women of advanced maternal age caused a decrease in clinical pregnancy rate: a randomized controlled trial. Hum Reprod 23, 2806–12
28 Debrock, S. et al. (2007) Preimplantation genetic screening (PGS) for aneuploidy in embryos after in vitro fertilization (IVF) does not improve reproductive outcome in women over 35: a prospective controlled randomised study. Fertil Steril 88, S237
29 Meyer, L.R. et al. (2009) A prospective randomized controlled trial of preimplantation genetic screening in the "good prognosis" patient. Fertil Steril 91, 1731–8
30 Jansen, R.P. et al. (2008) What next for preimplantation genetic screening (PGS)? Experience with blastocyst biopsy and testing for aneuploidy. Hum Reprod 23, 1476–8
31 Staessen, C. et al. (2008) Preimplantation genetic screening does not improve delivery rate in women under the age of 36 following single-embryo transfer. Hum Reprod 23, 2818–25
32 Mersereau, J.E. et al. (2008) Preimplantation genetic screening in older women: a cost-effectiveness analysis. Fertil. Steril. 90, 592–598
33 Handyside, A.H. et al. (2004) Isothermal whole genome amplification from single and small numbers of cells: a new era for preimplantation genetic diagnosis of inherited disease. Mol Hum Reprod 10, 767–72
34 Hu, D.G. et al. (2004) Aneuploidy detection in single cells using DNA array-based comparative genomic hybridization. Mol. Hum. Reprod. 10, 283–289
35 Northrop, L.E. et al. (2010) SNP microarray-based 24 chromosome aneuploidy screening demonstrates that cleavage-stage FISH poorly predicts aneuploidy in embryos that develop to morphologically normal blastocysts. Mol. Hum. Reprod. 16, 590–600
36 Wells, D. et al. (1999) Detailed chromosomal and molecular genetic analysis of single cells by whole genome amplification and comparative genomic hybridisation. Nucleic Acids Res 27, 1214–8
37 Gutierrez-Mateo, C. et al. (2009) Preimplantation genetic diagnosis of single-gene disorders: experience with more than 200 cycles conducted by a reference laboratory in the United States. Fertil Steril 92, 1544–56
38 Hellani, A. et al. (2004) Multiple displacement amplification on single cell and possible PGD applications. Mol Hum Reprod
39 Johnson, D.S. et al. (2010) Preclinical validation of a microarray method for full molecular karyotyping of blastomeres in a 24-h protocol. Hum Reprod 25, 1066–75
40 Handyside, A.H. et al. (2010) Karyomapping: a universal method for genome wide analysis of genetic disease based on mapping crossovers between parental haplotypes. J Med Genet 47, 651–658
41 Traversa, M.V. et al. (2011) The genetic screening of preimplantation embryos by comparative genomic hybridisation. Reprod. Biol. 11 Suppl 3, 51–60
42 Treff, N.R. et al. (2013) Evaluation of targeted next-generation sequencing-based preimplantation genetic diagnosis of monogenic disease. Fertil. Steril. 99, 1377–1384.e6
43 Treff, N.R. et al. (2012) Development and validation of an accurate quantitative real-time polymerase chain reaction-based assay for human blastocyst comprehensive chromosomal aneuploidy screening. Fertil Steril 97, 819–24