D-Fructose-1,6-diphosphate Trisodium Salt Octahydrate: A Key Intermediate for Research
Discover the biochemical power of FDP Na3 for metabolic studies and pharmaceutical innovation.
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D-Fructose-1,6-diphosphate Trisodium Salt Octahydrate
This product is a critical intermediate in carbohydrate metabolism, specifically within the glycolysis pathway. It plays a vital role in cellular energy production and is essential for studying various metabolic processes and enzyme kinetics.
- Explore the use of D-Fructose-1,6-diphosphate trisodium salt octahydrate in metabolic pathway studies to gain deeper insights into cellular functions.
- Utilize this high-purity biochemical intermediate for precise enzyme kinetics research, ensuring reliable experimental outcomes.
- Investigate its cardioprotective effects for ischemic disorders, aiding in the development of treatments that enhance ATP production.
- Leverage FDP Na3 for tissue protection during periods of low oxygen availability, crucial in understanding cellular stress responses.
Key Advantages
Metabolic Pathway Research Excellence
Benefit from using a well-characterized biochemical intermediate like D-Fructose-1,6-diphosphate trisodium salt octahydrate in your metabolic pathway studies, ensuring the accuracy of your findings.
Enhanced Energy Metabolism Insights
Understand how FDP Na3 contributes to cellular energy, supporting research into conditions related to energy metabolism and its therapeutic potential.
Therapeutic Potential in Ischemic Conditions
The role of D-Fructose-1,6-diphosphate trisodium salt octahydrate in protecting tissues during ischemia makes it a valuable compound for pharmaceutical research aimed at improving cardiovascular health.
Key Applications
Biochemical Research
A fundamental compound for investigating glycolysis and related metabolic pathways, contributing to a deeper understanding of cellular energy production.
Enzyme Kinetics Studies
Ideal for quantitative analysis of enzyme activity, providing a reliable substrate for research into enzyme mechanisms and inhibition.
Pharmaceutical Development
Its potential in enhancing ATP production and protecting against ischemic damage positions it as a key ingredient for developing novel therapeutic agents.
Cellular Energy Metabolism
Essential for studying how cells generate and utilize energy, offering insights into metabolic disorders and energy-related diseases.