|
HS Code |
950538 |
| Chemical Name | 3-Amino-1-Adamantanol |
| Molecular Formula | C10H17NO |
| Molecular Weight | 167.25 g/mol |
| Cas Number | 702-80-3 |
| Appearance | White to off-white solid |
| Melting Point | 218-222 °C |
| Density | 1.16 g/cm3 (estimated) |
| Solubility Water | Slightly soluble |
| Pka | Approx. 9.6 (amino group) |
| Smiles | OC12CC3CC(CC(C3)C1)C2N |
| Inchi | InChI=1S/C10H17NO/c11-10-6-1-7(2-10)4-8(3-10)5-9(12)13/h7-9,12H,1-6,11H2 |
| Synonyms | 1-Hydroxy-3-aminoadamantane |
As an accredited 3-Amino-1-Adamantanol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 100g 3-Amino-1-Adamantanol is packaged in a sealed amber glass bottle with a tamper-evident cap and label. |
| Shipping | 3-Amino-1-Adamantanol is shipped in secure, tightly sealed containers to prevent moisture and contamination. Packages are clearly labeled according to chemical safety regulations and include documentation for safe handling. Transportation adheres to applicable local and international guidelines for non-hazardous, solid organic chemicals. Store and ship at ambient temperature, avoiding excessive heat. |
| Storage | Store **3-Amino-1-Adamantanol** in a tightly sealed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizing agents and acids. Keep it protected from moisture and direct sunlight. Clearly label the container, and follow all relevant safety and regulatory guidelines for storage. Use appropriate personal protective equipment when handling or transferring the chemical. |
|
Purity 98%: 3-Amino-1-Adamantanol with purity 98% is used in pharmaceutical intermediates production, where it enhances yield consistency and reduces by-product formation. Melting point 239°C: 3-Amino-1-Adamantanol with a melting point of 239°C is used in high-temperature synthesis processes, where it maintains structural integrity under reaction conditions. Molecular weight 183.29 g/mol: 3-Amino-1-Adamantanol with molecular weight 183.29 g/mol is employed in drug formulation studies, where precise molecular mass allows for accurate dosing and formulation control. Particle size <10 µm: 3-Amino-1-Adamantanol with particle size less than 10 µm is utilized in solid dispersion systems, where improved dissolution rate and enhanced bioavailability are achieved. Stability temperature up to 150°C: 3-Amino-1-Adamantanol with stability temperature up to 150°C is applied in polymer modification, where it provides reliable performance during thermal processing. Water solubility 25 mg/mL: 3-Amino-1-Adamantanol with water solubility of 25 mg/mL is used in aqueous pharmaceutical formulations, where it enables homogenous distribution and consistent therapeutic effect. Low hygroscopicity: 3-Amino-1-Adamantanol with low hygroscopicity is implemented in long-term material storage, where it minimizes moisture uptake and preserves compound integrity. Enantiomeric purity >99%: 3-Amino-1-Adamantanol with enantiomeric purity greater than 99% is used in chiral synthesis applications, where it ensures stereoselective outcomes in target molecules. |
Competitive 3-Amino-1-Adamantanol prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please call us at +8615371019725 or mail to admin@sinochem-nanjing.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: admin@sinochem-nanjing.com
Flexible payment, competitive price, premium service - Inquire now!
Years ago, the chemical landscape thrived on classic building blocks, basic bricks that built up everything from everyday pharmaceuticals to breakthrough materials. Things have shifted. As labs demand more selectivity, reliability, and functionality, specialty chemicals like 3-Amino-1-Adamantanol have caught the eye of scientists who want not just purity, but real flexibility and value.
Looking at the structure alone, 3-Amino-1-Adamantanol tells a unique story. You get the rigid adamantane framework, famous for its stability, already a favorite among medicinal chemists and polymer specialists. Add to that an amino group and a hydroxyl, both strategically located. This isn’t a cosmetic change. A single functional group can mean the difference between a clunky synthesis and a streamlined pathway to big discoveries.
Many classic building blocks come with limitations. They’re often too simple or lack reactive sites in the right spots. 3-Amino-1-Adamantanol offers both polar and basic functionalities, wrapped up in a backbone that handles heat and tough reaction conditions without falling apart. The amino group opens the door to peptide coupling or selective derivatization. The hydroxyl gives access to etherification or phosphorylation. Together, this makes for a molecule that squeezes a lot of utility into a robust, three-dimensional frame.
This isn’t just a laboratory curiosity. In medicinal chemistry, every atom can tip the balance between activity and inactivity, toxicity and tolerability. Researchers have tested adamantane derivatives for years, seeking antivirals, Parkinson’s treatments, and even anti-inflammatory agents. Building on this track record, 3-Amino-1-Adamantanol steps in as a promising intermediate for those looking to fine-tune biological function.
Polymers gain a new edge as well. Those working in materials science know the value of a rigid, volumetric structure like adamantane. It resists collapse and brings mechanical strength without bloating molecular weight. Slip in an amino and a hydroxyl group, and the options multiply. Linking, cross-linking, or surface functionalization all become accessible. Few compounds offer this degree of adaptability without sacrificing core performance.
The paint and coatings industry turns to advanced molecules for durability and reactivity. Imagine a specialty coating cured at high temperatures, facing constant wear. Only certain compounds can survive that environment and contribute to crosslinking or binding with fillers. Here, 3-Amino-1-Adamantanol finds a place, not because it’s trendy, but because it works where simpler options break down.
Other adamantane derivatives like amantadine or memantine serve critical roles—amantadine tackled flu and movement disorders, while memantine fights neurodegeneration. Both showcase the advantages of adamantane’s stability in biological systems. They often lack multiple reactive groups and struggle to integrate efficiently into more complex architectures.
Simple amino derivatives tend to get lost in the shuffle. They react quickly but don’t hang onto stability. Meanwhile, multi-functional scaffolds sometimes turn out bulky or poorly soluble. 3-Amino-1-Adamantanol treads that line: a structure engineered for resilience, with functional groups placed for transformation, not obstruction. Researchers working with it can speed up synthesis or introduce new features at late stages, besides getting more output from each step.
Stories from real projects echo this. Medicinal chemists in crowded fields chase molecules that allow late-stage modification. Those modifications help dodge patent hurdles, hone properties, and reach novel targets. The dual-functionality on 3-Amino-1-Adamantanol checks those boxes, shaving weeks off project timelines and unlocking combinations that rarely pan out with single-purpose reagents.
Rather than drown in numbers, it’s worth highlighting what users actually notice. High chemical purity matters most for reliable synthesis—an off-ratio sample can lead to failed reactions and wasted time. Reliable solubility across a range of solvents matters too, because every lab has different workflows. 3-Amino-1-Adamantanol’s stability under ambient conditions means less stress around storage and transport.
Moisture sensitivity often snags researchers at the worst moments. The solid form of this compound minimizes hydrolysis or degradation, keeping more material on hand when it counts. Ironically, its stability widens its appeal for both bench chemists in small startups and process developers at major firms.
Scientists prize consistency batch-to-batch. This applies especially for those moving from milligrams to kilograms—a frequent jump in production and pharmaceutical work. Here, 3-Amino-1-Adamantanol meets the mark, letting its users scale up or down without fearing that small differences will derail months of optimization.
A product doesn't earn respect from paper specifications alone. It shows its value through muddy tasks, tricky reactions, and pressure-packed deadlines. From personal experience, having a reliable intermediate can decide if a project sails through or grinds to a halt. I’ve dealt with intermediates that required a ballet of anhydrous techniques, low-temperature baths, or endless purification. A compound that sidesteps half these headaches doesn’t just save time; it keeps a team sane during deadline crunches.
For teams juggling patent strategy or quick-and-dirty SAR exploration, time is measured in experiments, not hours. If a chemical reagent allows the introduction of polar handles, eases scale-up, and still reacts cleanly, it becomes the default choice. Colleagues who switched to 3-Amino-1-Adamantanol didn’t look back. They saw cleaner analytical data, more predictable reactivity, and smoother handoffs between discovery and process teams.
Solubility stands out, again and again. Too many functionalized adamantanes fizzle out due to poor handling or solubility. This product sits in solution, not clumps in the bottom of a vial, and it doesn’t clog reactor lines. Synthetic efficiency isn’t just a buzzword; it resets what’s considered possible in academic and industrial labs. Researchers find themselves revisiting abandoned projects and reopening old synthetic routes with this building block in hand.
Synthetic methodology evolves, but pressure never eases. Medicines, coatings, electronic materials—they all rely on reproducible, consistent supplies of critical intermediates. The demand keeps tightening. More often, researchers look to advanced starting materials that don’t just meet a checklist but create new space for discovery. 3-Amino-1-Adamantanol answers this need both in its chemical suitability and logistical reliability.
Regulatory pressure never lifts from industrial labs, either. I remember project leads combing through batch records for inconsistencies, looking for odd spikes in impurity or deviation from protocol. Successful runs with 3-Amino-1-Adamantanol generally closed those concerns. Uniform product, minimal surprises, and a transparent synthetic pedigree keep auditors happy and process chemists even happier.
One issue in modern synthesis lies in late-stage innovation. Back in the day, the field relied on brute-force screening. Now, chemists want more—access to scaffolds that can support a broad array of substitutions, not just endless analogs. Dual-functional building blocks like 3-Amino-1-Adamantanol unlock this creative space, letting teams drop in functionalities two or three steps from the end, saving on time and cost, while extending the reach of standard routes.
Every chemist hits bottlenecks: intermediates that work in theory but fail under scale-up, reagents that demand treacherous handling, supply chains that can’t guarantee quality from batch to batch. Solving these issues isn’t glamorous, but it determines the pace of innovation.
Instead of accepting limited stocks or high variability, users should look to suppliers who prioritize documentation, rigorous batch testing, and secure sourcing of raw materials. Products like 3-Amino-1-Adamantanol, produced with clear process accountability and thorough analysis, create a buffer against disruptions. This proves critical as teams transition from benchtop to pilot or commercial scale.
Insisting on validated analytical methods, full traceability, and third-party verification builds the trust needed for major investments. That process-oriented mindset, more than fancy packaging or lofty claims, ensures that the chemical you order in January matches what you’ll need come October. For researchers in regulated sectors, that continuity removes headaches before they become costly failures.
Chemical innovation responds to real-world pressure—on budgets, time, and outcomes. Shifts in legislation, environmental priorities, and market expectations make flexibility even more essential. Building-block molecules like 3-Amino-1-Adamantanol bring options for greener syntheses, as their sturdiness can simplify purification steps and their dual-functional nature means fewer reagents, less waste, and lower overall risk.
Students and trainees sometimes focus on pure novelty; those of us in pursuit of scalable outcomes know the hidden costs of every extra purification, failed scale-up, or inconsistent intermediate. Products that make workflows more predictable and introduce reliable sites for transformation anchor modern research in the real world. Teams from drug discovery, agrochemicals, or advanced coatings can plan faster, iterate more often, and strike the right balance between speed and safety.
Direct conversations with colleagues backs this up. They stick with intermediates they trust, especially in competitive environments where delays can cost months or open doors for competitors. Consistent experience—solid yields, clean NMR, happy analysts—repeatedly draws feedback pointing to 3-Amino-1-Adamantanol’s role in recent project wins. It’s a tale told more in relieved emails and steady reorder patterns than in press releases.
Science isn’t just a solitary affair. People talk, share, and compare notes over conference coffee or rushed lunch breaks. Experiences with versatile, dependable intermediates like 3-Amino-1-Adamantanol ripple through the community. I’ve watched seasoned chemists nudge younger colleagues away from flashy one-off reagents and toward scaffolds that adapt, scale, and survive scrutiny.
The shift isn’t just scientific—there’s a practical side driven by budgets and the need for rapidly deployable workflows. Purchasing managers weigh not just price, but value, warranty, and feedback from the bench. Products that prove tough enough for both research and manufacturing usually come from the intersection of rigorous chemistry and real-world listening. That’s a reputation this compound has started to build.
Broad as the applications for 3-Amino-1-Adamantanol are, no single product answers every problem. The future will keep asking for even more selective, even more robust intermediates. Ideas bounce around the community about next-gen analogs, expanded functional group arrays, and deeper integration with automated synthetic platforms.
It’s easy to get caught up in hype—yet, in conversations with professionals from pharma to materials, I keep hearing the same needs: functional handles in strategic positions, compliance-ready documentation, and chemical properties that handle practical rigors. Those are the boxes products like this tick for now. Teams hungry for data and process improvements know that strong building blocks support both innovation and safe, reproducible practice.
Integrating 3-Amino-1-Adamantanol in your chemistry toolkit means more than keeping up with the curve; it speaks to a professional’s knowledge of what propels projects from idea to reality.