2-CARBOXYBUTYRICACID CAS:601-75-2

2-Carboxybutyric acid is a metabolite involved in diverse physiological processes and has potential applications in scientific research, medical diagnostics, and therapeutic interventions. One significant area of study lies in its role as a biomarker for neurological disorders and brain injuries. Elevated levels of 2-carboxybutyric acid can be indicative of certain metabolic disorders and neurodegenerative conditions, making it a target for diagnostic testing and monitoring of neurological health. Moreover, research into the metabolic pathways involving 2-carboxybutyric acid provides insights into its potential impact on energy metabolism, neurotransmitter regulation, and oxidative stress responses. Understanding these mechanisms is crucial for unraveling the link between metabolic disturbances and neurological diseases, paving the way for the development of novel therapeutic strategies and drug targets. Additionally, 2-Carboxybutyric acid may find application in the field of personalized medicine and precision health, where it could serve as a molecular indicator for identifying individuals at risk of specific neurological conditions or metabolic dysregulations. Its potential inclusion in diagnostic panels and biomarker assays could contribute to early disease detection and tailored treatment approaches, thereby supporting advancements in healthcare and clinical management. Furthermore, the compound's involvement in metabolic processes underscores its relevance in studies focusing on mitochondrial function, energy production, and oxidative metabolism. By elucidating its interactions within cellular pathways, researchers aim to gain a deeper understanding of its impact on overall health and its potential implications for therapeutic interventions targeting metabolic disorders and neurological ailments. In summary, the applications of 2-Carboxybutyric acid center around its significance as a biomarker for neurological disorders, its role in metabolic pathways, and its potential contributions to diagnostic and therapeutic advancements in medical research. Ongoing investigation into its physiological functions and clinical relevance continues to drive progress in the fields of neuroscience, metabolomics, and personalized healthcare, highlighting its importance in advancing our understanding of neurological health and metabolic homeostasis.