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HS Code |
247112 |
| Product Name | 2-Amino-3-benzyloxypyridine |
| Purity | 98.50% |
| Molecular Formula | C12H12N2O |
| Molecular Weight | 200.24 g/mol |
| Appearance | Off-white to beige solid |
| Cas Number | 119193-10-3 |
| Melting Point | 56-58°C |
| Solubility | Soluble in common organic solvents |
| Storage Conditions | Store at room temperature, keep container tightly closed |
| Synonyms | 3-(Benzyloxy)-2-aminopyridine |
| Smiles | c1ccc(cc1)COc2cccnc2N |
As an accredited 2-Amino-3-benzyloxypyridine, 98.50% factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging consists of a 25g amber glass bottle, tightly sealed, labeled with "2-Amino-3-benzyloxypyridine, 98.50%" and safety information. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 2-Amino-3-benzyloxypyridine, 98.50%—Packed securely in drums/cartons, maximizing space, ensuring safe chemical transport. |
| Shipping | This chemical, **2-Amino-3-benzyloxypyridine (98.50%)**, is shipped in secure, sealed containers to preserve purity and stability. Packaging complies with all safety regulations for hazardous materials. Items are handled by certified carriers, with proper labeling and documentation, ensuring safe, prompt delivery and minimal risk of contamination or degradation during transit. |
| Storage | 2-Amino-3-benzyloxypyridine (98.50%) should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area, away from incompatible substances such as strong oxidizers and acids. Protect from moisture, direct sunlight, and sources of ignition. Store at room temperature or as specified by the manufacturer, and ensure proper labeling and secure storage to prevent unauthorized access. |
| Shelf Life | 2-Amino-3-benzyloxypyridine, 98.50%, typically has a shelf life of 2 years when stored in a cool, dry place. |
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Purity: 2-Amino-3-benzyloxypyridine, 98.50% purity is used in pharmaceutical intermediate synthesis, where it ensures high-yield and low-impurity product formation. Melting Point: 2-Amino-3-benzyloxypyridine, 98.50% with a controlled melting point is used in API process development, where it supports precise crystallization and batch reproducibility. Stability: 2-Amino-3-benzyloxypyridine, 98.50% with enhanced stability is used in medicinal chemistry research, where it provides reliable storage and minimized degradation over time. Solubility: 2-Amino-3-benzyloxypyridine, 98.50% with optimized solubility is used in heterocyclic compound synthesis, where it facilitates homogeneous reaction conditions and improved product isolation. Assay: 2-Amino-3-benzyloxypyridine, 98.50% high assay is used in fine chemical manufacturing, where it delivers consistent reactivity and formulation predictability. |
Competitive 2-Amino-3-benzyloxypyridine, 98.50% prices that fit your budget—flexible terms and customized quotes for every order.
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Aromatic heterocycles don’t often grab headlines outside of scientific circles, but for many modern syntheses, pyridines quietly do the heavy lifting. Our days on the shop floor and in analytical labs are spent with compounds like 2-Amino-3-benzyloxypyridine, purity 98.50%, whose properties and quirks influence everything downstream. Each batch serves as a foundation for innovators working in pharmaceuticals, agrochemicals, and specialty chemistry. This is not a compound picked at random from a catalogue—it’s the result of rigorous development and hands-on experience.
Every gram of 2-Amino-3-benzyloxypyridine made in our reactors reflects hundreds of hours invested in optimizing synthetic routes and maintaining strict process controls. The 98.50% purity matters on the bench. We see the difference in NMR traces and chromatogram baselines. Impurities, even at low levels, derail reactions or interfere with tricky coupling steps. Many customers have shared stories of failure with lower grades—a 95% lot can throw off yields, introduce unpredictable side products, or bleed into unrelated signals during analytics.
As a producer, our colleagues set purity benchmarks not just for regulatory audits, but because reliable performance saves time for everyone downstream. Whether a formulator is chasing a lead molecule for a CNS-active pharmaceutical or building a combinatorial library, the reaction doesn’t pause for ambiguity. That 98.50% figure stands as a real advantage for chemists facing harsh deadlines and budget constraints.
Over decades, we have refined crystallization and filtration steps to keep 2-Amino-3-benzyloxypyridine consistent in both appearance and reactivity. Occasionally, a customer notices color changes or variable flow from cheaper sources, caused by trace byproducts or incomplete drying. These issues arise less frequently with our product since our vacuum drying protocols and purification columns have been tested at scale. From a technical chemist’s point of view, there’s a confidence built by repetition and by the absence of failed batches.
Crystallization temperature—often overlooked—makes a visible difference. We have run enough batches to know which parameters yield optimal morphology for filtration or slurry transfers. Unlike compounds supplied through indirect channels, our direct oversight allows us to troubleshoot clogging or solubility issues as they arise, not after the fact. Each bottle ships with the physical consistency demanded by our own QC team, because we understand how essential it is for researchers to pour, weigh, and dissolve the material without encountering unpleasant surprises. No one wants to fight a rock-hard cake or a sticky mass when minutes count.
2-Amino-3-benzyloxypyridine’s core value is its utility as a building block or intermediate in complex organic syntheses. We have watched it become central to medicinal chemistry programs aiming for pyrazolopyridine derivatives or more elaborate bicyclic frameworks. Chemists often need a directing group at the 3-position, and the benzyloxy provides exactly that—offering stability while remaining removable under mild hydrogenation. The amino group at the 2-position is reactive enough for coupling reactions, including amide formation or palladium-catalyzed C–N bond formation. That dual functionality attracts researchers working on kinase inhibitors or custom heterocyclic platforms.
Our collaborations with medicinal chemists often highlight speed as critical. A high-purity intermediate lets teams move straight into SAR (structure-activity relationship) work without investing days or weeks into additional purification. Every shortcut in early discovery counts; failures traced to contaminated starting materials are costly and often hard to track. We have seen screening campaigns grind to a halt over an overlooked 2% contaminant, forcing project managers back to old, slow columns. Our consistent output, batch after batch, has rescued more than one timeline from disaster.
There are plenty of other pyridine derivatives out there. In our experience, 2-Amino-3-methoxypyridine and 2-Amino-3-hydroxypyridine are commonly considered as alternatives, especially if budget pressures exist or benzyl deprotection seems like an extra step. On paper, they look similar. Yet, for many synthetic applications, the benzyloxy protecting group offers higher chemoselectivity and greater ease of removal under standard conditions. We have tested rival products and encountered variable yields and persistent side-chain oxidation—issues minimized in the benzyl-protected analog due to its tailored synthetic route.
Even small details in impurity profiles set our product apart. Side reactions during synthesis, particularly with uncontrolled catalysts or raw materials sourced from less experienced operations, can introduce hard-to-remove byproducts such as N-oxides or unwanted alkyl substitutions. Over the years, we’ve found that adjusting catalyst loading and refining reagent quality—steps sometimes overlooked by traders—ensures our batch purity consistently exceeds 98%. By contrast, product from less careful providers can contain unreacted starting material or residual metal, both of which can halt downstream work or contaminate sensitive pharmacophores.
We have also explored customer-requested alternates and analogs. While some projects benefit from minor tweaks on the parent molecule, most demand reproducibility, scalability, and a documented trail of analysis. These are easiest to deliver with a product managed and refined from raw material intake to packaged vial by the hands of people who know each step. Our lab notebooks show how many times side reactions can creep in with subtle shifts in batch size or solvent grade—good enough for a trader won’t do for a custom synthesis group racing to the next milestone.
No synthetic route unfolds perfectly every time. Purging color-forming impurities and controlling moisture levels in intermediates are challenges manufacturers face, and our process reflects lessons learned through repeated cycles. Trace water in a key step once skewed a whole lot’s melting point by five degrees and required us to examine each valve and reactor seal. Upon adopting improved drying and inert gas protocols, we saw instant stabilization of both product purity and handling properties. Production teams pay close attention to isolation and air exposure, because even low-level hydrolysis changes both purity and usability.
Scalability stands at the crossroads of research and manufacturing. Producing a few grams in a hood is one thing—scaling to kilograms while maintaining batch integrity is a different ballgame. We have tailored reactor geometries, chosen optimal solvent systems, and built redundant safety checks into our routines to consistently meet demand. This consistent feedback from the synthesis bench shapes how future orders look—changes in load size, shifts in target impurity maximums, or requests for custom particle size distribution. We respond because we’re not just observers in the field; we’re participants.
Supply chain disruptions create another kind of challenge. There are moments—experienced throughout the wider industry—when a single precursor shortfall can ripple through months of scheduled work. As manufacturers, we have built partnerships with primary raw materials suppliers, running parallel qualification for each input. This strategy means we rarely miss a deadline for delivery. Flexibility comes from deep knowledge of upstream vulnerabilities—not from running a spreadsheet, but from standing in receiving bays, checking real bags of raw pyridine, verifying COAs, and sometimes sending back whole shipments that don’t meet spec.
Analytical transparency counts. NMR, HPLC, GC-MS—each provides a window into consistency and reliability. We share spectra with advanced users who want confirmation. More importantly, we maintain open lab records, giving chemists confidence in the lot they receive. Whether it’s about residual solvents, byproduct content, or trace metal analysis, we stay ready to answer with evidence. Our reputation attaches to every bottle, not just a catalogue promise.
On several occasions, partners working on scale-up projects have required detailed impurity mapping, with in-depth LC-MS datasets. We produce these because we’ve stood in their shoes—uncertainty about starting material kills momentum and creates costly rework. Transparency in batch records shields both sides from error and bolsters trust. We have worked through requests for custom analytical methods or special stability studies, investing the time to satisfy unique regulatory environments. Each successful delivery deepens relationships and opens new opportunities.
Chemical manufacturing draws scrutiny for resource use and byproduct management. We’ve designed our routes for efficiency, capturing and recycling solvents where feasible and minimizing hazardous effluents. It isn’t always glamorous—sometimes it means hundreds of hours rebalancing a waste stream or investing in better phase-separation equipment. These efforts lower both environmental impact and operational costs. Safer synthesis pays dividends in regulatory inspections and in operator well-being. Improvements stem not from press releases, but from hard lessons—near-misses with reactive intermediates or hard-won improvements in ergonomics on the packaging line.
This focus isn’t accidental. Each modification to our setup—new pipes for containment, fume hood upgrades, emergency training—follows from lived experience in dealing with chemicals every day. Our own workers, not just customers, stand to gain from a safer and more responsible facility. Investing in these processes shapes not just our current output, but also our resilience for the next decade of market shifts and regulatory reviews.
Direct customer feedback shapes our operations more than any market survey. Studios call us about reaction stalling, uneven dissolution, or yield fluctuations; a few grams shipped for an urgent fix sometimes spark weeks of new development or adjustments on the production line. We listen, document, troubleshoot, and reflect those lessons in future batches. In customer meetings, we’ve seen how the right product at the right time keeps whole pipelines moving and careers on track.
We keep records of recurring requests—a need for a tighter melting range, requests for drier material, interest in lower residual metal, or a finer powder for quicker dissolution. Each request feels technical, but also personal; someone, somewhere, is waiting for a problem to get solved. Tweaks come less from theory than the iterative process of listening to frustrations, replicating them in our own labs when possible, and adjusting real processes.
Some of the most meaningful advances grew from direct relationships. A team working in North America wanted a product variant with guaranteed <0.05% residual benzyl chloride for an especially sensitive reaction. We modified our washing and analytical process, supplied trial batches, gathered feedback, and made it a permanent option. Now, others benefit from that work. Solutions roll out not because they look good on a website, but because they fill recurring needs from real-world users doing gritty, hands-on chemistry.
All day, every day, our plant and lab teams face specific problems and pursue concrete solutions. Reliable 2-Amino-3-benzyloxypyridine comes not from luck or glossy sales collateral, but from the tireless attention of chemists, engineers, and operators refining the process, one step at a time.
Long before a sample bottle reaches a research chemist, it has passed multiple stages of scrutiny and adaptation. Every label reflects years of uncommon challenges and hard-earned problem solving—a product the team trusts enough to use in their own research and testing. For each box shipped, we know the stakes: careers and discoveries hinge on what’s inside. Reliability comes from being close to the process, understanding chemical details beyond the COA, and respecting the craft that makes synthetic chemistry possible.
