N-T-Butyl-4-Aza-5-Alpha-Androsta-3-One-17Beta-Carboxamide doesn’t exactly roll off the tongue, but its role in pharmaceutical chemistry speaks for itself. The compound belongs to a class of synthetic steroids with a significant reputation among researchers and developers of androgen-related therapies. In my work with chemical catalogs, this molecule stands out due to its intricate structure and the precision required to handle or synthesize it safely. Unlike chemicals that seem straightforward, N-T-Butyl-4-Aza-5-Alpha-Androsta-3-One-17Beta-Carboxamide carries a weighty combination of therapeutic potential and handling care that keeps it firmly on the desk of seasoned chemists.
Products like N-T-Butyl-4-Aza-5-Alpha-Androsta-3-One-17Beta-Carboxamide come with a set of notable physical properties. The typical appearance ranges from off-white crystalline flakes or powder to a fine solid, although some suppliers provide it in compact pearls or larger solid chunks, depending on the production batch. Touching or inhaling this powder should always be avoided due to its chemical reactivity and classification as a hazardous substance. Talking density, values often settle near 1.19 g/cm³, but as with many complex molecules, there’s some drift depending on purity and storage conditions. Along my years managing inventory for chemical supply chains, keeping powders like these dry and secure makes all the difference in preserving their molecular stability.
Discussing its state, N-T-Butyl-4-Aza-5-Alpha-Androsta-3-One-17Beta-Carboxamide shows up in market listings as a solid under standard conditions — not a liquid, not a solution, but a robust fine powder or occasional crystal clusters. Testing for solubility and reactivity shows low water solubility and a higher affinity for ethanol or similar solvents, which supports its use in targeted pharmaceutical syntheses. Its melting point hovers in the range of 180-185°C, and it tends to release hazardous fumes at excessive temperatures. Material safety data sheets flag it for chronic respiratory and skin exposure risks, leading labs to gear up with gloves, eye protection, and fume hoods.
Chemists break down the structure of N-T-Butyl-4-Aza-5-Alpha-Androsta-3-One-17Beta-Carboxamide by looking at its molecular backbone: a steroid nucleus fused with a t-butyl group and a 17beta-carboxamide function. Its formula, C24H39N3O2, translates into 24 carbons, 39 hydrogens, 3 nitrogens, and 2 oxygens. The structure itself bridges classic androstanes with 4-aza substitutions, meaning it’s closely related to inhibitors studied for antiandrogenic effects. In hands-on lab work, I’ve seen chemists struggle when they underestimate the sensitive amide and bulky side chain, both of which resist easy modification. The complexity in its atomic arrangement underpins both its promise and challenge.
Industry standards set specs like purity above 98% and strict controls on residual solvents, which directly tie to the product’s effectiveness in research or manufacturing. The HS Code, often listed as 2937290090 in customs documentation, flags it as an organic chemical raw material. From experience helping labs interpret MSDS paperwork, the hazard statements demand real attention. Anyone handling this compound joins a line of people prioritizing skin and respiratory protection, with disposal tailored to prevent environmental contamination. Spills of solids like this linger, so quick, contained cleanup with dedicated chemical waste bins protects both coworkers and the surrounding space. It’s classified as harmful, particularly through long-term repeated exposure, which keeps it in the ‘restricted handling’ list at many facilities.
N-T-Butyl-4-Aza-5-Alpha-Androsta-3-One-17Beta-Carboxamide plays a serious role as a raw material across pharmaceutical development. Companies rely on its stable molecular structure to develop drugs that manage hormone-related conditions, including therapies aimed at prostate health. Decades of research trace their way back to molecules like this, where slight shifts in the carboxamide or aza group open entirely new possibilities for medical advancement. Raw materials of this caliber undergo close testing, batch certifications, and cross-checks against supplier documentation. I’ve watched projects get delayed for weeks over a failed purity test, and nobody wants to repeat synthesis or purification unless absolutely necessary.
With chemicals such as N-T-Butyl-4-Aza-5-Alpha-Androsta-3-One-17Beta-Carboxamide, the challenge leans into supply chain stability and safe logistics. There’s no shortcut around proper labeling, hazard transportation protocols, and climate-controlled storage. Some issues with import and export arise from its classification and the high level of documentation required by customs and regulatory authorities. When I assisted in the logistics of a pharmaceutical plant, delays resulted mainly from incomplete or mismatched customs codes and safety certifications. Solutions demand a tight focus on compliance from start to finish, with procurement teams working directly with shippers to track every container and batch. Training staff and following updated safety procedures can make the difference between a smooth operation and a major incident.
N-T-Butyl-4-Aza-5-Alpha-Androsta-3-One-17Beta-Carboxamide matters far beyond its tongue-twisting name. In the world of pharmaceutical raw materials, detailed understanding ensures safe, effective use and protects everyone involved. Its molecular formula and physical features build a foundation for therapies changing lives, but only if handled with care, respect, and a dedication to scientific responsibility. This isn’t a compound for beginners, and each bottle or drum carries both promise and risk. Through careful sourcing, rigorous safety, and constant communication, labs and suppliers together can keep the pipeline for discovery moving forward while protecting everyone along the way.
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