Selecting the best possible embryo to implant in a woman undergoing in vitro fertilization (IVF) is a complicated task. As success rates for IVF have improved, many clinics now implant a single embryo during an IVF cycle -- with the goal of avoiding a multiple pregnancy -- and the responsibility of selecting the embryo falls to the embryologist. To determine the quality and viability of an embryo, embryologists typically examine specific features of the embryos using a light microscope. In addition, specialists can use data from preimplantation genetic testing for aneuploidy (PGT-A), a test of whether cells from the embryo at the blastocyst stage have a normal or abnormal number of chromosomes. However, this crucial test carries the risk of false positives (which could lead to discarding a normal embryo) and false negatives (which could lead to transferring an embryo with a chromosomal abnormality). A team of researchers from Brigham and Women's Hospital, in collaboration with colleagues at Peking University and Yikon Genomics in China, have evaluated a new way to conduct preimplantation genetic testing and present results showing that this new method may improve the reliability of the test. Their findings are published in Proceedings of the National Academy of Sciences.
"This technique holds the promise of a more precise test than the current method," said co-corresponding author Catherine Racowsky, PhD, director of the IVF laboratory at the Brigham, and professor in the Department of Obstetrics and Gynecology at Harvard Medical School. "It represents a new way to evaluate embryos with less risk of discarding a viable embryo."
Current PGT-A testing uses a trophectoderm (TE) biopsy. If the blastocyst was a tennis ball, then its fluffy, green outer covering would be its TE cells. Inside the blastocyst is the inner cell mass (ICM) -- cells that will give rise to the fetus. Since current PGT-A testing involves biopsy of a few TE cells, they sometimes fail to reflect the genomic profile of the ICM cells within, especially if the blastocyst contains both normal and abnormal cells -- a phenomenon known as mosaicism.
The new technique, originally developed by co-corresponding author Xiaoliang Sunney Xie, PhD, of Peking University, is known as noninvasive preimplantation genetic testing for aneuploidy (niPGT-A). Instead of extracting TE cells, niPGT-A analyzes DNA leaked from human blastocysts into the culture medium in which they are growing. The technique has several potential advantages. Since it is non-invasive, it does not interfere directly with the embryo. In addition, the technique has the potential to resolve the issue of mosaicism and is more likely to capture the genomic profile of cells from within the inner cell mass.
The team tested the accuracy of niPGT-A using 52 blastocysts donated for research by patients undergoing infertility treatment. Each blastocyst had previously undergone TE biopsy testing by an outside laboratory. The investigators compared the sequencing results of DNA from both the surrounding culture medium and TE biopsy samples with the true results obtained by sequencing the whole embryo.
The team found that the new technique of niPGT-A outperformed the current PGT-A with the TE biopsy method. The niPGT-A technique had a false positive rate of 20 percent, reporting that 3 of 15 embryos tested as abnormal when they were not; the TE method had a false positive rate of 50 percent, reporting that 9 of 18 embryos testing as abnormal were, indeed, normal.
The team notes that the sample size they used was small and that a higher percentage of the embryos were abnormal than would be traditionally seen from women of comparable age in an IVF clinic. The embryos had also been previously biopsied, frozen and then thawed, potentially increasing the amount of DNA leakage from the inner cell mass into the medium. The team is already at work on follow-up experiments to validate that DNA can be detected in the medium, even in embryos that have not been previously biopsied.
"Our ongoing work will help us to determine whether niPGT-A will translate into a paradigm shift for PGT-A in clinical IVF," said Racowsky.
In addition to Racowsky and Xie, co-authors of this work include Lei Huang, Berhan Bogale, Yaqiong Tang and Sijia Lu. Lu and Xie are co-founders and shareholders of Yikon Genomics, which helped with data analysis. This work was supported by Beijing Advanced Innovation Center for Genomics at Peking University and by a research grant from the Center of Infertility and Reproductive Surgery, Department of Obstetrics and Gynecology at Brigham and Women's Hospital.
Brigham Health, a global leader in creating a healthier world, consists of Brigham and Women's Hospital, Brigham and Women's Faulkner Hospital, the Brigham and Women's Physicians Organization and many related facilities and programs. With more than 1,000 inpatient beds, approximately 60,000 inpatient stays and 1.7 million outpatient encounters annually, Brigham Health's 1,200 physicians provide expert care in virtually every medical and surgical specialty to patients locally, regionally and around the world. An international leader in basic, clinical and translational research, Brigham Health has nearly 5,000 scientists, including physician-investigators, renowned biomedical researchers and faculty supported by over $700 million in funding. The Brigham's medical preeminence dates back to 1832, and now, with 19,000 employees, that rich history is the foundation for its commitment to research, innovation, and community. Boston-based Brigham and Women's Hospital is a teaching affiliate of Harvard Medical School and dedicated to educating and training the next generation of health care professionals. For more information, resources, and to follow us on social media, please visit brighamandwomens.org.
Proceedings of the National Academy of Sciences