Abstract
Here, we report a rapid and ultra-sensitive detection technique for fluorescent molecules called scanning single molecular counting (SSMC). The method uses a fluorescence-based digital measurement system to count single molecules in a solution. In this technique, noise is reduced by conforming the signal shape to the intensity distribution of the excitation light via a circular scan of the confocal region. This simple technique allows the fluorescent molecules to freely diffuse into the solution through the confocal region and be counted one by one and does not require statistical analysis. Using this technique, 28 to 62 aM fluorescent dye was detected through measurement for 600 s. Furthermore, we achieved a good signal-to-noise ratio (S/N = 2326) under the condition of 100 pM target nucleic acid by only mixing a hybridization-sensitive fluorescent probe, called Eprobe, into the target oligonucleotide solution. Combination of SSMC and Eprobe provides a simple, rapid, amplification-free, and high-sensitive target nucleic acid detection system. This method is promising for future applications to detect particularly difficult to design primers for amplification as miRNAs and other short oligo nucleotide biomarkers by only hybridization with high sensitivity.
Highlights
Genomic mutation and changes in the amount of DNA/RNA in biological samples are closely related to various human diseases such as cancer, Alzheimer’s, and infectious diseases
We present an example of single fluorescent molecule detection and demonstrate its practical application by showing nucleic acid detection without amplification
To evaluate the single molecule detection by scanning single molecular counting (SSMC) analysis, we verified the correlation between the scanning speed of the confocal region and width of the pulse series
Summary
Genomic mutation and changes in the amount of DNA/RNA in biological samples are closely related to various human diseases such as cancer, Alzheimer’s, and infectious diseases. Highly sensitive, cost effective, and easy procedures are required to evaluate these changes quantitatively [1, 2]. When a fluorescence-labelled target molecule is evaluated using the ensemble average of the fluorescence signal with a fluorometer, several problems arise with regard to the detection limit, quickness, and consumption of a large sample volume. Nucleic acid amplification methods such as real-time PCR are routinely applied for highly sensitive target gene detection [3].
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