PGD (Preimplantation Genetic Diagnosis) is genetic testing of embryos
in IVF to help avoid genetic birth defects such as Cystic Fibrosis,
Down Syndrome, Duchenne Muscular Dystrophy, Hemophilia A, Sickle Cell
Anemia, Tay Sachs Disease and Turner Syndrome
See a fertility specialist now
All our specialists offer PGD services.
Couples with a family history of a genetic disorder and older mothers are
more likely to have a baby with genetic birth defects. Preimplantation
genetic testing and diagnosis (PGD) can help these parents dramatically
improve their odds of giving birth to a healthy child.
Embryos that have certain genetic defects develop improperly. Used with
in vitro fertilization (IVF), PGD can help your doctor select the best
embryos and avoid specific birth defects.
In PGD, a embryologist removes one or two cells from each embryo created
in the IVF cycle. The cells are tested for abnormal genes. Only the
embryos that have normal cells are transferred into the woman.
Since PGD is not 100% reliable and only tests for specific defects,
parents should use other prenatal genetic tests, such as amniocentesis or
chorionic villus sampling. PGD is expensive and still considered an
experimental procedure.
Candidates for PGD
Couples with family history of genetic disease. Women over age 35.
PGD can detect genetic disorders when the defect is understood. As we
learn more about genes and gene defects, PGD will become useful for more
patients.
PGD can tell whether an embryo will become a boy or girl, and reveal
certain genetic conditions, including Cystic fibrosis, Down Syndrome,
Duchenne muscular dystrophy, Hemophilia A, Tay-Sachs disease, and Turner
Syndrome. Consult your doctor or genetic counselor for further
information.
Benefits
Prior to PGD, many couples with a family history of severe genetic
disorder may have decided against having children. PGD dramatically
improves the odds of having a baby without the disorder. In some cases,
biologists can see whether the embryo has the defect. Some disorders only
affect male offspring, so that female embryos may be selected to avoid
the condition even if the exact defect isn't understood.
PGD helps prevent the stress and trauma after an abnormal result from an
amniocentesis or chorionic villus sampling. These prenatal genetic tests
can only be performed after 10-12 weeks into the pregnancy. Patients who
use PGD should follow up with one of these tests, but the odds of an
abnormal result will be dramatically reduced.
Risks
Embryo damage. PGD requires the removal of one or two cells from each
embryo. The embryo development is slowed slightly, but is otherwise
normal. Most embryos are not adversely affected by the procedure. Some
embryos may be damaged during the removal.
Incorrect results. False positive: An embryo that the PGD detects as
abnormal may be normal. This embryo would not be transferred, even though
it could have become a healthy baby. False negative: An embryo that the
PGD detects as normal may be abnormal. This embryo would be transferred,
and would result in a miscarriage or child with birth defects. Because of
this risk, other genetic tests, amniocentesis or chorionic villus
sampling, should be performed.
IVF risks. Since PGD is performed using embryos from an IVF cycle, the
patient should be aware of the risks of IVF.
Not achieving pregnancy. There may be too few or no embryos without the
defect. The embryos may not implant and develop even if they do not have
the defect.
Procedure
Speak with your doctor or genetic counselor to determine whether PGD is
appropriate for you.
Egg stimulation and IVF. If you decide to pursue PGD, you will prepare
for an IVF procedure. The woman will take hormones to stimulate the
ovaries to produce many eggs.
Just as in a normal IVF procedure, the doctor retrieves the mature eggs
from the woman. The eggs are fertilized with sperm. After two days, the
embryos grow to four to six cells.
Cell biopsy. The biologist forms a small opening in the outer membrane of
the embryo, the zona pellucida. This is a similar process to assisted
hatching. The technician gently sucks one or two cells out of the embryo
through the hole. These cells are then tested for genetic abnormalities.
In most cases, all the cells of an embryo will have the identical genetic
makeup. Therefore, the tested cells will show the genetics of the
remaining, viable embryo. The remaining cells of the embryo are young
enough that they will form a complete, normal fetus.
Cell test. The test itself is a standard genetic test. It takes less than
24 hours to perform, so that the patient follows essentially the same
schedule as a standard IVF cycle.
Women over 35 are more likely to have eggs with an extra or missing
chromosome (aneuploidy). In these cases, the laboratory will examine the
cells to count the chromosomes that usually lead to severe birth defects.
Each human chromosome has a number, except the X and Y chromosomes that
determine gender. The biologist uses a technique called fluorescence in-
situ hybridization (FISH) to attach a particular color to each 13, 16,
18, 21, X, and Y chromosome. The biologist counts the spots of each color
for each cell. Normal cells will have two of each color for the numbered
chromosomes, as well as two X chromosomes (female cells) or an X and a Y
chromosome (male cells).
For a family history of a disorder, the laboratory will test for the
specific defect. The laboratory must first test cells from the parent who
has the disorder or may be a carrier to determine the exact defect. The
embryo cells are then tested in a process that uses FISH to see if they
contain that exact defect. The test doesn't reveal other genetic defects.
Embryo transfer. After the tests are completed, the best embryos without
the defect are transferred into the woman's uterus as in a standard IVF
cycle. Follow the recovery procedures for an IVF cycle. If you become
pregnant, be sure to follow up the PGD with another prenatal genetic
test.
See a fertility specialist now
All our specialists offer PGD services.