Genetic Disorders and the Fetus. Группа авторов

Genetic Disorders and the Fetus - Группа авторов


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cell attachment and growth. As with any component of the cell culture system, it is advisable to test new and old plastic ware in parallel for toxicity and ability to support growth in vitro. Hoehn's laboratory switched several times between Corning and Falcon and tested additional brands because of considerable fluctuations in quality.604

      Incubator failure

      Incubator failure is not a trivial cause of culture loss. The main threats are breakdown of the gas supply or equipment. AF cells cannot tolerate a pH close to or higher than 8 for more than 6–8 hours. On the other hand, a pH of less than 7.0 (for example, due to excess CO2 in the incubator) causes cells to stop dividing. A second danger is overheating of incubators due to mechanical failure or human error. Connection of incubators to emergency power sources is important. Temperature‐ and gas‐sensitive alarm systems are advisable.

      Record keeping and quality control

      With the advent of highly standardized cell culture methods, culture hazards have become a much rarer cause for concern in the prenatal diagnosis laboratory. Due to the greater number of specimens processed by the average laboratory, a variety of quality‐control measures need to be followed to avoid mistakes ranging from culture mixups to diagnostic errors. The most common and potentially serious laboratory errors are human errors in labeling and cross‐contamination of samples. Labeling errors can occur at any stage where cells are transferred between vessels: in the amniocentesis procedure room, at culture initiation, feeding and subculture, harvest, slide making, and even microscope analysis. Cross‐contamination of cells between patient samples is most common at the time of cell culture harvest, especially for suspension harvests. For these reasons, quality control and quality assurance programs must include a nonpunitive recording system for all laboratory events. A regular review of those events should seek patterns of error that can be eliminated by continuing education of laboratory staff or (often more effective) process improvement directed at reducing the opportunity for human error.

      Laboratory directors and supervisors should be familiar with the College of American Pathologists Laboratory General and Cytogenetics checklists and the American College of Medical Genetics Standards and Guidelines.665 Laboratories should also participate in a peer review system such as the CAP proficiency surveys.

      Safety in the laboratory

      It is the responsibility of the laboratory director and all the laboratory staff to protect the rights, privacy and health of employees, ancillary staff and patients alike. AF specimens and all cultures up to the stage of fixation should be treated as potentially hazardous. Universal precautions are essential. Available resources include the CAP Safety Checklist and excellent reviews of laboratory safety and management.672674

      Mesenchymal stem cells in amniotic fluid

      Multipotent mesenchymal stem cells (MSCs) can be obtained from several tissue sources and are of great interest for their potential uses in gene therapy and tissue repair. Those derived from adult bone marrow or other sources apart from AFCs have some drawbacks including their relative rarity and slow rate of proliferation in vitro. In contrast, MSCs derived from AFCs have distinct advantages.675679 MSCs comprise about 1 percent of the cells in midtrimester AF and likely derive from fibroblastic F‐type cells.675 Recent advances in the isolation and culture of MSCs from AF are welcomed because these cells apparently do not form teratomas and are not tumorigenic even after many passages. Amniotic MSCs proliferate well and have stable normal telomeres, cytogenetics, and cell surface markers of pleuripotency, similar to embryonic stem cells. Amniotic MSCs also circumvent ethical objections associated with the use of embryonic stem cells.

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