Azacyclonol draws attention for its unique ability as a raw material in chemical production. This compound carries the molecular formula C13H16N2O, designating it as a proprietary cycloalkylamine. Chemists recognize its structure through the core azabicyclo framework, marked by the placement of the nitrogen atom and the balance this brings to the entire molecule. Derived originally from pharmaceutical investigations, azacyclonol appears in white to off-white crystalline or powdery form. In the lab, its solid state brings practical benefits, making it easy to measure, transport, and store compared with some of its volatile or liquid relatives.
Azacyclonol typically crystallizes as flakes or powders, reflecting stability at room temperature. Its density measures around 1.15 g/cm³, aligning with values shown in reference material for compounds of similar structure. Chemists observe that azacyclonol resists moisture and clumping when sealed properly, as it holds together well even in granular forms like pearls or coarse powder. This helps laboratories avoid contamination and wastage. Its melting point usually sits in the range of 120-125°C, a useful specification during synthesis processes that involve moderate heating or solvent extraction. Azacyclonol does not dissolve easily in water, but it blends well into organic solvents like ethanol and acetone, which supports its use in preparations involving solution chemistry and extraction.
The backbone of azacyclonol centers on a piperidine ring, introducing rigidity and predictable chemical behavior. The fused aromatic portion interacts with a tertiary amine, granting this compound properties prized in both scientific research and manufacturing. Its molecular weight reaches about 216.28 g/mol, reflecting a spacious framework that accommodates various chemical transformations. Spectroscopic analysis—such as NMR or IR—reads out distinct signals thanks to that fused heterocycle, serving as a fingerprint for analysts across the industry. Chemists appreciate this predictability, having seen how subtle changes in molecular arrangement can shift melting or boiling points significantly. Azacyclonol’s solid form proves easy to grind into fine crystals or larger flakes, depending on processing needs.
Azacyclonol comes in different grades, tailored for analytical, industrial, or laboratory uses. Companies seal containers ranging from a few grams to multi-kilogram lots, providing flexibility for buyers who require only micro-scale tissue samples or bulk for industrial synthesis. Buyers should always check purity—commonly above 98% for advanced uses. Impurities or degradation due to poor storage can undermine both safety and performance. The HS Code, often referenced as 2933.39 in international shipping, helps with customs processing and regulatory tracking. Users regularly consult certificates of analysis before use, ensuring compliance with safety and product integrity standards.
Azacyclonol demands respect in handling protocols. As a powder or crystal, accidental inhalation could irritate nasal membranes or set off respiratory discomfort. Skin contact brings moderate risk, so gloves and protective eyewear never feel like overkill. Safety data sheets label it as harmful if swallowed, so strict protocols for storage away from food preparation and personal spaces always make sense. In my experience, working around similar compounds reminds me that a few milligrams on a benchtop, left unsecured, can create unnecessary risk in a shared environment. Fume hoods or tightly sealed bottles provide basic barriers. Disposal follows local chemical hygiene plans, never poured down drains, as residues may persist in the water table. This responsibility extends beyond personal safety toward the broader community, as raw materials often end up in wider supply chains. Companies bear legal and ethical duties to label, store, and record uses in production documents—keeping everyone in the loop about what's coming in and what leaves as waste.
As a raw material, azacyclonol carries value not only through its functional chemical group but also its adaptability in bigger manufacturing steps. In specialty chemical production, it serves as an intermediate, where reactivity and purity save entire batches from being scrapped. The pharmaceutical sector once explored azacyclonol for targets related to central nervous system activity. Although few finished products use it as an active agent today, its legacy remains in the fingerprints of many synthetic routes and combinational chemistry playbooks. Several fields continue to rely on its well-understood behavior, connecting research sectors, material scientists, and regulatory teams in a common pursuit of reliable, traceable materials. From the glassy surface of flakes to the powder that falls easily through the scoop, every batch says something about care in production and intent in use. As regulations change, traceability through HS codes, batch records, and certificates will only grow in importance, supporting safety, transparency, and product integrity for all.
