The Glass Slide Extraction System Snap Card Improves Non-Invasive Prenatal Genotyping in Pregnancies with Antibodies.

BACKGROUND: Determination of fetal blood groups in maternal plasma samples critically depends on adequate pre-analytical steps for optimal amplification of fetal DNA. We compared the extraction of cell-free DNA by binding on a glass surface (BCSI SNAP™ Card) with an automated system based on bead technology (MagnaPure compact™). METHODS: Maternal blood samples from 281 pregnancies (7th-39th week of gestation) with known antibodies were evaluated in this study. Both the SNAP card and the MagnaPure method were applied to isolate DNA in order to directly compare the amplification in a single base extension assay and/or real-time PCR. RESULTS: The mean concentration of total DNA obtained by the SNAP card (33.8 ng/µl) exceeded more than twofold that of MagnaPure extraction (15.7 ng/µl). SNAP card-extracted samples allowed to detect 3.7 single nucleotide polymorphisms (SNPs) versus 2.5 SNPs in MagnaPure extracts to control for traces of fetal DNA. This difference is highest for samples from 7th-13th week of gestation. CONCLUSION: The SNAP card system improves DNA extraction efficacy for prenatal diagnosis in maternal blood samples and provides an at least eightfold higher total amount of DNA for the ensuing analysis. Its advantage is most evident for samples from early stages of pregnancy and thus especially valuable for pregnancies with antibodies.

Capture of genomic DNA on glass microscope slides.

It is well known that DNA strands bind to silica surfaces in the presence of high concentrations of chaotropic salts. We developed simple methods to evaluate binding and recovery of DNA on flat glass microscope slides and compared their properties with commercially available silica "spin columns". Surprisingly, genomic DNA was recovered efficiently from untreated glass slides. Binding and elution times from glass slides were optimized in experiments with DNA samples of various sizes and defined buffers. Average DNA recovery from 500 ng of input genomic DNA varied from 25 to 53% for the glass slide protocol. Yields were comparable to those of spin columns. Human serum albumin and plasma components decreased DNA binding to glass several-fold in a concentration-dependent manner. These results support the concept of using flat glass slides as DNA purification surfaces in microfluidic devices for PCR sample preparation.