Abstract: Fetal cells may be obtained from amniocentesis, chorionic villus sampling, percutaneous umbilical cord sampling or in vitro fertilization embryos or products of conception, but are preferably from maternal peripheral blood. Fetal cells may be enriched by density gradient centrifugation. Fetal cells may also be enriched by removing maternal cells with an antibody to a cell surface antigen, e.g. anti-CD45, either immobilized or by fluorescence-activated cell sorting. Fetal cells are also distinguishable from maternal cells by staining, e.g. with a labeled antibody to cytokeratin or to fetal hemoglobin, or for fetal hemoglobin by hematoxylin/eosin, or by in situ hybridization to detect one or more fetal mRNAs, e.g., of fetal hemoglobin or fetoprotein. Amplification may be used in conjunction with the in situ hybridization. Fetal cells circulating in maternal blood may be separated by flow cytometry, sorting on their intrinsic light scattering properties.

Abstract: Fetal cells may be obtained from amniocentesis, chorionic villus sampling, percutaneous umbilical cord sampling or in vitro fertilization embryos or products of conception, but are preferably from maternal peripheral blood. Fetal cells may be enriched by density gradient centrifugation. Fetal cells may also be enriched by removing maternal cells with an antibody to a cell surface antigen, e.g. anti-CD45, either immobilized or by fluorescence-activated cell sorting. Fetal cells are also distinguishable from maternal cells by staining, e.g. with a labeled antibody to cytokeratin or to fetal hemoglobin, or for fetal hemoglobin by hematoxylin/eosin, or by in situ hybridization to detect one or more fetal mRNAs, e.g., of fetal hemoglobin or fetoprotein. Amplification may be used in conjunction with the in situ hybridization. Fetal cells circulating in maternal blood may be separated by flow cytometry, sorting on their intrinsic light scattering properties.

Abstract: Fetal cells may be obtained from amniocentesis, chorionic villus sampling, percutaneous umbilical cord sampling or in vitro fertilization embryos or products of conception, but are preferably from maternal peripheral blood. Fetal cells may be enriched by density gradient centrifugation. Fetal cells may also be enriched by removing maternal cells with an antibody to a cell surface antigen, e.g. anti-CD45, either immobilized or by fluorescence-activated cell sorting. Fetal cells are also distinguishable from maternal cells by staining, e.g. with a labeled antibody to cytokeratin or to fetal hemoglobin, or for fetal hemoglobin by hematoxylin/eosin, or by in situ hybridization to detect one or more fetal mRNAs, e.g., of fetal hemoglobin or fetoprotein. Amplification may be used in conjunction with the in situ hybridization. Fetal cells circulating in maternal blood may be separated by flow cytometry, sorting on their intrinsic light scattering properties.

Abstract: Assays for target molecules in and from cells and viruses, e.g. nucleic acids, wherein non-specific background is decreased by including an analogue of the reporter group, e.g. a non-fluorescent analogue such as fuchsin, of a fluorescent group such as fluorescein, to decrease non-specific background.

Abstract: Fetal cells may be obtained from amniocentesis, chorionic villus sampling, percutaneous umbilical cord sampling or in vitro fertilization embryos or products of conception, but are preferably from maternal peripheral blood. Fetal cells may be enriched by density gradient centrifugation. Fetal cells may also be enriched by removing maternal cells with an antibody to a cell surface antigen, e.g. anti-CD45, either immobilized or by fluorescence-activated cell sorting. Fetal cells are also distinguishable from maternal cells by staining, e.g. with a labeled antibody to cytokeratin or to fetal hemoglobin, or for fetal hemoglobin by hematoxylin/eosin, or by in situ hybridization to detect one or more fetal mRNAs, e.g., of fetal hemoglobin or fetoprotein. Amplification may be used in conjunction with the in situ hybridization. Fetal cells circulating in maternal blood may be separated by flow cytometry, sorting on their intrinsic light scattering properties.

Abstract: Assays for target molecules in and from cells and viruses, e.g. nucleic acids, wherein non-specific background is decreased by including an analogue of the reporter group, e.g. a non-fluorescent analogue such as fuchsin, of a fluorescent group such as fluorescein, to decrease non-specific backround.

Abstract: A biologically active cyclic synthetic peptide analog having an amino acid sequence similar to that of native epidermal growth factor between amino acids 32-48 is revealed. The peptide has been found to mimic certain biological activities of intact native epidermal growth factor (EGF). The EGF peptide analogs of the present invention include at least one sulfhydryl bond between two cysteines of the peptide containing block termini. The peptides comprise the end of the B-loop and the C-loop characteristic of the native form of the epidermal growth factor peptide. The biological activity of the peptide provides for methods of using the peptide as an agent in wound healing and also in cancer therapy. More particularly, the described peptides are used in cancer therapeutic applications and in the promotion of wound healing, especially burn wounds and peptic ulcer disease. Methods of preparing and using the described bioactive EGF analog peptides are also disclosed.