D-fructose-[1,2,3-13C3]

D-fructose-[1,2,3-13C3], a stable isotope-labeled compound, finds extensive use in metabolic research and various scientific realms. Here are the key applications of D-fructose-[1,2,3-13C3]:

Metabolic Flux Analysis: Positioned at the forefront of metabolic exploration, D-fructose-[1,2,3-13C3] plays a pivotal role in metabolic flux analysis, unraveling the convoluted pathways of carbohydrate metabolism. By introducing this isotopically labeled fructose into metabolic inquiries, researchers can scrutinize the redistributions of carbon atoms within intricate metabolic networks. This aids in unearthing the shifting metabolic landscapes associated with diseases, nutritional paradigms, and cellular dynamics.

NMR Spectroscopy: Delving deep into the elucidation of structural and dynamic facets of carbohydrates, the 13C-labeled D-fructose is a cornerstone in NMR spectroscopy investigations. The enriched carbon atoms amplify the clarity and precision of NMR signatures, enabling a nuanced scrutiny of sugar interactions and metamorphoses. This capability proves invaluable in deciphering the enigmatic workings of complex biological systems and the idiosyncrasies of carbohydrates in diverse milieus.

Stable Isotope Tracing: In the intricate domain of stable isotope tracing, D-fructose-[1,2,3-13C3] emerges as a prized beacon for delving into the destiny of fructose within metabolic pathways. By tracking the labeled carbon atoms across biochemical cascades, scientists glean insights into fructose metabolism and its implications for overall health. This methodological approach stands as a linchpin in investigations relating to metabolic maladies like diabetes and obesity.

Plant Physiology Studies: Branching into the intricate realms of plant physiology, D-fructose-[1,2,3-13C3] serves as a vital cog in tracking carbon allocation and photosynthetic processes. By endowing plants with 13C-labeled fructose, researchers embark on a journey to unravel how carbon is assimilated, translocated, and sequestered within the plant matrix. This knowledge is indispensable for decoding the intricacies of plant growth, productivity, and adaptive responses to shifting environmental dynamics.