Development of an Automated, Non-Enzymatic Nucleic Acid Amplification Test.

Among nucleic acid diagnostic strategies, non-enzymatic tests are the most promising for application at the point of care in low-resource settings. They remain relatively under-utilized, however, due to inadequate sensitivity. Inspired by a recent demonstration of a highly-sensitive dumbbell DNA amplification strategy, we developed an automated, self-contained assay for detection of target DNA.

Addition of mirror-image L-DNA elements to DNA amplification circuits to distinguish leakage from target signal.

DNA amplification circuits that rely on thermodynamically-driven hybridization events triggered by a target nucleic acid are becoming increasingly utilized due to their relative simplicity. A drawback of these circuits is that non-specific amplification, or circuit leakage, must be estimated using a separate "no-target" control reaction to eliminate false positives. Aside from requiring an additional reaction, the problem with this approach is the difficulty of creating a no-target control for biological specimens.

Fluorophore-Quencher Interactions Effect on Hybridization Characteristics of Complementary Oligonucleotides.

Nucleic acids are often covalently modified with fluorescent reporter molecules to create a hybridization state-dependent optical signal. Designing such a nucleic acid reporter involves selecting a fluorophore, quencher, and fluorescence quenching design. This report outlines the effect that these choices have on the DNA hybridization characteristics by examining six fluorophores in four quenching schemes: a quencher molecule offset from the fluorophore by 0, 5, or 10 bases, and nucleotide quenching.