D-xylulose-[1,2-13C2]

D-xylulose-[1,2-13C2], a stable isotope-labeled compound, serves as a versatile tracer and analytical tool across diverse scientific disciplines. Here are the key applications of D-xylulose-[1,2-13C2]:

Metabolic Pathway Analysis: Delving into metabolic intricacies, D-xylulose-[1,2-13C2] emerges as a pivotal player in metabolic studies, tracing the intricate utilization and transformation of sugars within complex pathways. By integrating this labeled compound, researchers embark on a journey to monitor metabolite fluxes, unraveling the enigmatic biochemical labyrinth within cells. This knowledge is indispensable in decoding cellular metabolism and pinpointing potential therapeutic targets buried deep within the metabolic tapestry.

Drug Metabolism Research: Stepping into the realm of pharmacokinetics, D-xylulose-[1,2-13C2] takes center stage as a beacon for studying drug metabolism and bioavailability. By charting the metabolic destiny of labeled compounds, scientists acquire profound insights into the absorption, distribution, metabolism, and excretion pathways of drugs. This scrutiny aids in refining drug formulations, foreseeing potential drug interplays, and sculpting the future landscape of pharmaceutical innovation.

NMR Spectroscopy: Nurturing insights through intricate spectroscopy, D-xylulose-[1,2-13C2] assumes a pivotal role in nuclear magnetic resonance (NMR) investigations of carbohydrate structures and dynamics. Leveraging the power of stable isotopes, researchers enhance the resolution of NMR spectra, unraveling intricate molecular architectures with precision. These revelations offer a glimpse into molecular conformations and interactions, paving the way for a deeper comprehension of molecular realms.

Isotope Dilution Analysis: Embarking on a journey of quantitative precision, D-xylulose-[1,2-13C2] emerges as a stalwart in isotope dilution techniques, acting as an internal beacon of accuracy. By leveraging this labeled standard, researchers unlock the realms of accurate quantification of sugars and metabolites within labyrinthine biological samples. The utilization of labeled standards elevates the precision and reliability of analytical measurements across diverse research and clinical landscapes, ushering in a new era of analytical prowess.