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Ethanol-2-13C: A Comprehensive Overview

Ethanol-2-13C, also known by its CAS number 14770-41-3, is a compound that has garnered significant attention in various scientific and industrial applications. This compound is a stable isotope of ethanol, where the carbon at the second position is replaced with carbon-13. The use of stable isotopes like Ethanol-2-13C has become increasingly important in fields such as metabolic research, biochemistry, and environmental science due to its unique properties and versatility.

The structure of Ethanol-2-13C is similar to regular ethanol, with the only difference being the substitution of a carbon atom with carbon-13. This substitution does not alter the chemical properties significantly but provides a distinct isotopic signature that can be detected using advanced analytical techniques such as mass spectrometry. This makes it an invaluable tool for tracing metabolic pathways and studying biochemical processes in living organisms.

Recent advancements in metabolic flux analysis have highlighted the importance of Ethanol-2-13C in understanding cellular metabolism. By incorporating this compound into experimental systems, researchers can track the flow of carbon through metabolic networks with unprecedented precision. For instance, studies have utilized Ethanol-2-13C to investigate the dynamics of glycolysis, fermentation, and lipid biosynthesis in various model organisms, providing insights into metabolic regulation under different conditions.

In addition to its role in basic research, Ethanol-2-13C has found practical applications in the food and beverage industry. For example, it is used as a tracer to study fermentation processes in winemaking and brewing. By monitoring the incorporation of Ethanol-2-13C into final products, manufacturers can optimize fermentation conditions to enhance product quality and consistency. This not only improves efficiency but also contributes to sustainable production practices.

The environmental science community has also embraced Ethanol-2-13C as a tool for studying carbon cycling in ecosystems. Researchers have employed this compound to trace the movement of carbon through soil microbial communities, plant tissues, and aquatic systems. Such studies are crucial for understanding global carbon dynamics and developing strategies to mitigate climate change.

From a technological standpoint, the production of Ethanol-2-13C has become more efficient with advancements in isotope enrichment techniques. Modern methods leverage biotechnological approaches, such as genetically engineered microorganisms capable of selectively producing isotopically labeled compounds. These innovations have significantly reduced production costs while improving purity levels, making Ethanol-2-13C more accessible to researchers worldwide.

Looking ahead, the potential applications of Ethanol-2 - 13 C are vast and continually expanding. As research methodologies become more sophisticated, this compound is expected to play an even greater role in unraveling complex biological processes and addressing real-world challenges in health, agriculture, and environmental sustainability.

• 25322-68-3(Polyethylene Glycol)
• 107-21-1(Ethylene Glycol, Dehydrated)
• 104700-12-1(1,2-Ethylene Glycol-13C2)
• 1759-87-1(Ethyl-2,2,2-d3 Alcohol)
• 15054-86-1(Ethylene Glycol-d6)
• 1516-08-1(Ethanol-d6)
• 14742-23-5(Ethanol-1-13C (9CI))
• 1859-09-2(Ethanol-1,1-d2)
• 1859-08-1(Ethanol-d5)
• 332062-08-5(Fmoc-S-3-amino-4,4-diphenyl-butyric acid)