β-Lactosyl ureide-[13C] dihydrate

β-Lactosyl ureide-[13C] dihydrate, a widely utilized labeled compound in metabolic and nutritional studies, boasts a multitude of applications. Here are the key applications:

Metabolic Tracing: In the realm of metabolic research, β-Lactosyl ureide-[13C] dihydrate serves as an indispensable tool for tracing the intricate pathways of carbohydrate metabolism and digestion. Through the integration of this labeled compound, scientists delve deep into the complexities of metabolic transformations in the body and the processing of lactose. This exploration sheds light on lactose intolerance and other metabolic irregularities linked to carbohydrate breakdown processes.

Nutritional Studies: Within the domain of nutritional science, β-Lactosyl ureide-[13C] dihydrate assumes a pivotal role in evaluating the digestive and absorptive capacities of the gastrointestinal tract. By meticulously tracing the journey of this labeled compound through the digestive system, researchers scrutinize the effects of varied foods and diets on nutrient absorption and gut health. This knowledge forms the foundation for crafting dietary recommendations and devising therapeutic interventions.

Gut Microbiome Research: At the forefront of gut microbiome exploration, β-Lactosyl ureide-[13C] dihydrate emerges as a cornerstone for dissecting the activities of gut microbiota. Serving as a substrate for microbial fermentation, this labeled compound enables scientists to unravel the metabolic behaviors and compositions of gut bacteria. Such profound insights are essential for understanding the microbiome's role in health and disease while also driving forward the development of probiotics and microbiome-targeted therapies.

Pharmacokinetics: Delving deep into the intricacies of pharmacokinetics, β-Lactosyl ureide-[13C] dihydrate acts as a powerful tool for investigating the dynamic profiles of drugs and bioactive compounds. By observing the patterns of absorption, distribution, metabolism, and excretion of the labeled compound, researchers extract valuable insights into the mechanisms underlying drug interactions and efficacy. This application forms a cornerstone for refining the development of personalized and effective medical research.