D-Xylose-[1-18O]

D-Xylose-[1-18O], a stable isotope-labeled sugar, finds diverse applications in scientific studies and industrial settings. Here are the key applications of D-Xylose-[1-18O]:

Metabolic Tracing: Delving into sugar metabolism, researchers utilize D-Xylose-[1-18O] to trace the intricate pathways of sugar utilization within biological systems. By integrating this isotopically labeled sugar into metabolic processes, scientists can meticulously monitor the journey of xylose within cells and tissues. This method allows for in-depth investigations into carbohydrate metabolism, facilitating the identification of potential metabolic disorders lurking within.

Isotope Dilution Analysis: In the realm of analytical chemistry, D-Xylose-[1-18O] assumes the role of an internal standard for isotope dilution mass spectrometry (IDMS). Employing this methodology heightens the precision and accuracy of quantitative measurements of xylose in diverse samples, encompassing food products and biological fluids. The utilization of IDMS with D-Xylose-[1-18O] proves invaluable for nutritional assessments and quality control measures in the ever-evolving landscape of the food industry.

Plant Physiology Research: Unveiling the mysteries of plant physiology, researchers harness D-Xylose-[1-18O] to explore the absorption and utilization of xylose within plant systems. By meticulously tracking the labeled sugar's journey through plant tissues, scientists glean profound insights into plant metabolic processes, shedding light on the efficiency of xylose uptake and conversion. This acquired knowledge serves as a stepping stone towards enhancing biofuel production methods and refining agricultural strategies.

Enzymology: Within the realm of enzyme assays, D-Xylose-[1-18O] emerges as a versatile tool, enabling researchers to delve into enzyme-catalyzed reactions involving xylose. By observing isotope effects and kinetic isotope fractionation, valuable information on enzyme specificity and reaction mechanisms is unveiled. This newfound understanding aids in the development of more efficient biocatalysts and industrial enzymes, propelling advancements within the field of enzymology and catalysis.