Preimplantation Genetic Screening for Single Gene Disorders
What is preimplantation genetic screening for single gene disorders?
Preimplantation genetic screening (PGS) is a highly sophisticated scientific technique to test embryos for the presence of a single gene (monogenic) disorder. This allows embryos that are not affected by a specific disorder to be selected for embryo transfer during an IVF cycle, preventing the condition from being passed on to any future children.
At Nairobi IVF, PGS is performed using Next Generation Sequencing. Nairobi IVF is the first fertility clinic in Eastern Africa to offer PGS, a new form of genetic test which can be developed in hours rather than months.
What is pre-implantation genetic screening (PGS)?
PGS (also known as aneuploidy screening) involves checking the chromosomes of embryos conceived by IVF or ICSI for common abnormalities. Chromosomal abnormalities are a major cause of the failure of embryos to implant, and of miscarriages. They can also cause conditions such as Down’s syndrome…
Is PGS for me?
Your specialist may recommend PGS if:
- you are over 35 and have a higher risk of having a baby with a chromosome problem (such as Down’s syndrome)
- you have a family history of chromosome problems
- you have a history of recurrent miscarriages
- you have had several unsuccessful cycles of IVF where embryos have been transferred, or
- your sperm are known to be at high risk of having chromosome problems.
How does PGS work?
The procedure for PGS is usually as follows:
Step 1. You undergo normal IVF or ICSI treatment to collect and fertilise your eggs
Step 2. The embryo is grown in the laboratory for two to three days until the cells have divided and the embryo consists of about eight cells.
Step 3. A trained embryologist removes one or two of the cells (blastomeres) from the embryo.
Step 4. The chromosomes are examined to see how many there are and whether they are normal.
Step 5. One, two or three of the embryos without abnormal numbers of chromosomes are transferred to the womb so that they can develop. Any remaining unaffected embryos can be frozen for later use.
Step 6. Those embryos that had abnormal chromosomes are allowed to perish or may be used for research (with your consent).
Possible variations to this procedure
There are possible variations to this procedure and the trophectoderm biopsy technique can be used in some cases.
Testing at five to six days
It is possible that instead of removing and testing one or two cells from a two – three day old embryo, some centres may allow the embryo to develop to five – six days, when there are 100-150 cells.
More cells can be removed at this stage without compromising the viability of the embryo, possibly leading to a more accurate test.
Alternatively some centres may test eggs for chromosomal abnormalities before they are used to create embryos. Polar bodies (small cells extruded by eggs as they mature) can be extracted and tested.
Comparative Genomic Hybridisation (CGH)
A small number of clinics are now using a procedure called comparative genomic hybridisation (CGH) which allows centres to test for abnormalities in all 23 chromosomes.
These abnormalities may or may not be of biological significance, but their presence will lower the chance of finding suitable embryos for transfer.