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Abstract
The polymerase chain reaction is an important technique in biological research because it tests for diseases with a small amount of DNA. However, this process is time consuming and can lead to sample contamination. Recently, real-time PCR techniques have emerged which make it possible to monitor the amplification process for each cycle in real time. Existing camera-based systems that measure fluorescence after DNA amplification simultaneously process fluorescence excitation and emission for dozens of tubes. Therefore, there is a limit to the size, cost, and assembly of the optical element. In recent years, imaging devices for high-performance, open platforms have benefitted from significant innovations. In this paper, we propose a fluorescence detector for real-time PCR devices using an open platform camera. This system can reduce the cost, and can be miniaturized. To simplify the optical system, four low-cost, compact cameras were used. In addition, the field of view of the entire tube was minimized by dividing it into quadrants. An effective image processing method was used to compensate for the reduction in the signal-to-noise ratio. Using a reference fluorescence material, it was confirmed that the proposed system enables stable fluorescence detection according to the amount of DNA.
Highlights
The polymerase chain reaction (PCR) is an important technique in biological research because it can identify diseases with a small amount of DNA [1,2,3,4]
PCR consists of a total of three steps, i.e., a denaturation step that separates the double-stranded DNA at high temperature, an annealing step that binds the primer to DNA, and an extension step that makes new DNA
We propose a low-cost and small-sized real-time PCR system including an open platform camera
Summary
The polymerase chain reaction (PCR) is an important technique in biological research because it can identify diseases with a small amount of DNA [1,2,3,4]. There is a high risk of false-positive results due to carryover contamination in the process of transferring amplification products for fluorescence detection and analysis. To overcome these shortcomings, Real-Time PCR was developed. LOC (Lab-on-a-Chip)-based technology is progressing due to developments in diagnostic devices [18,19] Research in this field needs to be able to handle a small amount of sample, and it is important to reduce production costs. We propose a low-cost and small-sized real-time PCR system including an open platform camera. Our system could be applied to various fluorescence measurement systems that require a wide field of view
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