摘要
Objective To design an ultra-fast thermal cycle fluorescent quantitative PCR system for on-site detection of pathogenic nucleic acids and evaluate its performances.Methods An ultra-fast thermal cycle fluorescent quantitative PCR system was developed with the components of a flat reaction cup,an ultra-fast thermal cycle module,a fluorescence detection module with fixed optical path and a data processing module based on the smartphone platform.The ultra-fast thermal cycle module was composed of a heating unit and a cooling unit,of which the heating unit was made of ceramic sheet and Ag/Pb alloy and the cooling unit consisted of a high-speed magnetic levitation cooling fan and a double-curved throat;the fluorescence detection module with fixed optical path was prepared with injection molding process,and made up of a light source excitation unit and a light detector unit;the data processing module based on the smartphone platform included a Bluetooth serial port adapter unit and a smartphone App,which used C2540F256 chip from TI company for developing the Bluetooth serial port adapter and Android Studio for the App.The ultra-fast thermal cycle fluorescent quantitative PCR system was used to detect influenza A/B virus and SARS-CoV-2 to verify its performances.Results The ultra-fast thermal cycle fluorescent quantitative PCR system realized rapid nucleic acid detection of influenza A/B virus and SARS-CoV-2,and the detection results were in high agreement with those by conventional real-time quantitative PCR.Conclusion The ultra-fast thermal cycle fluorescence quantitative PCR system gains advantages in small size and light weight,and can be used for rapid on-site detection of pathogen nucleic acids.[Chinese Medical Equipment Journal,2023,44(11):15-20]
摘要
This paper discusses the limitations of current NO inhalation systems, based on the research in collocation of NO, inspection of NO/NO2 and synchronous working of NO inhalation systems with ventilators. And then, the developing trend of NO inhalation systems is put forward here too.