Prenatal diagnosis

Prenatal diagnosis and prenatal screening are aspects of prenatal care that focus on detecting anatomic and physiologic problems with the zygote, embryo, or fetus as early as possible, either before gestation even starts (as in preimplantation genetic diagnosis) or as early in gestation as practicable. They use medical tests to detect problems such as neural tube defects, chromosome abnormalities, and gene mutations that would lead to genetic disorders and birth defects, such as spina bifida, cleft palate, Tay–Sachs disease, sickle cell anemia, thalassemia, cystic fibrosis, muscular dystrophy, and fragile X syndrome. The screening focuses on finding problems among a large population with affordable and noninvasive methods, whereas the diagnosis focuses on pursuing additional detailed information once a particular problem has been found, and can sometimes be more invasive. Screening can also be used for prenatal sex discernment. Common testing procedures include amniocentesis, ultrasonography including nuchal translucency ultrasound, serum biomarker testing, or genetic screening. In some cases, the tests are administered to determine if the fetus will be aborted, though physicians and patients also find it useful to diagnose high-risk pregnancies early so that delivery can be scheduled in a tertiary care hospital where the baby can receive appropriate care.

Invasiveness

Diagnostic prenatal testing can be performed by invasive or non-invasive methods. An invasive method involves probes or needles being inserted into the uterus, e.g. amniocentesis, which can be done from about 14 weeks gestation, and usually up to about 20 weeks, and chorionic villus sampling, which can be done earlier (between 9.5 and 12.5 weeks gestation) but which may be slightly more risky to the fetus. One study comparing transabdominal chorionic villus sampling with second trimester amniocentesis found no significant difference in the total pregnancy loss between the two procedures.[1] However, transcervical chorionic villus sampling carries a significantly higher risk, compared with a second trimester amniocentesis, of total pregnancy loss (relative risk 1.40; 95% confidence interval 1.09 to 1.81) and spontaneous miscarriage (9.4% risk; relative risk 1.50; 95% confidence interval 1.07 to 2.11).[1]

Non-invasive techniques include examinations of the woman's womb through ultrasonography and maternal serum screens (i.e. Alpha-fetoprotein). Blood tests for select trisomies (Down syndrome in the United States, Down and Edwards syndromes in China) based on detecting cell-free placental DNA present in maternal blood, also known as non-invasive prenatal testing (NIPT), have become available.[2] If an elevated risk of chromosomal or genetic abnormality is indicated by a non-invasive screening test, a more invasive technique may be employed to gather more information.[3] In the case of neural tube defects, a detailed ultrasound can non-invasively provide a definitive diagnosis.

Fetal versus maternal

Some screening tests performed on the woman are intended to detect traits or characteristics of the fetus. Others detect conditions in the woman that may have an adverse effect on the fetus, or that threaten the pregnancy. For example, abnormally low levels of the serum marker PAPP-A have been shown to correspond to an increased risk of pre-eclampsia, in which the mother's high blood pressure can threaten the pregnancy, though many physicians find regular blood-pressure monitoring to be more reliable.

Reasons for prenatal diagnosis

There are three purposes of prenatal diagnosis: (1) to enable timely medical or surgical treatment of a condition before or after birth, (2) to give the parents the chance to abort a fetus with the diagnosed condition, and (3) to give parents the chance to "prepare" psychologically, socially, financially, and medically for a baby with a health problem or disability, or for the likelihood of a stillbirth.

Having this information in advance of the birth means that healthcare staff as well as parents can better prepare themselves for the delivery of a child with a health problem. For example, Down Syndrome is associated with cardiac defects that may need intervention immediately upon birth.

Many expectant parents would like to know the sex of their baby before birth. Methods include amniocentesis with karyotyping, and prenatal ultrasound. In some countries, health care providers are expected to withhold this information from parents, while in other countries they are expected to give this information.

Qualifying risk factors

Because of the miscarriage and fetal damage risks associated with amniocentesis and CVS procedures, many women prefer to first undergo screening so they can find out if the fetus' risk of birth defects is high enough to justify the risks of invasive testing. Since screening tests yield a risk score which represents the chance that the baby has the birth defect, the most common threshold for high-risk is 1:270. A risk score of 1:300 would therefore be considered low-risk by many physicians. However, the trade-off between risk of birth defect and risk of complications from invasive testing is relative and subjective; some parents may decide that even a 1:1000 risk of birth defects warrants an invasive test while others wouldn't opt for an invasive test even if they had a 1:10 risk score.

ACOG guidelines currently recommend that all pregnant women, regardless of age, be offered invasive testing to obtain a definitive diagnosis of certain birth defects. Therefore, most physicians offer diagnostic testing to all their patients, with or without prior screening and let the patient decide.

The following are some reasons why a patient might consider her risk of birth defects already to be high enough to warrant skipping screening and going straight for invasive testing.

Methods of prenatal screening and diagnosis

There are multiple ways of classifying the methods available, including the invasiveness and the time performed.

Invasiveness Test Comments Time
Non-invasive Fetal cells in maternal blood (FCMB)[4] Based on enrichment of fetal cells which circulate in maternal blood. Since fetal cells hold all the genetic information of the developing fetus, they can be used to perform prenatal diagnosis.[5] First trimester
Non-invasive Cell-free fetal DNA in maternal blood Based on DNA of fetal origin circulating in the maternal blood. Testing can potentially identify fetal aneuploidy[6] (available in the United States, beginning 2011) and gender of a fetus as early as six weeks into a pregnancy. Fetal DNA ranges from about 2–10% of the total DNA in maternal blood.

Cell-free fetal DNA also allows whole genome sequencing of the fetus, thus determining the complete DNA sequence of every gene.[7]

First trimester
Non-invasive Preimplantation genetic diagnosis (PGD) During in vitro fertilization (IVF) procedures, it is possible to sample cells from human embryos before implantation.[8] PGD is in itself non-invasive, but IVF usually involves invasive procedures such as transvaginal oocyte retrieval before implantation
Non-invasive External examination Examination of the woman's uterus from outside the body. First or second trimester
Non-invasive Ultrasound detection Commonly dating scans (sometimes known as booking scans) from 7 weeks to confirm pregnancy dates and look for twins. The specialised nuchal scan at 11–13 weeks may be used to identify higher risks of Downs syndrome. Later morphology scans from 18 weeks may check for any abnormal development. First or second trimester
Non-invasive Fetal heartbeat Listening to the fetal heartbeat First or second trimester
Non-invasive Non-stress test Use of cardiotocography during the third trimester to monitor fetal wellbeing Third trimester
Less invasive Transcervical retrieval of trophoblast cells Cervical mucus aspiration, cervical swabbing, and cervical or intrauterine lavage can be used to retrieve trophoblast cells for diagnostic purposes, including prenatal genetic analysis. Success rates for retrieving fetal trophoblast cells vary from 40% to 90%.[9] It can be used for fetal sex determination and identify aneuploidies.[9] Antibody markers have proven useful to select trophoblast cells for genetic analysis and to demonstrate that the abundance of recoverable trophoblast cells diminishes in abnormal gestations, such as in ectopic pregnancy or anembryonic gestation.[9] First trimester[9]
Less invasive Maternal serum screening Including β-hCG, PAPP-A, alpha fetoprotein, inhibin-A.
See separate section below
First or second trimester
More invasive Chorionic villus sampling Involves getting a sample of the chorionic villus and testing it. This can be done earlier than amniocentesis, but may have a higher risk of miscarriage, estimated at 1%. After 10 weeks
More invasive Amniocentesis This can be done once enough amniotic fluid has developed to sample. Cells from the fetus will be floating in this fluid, and can be separated and tested. Miscarriage risk of amniocentesis is commonly quoted as 0.06% (1:1600).[10] By amniocentesis is also possible to cryopreserve amniotic stem cells.[11][12][13] After 15 weeks
More invasive Embryoscopy and fetoscopy Though rarely done, these involve putting a probe into a women's uterus to observe (with a video camera), or to sample blood or tissue from the embryo or fetus.
More invasive Percutaneous umbilical cord blood sampling PUBS is a diagnostic genetic test that examines blood from the fetal umbilical cord to detect fetal abnormalities. 24–34 weeks

Maternal serum screening

First trimester maternal serum screening can check levels of free β-hCG, PAPP-A, intact or beta hCG, or h-hCG in the woman's serum, and combine these with the measurement of nuchal translucency (NT). Some institutions also look for the presence of a fetal nasalbone on the ultrasound.

Second trimester maternal serum screening (AFP screening, triple screen, quad screen, or penta screen) can check levels of alpha fetoprotein, β-hCG, inhibin-A, estriol, and h-hCG (hyperglycosolated hCG) in the woman's serum.

The triple test measures serum levels of AFP, estriol, and beta-hCG, with a 70% sensitivity and 5% false-positive rate. It is complemented in some regions of the United States, as the Quad test (adding inhibin A to the panel, resulting in an 81% sensitivity and 5% false-positive rate for detecting Down syndrome when taken at 15–18 weeks of gestational age).[14]

The biomarkers PAPP-A and β-hCG seem to be altered for pregnancies resulting from ICSI, causing a higher false-positive rate. Correction factors have been developed and should be used when screening for Down’s syndrome in singleton pregnancies after ICSI,[15] but in twin pregnancies such correction factors have not been fully elucidated.[15] In vanishing twin pregnancies with a second gestational sac with a dead fetus, first trimester screening should be based solely on the maternal age and the nuchal translucency scan as biomarkers are altered in these cases.[15]

Advances in prenatal screening

Measurement of fetal proteins in maternal serum is a part of standard prenatal screening for fetal aneuploidy and neural tube defects.[16][17] Computational predictive model shows that extensive and diverse feto-maternal protein trafficking occurs during pregnancy and can be readily detected non-invasively in maternal whole blood.[18] This computational approach circumvented a major limitation, the abundance of maternal proteins interfering with the detection of fetal proteins, to fetal proteomic analysis of maternal blood. Entering fetal gene transcripts previously identified in maternal whole blood into a computational predictive model helped develop a comprehensive proteomic network of the term neonate. It also shows that the fetal proteins detected in pregnant woman’s blood originate from a diverse group of tissues and organs from the developing fetus. Development proteomic networks dominate the functional characterization of the predicted proteins, illustrating the potential clinical application of this technology as a way to monitor normal and abnormal fetal development.

The difference in methylation of specific DNA sequences between mother and fetus can be used to identify fetal-specific DNA in the blood circulation of the mother. In a study published in March 6, 2011 online issue of Nature journal, using this non-invasive technique a group of investigators from Greece and UK achieved correct diagnosis of 14 trisomy 21 (Down Syndrome) and 26 normal cases.[19][20] Using massive parallel sequencing, a study testing for trisomy 21 only, successfully detected 209 of 212 cases (98.6%) with 3 false-positives in 1,471 pregnancies (0.2%).[2] With commercially available non-invasive (blood) testing for Down syndrome having become available to patients in the United States and already available in China, in October 2011, the International Society for Prenatal Diagnosis created some guidance. Based on its sensitivity and specificity, it constitutes an advanced screening test and that positive results require confirmation by an invasive test, and that while effective in the diagnosis of Down syndrome, it cannot assess half the abnormalities detected by invasive testing. The test is not recommended for general use until results from broader studies have been reported, but may be useful in high-risk patients in conjunction with genetic counseling.[3]

A study in 2012 found that the maternal plasma cell-free DNA test was also able to detect Trisomy 18 (Edwards syndrome) in 100% of the cases (59/59) at a false-positive rate of 0.28%, and Trisomy 13 (Patau syndrome) in 91.7% of the cases (11/12) at a false-positive rate of 0.97%. The test interpreted 99.1% of samples (1,971/1,988); among the 17 samples without an interpretation, three were Trisomy 18. The study stated that if z-score cutoffs for Trisomy 18 and 13 were raised slightly, the overall false-positive rates for the three aneuploidies could be as low as 0.1% (2/1,688) at an overall detection rate of 98.9% (280/283) for common aneuploidies (this includes all three trisomies- Down, Edwards and Patau).[21]

Typical screening sequence

California provides a useful guide to most of the currently available screening paradigms.[22]

At early presentation of pregnancy at around 6 weeks, early dating ultrasound scan may be offered to help confirm the gestational age of the embryo and check for a single or twin pregnancy, but such a scan is unable detect common abnormalities. Details of prenatal screening and testing options may be provided.

Around weeks 10–11, nuchal thickness scan (NT) may be offered which can be combined with blood tests for PAPP-A and beta-hCG, two serum markers that correlate with chromosomal abnormalities, in what is called the First Trimester Combined Test. The results of the blood test are then combined with the NT ultrasound measurements, maternal age, and gestational age of the fetus to yield a risk score for Down Syndrome, Trisomy 18, and Trisomy 13. First Trimester Combined Test has a sensitivity (i.e. detection rate for abnormalities) of 82–87% and a false-positive rate around 5%.

Alternatively, a second trimester Quad blood test may be taken (the triple test is widely considered obsolete but in some states, such as Missouri, where Medicaid only covers the Triple test, that's what the patient typically gets). With integrated screening, both a First Trimester Combined Test and a Triple/Quad test is performed, and a report is only produced after both tests have been analyzed. However patients may not wish to wait between these two sets of test. With sequential screening, a first report is produced after the first trimester sample has been submitted, and a final report after the second sample. With contingent screening, patients at very high or very low risks will get reports after the first trimester sample has been submitted. Only patients with moderate risk (risk score between 1:50 and 1:2000) will be asked to submit a second trimester sample, after which they will receive a report combining information from both serum samples and the NT measurement. The First Trimester Combined Test and the Triple/Quad test together have a sensitivity of 88–95% with a 5% false-positive rate for Down Syndrome, though they can also be analyzed in such a way as to offer a 90% sensitivity with a 2% false-positive rate.

Finally for patients who do not receive an NT ultrasound in the 1st trimester may still receive a Serum Integrated test involving measuring PAPP-A serum levels in the 1st trimester and then doing a Quad test in the 2nd trimester. This offers an 85–88% sensitivity and 5% false-positive rate for Down Syndrome. Also, patient may skip 1st trimester screening entirely and receive only a 2nd trimester Quad test, with an 81% sensitivity for Down Syndrome and 5% false-positive rate.

Conditions typically tested for

Aneuploidy

Use of ultrasound for nuchal translucency will screen for aneuploidy such as Down Syndrome (Trisomy 21), Edwards Syndrome (Trisomy 18), and Patau Syndrome (Trisomy 13), whilst screens that only use serum markers will screen for Down Syndrome and Trisomy 18, but not Trisomy 13. Considering that Trisomy 13 is extremely rare, maybe 1:5000 pregnancies and 1:16000 births, this difference is probably not significant. The AFP marker, whether alone or as part of the Quad test, can identify 80% of spina bifida, 85% of abdominal wall defects, and 97% of anencephaly. Frequently women will receive a detailed 2nd trimester ultrasound in Weeks 18–20 (Morphology scan) regardless of her AFP level, which makes the AFP score unnecessary. Morphology ultrasound scans being undertaken on larger sized fetuses than in earlier scans, detect other structural abnormalities such as cardiac and renal tract abnormalities.

Interphase-fluorescence in situ hybridization (FISH), quantitative PCR and direct preparation of chromosomes from chorionic villi are all current methods being used that are the most effective for detecting fetal aneuploidy.[23]

Noninvasive techniques for detecting aneuploidy

Due to the detection of fetal cells and fetal DNA circulating in maternal blood, noninvasive diagnosis of fetal aneuploidy is becoming more promising.[23][24] The development of a variety of screening methods for fetal aneuploidy and other chromosomal aberrations is now a prominent research area because of the discovery of circulating fetal nucleic acid in maternal blood plasma. However, the key problem is that circulating fetal nucleated cells comprise only three to six percent of maternal blood plasma DNA. Therefore, two effective approaches have been developed that can be used for the detection of fetal aneuploidy. The first involves the measuring of the allelic ratio of single nucleotide polymorphisms (SNPs) in the mRNA coding region in the placenta. The next approach is analyzing both maternal and fetal DNA and looking for differences in the DNA methylation patterns.[25] Fetal cell DNA in maternal blood plasma is elevated in pregnancies complicated by fetal trisomy 21, 13 and 18, making it easier to acquire enough sample sizes of maternal blood plasma to test for fetal aneuploidy.

Digital PCR

Recently, it has been proposed that digital PCR can used for detection of fetal aneuploidy using fetal DNA and RNA found in maternal blood plasma. Research has shown that digital PCR can be used to differentiate between normal and aneuploid DNA using fetal DNA in the maternal blood plasma.[26]

A variation of the PCR technique called multiplex ligation-dependent probe amplification (MLPA), targeting DNA, has been successively applied for diagnosing fetal aneuploidy as a chromosome- or gene-specific assay.[27]

Shotgun sequencing

Fetal cell DNA has been directly sequenced using shotgun sequencing technology. This DNA was obtained from the blood plasma of eighteen pregnant women. This was followed by mapping the chromosome using the quantification of fragments. This was done using advanced methods in DNA sequencing resulting in the parallel sequencing of the fetal DNA. The amount of sequence tags mapped to each chromosome was counted. If there was a surplus or deficiency in any of the chromosomes, this meant that there was a fetal aneuploid. Using this method of shotgun sequencing, the successful identification of trisomy 21 (Down syndrome), trisomy 18 (Edward syndrome), and trisomy 13 (Patau syndrome) was possible. This method of noninvasive diagnosis is now starting to be heavily used and researched further.[28]

Other techniques

Fetal components in samples from maternal blood plasma can be analyzed by genome-wide techniques not only by total DNA, but also by methylated DNA immunoprecipitation (with tiling array), microRNA (such as with Megaplex) and total RNA (RNA-sequencing).[27]

Patient acceptance

Research was conducted to determine how women felt about noninvasive diagnosis of fetal aneuploid using maternal blood. This study was conducted using surveys. It was reported that eight-two percent of pregnant women and seventy-nine percent of female medical students view this type of diagnosis in a positive light, agreeing that it is important for prenatal care. Overall, women responded optimistically that this form of diagnosis will be available in the future.[29]

Rarer conditions also detected

In addition to the direct seeking of chromosomal abnormalities and spina bifida, the blood tests can suggest additional conditions:

Ethical and practical issues

Ethical issues of prenatal testing

Will the result of the test affect treatment of the fetus?

In some genetic conditions, for instance cystic fibrosis, an abnormality can only be detected if DNA is obtained from the fetus. Usually an invasive method is needed to do this.

If a genetic disease is detected, there is often no treatment that can help the fetus until it is born. However, in the US, there are prenatal surgeries for spina bifida fetus. Early diagnosis gives the parents time to research and discuss post-natal treatment and care, or in some cases, abortion. Genetic counselors are usually called upon to help families make informed decisions regarding results of prenatal diagnosis.

False positives and false negatives

Ultrasound of a fetus, which is considered a screening test, can sometimes miss subtle abnormalities. For example, studies show that a detailed 2nd trimester ultrasound, also called a level 2 ultrasound, can detect about 97% of neural tube defects such as spina bifida . Ultrasound results may also show "soft signs," such as an Echogenic intracardiac focus or a Choroid plexus cyst, which are usually normal, but can be associated with an increased risk for chromosome abnormalities.

Other screening tests, such as the Quad test, can also have false positives and false negatives. Even when the Quad results are positive (or, to be more precise, when the Quad test yields a score that shows at least a 1 in 270 risk of abnormality), usually the pregnancy is normal, but additional diagnostic tests are offered. In fact, consider that Down Syndrome affects about 1:400 pregnancies; if you screened 4000 pregnancies with a Quad test, there would probably be 10 Down Syndrome pregnancies of which the Quad test, with its 80% sensitivity, would call 8 of them high-risk. The quad test would also tell 5% (~200) of the 3990 normal women that they are high-risk. Therefore, about 208 women would be told they are high-risk, but when they undergo an invasive test, only 8 (or 4% of the high risk pool) will be confirmed as positive and 200 (96%) will be told that their pregnancies are normal. Since amniocentesis has approximately a 0.5% chance of miscarriage, one of those 200 normal pregnancies might result in a miscarriage because of the invasive procedure. Meanwhile, of the 3792 women told they are low-risk by the Quad test, 2 of them will go on to deliver a baby with Down Syndrome. The Quad test is therefore said to have a 4% positive predictive value (PPV) because only 4% of women who are told they are "high-risk" by the screening test actually have an affected fetus. The other 96% of the women who are told they are "high-risk" find out that their pregnancy is normal.

By comparison, in the same 4000 women, a screening test that has a 99% sensitivity and a 0.5% false positive rate would detect all 10 positives while telling 20 normal women that they are positive. Therefore, 30 women would undergo a confirmatory invasive procedure and 10 of them (33%) would be confirmed as positive and 20 would be told that they have a normal pregnancy. Of the 3970 women told by the screen that they are negative, none of the women would have an affected pregnancy. Therefore, such a screen would have a 33% positive predictive value. It's still unfortunate that 20 false-positive women have had to undergo an invasive procedure to find out they have a normal pregnancy, but it's still better than 200 false-positives with the Quad test.

The real-world false-positive rate for the Quad test (as well as 1st Trimester Combined, Integrated, etc.) is greater than 5%. 5% was the rate quoted in the large clinical studies that were done by the best researchers and physicians, where all the ultrasounds were done by well-trained sonographers and the gestational age of the fetus was calculated as closely as possible. In the real world, where calculating gestational age may be a less precise art, the formulas that generate a patient's risk score are not as accurate and the false-positive rate can be higher, even 10%.

Because of the low accuracy of conventional screening tests, 5–10% of women, often those who are older, will opt for an invasive test even if they received a low-risk score from the screening. A patient who received a 1:330 risk score, while technically low-risk (since the cutoff for high-risk is commonly quoted as 1:270), might be more likely to still opt for a confirmatory invasive test. On the other hand, a patient who receives a 1:1000 risk score is more likely to feel assuaged that her pregnancy is normal.

Both false positives and false negatives will have a large impact on a couple when they are told the result, or when the child is born. Diagnostic tests, such as amniocentesis, are considered to be very accurate for the defects they check for, though even these tests are not perfect, with a reported 0.2% error rate (often due to rare abnormalities such as mosaic Down Syndrome where only some of the fetal/placental cells carry the genetic abnormality).

A higher maternal serum AFP level indicates a greater risk for anencephaly and open spina bifida. This screening is 80% and 90% sensitive for spina bifida and anencephaly, respectively.

Amniotic fluid acetylcholinesterase and AFP level are more sensitive and specific than AFP in predicting neural tube defects.

Many maternal-fetal specialists do not bother to even do an AFP test on their patients because they do a detail ultrasound on all of them in the 2nd trimester, which has a 97% detection rate for neural tube defects such as anencephaly and open spina bifida. Performing tests to determine possible birth defects is mandatory in all states. Failure to detect issues early can have dangerous consequences on both the mother and the baby. OBGYNs may be held culpable. In one case a man who was born with spina fibia was awarded $2 million in settlement, apart from medical expenses, due to the OBGYN's negligence in conducting AFP tests.[30]

No prenatal test can detect all forms of birth defects and abnormalities.

Societal pressures on prenatal testing decisions

Amniocentesis has become the standard of care for prenatal care visits for women who are "at risk" or over a certain age. The wide use of amniocentesis has been defined as consumeristic.[31] and some argue that this can be in conflict with the right to privacy,[32] Most obstetricians (depending on the country) offer patients the AFP triple test, HIV test, and ultrasounds routinely. However, almost all women meet with a genetic counselor before deciding whether to have prenatal diagnosis. It is the role of the genetic counselor to accurately inform women of the risks and benefits of prenatal diagnosis. Genetic counselors are trained to be non-directive and to support the patient's decision. Some doctors do advise women to have certain prenatal tests and the patient's partner may also influence the woman's decision.

Obstetricians have an ethical duty to properly inform patients of their options, specifically the availability of screening and diagnostic testing. Physicians have been successfully sued by women who gave birth to babies with abnormalities that could have been detected had they known about their screening options, though the plaintiff must also prove that she would have elected to terminate the pregnancy in the event of a positive finding. Also, physicians who fail to inform their patients of the risks of amniocentesis and CVS might be found guilty of negligence informed consent in the event that the patient sues after a procedure-related miscarriage or fetal damage.

There is a misconception that a physician only needs to do what other physicians typically do (i.e. standard of care). However, in the case of informed consent, the legal standard is more commonly defined as what a reasonable patient would elect to do if she is informed. So if a reasonable patient would want to be screened if only she is informed or if a reasonable patient would want to receive an amniocentesis if only she is informed of that option, then a physician is legally obligated to inform the patient of these options.

As newer, more accurate screening tests emerge, physicians may need to quickly get up to speed on the most recent data and start informing their patients of the existence of these tests. Failure to inform patients of the available of these more accurate screening tests might result in a wrongful birth or wrongful miscarriage lawsuit if the patient can demonstrate that she would have chosen the newer test, if she had known about it, to avoid the unfortunate outcome that resulted from receiving a conventional screening test or invasive procedure.

See also

Notes and references

  1. 1 2 Amniocentesis and chorionic villus sampling for prenatal diagnosis (Review). By Alfirevic Z, Mujezinovic F, Sundberg K at The Cochrane Collaboration, 2009
  2. 1 2 Palomaki, G. E.; Kloza, E. M.; Lambert-Messerlian, G. M.; Haddow, J. E.; Neveux, L. M.; Ehrich, M.; Van Den Boom, D.; Bombard, A. T.; Deciu, C.; Grody, W. W.; Nelson, S. F.; Canick, J. A. (2011). "DNA sequencing of maternal plasma to detect Down syndrome: An international clinical validation study". Genetics in Medicine. 13 (11): 913–920. doi:10.1097/GIM.0b013e3182368a0e. PMID 22005709.
  3. 1 2 Committee: Peter Benn, Antoni Borrell, Howard Cuckle, Lorraine Dugoff, Susan Gross, Jo-Ann Johnson, Ron Maymon, Anthony Odibo, Peter Schielen, Kevin Spencer, Dave Wright and Yuval Yaron (October 24, 2011), "Prenatal Detection of Down Syndrome using Massively Parallel Sequencing (MPS): a rapid response statement from a committee on behalf of the Board of the International Society for Prenatal Diagnosis" (pdf), ISPD rapid response statement, Charlottesville, VA: International Society for Prenatal Diagnosis, retrieved October 25, 2011
  4. Wachtel, SS; Shulman, LP; Sammons, D (February 2001). "Fetal cells in maternal blood.". Clinical genetics. 59 (2): 74–9. doi:10.1034/j.1399-0004.2001.590202.x. PMID 11260204.
  5. Herzenberg, LA; Bianchi, DW; Schröder, J; Cann, HM; Iverson, GM (March 1979). "Fetal cells in the blood of pregnant women: detection and enrichment by fluorescence-activated cell sorting" (PDF). Proceedings of the National Academy of Sciences of the United States of America. 76 (3): 1453–5. Bibcode:1979PNAS...76.1453H. doi:10.1073/pnas.76.3.1453. PMC 383270Freely accessible. PMID 286330.
  6. Fan HC, Blumenfeld YJ, Chitkara U, Hudgins L, Quake SR; Blumenfeld; Chitkara; Hudgins; Quake (October 2008). "Noninvasive diagnosis of fetal aneuploidy by shotgun sequencing DNA from maternal blood". Proc. Natl. Acad. Sci. U.S.A. 105 (42): 16266–71. Bibcode:2008PNAS..10516266F. doi:10.1073/pnas.0808319105. PMC 2562413Freely accessible. PMID 18838674.
  7. Yurkiewicz, I. R.; Korf, B. R.; Lehmann, L. S. (2014). "Prenatal whole-genome sequencing--is the quest to know a fetus's future ethical?". New England Journal of Medicine. 370 (3): 195–7. doi:10.1056/NEJMp1215536. PMID 24428465.
  8. Santiago Munne, INCIID – accessed July 18, 2009
  9. 1 2 3 4 Imudia AN, Kumar S, Diamond MP, DeCherney AH, Armant DR; Kumar; Diamond; Decherney; Armant (April 2010). "Transcervical retrieval of fetal cells in the practice of modern medicine: a review of the current literature and future direction". Fertil. Steril. 93 (6): 1725–30. doi:10.1016/j.fertnstert.2009.11.022. PMC 2847626Freely accessible. PMID 20056202.
  10. "Mid-Trimester Amniocentesis Fetal Loss Rate" (PDF). J Obstet Gynaecol Can. 29 (7): 586–590. 2007. Retrieved 15 July 2015.
  11. "European Biotech Company Biocell Center Opens First U.S. Facility for Preservation of Amniotic Stem Cells in Medford, Massachusetts | Reuters". 2009-10-22. Retrieved 2010-01-11.
  12. "Europe's Biocell Center opens Medford office – Daily Business Update – The Boston Globe". 2009-10-22. Retrieved 2010-01-11.
  13. "The Ticker". Retrieved 2010-01-11.
  14. Lao, M.R.; Calhoun, B. C.; Bracero, L. A.; Wang, Y.; Seybold, D. J.; Broce, M.; Hatjis, C. G. (2009). "The ability of the quadruple test to predict adverse perinatal outcomes in a high-risk obstetric population". J Med Screen. 16 (2): 55–59. doi:10.1258/jms.2009.009017. PMID 19564516.
  15. 1 2 3 Gjerris, A. C.; Tabor, A.; Loft, A.; Christiansen, M.; Pinborg, A. (2012). "First trimester prenatal screening among women pregnant after IVF/ICSI". Human Reproduction Update. 18 (4): 350–359. doi:10.1093/humupd/dms010. PMID 22523111.
  16. Ball RH, Caughey AB, Malone FD, et al. (July 2007). "First- and second-trimester evaluation of risk for Down syndrome". Obstet Gynecol. 110 (1): 10–7. doi:10.1097/01.AOG.0000263470.89007.e3. PMID 17601890.
  17. Dashe J.S., Twickler D.M., McIntire D.D., Ramus R.M.; Twickler; Santos-Ramos; McIntire; Ramus (2006). "Alpha-fetoprotein Deduction of Neural Tube Defects and the Impact of Standard Ultrasound" (PDF). American Journal of Obstetrics and Gynecology. 195 (6): 1623–1628. doi:10.1016/j.ajog.2006.03.097.
  18. Maron JL, Alterovitz G, Ramoni M, Johnson KL, Bianchi DW; Alterovitz; Ramoni; Johnson; Bianchi (December 2009). "High-Throughput Discovery and Characterization of Fetal Protein Trafficking in the Blood of Pregnant Women". Proteomics: Clinical Applications. 3 (12): 1389–1396. doi:10.1002/prca.200900109. PMC 2825712Freely accessible. PMID 20186258.
  19. Papageorgiou EA, Karagrigoriou A, Tsaliki E, Velissariou V, Carter NP, Patsalis PC; Karagrigoriou; Tsaliki; Velissariou; Carter; Patsalis (April 2011). "Fetal-specific DNA methylation ratio permits noninvasive prenatal diagnosis of trisomy 21". Nat. Med. 17 (4): 510–3. doi:10.1038/nm.2312. PMC 3977039Freely accessible. PMID 21378977.
  20. "A New Non-invasive Test for Down Syndrome:Trisomy 21 Diagnosis using Fetal-Specific DNA Methylation". SciGuru.com. Retrieved 8 March 2011.
  21. Palomaki, G. E.; Deciu, C; Kloza, E. M.; Lambert-Messerlian, G. M.; Haddow, J. E.; Neveux, L. M.; Ehrich, M; Van Den Boom, D; Bombard, A. T.; Grody, W. W.; Nelson, S. F.; Canick, J. A. (2012). "DNA sequencing of maternal plasma reliably identifies trisomy 18 and trisomy 13 as well as Down syndrome: An international collaborative study". Genetics in Medicine. 14 (3): 296–305. doi:10.1038/gim.2011.73. PMC 3938175Freely accessible. PMID 22281937.
  22. The California Prenatal Screening Program. cdph.ca.gov
  23. 1 2 Miny, P; Tercanli S; Holzgreve W (April 2002). "Developments in laboratory techniques for prenatal diagnosis". Current Opinion in Obstetrics and Gynecology. 14 (2): 161–8. doi:10.1097/00001703-200204000-00010. PMID 11914694.
  24. "Fetal Cells from Maternal Blood – A Powerful tool for Prenatal Diagnosis". Archived from the original on March 8, 2012.
  25. Lo, YM (January 2009). "Noninvasive prenatal detection of fetal chromosomal aneuploidies by maternal plasma nucleic acid analysis: a review of the current state of the art". BJOG. 116 (2): 152–7. doi:10.1111/j.1471-0528.2008.02010.x. PMID 19076946.
  26. Zimmermann, BG; Grill S; Holzgreve W; Zhong XY; Jackson LG; Hahn S (December 2008). "Digital PCR: a powerful new tool for noninvasive prenatal diagnosis?". Prenata Diagnostics. 28 (12): 1087–93. doi:10.1002/pd.2150. PMID 19003785.
  27. 1 2 Go, A. T. J. I.; Van Vugt, J. M. G.; Oudejans, C. B. M. (2010). "Non-invasive aneuploidy detection using free fetal DNA and RNA in maternal plasma: Recent progress and future possibilities". Human Reproduction Update. 17 (3): 372–382. doi:10.1093/humupd/dmq054. PMID 21076134.
  28. Fan, HC; Blumenfeld YJ; Chitkara U; Hudgins L; Quake SR (October 21, 2008). "Noninvasive diagnosis of fetal aneuploidy by shotgun sequencing DNA from maternal blood". Proceedings of the National Academy of Sciences. United States. 105 (42): 16266–71. Bibcode:2008PNAS..10516266F. doi:10.1073/pnas.0808319105. PMC 2562413Freely accessible. PMID 18838674.
  29. Kooij, L; Tymstra T; Berg P (February 2009). "The attitude of women toward current and future possibilities of diagnostic testing in maternal blood using fetal DNA". Prenat Diagn. 29 (2): 164–8. doi:10.1002/pd.2205. PMID 19180577.
  30. "Medical malpractice: Childbirth, failed to perform AFP test" (PDF).
  31. Henn, W. (Dec 2000). "Consumerism in Prenatal Diagnosis: A Challenge for Ethical Guidelines". J Med Ethics. 26 (6): 444–6. doi:10.1136/jme.26.6.444.
  32. Botkin JR. Fetal privacy and confidentiality. Hastings Cent Rep. 1995 Sep–Oct;25(5):32–9
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