L-arabinose-[UL-13C5]

L-arabinose-[UL-13C5], a sugar variant enriched with stable carbon-13 isotopes, finds wide-ranging applications in diverse bioscience fields. Here are the key applications of L-arabinose-[UL-13C5]:

Metabolic Flux Analysis: Delving into metabolic intricacies, researchers utilize L-arabinose-[UL-13C5] to meticulously dissect and quantify metabolite fluxes within complex networks. By tracing the labeled carbon atoms with precision, scientists unveil profound insights into metabolic pathways and their intricate regulation, offering critical knowledge for comprehending cell metabolism and optimizing microbial engineering to boost biochemical production.

Isotopic Tracing in Nutritional Studies: In the arena of nutritional research, L-arabinose-[UL-13C5] emerges as a key player in unraveling the digestion, absorption, and metabolism of dietary sugars. Integrating this labeled sugar into dietary investigations enables meticulous tracking of its metabolic fate, providing crucial insights into overall energy metabolism. This precision aids in refining nutritional formulations and evaluating dietary interventions' efficacy, with an exactness essential for enhancing health outcomes.

Analytical Chemistry: Serving as a pinnacle in mass spectrometry and nuclear magnetic resonance (NMR) spectroscopy, L-arabinose-[UL-13C5] facilitates precise quantification and structural elucidation of sugars. The presence of carbon-13 in this labeled sugar elevates analytical measurements' precision and sensitivity, crucial for analyzing intricate biological samples and characterizing carbohydrate-containing compounds with a meticulousness essential for advancing analytical chemistry.

Enzyme Mechanism Studies: Researchers employ the potency of L-arabinose-[UL-13C5] to probe into the complex mechanisms of enzymes involved in carbohydrate metabolism. By utilizing this labeled substrate in enzyme assays, scientists unravel reaction intermediates and map out product formation pathways, shedding light on enzyme function intricacies. This profound comprehension not only advances fundamental biochemistry knowledge but also drives enzyme-based applications in biotechnology, paving the way for innovative solutions in enzyme engineering and biocatalysis.