Unlock Precision with Glucose 1-Dehydrogenase (FAD, quinone)
Discover the enzyme revolutionizing biosensors and biocatalysis. High specificity and stability for advanced analytical applications. Your trusted supplier for cutting-edge biochemicals.
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Glucose 1-Dehydrogenase (FAD, quinone)
As a leading supplier in China, we offer high-quality Glucose 1-Dehydrogenase (FAD, quinone), a critical enzyme for advanced biosensor development and biocatalytic processes. Its exceptional properties make it ideal for demanding applications where precision and reliability are paramount. We are committed to providing innovative solutions as a trusted manufacturer in China.
- Achieve superior accuracy in glucose monitoring through the high specificity of FAD-dependent glucose dehydrogenase for beta-D-glucose.
- Leverage the enzyme's thermal stability, maintaining performance up to 50°C, crucial for robust industrial biocatalysis and biofuel cell applications.
- Benefit from efficient electron transfer mechanisms, enabling oxygen-insensitive reactions essential for diverse analytical and biotechnological systems.
- Explore advanced applications in medical diagnostics and food quality control with this key enzyme for biosensors.
Key Advantages You'll Experience
Unmatched Specificity
Experience enhanced accuracy in your glucose detection systems, as this enzyme offers unparalleled specificity for beta-D-glucose, minimizing interference from other sugars, a critical aspect for precise glucose monitoring.
Robust Thermal Stability
Rely on consistent performance even under varying temperature conditions. Its stability up to 50°C ensures dependable results in industrial biocatalysis and challenging biofuel cell environments.
Efficient Electron Transfer
Benefit from the enzyme's ability to facilitate direct electron transfer (DET), crucial for oxygen-insensitive reactions in advanced biosensors, leading to more reliable and sensitive analytical devices.
Diverse Application Fields
Biosensors
The high specificity and efficient electron transfer make this enzyme a cornerstone for developing next-generation glucose biosensors for medical diagnostics and continuous monitoring.
Biocatalysis
Its thermal stability and specificity are ideal for industrial biocatalytic processes, offering efficient and controlled enzymatic conversions in various chemical synthesis pathways.
Biofuel Cells
The oxygen-insensitive reaction mechanism is a significant advantage for its use in biofuel cells, enabling stable power generation in diverse environments.
Diagnostics
Crucial for accurate glucose level determination in medical testing, contributing to effective diabetes management and clinical research.