Understanding the fundamental chemical properties of a research compound is crucial for its effective application in scientific investigations. L-m-Tyrosine, an unnatural amino acid with potential applications in neurodegenerative disease research, possesses a distinct chemical profile that informs its utility. This profile includes its molecular formula, weight, physical state, and other key characteristics.

With the molecular formula C9H11NO3 and a molecular weight of 181.18900, L-m-Tyrosine is a specific organic compound. Its physical properties, such as a melting point of 260-270ºC and a flash point of 188ºC, provide essential data for handling and storage. The density of 1.333g/cm3 and a boiling point of 387.2ºC at 760mmHg further define its physical behavior under various conditions.

The chemical profile of m-Tyrosine is directly relevant to its use in advanced biomedical research. For instance, its structure as an unnatural amino acid suggests potential roles in areas where typical amino acid metabolism might be altered, such as in certain neurological disorders. Researchers might leverage these specific properties to probe enzymatic pathways or receptor interactions that are distinct from naturally occurring amino acids.

Key characteristics that make L-m-Tyrosine valuable in research settings include:

  • Molecular Formula (C9H11NO3) and Weight (181.18900): These define its precise chemical identity and mass, crucial for stoichiometric calculations in experiments.
  • Melting Point (260-270ºC): Indicates a stable solid form at room temperature, simplifying handling and storage.
  • Purity (>98.0%): High purity ensures experimental reliability and minimizes the risk of confounding results from impurities.
  • Storage Conditions (Room Temperature): Practical storage requirements facilitate its use in standard laboratory environments.

The detailed chemical and physical data for L-m-Tyrosine are essential for researchers planning experiments, ensuring they can accurately incorporate the compound into their protocols. This meticulous approach is particularly important when studying complex biological systems, such as those implicated in Parkinson's disease, Alzheimer's disease, or arthritis.

By understanding the complete chemical profile of L-m-Tyrosine, scientists can more effectively design experiments, interpret results, and contribute to the growing body of knowledge in biomedical research. This foundational knowledge is key to unlocking the potential of specialized compounds in advancing our understanding of health and disease.