Your search keyword '"Bang DD"' showing total 2 results

1. Solid-phase PCR for rapid multiplex detection of Salmonella spp. at the subspecies level, with amplification efficiency comparable to conventional PCR.

Author

Chin WH, Sun Y, Høgberg J, Hung TQ, Wolff A, and Bang DD

Subjects

DNA Primers chemistry, DNA, Bacterial genetics, Humans, Polymerase Chain Reaction classification, Salmonella genetics, Salmonella Infections genetics, Salmonella Infections microbiology, DNA, Bacterial analysis, High-Throughput Nucleotide Sequencing methods, Polymerase Chain Reaction methods, Salmonella isolation & purification, Salmonella Infections diagnosis

Abstract

Solid-phase PCR (SP-PCR) has attracted considerable interest in different research fields since it allows parallel DNA amplification on the surface of a solid substrate. However, the applications of SP-PCR have been hampered by the low efficiency of the solid-phase amplification. In order to increase the yield of the solid-phase amplification, we studied various parameters including the length, the density, as well as the annealing position of the solid support primer. A dramatic increase in the signal-to-noise (S/N) ratio was observed when increasing the length of solid support primers from 45 to 80 bp. The density of the primer on the surface was found to be important for the S/N ratio of the SP-PCR, and the optimal S/N was obtained with a density of 1.49 × 10 11  molecules/mm 2 . In addition, the use of solid support primers with a short overhang at the 5' end would help improve the S/N ratio of the SP-PCR. With optimized conditions, SP-PCR can achieve amplification efficiency comparable to conventional PCR, with a limit of detection of 1.5 copies/μl (37.5 copies/reaction). These improvements will pave the way for wider applications of SP-PCR in various fields such as clinical diagnosis, high-throughput DNA sequencing, and single-nucleotide polymorphism analysis. Graphical abstract Schematic representation of solid-phase PCR.

Published

2017

2. Direct immobilization of DNA probes on non-modified plastics by UV irradiation and integration in microfluidic devices for rapid bioassay.

Author

Sun Y, Perch-Nielsen I, Dufva M, Sabourin D, Bang DD, Høgberg J, and Wolff A

Subjects

DNA Probes radiation effects, DNA, Viral chemistry, DNA, Viral genetics, Influenza A virus genetics, Plastics radiation effects, Biological Assay methods, DNA Probes chemistry, Microfluidic Analytical Techniques methods, Oligonucleotide Array Sequence Analysis methods, Plastics chemistry, Ultraviolet Rays

Abstract

DNA microarrays have become one of the most powerful tools in the field of genomics and medical diagnosis. Recently, there has been increased interest in combining microfluidics with microarrays since this approach offers advantages in terms of portability, reduced analysis time, low consumption of reagents, and increased system integration. Polymers are widely used for microfluidic systems, but fabrication of microarrays on such materials often requires complicated chemical surface modifications, which hinders the integration of microarrays into microfluidic systems. In this paper, we demonstrate that simple UV irradiation can be used to directly immobilize poly(T)poly(C)-tagged DNA oligonucleotide probes on many different types of plastics without any surface modification. On average, five- and fourfold improvement in immobilization and hybridization efficiency have been achieved compared to surface-modified slides with aminated DNA probes. Moreover, the TC tag only costs 30% of the commonly used amino group modifications. Using this microarray fabrication technique, a portable cyclic olefin copolymer biochip containing eight individually addressable microfluidic channels was developed and used for rapid and parallel identification of Avian Influenza Virus by DNA hybridization. The one-step, cost-effective DNA-linking method on non-modified polymers significantly simplifies microarray fabrication procedures and permits great flexibility to plastic material selection, thus making it convenient to integrate microarrays into plastic microfluidic systems.

Published

2012