Preimplantation Genetic Testing (PGT)

Assisted reproduction has revolutionized couples’ ability to have children, even when facing fertility problems. One of the most innovative tools in this process is preimplantation genetic testing (PGT). This testing helps ensure that embryos implanted in the uterus are free from serious genetic abnormalities. In the following text, we will examine in detail preimplantation genetic testing, its types, how it works, what the benefits are, and who can benefit from it.

What is Preimplantation Genetic Testing (PGT)?

Preimplantation genetic testing is a procedure performed during in vitro fertilization (IVF) to examine embryos before their implantation in the uterus. PGT allows detection of genetic abnormalities and chromosomal problems, thus ensuring that only embryos without these abnormalities are selected for transfer and implantation. This can increase the chances of a successful pregnancy and reduce the required number of embryo transfers, as well as reduce the risk of genetic disorders in the child.

Types of Preimplantation Genetic Testing (PGT)

There are different types of PGT, each used for different purposes:

PGT-A (Aneuploidy): Tests for aneuploidies, i.e., abnormalities in chromosome number, such as Down syndrome.
PGT-M (Monogenic): Tests for specific monogenic disorders, such as cystic fibrosis and beta-thalassemia.
PGT-SR (Structural Rearrangements): Tests for structural chromosome rearrangements, such as translocations and inversions. These rearrangements, usually found in one of the two parents, often lead to infertility, recurrent miscarriages, and birth of children with health problems.

How does Preimplantation Genetic Testing work?

The PGT procedure includes several stages:

In Vitro Fertilization (IVF): The woman receives medications to stimulate her ovaries to produce multiple eggs. These eggs are collected and fertilized with her partner’s sperm (or donor sperm) in the laboratory.
Embryo Culture: The fertilized eggs (embryos) are cultured for several days in the laboratory, usually until the blastocyst stage (day 5 or 6 of culture).
Embryo Biopsy: At this stage, a few cells are removed from the embryo for genetic analysis. This biopsy is generally considered not to harm embryo development.
Genetic Analysis: The removed cells are analyzed to detect genetic abnormalities.
Selection and Embryo Transfer: Embryos that do not appear to have genetic abnormalities are selected for transfer to the woman’s uterus. Embryo transfer is performed in a natural or slightly stimulated cycle to increase the chances of success.

Who can benefit from Preimplantation Genetic Testing?

PGT can be particularly useful for the following couples:

Couples with Family History of Genetic Disorders: If one or both parents are carriers of a genetic disorder (e.g., carriers of beta-thalassemia or cystic fibrosis), PGT can help avoid transmitting the disorder to their children.
Couples with Recurrent Miscarriages: Certain genetic abnormalities (e.g., structural chromosome rearrangements) can cause recurrent miscarriages. PGT can detect these problems before implantation.
Couples with Multiple Implantation Failures: In cases where IVF has repeatedly failed, PGT can help identify healthy embryos that have greater chances of successful implantation.
Women of Advanced Age: Women over 35 years have an increased risk of chromosomal abnormalities in their embryos. PGT can help identify and select healthy embryos.

What are the Benefits of Preimplantation Genetic Testing?

The use of PGT can offer significant benefits to prospective parents:

Reduction of Risk of Genetic Diseases: By detecting and selecting healthy embryos, PGT reduces the risk of giving birth to children with genetic diseases.
Increased Chances of Successful Pregnancy per Embryo Transfer: By selecting healthy embryos for implantation, PGT can increase the chances of successful pregnancy and reduce the risk of miscarriage after each embryo transfer.
Reduction of Repeated IVF Failures: By detecting the healthiest embryos, PGT can reduce the need for multiple IVF cycles, saving time, money, and emotional distress.

What are the Limitations and Challenges of Preimplantation Genetic Testing?

Cost: The PGT procedure is often expensive. It is important to discuss the cost with your doctor and consider all your financial options.
Ethical Issues: Some people may have ethical objections regarding embryo selection based on their genetic composition. It is important to discuss these issues with your Fertility/Reproductive Medicine specialist and your geneticist.
Legal Restrictions: Greek legislation sets certain restrictions on the use of this technology. Specifically, preimplantation genetic testing is permitted when there is an increased risk of transmitting genetic diseases to a couple’s children (e.g., both parents are carriers of beta-thalassemia) or an increased risk of miscarriages due to chromosomal abnormalities. It is also permitted for couples who have had recurrent (at least 2) miscarriages or failed (at least 3) embryo transfers. Finally, before preimplantation genetic testing can be performed, authorization from the National Authority for Medically Assisted Reproduction is required.
Technical Limitations: PGT cannot detect all genetic abnormalities, and there is always the possibility of false negatives or false positives. This means that while PGT can reduce the risk of genetic disorders, it cannot eliminate it completely. Also, sometimes considerable time (2-6 months) is required to create the appropriate test for detecting the specific genetic disease carried by one or both parents.
IVF Success Rates: The success of IVF is not guaranteed and depends on many factors, including the woman’s age and general health. Thus, even in cases of preimplantation genetic testing, the probability of success usually does not exceed 60% per embryo transferred.

What are the Risks of Preimplantation Genetic Testing?

Potential Embryo Damage: Embryo biopsy is an invasive procedure that, theoretically, can cause damage to the embryo. This, however, is rare, especially in accredited laboratories with experienced personnel.
Implantation Failure: As mentioned above, even healthy embryos may not implant successfully in the uterus.
Errors in Genetic Analysis: Although rare, there may be false positive or false negative results in genetic analysis. For this reason, it is always recommended to confirm the PGT diagnosis by performing amniocentesis during pregnancy (usually at 16-18 weeks of gestation).

Conclusion

Preimplantation genetic testing is an important tool in modern reproductive medicine that can help many couples have healthy children. Despite ethical issues and technical challenges, PGT offers hope to couples with a family history of genetic disorders and increases the chances of successful pregnancy.

If you want to learn more or need to undergo preimplantation genetic testing (PGT), you can contact Dr. Venetis to understand its possibilities and limitations and proceed with this procedure if you wish.