AI Article Synopsis
- Efforts to find efficient testing technologies for diseases like SARS and COVID-19 have highlighted the limitations of current methods, such as RT-PCR, which, despite its accuracy, takes a long time and requires specialized facilities.
- A new chemiluminescence sensor offers a simpler alternative, but its effectiveness hinges on precise reagent mixing, where traditional micropipette methods can introduce errors.
- This study successfully developed a microchip that allows for precise sample injection through air pressure, achieving an error rate below 2%, and demonstrated improved detection of thrombin, a heart disease biomarker, compared to typical micropipette methods.
Article Abstract
Efforts have been devoted to screening various prevalent diseases, such as severe acute respiratory syndrome (SARS) and coronavirus disease 2019 (COVID-19). Real-time polymerase chain reaction (RT-PCR), which is currently the most widely used, has high accuracy, but it requires several facilities and takes a relatively long time to check; so, new testing technology is necessary for a higher test efficiency. A chemiluminescence (CL) sensor is a relatively simple device and suitable as an alternative because it can detect very precise specimens. However, in measurements via CL, the quantitative formulation of reagents that cause color development is important. In the case of mixing using micropipettes, precise analysis is possible, but this technique is limited by uncontrollable errors or deviations in detection amounts. In addition, in using a microfluidic chip to increase field applicability, a syringe pump or other quantification injection tools are required, so problems must be overcome for practical use. Therefore, in this study, a microchip was designed and manufactured to supply a sample of a certain volume by simply blowing air and injecting a sample into the chamber. By utilizing the luminescence reaction of luminol, CuSO and HO the performance of the prepared chip was confirmed, and the desired amount of the sample could be injected with a simple device with an error rate of 2% or less. For feasible applications, an experiment was performed to quantitatively analyze thrombin, a biomarker of heart disease. Results demonstrated that biomarkers could be more precisely detected using the proposed microchips than using micropipettes.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8444323 | PMC |
| http://dx.doi.org/10.1021/acsomega.1c03347 | DOI Listing |
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