xylitol-[UL-13C5,UL-D7]

xylitol-[UL-13C5,UL-D7], an isotopically labeled derivative of xylitol, plays a pivotal role in bioscience research specifically in metabolic studies. Here are the key applications of xylitol-[UL-13C5,UL-D7]:

Metabolic Research: xylitol-[UL-13C5,UL-D7] serves as a cornerstone in tracing metabolic pathways within cellular systems. By integrating this labeled compound, researchers can utilize mass spectrometry to meticulously monitor the metabolic destiny of xylitol, shedding light on carbohydrate metabolism. This insight is instrumental in unraveling the complexities of metabolic disorders and crafting precise interventions tailored to address them effectively.

NMR Spectroscopy: Leveraging this isotopically labeled xylitol in nuclear magnetic resonance (NMR) spectroscopy allows for a profound exploration of molecular structures and dynamics. The incorporation of carbon-13 and deuterium isotopes heightens signal sensitivity and resolution, enabling in-depth analysis of xylitol's interactions with biomolecules and its impact on biological systems. This sophisticated approach provides a nuanced understanding of the molecular interplay at play within biological frameworks.

Quantitative Analysis: In the realm of quantitative metabolomics, xylitol-[UL-13C5,UL-D7] emerges as an indispensable internal standard for precisely quantifying endogenous xylitol levels in biological samples. This precision ensures accurate and consistent measurements, facilitating the examination of metabolic alterations under diverse conditions. Such meticulous data are pivotal in identifying biomarkers and unraveling the intricate mechanisms underlying various diseases, offering profound insights into the underlying pathophysiology.

Biotechnological Production: Within the domain of biotechnological research, the utilization of xylitol-[UL-13C5,UL-D7] is paramount in optimizing processes related to xylitol production. By monitoring the labeled xylitol, researchers can evaluate the efficiency of microbial fermentation pathways, thus enhancing production yields. This knowledge is instrumental in devising cost-effective strategies for industrial-scale synthesis of xylitol, driving innovation and sustainability in biotechnological production processes.