Your search keyword '"Dentinger PM"' showing total 4 results

1. Fabrication of Inverted High-Density DNA Microarrays in a Hydrogel.

Author

Costa JA, Dentinger PM, McGall GH, Crnogorac F, and Zhou W

Subjects

Hydrogels chemistry, Oligonucleotide Array Sequence Analysis, Oligonucleotide Probes chemistry

Abstract

Current techniques for making high-resolution, photolithographic DNA microarrays suffer from the limitation that the 3' end of each sequence is anchored to a hard substrate and hence is unavailable for many potential enzymatic reactions. Here, we demonstrate a technique that inverts the entire microarray into a hydrogel. This method preserves the spatial fidelity of the original pattern while simultaneously removing incorrectly synthesized oligomers that are inherent to all other microarray fabrication strategies. First, a standard 5'-up microarray on a donor wafer is synthesized, in which each oligo is anchored with a cleavable linker at the 3' end and an Acrydite phosphoramidite at the 5' end. Following the synthesis of the array, an acrylamide monomer solution is applied to the donor wafer, and an acrylamide-silanized acceptor wafer is placed on top. As the polyacrylamide hydrogel forms between the two wafers, it covalently incorporates the acrydite-terminated sequences into the matrix. Finally, the oligos are released from the donor wafer upon immersing in an ammonia solution that cleaves the 3'-linkers, thus freeing the oligos at the 3' end. The array is now presented 3'-up on the surface of the gel-coated acceptor wafer. Various types of on-gel enzymatic reactions demonstrate a versatile and robust platform that can easily be constructed with far more molecular complexity than traditional photolithographic arrays by endowing the system with multiple enzymatic substrates. We produce a new generation of microarrays where highly ordered, purified oligos are inverted 3'-up, in a biocompatible soft hydrogel, and functional with respect to a wide variety of programable enzymatic reactions.

Published

2019

2. DNA-mediated delivery of lipophilic molecules via hybridization to DNA-based vesicular aggregates.

Author

Dentinger PM, Simmons BA, Cruz E, and Sprague M

Subjects

Hydrophobic and Hydrophilic Interactions, Coloring Agents chemistry, DNA chemistry, Drug Delivery Systems, Nucleic Acid Hybridization, Pyrenes chemistry

Abstract

A scheme is presented for stabilizing hydrophobic molecules and releasing them into aqueous solution via DNA hybridization. A tetradecyl hydrophobic tail is covalently attached to synthetic oligomers, and the resulting amphiphilic molecules take up substantial amounts of orange OT and pyrene dyes in aqueous environments. The resulting structures do not affect the surface tension and are predominantly spherical as shown by light scattering and TEM, and the pyrene fluorescence is consistent with a hydrophobic environment. It is concluded that the amphiphilic DNA creates vesicular domains upon which the hydrophobic dyes reside and are stabilized in solution. Upon exposure to the complementary strand, the pyrene dye is released from the structures, showing that the scheme can be used for unlabeled or DNA-mediated drug delivery.

Published

2006

3. Silver growth on micropatterned DNA chips: effect of growth conditions and morphology on I-V behavior.

Author

Greninger DA, Pathak S, Talin AA, and Dentinger PM

Subjects

Biosensing Techniques methods, Coated Materials, Biocompatible analysis, Electrochemistry methods, Equipment Design, Equipment Failure Analysis, In Situ Hybridization methods, Microelectrodes, Nanotechnology methods, Oligonucleotide Array Sequence Analysis methods, Silver analysis, Biosensing Techniques instrumentation, Coated Materials, Biocompatible chemistry, Crystallization methods, Electrochemistry instrumentation, In Situ Hybridization instrumentation, Nanotechnology instrumentation, Oligonucleotide Array Sequence Analysis instrumentation, Silver chemistry

Abstract

An approach to the design of DNA-based electronics is presented, in which standard microfabrication processes are integrated with lithographic patterning of single-stranded oligonucleotides followed by hybridization to gold-labeled, complementary oligonucleotides and subsequent silver enhancement for signal amplification. The resulting bioinorganic devices demonstrate micron-sized geometric features, very little non-specific silver growth, a distinct silver morphology in the patterned region, and a 10(9)-fold increase in conductivity across an electrode gap when compared with control devices. This approach may prove useful for the fabrication of high fidelity, high-density arrays for DNA-based biosensing applications.

Published

2005

4. Dendrimer-activated surfaces for high density and high activity protein chip applications.

Author

Pathak S, Singh AK, McElhanon JR, and Dentinger PM

Subjects

Alkaline Phosphatase chemistry, Chemical Phenomena, Chemistry, Physical, Immobilized Proteins, Models, Molecular, Molecular Structure, Surface Properties, Dendrimers chemistry, Imidazoles chemistry, Polypropylenes chemistry, Protein Array Analysis methods, Proteins chemistry, Silanes chemistry

Abstract

Highly functional Si and glass surfaces for protein immobilization have been prepared by a facile activation of native surface silanol groups. Poly(propyleneimine) dendrimers of generations 1-5 were immobilized onto the surface using a facile room-temperature coupling procedure that involved activation of native silanol groups of glass using 1,1'-carbonyldiimidazole under anhydrous conditions. The dendrimer-coated surfaces were used to immobilize proteins and were characterized with respect to surface loading and activity. A number of different chemical, physical, and biochemical techniques including contact angle measurement, ellipsometry, and fluorescence microscopy were used to characterize the resulting surfaces. Increasing the dendrimer generation past G-3 led to increased surface amine content, immobilized protein concentration, and the activity of immobilized alkaline phosphatase (used as a test system). Very high activity of the immobilized proteins in the case of higher generation (G-4 and G-5) dendrimers led us to conclude that such an approach has true potential for creating highly functional surfaces for protein chip applications.

Published

2004