Book contents
- Frontmatter
- Contents
- Participants
- Declarations of personal interest
- Preface
- 1 Genetic aetiology of infertility
- 2 Disorders of sex development
- 3 Preimplantation genetic diagnosis: current practice and future possibilities
- 4 Ethical aspects of saviour siblings: procreative reasons and the treatment of children
- 5 Epigenetics, assisted reproductive technologies and growth restriction
- 6 Fetal stem cell therapy
- 7 Prenatal gene therapy
- 8 Ethical aspects of stem cell therapy and gene therapy
- 9 Fetal dysmorphology: the role of the geneticist in the fetal medicine unit in targeting diagnostic tests
- 10 Fetal karyotyping: what should we be offering and how?
- 11 Non-invasive prenatal diagnosis: the future of prenatal genetic diagnosis?
- 12 Non-invasive prenatal diagnosis for fetal blood group status
- 13 Selective termination of pregnancy and preimplantation genetic diagnosis: some ethical issues in the interpretation of the legal criteria
- 14 Implementation and auditing of new genetics and tests: translating genetic tests into practice in the NHS
- 15 New advances in prenatal genetic testing: the parent perspective
- 16 Informed consent: what should we be doing?
- 17 Consensus views arising from the 57th Study Group: Reproductive Genetics
- Index
12 - Non-invasive prenatal diagnosis for fetal blood group status
Published online by Cambridge University Press: 05 February 2014
- Frontmatter
- Contents
- Participants
- Declarations of personal interest
- Preface
- 1 Genetic aetiology of infertility
- 2 Disorders of sex development
- 3 Preimplantation genetic diagnosis: current practice and future possibilities
- 4 Ethical aspects of saviour siblings: procreative reasons and the treatment of children
- 5 Epigenetics, assisted reproductive technologies and growth restriction
- 6 Fetal stem cell therapy
- 7 Prenatal gene therapy
- 8 Ethical aspects of stem cell therapy and gene therapy
- 9 Fetal dysmorphology: the role of the geneticist in the fetal medicine unit in targeting diagnostic tests
- 10 Fetal karyotyping: what should we be offering and how?
- 11 Non-invasive prenatal diagnosis: the future of prenatal genetic diagnosis?
- 12 Non-invasive prenatal diagnosis for fetal blood group status
- 13 Selective termination of pregnancy and preimplantation genetic diagnosis: some ethical issues in the interpretation of the legal criteria
- 14 Implementation and auditing of new genetics and tests: translating genetic tests into practice in the NHS
- 15 New advances in prenatal genetic testing: the parent perspective
- 16 Informed consent: what should we be doing?
- 17 Consensus views arising from the 57th Study Group: Reproductive Genetics
- Index
Summary
Introduction
When Denis Lo and his colleagues in Oxford identified the presence of free fetal DNA in the blood of pregnant women, the implications for prenatal diagnostics without the requirement for invasive procedures were obvious. The main complication is that a very low concentration of fetal DNA is present in the maternal plasma, representing between 3% and 6% of the total free DNA. Although enrichment of fetal DNA can be achieved by exploiting the differences in fragment size between fetal and maternal DNA, complete separation has not proved possible. The only diagnostic tests using free fetal DNA in maternal plasma that are used routinely are those where the target gene or allele is not present in the mother. These are fetal sexing by detection of a Y-borne gene and fetal blood grouping in women whose red cells lack the corresponding antigen.
Alloimmunisation against the D (RH1) red cell surface antigen of the Rh blood group system is the most common cause of haemolytic disease of the fetus and newborn (HDFN), which, before the introduction of post-delivery anti-D prophylaxis in the 1960s, accounted for the death of one baby in 2200. In the following 40 years, the effect of the anti-D prophylaxis programme and improved neonatal care reduced the prevalence to one death in 21000. In England and Wales, about 500 fetuses develop HDFN each year, of which 25–30 babies die, and at least 20 pregnancies per year are lost to miscarriage before 24 weeks of gestation.
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- Information
- Reproductive Genetics , pp. 173 - 182Publisher: Cambridge University PressPrint publication year: 2009