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| Model Number: | Digital Isothermal Fluorescence Detector |
| MOQ: | 1 piece |
| Price: | Negotiable |
| Delivery Time: | After receiving the payment, we will send the express within 7 working days |
The Digital Isothermal Fluorescence Detector is an advanced instrument designed for high-precision, real-time monitoring of nucleic acid amplification under constant temperature conditions.
1. Suitable for fluorescence signal detection of isothermal nucleic acid amplification technology;
2. FAM single channel, display results by endpoint numerical method;
3. 8 throughput, compact and portable.
The Digital Isothermal Fluorescence Detector is an advanced instrument designed for high-precision, real-time monitoring of nucleic acid amplification under constant temperature conditions.
Product Features:
| Product Name |
High-sensitivity fluorescence signal capture, ensuring accurate and quantitative results. |
|---|---|
| Digital fluorescence detection | Stable reaction conditions (typically 39–42°C) for optimal amplification efficiency. |
| Real-time data acquisition | Continuous monitoring of amplification curves, with intuitive software for visualization and analysis. |
| Compact & portable design | Lightweight and suitable for laboratory, field, or clinical environments. |
| Report generation | Automated export of amplification data and detection reports for record-keeping and analysis. |
| User-Friendly Operation | Easy-to-use system for both experienced professionals and non-expert operators. |
Application Areas:
Applications Of Fluorescence Detectors
Analytical chemistry: Fluorescence detectors are extensively used in analytical chemistry for the quantification and identification of various compounds. They are highly sensitive and selective, making them suitable for a wide range of applications.
Pharmaceutical analysis: In the pharmaceutical industry, fluorescence detectors are crucial for analyzing drug compounds, including pharmaceuticals, metabolites, and impurities. They are used in quality control and formulation studies.
Environmental monitoring: Fluorescence detectors are employed to detect and measure pollutants, such as polycyclic aromatic hydrocarbons (pahs), heavy metals, and organic contaminants in water, soil, and air samples.
Biomedical research: In biological and biomedical research, fluorescence detectors play a vital role in studying cellular processes, protein interactions, dna sequencing, and gene expression. Fluorescent labels are often used to tag biomolecules for detection.
Clinical diagnostics: Fluorescence detectors are used in clinical laboratories for assays, immunoassays, and tests that rely on fluorescent labels. They are valuable tools for diagnosing diseases and monitoring biomarkers in patient samples.
Food and beverage analysis: Fluorescence detectors are utilized in the food industry to detect and quantify contaminants, additives, vitamins, and other compounds. They are crucial for quality control and safety assessments.
Drug discovery: Fluorescence detectors are employed in high-throughput screening (hts) assays to identify potential drug candidates and evaluate their interactions with specific targets, including receptors and enzymes.
Environmental fluorescence sensors: Fluorescence detectors can be integrated into environmental sensors to continuously monitor specific analytes or parameters, such as ph, oxygen levels, and pollutant concentrations in natural water bodies.
Material science: Fluorescence detectors help researchers investigate the properties and characteristics of materials, such as polymers, nanoparticles, and quantum dots, through fluorescence spectroscopy.
Forensic science: In forensic laboratories, fluorescence detectors are used for the analysis of various substances, including drugs, explosives, and bodily fluids. They can help identify trace amounts of these substances in crime scene investigations.
How does the fluorescence detector work?
