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HS Code |
520103 |
| Chemical Name | 2-Amino-4-Methoxylpyridine |
| Molecular Formula | C6H8N2O |
| Appearance | Light yellow to beige solid |
| Melting Point | 73-77°C |
| Boiling Point | 312.5°C at 760 mmHg |
| Cas Number | 15715-41-0 |
| Density | 1.17 g/cm3 |
| Solubility In Water | Moderate |
| Purity | Typically ≥98% |
| Storage Conditions | Store in a cool, dry, well-ventilated place |
| Pka | 4.6 (amino group) |
| Smiles | COC1=CC=NC(=C1)N |
As an accredited 2-Amino-4-Methoxylpyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical 2-Amino-4-Methoxylpyridine is packaged in a 25g amber glass bottle with a tamper-evident cap and safety labeling. |
| Container Loading (20′ FCL) | 20′ FCL container loaded with securely packed drums of 2-Amino-4-Methoxylpyridine, ensuring safe, leak-proof, and efficient transport. |
| Shipping | 2-Amino-4-Methoxylpyridine is shipped in tightly sealed, clearly labeled containers to prevent moisture and contamination. It should be packed according to chemical safety regulations, with appropriate hazard labeling. Transport must comply with local and international regulations, ensuring the chemical is protected from incompatible substances, extreme temperatures, and physical damage during transit. |
| Storage | 2-Amino-4-Methoxypyridine should be stored in a tightly sealed container, away from direct sunlight, moisture, and sources of ignition. Keep in a cool, dry, and well-ventilated area, preferably in a dedicated chemical storage cabinet. Avoid contact with incompatible substances such as strong oxidizers and acids. Properly label the container and ensure only trained personnel have access. |
| Shelf Life | 2-Amino-4-Methoxypyridine typically has a shelf life of two years when stored in a cool, dry, and airtight container. |
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Purity 99%: 2-Amino-4-Methoxylpyridine with 99% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield and reproducibility. Melting Point 80°C: 2-Amino-4-Methoxylpyridine with a melting point of 80°C is used in the formulation of diagnostic reagents, where it enables consistent solid-phase processing. Molecular Weight 124.14 g/mol: 2-Amino-4-Methoxylpyridine at 124.14 g/mol is used in heterocyclic compound development, where it provides precise stoichiometry for targeted synthesis. Particle Size <10 μm: 2-Amino-4-Methoxylpyridine with particle size below 10 μm is used in fine chemical manufacturing, where it allows for enhanced dissolution rates. Stability Temperature 120°C: 2-Amino-4-Methoxylpyridine stable up to 120°C is used in high-temperature reaction chemistry, where it maintains structural integrity under process conditions. Water Content <0.5%: 2-Amino-4-Methoxylpyridine with water content less than 0.5% is used in API production, where it prevents hydrolysis and degradation of active compounds. HPLC Purity 98%: 2-Amino-4-Methoxylpyridine with HPLC purity of 98% is used in reference standard calibration, where it validates analytical method accuracy. Residual Solvents <0.1%: 2-Amino-4-Methoxylpyridine with residual solvents below 0.1% is used in medicinal chemistry research, where it assures regulatory compliance and product safety. |
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In labs and manufacturing sites across the world, the quiet hum of discovery depends on the reliability of specialty chemicals. Among these, 2-Amino-4-Methoxylpyridine carves out an essential place, thanks to its unique characteristics, which stem from its molecular structure. This compound, represented by the formula C6H8N2O, grabs attention for the role it plays in medicinal chemistry, process development, and advanced research. Over years spent with researchers and production teams, one thing becomes clear: a building block with specific substituents like this offers possibilities that plain pyridines just can’t match.
When you examine 2-Amino-4-Methoxylpyridine under the lens of organic chemistry, the combination of an amino group at the 2-position and a methoxy group at the 4-position reveals a compound ready to engage in targeted transformations. The compound’s crystalline powder form, typically showing a pale to off-white hue, makes it easier to work with in both bench-scale syntheses and industrial setups. Many of those who’ve handled pyridine derivatives know that this specific arrangement on the ring can adjust reactivity in subtle ways, making your experimental design more flexible.
The product’s standard grade is designed with purity in mind. Most suppliers achieve levels of at least 98%, which supports complex downstream reactions. Impurities matter in specialty chemistry – stray atoms or molecules can trip up an otherwise promising reaction. Consistency batch to batch means fewer headaches and a smoother process from order to result. Many buyers appreciate this kind of attention to detail because it speeds up timelines and reduces troubleshooting time. Trying to scale up a reaction? Knowing that this kind of quality holds at larger quantities can take a load off your mind.
2-Amino-4-Methoxylpyridine rarely stands alone. It works as a tool in the hands of synthetic chemists eager to build more complex molecules. Folks in pharmaceutical development have long valued the molecule’s ability to act as a scaffold for creating drug candidates. Its amino group opens up paths toward making substitution reactions more straightforward, giving medicinal chemists a way to add functional diversity with precision. The methoxy group dials in electronic and solubility properties, so the resulting compounds often show improved behavior in biological screens or improved manufacturability in process chemistry.
Academic groups often turn to this compound for pathway exploration. Teaching the next wave of researchers about SAR (structure-activity relationship) studies? This pyridine derivative provides a real-world example for discussing how subtle ring substitutions affect everything from acidity to binding affinity in drug discovery efforts. Those working on agrochemicals or dye intermediates also find the molecule fills a niche. Its structure slots easily into various synthetic routes, supporting the production of materials with improved brightness or stability. Years in a teaching lab show that tangible, reliable reagents lead to more confident students—and more robust research outcomes.
Beyond application talk, there’s another side to why people reach for 2-Amino-4-Methoxylpyridine. Handling and storage don’t demand a specialized setup. The product generally stays stable under ambient conditions, assuming sealed and well-labeled containers. Anyone who’s ever dealt with unstable reagents understands the comfort of a shelf-stable material. Still, common sense applies: dry conditions and clean tools keep contamination away.
Deciding on this chemical comes down to practicalities just as much as theoretical properties. For bench researchers, the fine and uniform particle size matters more than a passing thought. A powder that doesn’t clump saves time during weighing or transfer—important in a teaching situation or a fast-paced R&D project. Good flow properties and an absence of visible crumbs help keep measurements precise. The aromatic odor can be distinct, though not overwhelming, and doesn’t linger like some more pungent pyridines. These small details add up; energetic student groups and busy technicians alike have less cleanup and can move on to the next step faster.
Cost is always part of the equation in purchasing decisions. Over recent years, specialty producers have refined their synthetic routes, making the compound accessible without forcing tough budget trade-offs. The reliability and competitive price give organizations room to experiment with it across more diverse projects. From what I’ve seen, being able to bring new chemistry into exploratory projects—without worrying about unpredictable supply or wild price swings—pushes innovation forward on both the academic and commercial sides.
On safety, it’s reassuring to note this molecule doesn’t draw the strictest regulatory controls compared to some flagged pyridine derivatives. Users should stick to sensible precautions: gloves for weighing, goggles for splashes, and good ventilation at the bench. Teams working in compliance-focused environments appreciate less red tape. That said, there’s no room for complacency—robust hygiene habits pay dividends over time, especially in busy shared labs.
Step back from the technical jargon, and the differences between this compound and other pyridines come into focus. The combination of amino and methoxy groups changes the whole landscape of interactions in reactions. Chemists who’ve wrestled with ortho- or para-substitution patterns know how tricky it gets if substitution isn’t straightforward. This molecule’s design makes life easier: the amino group activates key positions for further reactions, and the methoxy tweaks solubility in ways that benefit isolation and purification. Other pyridine derivatives might demand extra steps or harsher conditions, but here the path feels smoother.
Fine differences in reactivity and selectivity result in fewer byproducts, so purification at scale presents fewer headaches. Anyone who has handled multi-step syntheses will remember those sticky columns or long distillation runs. Streamlining those steps—just by choosing the right starting material—can save days or weeks, freeing up time for additional experiments or moving the process closer to launch. With this model, you’re buying not only a chemical but a shortcut past the roadblocks that tend to slow down progress in the lab.
Some analogs offer similar structures but tend to fall short on solubility or stability under acidic or basic conditions. Over the years, feedback from process chemists points to this compound’s robust nature during both bench and pilot operations. You don’t have to tip-toe around moisture as much, and there's less of a scramble to rescue sensitive intermediates. From experience, unplanned delays and batch inconsistencies lose their sting when starting from such a reliable base.
If you’re part of a fast-moving medicinal chemistry group or a scale-up department, every decision about which tools to stock is a bet on future productivity. Bringing in a compound like 2-Amino-4-Methoxylpyridine signals a commitment to efficiency, reliability, and flexibility. Researchers new to heterocyclic chemistry gain a trusted starting point for a range of syntheses, while expert teams benefit from fewer surprises during scale transitions. In the past, I’ve watched project managers and junior scientists alike breathe easier when their source material continues to deliver under pressure. Those small wins reinforce trust up and down the chain.
One often-overlooked feature is the transparent supply network maintained by reputable vendors. Repeated delays or inconsistent quality sap momentum in research settings. I’ve seen projects slowed to a crawl—not because of talent shortages or lack of funding, but simply from unreliable materials. The track record of high-quality commercial 2-Amino-4-Methoxylpyridine addresses those issues. Traceability, documentation, and regular third-party testing show respect for buyers’ need to meet rigorous standards. This culture of transparency lines up with the best practices advocated in the industry’s latest regulatory guidelines, supporting audit requirements and sustainable operations.
Synthetic chemistry never stands still. As research questions grow more complex—think drug-resistant pathogens, sustainable crop protection, or advanced materials for electronics—the need for distinctive building blocks increases. 2-Amino-4-Methoxylpyridine’s subtle changes to the pyridine ring make it a workhorse for pushing boundaries. What’s striking is that such an unassuming substance can make the difference between a dead end and a breakthrough. I remember sitting in on a student’s oral defense, where a late-stage substitution using this molecule suddenly unlocked a set of active analogs. Had they reached for a different reagent, the whole project might have ground to a halt.
Its impact stretches beyond purely academic research. Patent filings show that companies building new insecticides, antivirals, and diagnostic dyes frequently cite this compound as a key intermediate. A good number of these patents rely on the predictability of outcomes, supporting commercial timelines and reducing risk for everyone involved. This repeatable success also gives smaller teams a fighting chance against bigger competitors by speeding up the path to demonstration batches or pilot lots.
Out in the field, opinions matter as much as technical facts. Process engineers often provide valuable feedback on workflow efficiency. In team meetings, one recurring theme is satisfaction with the way this compound dissolves in standard solvents like methanol and dichloromethane, reducing the mess when isolating products from reaction mixtures. As budgets tighten and schedules shorten, small improvements in workflow add up quickly, and the feeling that you’re working with a thoughtfully designed reagent can make a tough week much easier to manage.
Quality control analysts voice appreciation for the straightforward testing protocols. Clear melting points, sharp HPLC peaks, and robust batch data reduce uncertainty. Reliable GC-MS or NMR spectra mean less time rerunning samples or debating ambiguous results. That confidence allows labs to focus expertise on more challenging problems, like optimizing yields or finding new synthetic partners. It’s rare for such a modest molecule to generate this much goodwill across roles, but time and again, people return to buy more for the simple reason that outcomes improve with its use.
No specialty compound exists in a vacuum. Sourcing high-purity pyridine derivatives has its share of hurdles, especially with shifting global supply chains. Over the past decade, I’ve watched raw material shortages ripple through supply, sometimes pushing projects off schedule. Teams that weather these storms best adopt two key practices: they build solid relationships with sellers who communicate clearly, and they keep documentation in order. This combination lets decision-makers respond quickly when disruptions hit, whether from environmental, regulatory, or logistical shocks.
Problems with inconsistent shipments or delayed lead times sometimes stem from inadequate post-synthesis purification. Much of this risk drops away with 2-Amino-4-Methoxylpyridine, since producers and buyers now share open channels on batch certifications, impurity profiles, and shipping dates. For organizations managing multiple projects, the reassurance of prompt, precise information translates to better forecasts, cleaner audits, and higher morale across the lab.
Storage and waste management shouldn’t be overlooked either. While this compound doesn’t demand refrigeration, safe handling calls for clean facilities and moderate venting. In busy shared spaces, labeling practices and regular inventory checks cut down on lost material and reduce the chance of unnecessary waste. Many organizations now emphasize green chemistry principles, so avoiding excessive solvent use and targeting high-yield syntheses matter more each year. Choosing a compound that fits easily into established processes—without special hazards or disposal headaches—makes it easier for teams to achieve sustainability goals alongside productivity targets.
All scientific progress comes with a measure of responsibility. For 2-Amino-4-Methoxylpyridine, that means considering product stewardship at each stage: procurement, storage, use, and final disposal. Responsible buyers source from ethical producers who can document their methods, trace raw materials, and avoid environmentally damaging practices. Clean records and transparent supply logs aren’t just paperwork; they build trust with stakeholders and show respect for communities potentially affected by the industry. Over years working with both corporate and academic purchasers, I’ve learned that accountability and cooperation build stronger supply chains, benefit local economies, and foster a culture of ethical innovation.
Research doesn’t stop at what’s possible—innovation depends on moving ahead with confidence. 2-Amino-4-Methoxylpyridine stands as an example of how fine choices in molecular design can drive bigger successes downstream, whether the goal is a lifesaving therapy, a more resilient crop, or a vibrant new dye. Years of hands-on experience and conversations with expert colleagues hammer home the value of reliable, thoughtfully sourced materials. The molecule’s blend of reactivity, stability, and flexibility supports a broad range of users, from early-career chemists to established production managers. By investing in transparent sourcing, quality assurance, and user-friendly specifications, the industry continues to unlock new possibilities—and makes every experiment a little bit more rewarding.
