L-idose-[2-13C]

L-idose-[2-13C], a labeled sugar molecule featuring a carbon-13 isotope at the second position, holds significant value in biochemical and medical research. Here are the key applications of L-idose-[2-13C]:

Metabolic Flux Analysis: Harnessing the potential of L-idose-[2-13C], researchers delve into metabolic flux analysis to explore the intricacies of carbohydrate metabolism within cells. By meticulously tracking the incorporation of the carbon-13 label, scientists unveil the diverse metabolic pathways traversed by this sugar. This deep dive aids in unraveling the mystery of cellular energy production, deciphering biosynthetic pathways, and shedding light on nutrient utilization dynamics.

NMR Spectroscopy: With its carbon-13 isotope, L-idose-[2-13C] becomes a beacon for nuclear magnetic resonance (NMR) spectroscopy investigations. Researchers leverage NMR to peer into the structural and conformational nuances of sugars across various biological landscapes. This wealth of information proves pivotal in deciphering the enigmatic realm of carbohydrate-protein interactions and unraveling the intricate dance of molecular recognition processes.

Tracing Glycosylation Pathways: In the realm of glycoprotein biosynthesis, L-idose-[2-13C] emerges as a powerful tool for tracing glycosylation pathways. By integrating this labeled sugar into the glycan structures of proteins, scientists embark on a journey to chart the intricate assembly of complex carbohydrates step by step. This meticulous exploration holds immense value in probing disorders linked to glycosylation and in the crafting of therapeutic glycoproteins for potential medical breakthroughs.

Stable Isotope Labeling in Mass Spectrometry: Embracing the capabilities of L-idose-[2-13C], researchers delve into stable isotope labeling experiments for mass spectrometry-driven proteomics and metabolomics studies. By bestowing a unique mass signature, this isotope-labeled sugar emerges as a critical ally in the precise quantification and identification of metabolites and proteins. This cutting-edge technique elevates the precision of biomolecular analyses, propelling biomarker discovery endeavors to new heights of accuracy and reliability.