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Error-filled embryos

Humans are incredibly inefficient when it comes to reproduction. Fertile couples have only a 25% chance of achieving a viable pregnancy per menstrual cycle. Now, in the November Molecular Human Reproduction, Wells and Delhanty suggest that the low success rate may be explained by the high incidence of chromosomal abnormalities in early embryos, many of which never reach the stage of implantation (Mol Hum Reprod 2000, 6:1055-1062). In previous research, fluorescent in-situ hybridization (FISH) me

By | October 27, 2000

Humans are incredibly inefficient when it comes to reproduction. Fertile couples have only a 25% chance of achieving a viable pregnancy per menstrual cycle. Now, in the November Molecular Human Reproduction, Wells and Delhanty suggest that the low success rate may be explained by the high incidence of chromosomal abnormalities in early embryos, many of which never reach the stage of implantation (Mol Hum Reprod 2000, 6:1055-1062). In previous research, fluorescent in-situ hybridization (FISH) methods that detect individual chromosomes were used to show that up to half of all embryos have abnormalities. FISH, however, can be reliably used for only a few chromosomes at a time. Therefore Wells and Delhanty combined whole genome amplification with comparative genomic hybridization to analyze all chromosomes of each cell of in-vitro fertilized (IVF) embryos. Of the 12 embryos analyzed (a total of 64 separate cells), nine had at least some aneuploid cells. Eight embryos were mosaic, containing different chromosome complements in different cells. The presence of three completely normal embryos was actually surprising given the high frequency of abnormalities detected with just a few FISH chromosome probes, but can be explained by the clustering of multiple aneuploidies in single cells. All the aneuploidy may arise from the lack of a mitotic checkpoint in early embryonic cells. To get around this deficiency, and improve the success rate of IVF, a simplified version of the current protocol could be used to analyze a single cell extracted from early embryos.

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