Melanie Duhon scite author profile

Cell membrane dielectric properties of five different cultivated cell lines and human peripheral blood mononuclear cells (PBMC) were determined from dielectrophoretic crossover frequency measurements on a 5 x 5 microelectronic chip array. Based on distinct dielectric property differences between individual cell types, efficient cell separations were achieved by dielectrophoresis on this 5 x 5 array, which included separation of monocytic cells (U937) or human T cell leukemia virus type 1 (HTLV-1) tax-transformed cells (Ind-2) from PBMC, as well as separation of neuroblastoma cells (SH-SY5Y) from glioma cells (HTB). The purity of dielectrophoretically separated cells can be greater than 95%. Expression profiles of IL-1, TNF-alpha, and TGF-beta genes for U937 cells mixed with PBMC before and after the separation were determined by a means of electric field-facilitated hybridization on a 10 x 10 microelectronic chip array. By using the expression levels of pure U937 cells as a control, it was shown that the gene expression profiles of the postseparation cells were significantly different from those of the preseparation cell mixtures. The increase in gene expression levels for U937 cells upon lipopolysaccharide induction could be accurately determined only in the postseparation cells, while the preseparation samples masked these changes. Furthermore, by cultivating the separated HTB and SH-SY5Y cells and measuring expression of the stress-related gene c-fos, dielectrophoretic forces were shown to have little effect on cell survival and stress. The presented approach of using microelectronic chip arrays for both cell separation and gene expression profiling provides a great potential for accurate genetic analysis of specific cell subpopulations in heterogeneous samples.

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Rapid, high fidelity analysis of simple sequence repeats on an electronically active DNA microchip

Radtkey

Feng²,

Muralhidar³

et al. 2000

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We describe a method for the discrimination of short tandem repeat (STR) alleles based on active microarray hybridization. An essential factor in this method is electronic hybridization of the target DNA, at high stringency, in <5 min. High stringency is critical to avoid slippage of hybrids along repeat tracts at allelespecific test sites in the array. These conditions are attainable only with hybridization kinetics realized by electronic concentration of DNA. A sandwich hybrid is assembled, in which proper base stacking of juxtaposed terminal nucleotides results in a thermodynamically favored complex. The increased stability of this complex relative to non-stacked termini and/or base pair mismatches is used to determine the identification of STR alleles. This method is capable of simultaneous and precise identification of alleles containing different numbers of repeats, as well as mutations within these repeats. Given the throughput capabilities of microarrays our system has the potential to enhance the use of microsatellites in forensic criminology, diagnostics and genetic mapping.

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Multiplexed, Targeted Gene Expression Profiling and Genetic Analysis on Electronic Microarrays

Weidenhammer

Kahl

Wang

et al. 2002

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Background: Electronic microarrays comprise independent microelectrode test sites that can be electronically biased positive or negative, or left neutral, to move and concentrate charged molecules such as DNA and RNA to one or more test sites. We developed a protocol for multiplexed gene expression profiling of mRNA targets that uses electronic field-facilitated hybridization on electronic microarrays. Methods: A multiplexed, T7 RNA polymerase-mediated amplification method was used for expression profiling of target mRNAs from total cellular RNA; targets were detected by hybridization to sequence-specific capture oligonucleotides on electronic microarrays. Activation of individual test sites on the electronic microarray was used to target hybridization to designated subsets of sites and allow comparisons of target concentrations in different samples. We used multiplexed amplification and electronic field-facilitated hybridization to analyze expression of a model set of 10 target genes in the U937 cell line during lipopolysaccharide-mediated differentiation. Performance of multiple genetic analyses (single-nucleotide polymorphism detection, gene expression profiling, and splicing isoform detection) on a single electronic microarray was demonstrated using the ApoE and ApoER2 genes as a model system. Results: Targets were detected after a 2-min hybridization reaction. With noncomplementary capture probes, no signal was detectable. Twofold changes in target concentration were detectable throughout the (∼64-fold) range of concentrations tested. Levels of 10 targets were analyzed side by side across seven time points. By confining electronic activation to subsets of test sites, polymorphism detection, expression profiling, and splicing isoform analysis were performed on a single electronic microarray. Conclusions: Microelectronic array technology provides specific target detection and quantification with advantages over currently available methodologies for targeted gene expression profiling and combinatorial genomics testing.

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Quantitation of Host Cell DNA Contaminate in Pharmaceutical-Grade Plasmid DNA Using Competitive Polymerase Chain Reaction and Enzyme-Linked Immunosorbent Assay

Lahijani

Duhon²,

Lusby³

et al. 1998

Human Gene Therapy

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The rising interest in gene therapy for the treatment of numerous disorders necessitates the need for the large-scale production of therapeutic biopharmaceuticals that meet stringent purity standards. Residual host cell DNA in recombinant pharmaceuticals has been identified as a potential risk factor that must be quantitated carefully both during the manufacturing process and in the final product. We describe a PCR method to quantitate contaminating levels of host cell DNA in clinical plasmid DNA preparations intended for human gene therapy. The quantitation is based on the coamplification of two similar templates, the target DNA and a synthetic competitor, and the quantitation of the resulting PCR products. The competitor is identical to the target DNA PCR product except for a 29-bp internal replacement. As a result, the two PCR products can easily be distinguished from each other. The competitive nature of the assay allows the use of the ratio of the target DNA PCR product to the competitor DNA PCR product to determine the original amount of target DNA in a sample. The primers used in this assay anneal to a conserved region of the E. coli 23S rRNA gene. One of the primers is biotinylated, allowing the PCR products to be detected colorimetrically after their capture on microtiter plates. The capture is accomplished by differential hybridization to target and competitor-specific probes covalently attached to wells of microtiter plates. The entire assay is performed in less than 2 hr postamplification. This method represents an attractive alternative to Southern blot analysis, which is the currently established method for DNA quantitation.

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Melanie Duhon

Dielectrophoretic Cell Separation and Gene Expression Profiling on Microelectronic Chip Arrays

Rapid, high fidelity analysis of simple sequence repeats on an electronically active DNA microchip

Multiplexed, Targeted Gene Expression Profiling and Genetic Analysis on Electronic Microarrays

Quantitation of Host Cell DNA Contaminate in Pharmaceutical-Grade Plasmid DNA Using Competitive Polymerase Chain Reaction and Enzyme-Linked Immunosorbent Assay

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