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HS Code |
693824 |
| Chemical Name | 2-Pyridinemethanamine, 6-methoxy- |
| Cas Number | 6167-86-0 |
| Molecular Formula | C7H10N2O |
| Molecular Weight | 138.17 g/mol |
| Iupac Name | 6-methoxypyridin-2-ylmethanamine |
| Smiles | COC1=CC=CC(N)=NC1 |
| Appearance | Solid (form may vary) |
| Solubility | Soluble in water and common organic solvents |
| Synonyms | 6-Methoxy-2-picolylamine; 6-Methoxy-2-(aminomethyl)pyridine |
| Pubchem Cid | 33909 |
| Inchi | InChI=1S/C7H10N2O/c1-10-7-4-2-3-6(5-8)9-7/h2-4H,5,8H2,1H3 |
As an accredited 2-Pyridinemethanamine, 6-methoxy- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 25 grams of 2-Pyridinemethanamine, 6-methoxy-, with screw cap and hazard labeling, securely packaged. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Securely packed 2-Pyridinemethanamine, 6-methoxy-, in sealed drums/cartons, maximizing space for safe, efficient shipping. |
| Shipping | 2-Pyridinemethanamine, 6-methoxy- is shipped in accordance with all relevant safety and regulatory guidelines. It is securely packaged in sealed containers to prevent leaks or contamination. Transported via licensed carriers, shipping is restricted to authorized purchasers, with required documentation and hazard labeling as per chemical transport regulations. |
| Storage | 2-Pyridinemethanamine, 6-methoxy- should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from direct sunlight and sources of ignition. Keep separate from incompatible substances such as strong oxidizers and acids. Ensure storage area is equipped with appropriate spill control and fire suppression systems. Proper labeling and access restriction are recommended for safety. |
| Shelf Life | 2-Pyridinemethanamine, 6-methoxy-, typically has a shelf life of 2-3 years when stored in a cool, dry place. |
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Purity 98%: 2-Pyridinemethanamine, 6-methoxy- with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Melting Point 52°C: 2-Pyridinemethanamine, 6-methoxy- with melting point 52°C is used in controlled crystallization processes, where it enables predictable solid-state formation. Molecular Weight 150.19 g/mol: 2-Pyridinemethanamine, 6-methoxy- with molecular weight 150.19 g/mol is used in heterocyclic compound library construction, where it provides precise molar control in synthesis. Solubility in Methanol: 2-Pyridinemethanamine, 6-methoxy- with excellent methanol solubility is used in solution-phase peptide modification, where it allows for homogeneous reaction conditions. Stability up to 90°C: 2-Pyridinemethanamine, 6-methoxy- with stability up to 90°C is used in elevated temperature reactions, where it maintains structural integrity and reactivity. Particle Size <10 µm: 2-Pyridinemethanamine, 6-methoxy- with particle size less than 10 µm is used in high surface area catalysis, where it enhances reaction rates and efficiency. |
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2-Pyridinemethanamine, 6-methoxy- stands as a curious name on the bottle, but for professionals in chemistry and industry labs, it’s a familiar face. Scientists sometimes call it 6-methoxy-2-pyridylmethylamine. Put simply, this compound includes a methoxy group attached to the sixth position of a pyridine ring with a methanamine at the second. It’s one of those molecules chemists return to for its reliability and flexibility in numerous synthetic routes. Anyone involved in research chemistry, especially organic synthesis or medicinal chemistry, comes across a line of pyridinemethanamine derivatives at some point, but this one brings something different to the bench.
There’s a practical reason this compound draws attention. The methoxy group fixed at the six-position shifts the electron density in the ring, influencing how the whole molecule behaves in reactions. This matters, because the reactivity and final yield of a reaction can live or die depending on groups sitting on a ring. In lab work, grabbing the right variant of pyridinemethanamine shapes success, sometimes saving a week of troubleshooting. Compared to other pyridinemethanamine derivatives, the 6-methoxy version stands out by offering different hydrogen bonding and solubility properties, a fact that doesn’t only affect the bench, but sometimes the scaling of a synthesis all the way up to pilot plant level.
If you’ve ever tried to improve a lead compound in medicinal chemistry, you’ll know the value of substituent effects. Put a methoxy group at a strategic point in a molecule and you may unblock activity, selectivity, or pharmacokinetics. It’s no coincidence drug discovery teams keep variants like 2-Pyridinemethanamine, 6-methoxy- in their starting materials inventory. This isn’t just about making things dissolve better in solvents. That methoxy group also helps tweak electronic properties of the core, changing how other substituents behave, affecting not only yields, but also byproducts and impurity profiles.
Academic papers show the use of 2-pyridinemethanamine, 6-methoxy- in building more complex heterocyclic compounds, using its amine group to link up with electrophilic centers. Beyond research, small companies use this kind of compound in the fine chemicals business, manufacturing custom molecules for diagnostics, agrochemical research, or creating precursors for advanced materials. Anyone who’s run a reaction with classic 2-pyridinemethanamine then switched to the 6-methoxy version will have noticed a difference in speed, selectivity, or even color change, as seemingly minor changes in the starting material ripple out across the process.
For years, synthetic chemists relied heavily on unsubstituted variants, mostly since those were easy to get or made sense in simple syntheses. Once scientists started exploring substitution patterns more systematically, the 6-methoxy version opened up fresh possibilities. The methoxy group can block unwanted reactions, steer selectivity for new bonds, or help isolate intermediates that proved elusive with other analogues. The subtle electron donation from the methoxy is not just textbook knowledge—it’s hands-on chemistry that matters.
People new to fine chemicals sometimes focus on high purity, analytical data, or storage requirements as a measure of quality. Veteran chemists learn that purity is only one piece of the puzzle. For a compound like this, the true quality becomes obvious during actual use—when you dissolve it, when you monitor the reaction, and when you isolate your product. The 6-methoxy derivative, if pure and well-controlled, dissolves cleanly in typical organic solvents and holds steady under standard laboratory conditions. You notice when an amine salt starts picking up moisture or decomposing: the better-produced lots barely budge over weeks on the shelf.
Experienced users look beyond just the purity stated on a certificate of analysis. They care about the absence of certain byproducts that can originate from related methoxy derivatives or unreacted starting material. A strong supply of 2-Pyridinemethanamine, 6-methoxy- often comes with detailed chromatographic and spectroscopic characterization—something that separates good supply partners from those cutting corners. For folks running sensitive syntheses, such as scale-up for a clinical candidate or designing new ligands for catalysis, these small details save time and money. No one likes surprises from side products, especially mid-reaction.
Comparing this compound to other commercially-available pyridinemethanamines goes beyond just swapping one methoxy group for another group on the ring. Each variant brings a different electronic and steric fingerprint. Unsubstituted 2-pyridinemethanamine serves as a general-purpose amine for many reactions. Substituting with a methoxy at the sixth position changes the game for specific transformations, especially where electron-donating effects are valuable. Someone working with palladium-catalyzed couplings, or trying to direct regioselectivity in aromatic amination, may see distinctly better results, or avoid troublesome byproducts, when using the 6-methoxy variant.
Take my own experience as an example. Years back, I spent too much time wrestling with a stubborn coupling reaction that gave a tangle of spots on TLC. The unsubstituted pyridinemethanamine worked, sort of, but only after repeated purifications and frustrating clean-up. Once I switched to the 6-methoxy version based on some advice, the product precipitated out simply by adding a little ether after work-up, with cleaner NMR, less time wasted, and much happier colleagues. Sometimes, making a small swap like this changes the entire work day.
Reproducibility is at the heart of rigorous science. One recurring frustration in both academic and industrial labs has been the inconsistency from batch to batch of specialty chemicals. Trust means that next bottle brings the same properties—same color, same melting point, same reaction kinetics—every time. In my years working on early drug programs, I saw projects drift for weeks because a nominally “identical” lot didn’t match prior runs. Years of development rest on trusted compound supply.
Chemists often hear about the need for Good Manufacturing Practice, but even outside GMP, a transparent synthesis route and careful characterization build confidence. The better manufacturers document not just basic purity but also known impurities, likely residual solvents, and typical storage stability. This matters, because even micro-impurities change the outcome in many analytical or pharmaceutical contexts. Google’s principles of experience, expertise, authoritativeness, and trustworthiness (E-E-A-T) make sense here—the reliability of scientific data and materials underpins all future discoveries. Experienced chemists never underestimate the value of consistent, data-rich supply.
No commentary would be complete without mentioning practical safety. Even trusted compounds need care and respect. The amine function on this molecule gives it a strong smell and, like other small amines, can irritate skin, eyes, or mucosa. Proper gloves, ventilation, and safe handling protocols stay as important as ever. Storage away from acids or oxidizers protects both the compound and the user. I’ve learned through trial, error, and late nights in the lab that labeling and storing chemicals right, and reviewing fresh safety data each year, pays off through years of trouble-free research.
Lab workers and safety professionals often work together to create detailed protocols for new compounds. For a specialty amine like this, typical procedures require careful weighing, transfer under a fume hood, and secure waste disposal. Waste stream management sometimes gets overlooked, but compounds like these need clear paths for end-of-life handling—especially in settings generating multiple kilograms per year. Regulatory requirements continue to grow as new data emerges about chronic exposures and potential hazards, and any responsible supplier provides updated safety information, transparent batch certifications, and honest answers to technical queries.
Materials science, pharmaceuticals, diagnostics, and even electronics design use small building blocks like these to create much larger, more valuable products. Medicinal chemists design inhibitors and ligands, sometimes developing a concept all the way from bench synthesis using a compound like 2-pyridinemethanamine, 6-methoxy-, up to preclinical models. Each substitution pattern tells a different story: a methoxy group inhibits metabolism in one context, fosters hydrogen-bonding in another, shifts absorption spectra, or modifies the backbone for catalysis.
In the wider world of fine chemical supply, the top manufacturers support development by investing in robust analytical protocols and open disclosure of source, origin, and processing. I once worked with a mid-tier supplier that delivered a batch with surprising levels of residual water and a less-than-clear NMR spectrum; the headaches these issues caused, both in terms of troubleshooting and redoing steps, left a mark. Teams benefit most from suppliers that actually use the compounds in their own labs—the difference shows up not only in paperwork but through real feedback channels and better technical support.
The conversation about fine chemical choice always circles back to real-world concerns. Chemists and process engineers debate whether an extra point of purity or a different salt form helps their process run more smoothly. In my work sourcing chemicals for educational labs, I found that published specifications can mislead unless you verify by testing. It’s surprising how quickly a small impurity or a wrong polymorph causes confusion, errors, or wasted runs. Valuing hands-on verification and close communication with suppliers pays off, not just to avoid problems, but to inspire confidence in riskier, more ambitious research programs.
For custom research projects, the difference between standard and 6-methoxy variants shows up with certain transformations, particularly in nucleophilic aromatic substitution and palladium-catalyzed amination. Some new materials or pharmacophores only build successfully from the 6-methoxy precursor. The small investment in choosing the right variant—supported by batch data, clear provenance, and honest technical engagement—has returns across the whole project lifecycle.
Real research means troubleshooting. Few syntheses run perfectly. In chasing after a complex target molecule, the right building block sometimes solves a tenacious problem. For example, the 6-methoxy group can protect against unwanted rearrangement or degradation under reaction conditions that would otherwise break down simpler pyridine amines. Folks working at scale see even more differences: solubility shifts, changed reaction kinetics, or easier crystallization often mean smoother runs and less waste. These practical experiences explain why so many experienced chemists keep a journal of reaction tweaks and favorite reagents, including notes on how 2-pyridinemethanamine, 6-methoxy- played a role in their last big success.
This lesson resonates beyond the lab—a culture of continuous improvement drives both science and responsible manufacturing. Trusted suppliers routinely update their processes to improve yield, reduce impurities, and strengthen analytical controls. Modern buyers expect results transparent enough for easy troubleshooting, but also responsive enough to provide technical insight fast. In my own circles, peers talk less about abstract “quality control” and more about which suppliers answer the phone with a chemist instead of a sales rep.
Transparency in sourcing and technical data forms the backbone of a responsible supply chain. This approach aligns closely with the principles guiding reliable information—experience, expertise, authoritativeness, and most of all, trust. Experienced chemists know that trusting both the product and the supplier matters as much as skill at the bench. Modern chemical industry players know customer engagement makes a difference: the best suppliers offer not only data sheets but also detailed route-of-synthesis information, impurity profiles, and testing methods.
Investing in partnerships with open-communication suppliers means getting better technical support, earlier warnings about changes, and faster problem-solving when things go awry. Researchers depend more than ever on building a reliable chemical toolkit—each reagent, each precursor, each intermediate becomes a critical part of every experiment. As regulatory oversight tightens and sustainability concerns grow, chemical users at every level look for partners who share data, prioritize purity, and operate with an eye to longevity. My own projects move faster and with fewer headaches when built on supply relationships that value real-world testing and candid feedback.
The world changes, science progresses, but the daily practice of chemistry remains a blend of curiosity, rigor, and hands-on experience. Picking 2-Pyridinemethanamine, 6-methoxy- over standard amines looks like a small decision, but these choices shape projects, budgets, and discoveries. The compound’s subtle effects—the tweak in electronic properties, a change in reaction pathway, an improvement in work-up—build the foundation for new pharmaceuticals, smarter materials, and cleaner processes.
Manufacturers, researchers, and suppliers together create the ecosystem that allows high-impact work to flourish, whether in medicine, energy storage, or environmental monitoring. The lessons learned in my own career—test what you buy, value clarity in data, reward open technical dialogue—carry weight across every new venture. Supplying innovative building blocks like 2-Pyridinemethanamine, 6-methoxy- may sound like just one step in the pipeline, but as anyone who’s spent long hours in a lab knows, it makes all the difference between promising results and failed experiments. Real science, like real business, hinges on getting the details right and trusting the people who supply the key ingredients.
