D-mannohept-2-ulose-[UL-13C7]

D-mannohept-2-ulose-[UL-13C7], a specialized labeled sugar compound, finds diverse applications in bioscience research. Here are the key applications:

Metabolic Tracing: Delving into metabolic tracing studies, D-mannohept-2-ulose-[UL-13C7] emerges as a pivotal tool for monitoring the intricate pathways and destinies of sugars within biological systems. By integrating this labeled sugar into metabolic experiments, researchers can meticulously monitor its conversions and distributions through advanced techniques like mass spectrometry or NMR spectroscopy. This in-depth analysis sheds light on metabolic flux dynamics and facilitates the identification of pivotal metabolic intermediates and pathways.

Stable Isotope Labeling: In the realms of carbohydrate metabolism and biochemistry, the stable isotope-labeled compound D-mannohept-2-ulose-[UL-13C7] plays a crucial role. This compound serves as a cornerstone for labeling glycoconjugates, enabling precise analysis and quantification of glycan structures within complex biological systems. Such applications are invaluable for advancing glycomics research and deepening our insights into carbohydrate-related diseases, showcasing the intricate interplay between isotope labeling and biochemical analysis.

Isotope Dilution Analysis: Introducing a level of precision unparalleled, D-mannohept-2-ulose-[UL-13C7] is harnessed in isotope dilution analysis for the accurate quantification of sugars within biological samples. By leveraging this labeled sugar as an internal standard, researchers can attain unparalleled accuracy and reliability in their quantitative assessments. This technique holds significant importance in fields like clinical diagnostics and nutritional studies, where precise sugar quantification stands as a cornerstone for informed decision-making and research advancement.

Pathway Elucidation: At the forefront of elucidating novel biochemical pathways involving sugar metabolism, this compound plays a pivotal role. Through innovative studies involving the introduction of D-mannohept-2-ulose-[UL-13C7] into cells or organisms, researchers unlock profound insights into previously uncharted metabolic pathways. This wealth of knowledge not only enriches our understanding of intricate metabolic networks but also holds the potential to unveil new biological functions and therapeutic targets, propelling the boundaries of bioscience discovery.