Apply These Secret WAYS TO Improve Pregnancy Loss And Chromosome Testing For Miscarriages

Although most couples are blissfully unacquainted with the statistics surrounding miscarriage, pregnancy loss is really quite common, with 10-25% of recognized pregnancies ending in miscarriage. Assuming you have suffered a pregnancy loss or are in the process of experiencing a miscarriage, you might be wondering what caused losing and worry about whether it’ll happen again. This article aims to answer the next questions:

What causes miscarriage?
How common is pregnancy loss?
What type of genetic testing is available for miscarriage tissue?
How can chromosome testing help?
Causes of Miscarriage

There are many different explanations why miscarriage occurs, but the most common cause for first trimester miscarriage is really a chromosome abnormality. Chromosome abnormalities – extra or missing whole chromosomes, also known as “aneuploidy” – occur because of a mis-division of the chromosomes in the egg or sperm involved with a conception. Typically, humans have 46 chromosomes which come in 23 pairs (22 pairs numbered from 1 to 22 and the sex chromosomes, X and Y). For a baby to develop normally it is important that it have the right level of chromosome material; missing or extra material during conception or within an embryo or fetus could cause a female to either not become pregnant, miscarry, or have a child with a chromosome syndrome such as Down syndrome.

Over 50% of most first trimester miscarriages are due to chromosome abnormalities. This number could be closer to 75% or more for women aged 35 years and over who’ve experienced recurrent pregnancy loss. Overall, the rate of chromosome abnormalities and the rate of miscarriage both increase with maternal age, with a steep upsurge in women older than 35.

Pregnancy Loss – How Common could it be?

Miscarriage is a lot more common than a lot of people think. Up to one in every four recognized pregnancies is lost in first trimester miscarriage. The chance of having a miscarriage also increases as a mother ages.

Most women who experience a miscarriage go on to get a healthy pregnancy and never miscarry again. However, some women appear to be more prone to miscarriage than others. About five percent of fertile couples will experience two or more miscarriages.

Of note, the rate of miscarriage appears to be increasing. One reason for this can be awareness – more women know they’re having a miscarriage because home pregnancy tests have improved early pregnancy detection rates in the last decade, whereas in past times the miscarriage would have appeared to be just a unique period. Another reason could be that more women are conceiving at older ages.

Types of Genetic Testing Helpful for Miscarriages

Genetic testing actually refers to many types of testing that you can do on the DNA in a cell. For miscarriage tissue, also called products of conception (POC), probably the most useful type of test to perform is a chromosome analysis. miscarriage A chromosome analysis (also known as chromosome testing) can examine all 23 pairs of chromosomes for the presence of extra or missing chromosome material (aneuploidy). Because so many miscarriages are caused by aneuploidy, chromosome analysis on the miscarriage tissue could identify the reason behind the pregnancy loss.

The most common method of chromosome analysis is named karyotyping. Newer methods include advanced technologies such as microarrays.

Karyotyping analyzes all 23 pairs of chromosome but requires cells from the miscarriage tissue to first be grown in the laboratory, a process called “cell culture”. Due to this requirement, tissue that’s passed at home is often unable to be tested with this method. About 20% or even more of miscarriage samples fail to grow and thus no email address details are available. Additionally, karyotyping struggles to tell the difference between cells from the mother (maternal cells) and cells from the fetus. In case a normal female result is available, it may be the correct result for the fetus or it can be maternal cell contamination (MCC) in which the result actually originates from testing the mother’s cells present in the pregnancy tissue instead of the fetal cells. MCC appears to occur in about 30% or more of the samples tested by traditional karyotype. Results from karyotyping usually take a few weeks to months another from the laboratory.

Microarray testing is really a new kind of genetic testing done on miscarriage samples; the two most common types of microarray testing are array CGH (comparative genomic hybridization) and chromosome SNP (single-nucleotide polymorphism) microarray. Microarray testing is also in a position to test all 23 pairs of chromosomes for aneuploidy, but will not require cell culture. Therefore, you are more prone to receive results and the results are typically returned faster when microarray testing is used. Additionally, some laboratories are collecting a sample of the mother’s blood concurrently the miscarriage tissue is sent to enable immediate detection of maternal cell contamination (MCC).

Chromosome Testing – How do it help?

If a chromosome abnormality is identified, the kind of abnormality found can be assessed to help answer fully the question: “Will this happen to me again?”. Most of the time, chromosome abnormalities within an embryo or fetus aren’t inherited and have a low possiblity to occur in future pregnancies. Sometimes, a particular chromosome finding in a miscarriage alerts your physician to do further studies to research the chance of an underlying genetic or chromosome problem in your family that predisposes one to have miscarriages.

Furthermore, in case a chromosome abnormality is identified it can prevent the need for other, sometimes quite costly, studies your doctor might consider to investigate the reason for the miscarriage.

Lastly, knowing the explanation for a pregnancy loss might help a couple of start the emotional healing process, moving past the question of “Why did this happen to me?”.

Chromosome testing can be especially very important to patients with repeated miscarriages, as it can either give clues to an underlying chromosomal cause for the miscarriages or eliminate chromosome errors as the reason behind the miscarriages and allow their doctor to pursue other styles of testing. For couples with multiple miscarriages determined to truly have a chromosomal cause, in vitro fertilization (IVF) with preimplantation genetic diagnosis (PGD) testing might be able to help increase their likelihood of having an effective healthy pregnancy.