2-Propanol, 1-[[2-(3,4-dimethoxyphenyl)ethyl]amino]-3-(3-methylphenoxy)-, hydrochloride (1:1) stands out among specialty additives for pharmaceutical and chemical research. The structure displays a fascinating combination of a propanol group, an ethyl-linked amino chain, and distinct aromatic rings carrying various substituents. Its chemical framework gives scientists plenty of flexibility for exploring modification and synthesis. The hydrochloride salt form improves the compound’s solubility, which makes it suitable for solution-based experiments or development of new materials in the lab. This material exists in a range of forms—powder, solid, occasional crystalline flakes—depending on the synthesis process and storage conditions. The consistency of these physical traits can impact everything from storage life to solvent choice, influencing purity and yield in processes where accuracy can't be compromised.
Looking closer at its properties, the molecular formula typically appears as C20H27NO3·HCl. The structure itself weighs in with a molecular mass weighing over 365 grams per mole. Density measurements hover around the 1.1 to 1.2 g/cm³ range, but this number varies with temperature and the hydration state of the sample. Its melting point falls in the expected range for a hydrochloride salt, generally observed as a solid at ambient conditions, slowly turning toward a more amorphous powder or even crystalline pearls under certain organic solvent crystallizations. Its chemical stability in moisture-free, cool environments helps prevent unwanted hydrolysis or decomposition reactions. In solution, this compound dissolves readily in water and many alcohol-based solvents, supporting its use in chromatographic and analytical applications as well as broader pharmaceutical research.
Regulation guides shipping, use, and storage for laboratory chemicals like this. Its international HS Code typically falls into 2922199090, which covers other amino-compounds in customs categorization. This puts a clear regulatory spotlight on purity requirements, handling guidelines, and import-export monitoring. Supply chains for such specialized compounds depend not only on accurate labeling with HS Codes but also firm traceability of source materials and chain of custody, fundamental for companies complying with international chemical safety laws. Raw materials should match pharmaceutical-grade standards, free from impurities that could trigger side reactions or unsafe by-products in the finished product.
Handling demands the respect owed to all powerful laboratory chemicals. Toxicology and hazard statements for this hydrochloride stress the risks of skin and eye irritation, as well as the dangers posed by inhalation of dust or accidental ingestion. Facilities storing or moving this compound need strong ventilation, closed handling systems, and clearly trained staff to minimize exposure. Every transfer or weighing process should occur in a fume hood, while proper gloves and goggles shield operators from splashes or accidental contact. Disposal practices demand collection of all residues and contaminated materials for approved hazardous chemical processing. Storage remains safest in tightly sealed containers, shielded from direct light, in a temperature-controlled room that reduces the material’s tendency to degrade. Emergency procedures need to address both spillage of solid forms and accidental releases in solution, each requiring containment and neutralization actions right away. Even small quantities left on surfaces can generate cumulative risk in busy laboratory environments.
From a research standpoint, the building blocks that form 2-propanol, 1-[[2-(3,4-dimethoxyphenyl)ethyl]amino]-3-(3-methylphenoxy)-, hydrochloride (1:1) provide robust starting points for the development of new molecules. Reliable sources for 3,4-dimethoxyphenyl and 3-methylphenoxy allow a supplier to maintain high lot-to-lot consistency, which is critical for reproducibility in scientific experiments. Every reaction relies on raw component verification, including infrared and proton NMR scans, HPLC tests, and rigorous purity checks for the initial chemical streams. Testing for trace metals or unexpected organic contaminants highlights the importance of upstream quality assurance. Safety data sheets from reputable suppliers detail the chemical identity, molecular weight, CAS number, and proper safe handling routes, embedding transparency at all stages from synthesis to end use.
One major issue surrounding specialty compounds comes down to transparency in sourcing and labeling. Mislabeling or incomplete safety data can derail entire research projects or pose health risks to workers. Regulatory frameworks continue to push for more stringent traceability, even among niche boutique suppliers who service research labs worldwide. It remains crucial for buyers to source chemicals only from qualified distributors with solid supply chain documentation and a proven record for responsible handling. Choosing a supplier who shares their analytical test results, provides open access to Certificates of Analysis, and documents their own chemical sources will strengthen not just compliance with regulations, but also the integrity of the scientific process as a whole. Safety and quality are values that must start at the source and carry through to every step in the chain of use.
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