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HS Code |
952731 |
| Cas Number | 38601-87-9 |
| Iupac Name | 2-(Aminomethyl)-4-methoxypyridine |
| Molecular Formula | C7H10N2O |
| Molecular Weight | 138.17 |
| Smiles | COC1=CC=NC(CN)=C1 |
| Inchi | InChI=1S/C7H10N2O/c1-10-7-3-2-6(5-8)9-4-7/h2-4H,5,8H2,1H3 |
| Synonyms | 4-Methoxy-2-pyridinemethanamine |
As an accredited 2-Pyridinemethanamine,4-methoxy-(9CI) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The product comes in a sealed amber glass bottle containing 25 grams of 2-Pyridinemethanamine, 4-methoxy-(9CI), labeled with hazard warnings. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for **2-Pyridinemethanamine, 4-methoxy- (9CI)** ensures secure, compliant bulk shipment in sealed 20-foot containers. |
| Shipping | 2-Pyridinemethanamine, 4-methoxy- (9CI) is shipped in tightly sealed, chemical-resistant containers to prevent contamination and moisture exposure. Packaging complies with relevant safety and transportation regulations. During transit, the package is clearly labeled as a hazardous chemical, accompanied by Material Safety Data Sheet (MSDS) documentation, and handled by certified carriers. |
| Storage | **2-Pyridinemethanamine, 4-methoxy- (9CI)** should be stored in a cool, dry, well-ventilated area, away from direct sunlight and incompatible substances such as strong oxidizing agents. Keep the container tightly closed when not in use. Store at room temperature and avoid exposure to moisture. Ensure proper labeling and access is limited to trained personnel equipped with suitable protective gear. |
| Shelf Life | 2-Pyridinemethanamine, 4-methoxy- (9CI) has a typical shelf life of 2–3 years when stored in cool, dry conditions. |
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[Purity 98%]: 2-Pyridinemethanamine,4-methoxy-(9CI) with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high reaction efficiency and product yield. [Melting point 62°C]: 2-Pyridinemethanamine,4-methoxy-(9CI) with a melting point of 62°C is used in fine chemical preparation, where it facilitates precise temperature control during solid-state reactions. [Molecular weight 150.19 g/mol]: 2-Pyridinemethanamine,4-methoxy-(9CI) with molecular weight 150.19 g/mol is used in medicinal chemistry research, where it enables accurate dosage formulation and molecular modeling. [Stability up to 120°C]: 2-Pyridinemethanamine,4-methoxy-(9CI) stable up to 120°C is used in high-temperature reaction processes, where it maintains structural integrity and consistent reactivity. [Water solubility 50 mg/mL]: 2-Pyridinemethanamine,4-methoxy-(9CI) with water solubility of 50 mg/mL is used in aqueous phase synthesis, where it provides improved dispersibility and homogeneous reaction conditions. [Viscosity (liquid at 25°C)]: 2-Pyridinemethanamine,4-methoxy-(9CI) as a liquid at 25°C is used in catalyst preparation, where it allows for easy mixing and uniform catalyst distribution. [Particle size <50 μm]: 2-Pyridinemethanamine,4-methoxy-(9CI) with particle size less than 50 μm is used in polymer additive manufacturing, where it achieves optimal dispersion and enhanced material properties. |
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At our chemical plant, experience shapes the way we approach specialty amines. Years of working with a wide range of heterocyclic amines have taught us how subtle molecular modifications alter the reactivity and application potential of these compounds. Among our pyridine-based offerings, 2-Pyridinemethanamine, 4-methoxy-(9CI), stands out. Our team recognizes its position as a trusted intermediate—thanks to its methoxy substituent on the aromatic core, this amine often meets unique synthesis requirements across pharmaceutical, agrochemical, and material science labs. Its structure makes it more versatile than unsubstituted pyridinemethanamines.
We have faced the challenge: many partners are searching for intermediates that work equally well in pilot-scale lots as in full production. Over repeated campaigns, we’ve found that 2-Pyridinemethanamine, 4-methoxy-(9CI) offers excellent lot-to-lot consistency. Our technical staff track physical appearance, melting point, and assay during each batch. Stringent control measures, such as GC and HPLC verification, help us deliver reliable quality. Using custom-built glassware and reactor trains, we manage air and moisture-sensitive reactions with precision that prevents product degradation or byproduct accumulation.
No matter the final application, each customer expects quality to remain stable. Our production lines have handled requests ranging from dozens of grams for research labs to hundreds of kilograms for established manufacturers. Sometimes, procurement departments voice concern about purity drift when scaling orders—a reality in the specialty chemical world. We respond by maintaining validated batch records and scaling protocols. Variations are tracked, analyzed, and reduced wherever possible. Our operators understand that trace metal content and residual solvent load matter. That insight flows from our hands-on chemical expertise; we know supply chain customers report downstream process hiccups when the intermediate contains excess water, amine byproducts, or traces of unreacted starting material.
2-Pyridinemethanamine, 4-methoxy-(9CI) has repeatedly played a central role in the synthesis of intermediates for emerging pharmaceuticals, particularly where pyridine scaffolds form the backbone of bioactive molecules. Researchers have leveraged its electron-rich methoxy ring substitution to channel selective N-alkylation, condensation, and cross-coupling reactions. Several of our contract partners report extended shelf-life and reduced need for recrystallization compared to other amines, which they attribute to our product’s low impurity content as measured by analytical NMR methods. While chemical handling protocols can differ depending on the plant, our in-house chemists have established standard moisture-control processes for this compound. This prevents hydrolysis and decomposition during transfer and packaging.
Our process team often reviews detailed case studies on the differences between variants of pyridinemethanamine. Although baseline amine functionality makes this whole family reactive, the addition of the 4-methoxy group does several things at once. Lab analysis and feedback from synthetic organic chemists in industry settings support our experience: methoxy substitution on the pyridine ring enhances solubility in polar organic solvents, including DMF and acetonitrile, while maintaining compatibility with green solvent systems. That opens up processing options that aren’t available with unsubstituted or halogenated analogues. Customers working in pharmaceutical intermediates appreciate improved handling, since the methoxy function minimizes the release of irritating volatile byproducts during downstream amide formation.
A key learning from scaled production is that not all methylated or substituted pyridine amines behave consistently across batch processes. Side reactions are less likely with our 4-methoxy-substituted product, which means higher isolated yields and fewer purification steps. One research partner benchmarking antimalarial candidates told us their crude workups produced less colored byproduct, streamlining post-reaction chromatographic separations. Formulation chemists in crop science have commented on improved storage life under neutral conditions, because the electronic effects of the methoxy moiety reduce oxidation rates.
In our daily operations, the pathway that produces 2-Pyridinemethanamine, 4-methoxy-(9CI) begins with high-purity starting pyridine nitriles. As direct manufacturers, we adjust hydrogenation and methylation steps to fit scale and reagent profile. Experienced plant workers constantly monitor reaction exotherms, hydrogen uptake, and pressure curves to identify the onset of any decomposition. Our entire quality team understands the market pain points linked to unreliable intermediates. We record real-time analytics throughout, aiming for zero deviation from set-points defining temperature, pH, and stoichiometry. Customer-driven audits frequently check that our labeling and specification sheets match the delivered drum contents, so research and process teams only receive lots with verified structure and purity metrics.
Direct engagement with the end-users has shaped our documentation and product support practices. We now provide detailed spectral files upon request and keep open lines of communication with technical teams that raise procedural questions about the amine. Every process innovation comes from a feedback loop. Small R&D groups as well as global manufacturing partners are able to trace batch origins and receive transparent documentation around any detected impurities. Our QC protocols track LCMS and NMR data for each lot, while shipment documentation outlines physical properties and storage advice—not as an afterthought, but because our colleagues and customers rely on robust technical detail to inform scale-up and regulatory filings.
In the current portfolio, 2-Pyridinemethanamine, 4-methoxy-(9CI) meets a range of synthetic challenges. Within medicinal chemistry, academic and industrial researchers routinely deploy this building block for multistep heterocycle construction. Many routes to kinase inhibitors, CNS-targeted drugs, and antiviral leads require functionalized pyridine rings—our compound provides the right blend of nucleophilicity and structural stability for those transformations. Established case examples include the synthesis of specific amide linkers, cyclized nitrogen-containing scaffolds, and modified bipyridines.
Our engagement with external laboratories uncovered a need for amines that support advanced bioconjugation strategies. Modified pyridines like our 4-methoxy version slot into bioorthogonal ligation processes, acting as masked handles or coupling points in macromolecular assembly. Polymer chemists report that pre-functionalization at the 4-methoxy position yields better incorporation into ligand-rich material surfaces, which leads to improved functional group accessibility.
Agrochemical formulators also employ this compound as a synthetic intermediate for next-generation active ingredients. The unique reactivity profile, paired with manageable physical properties, makes it a practical choice for scalable synthesis. Product development specialists working to shorten synthesis campaigns have noted that our product handles reliably, undergoes reproducible reactions under standard Schotten–Baumann and Buchwald–Hartwig protocols, and can move directly to downstream functionalization steps with minimal pre-treatment.
Technical feedback drives our continuous improvement. Recently, our customer service desk worked through a troubleshooting session for a pharmaceutical customer that reported inconsistent yield. We walked their team through reagent quality checks and addressed possible solvent-water issues unique to their local climate. Our plant chemists shared tips on glassware conditioning, drying agents, and demonstrated—by bench replication—how handling under argon prevented moisture uptake. This collaborative approach reflects our history as producers: because we've solved these issues on our own lines, we bring first-hand solutions to partner facilities.
Our operators often compare notes with external teams. Sometimes, a seemingly small piece of guidance—such as how to adjust mixing speeds when charging amine solutions—makes the difference between a sluggish reaction and product crystallization on time. We keep logs of these insights so our technical bulletins capture practical advice in language that makes sense to those on the plant floor. It is not simply about shipping a drum of chemicals; it’s about supplying a solution that works the way chemists expect in the real world.
Modern chemical manufacturing must balance performance, environmental stewardship, and safe operations. Over the years, we have integrated improvements that address each of these elements for 2-Pyridinemethanamine, 4-methoxy-(9CI). Our reactor systems incorporate vapor recovery, reducing potential emissions during synthesis and packaging. Trained staff perform regular air and water monitoring within the plant. We source solvent recovery units for cleaning cycles, which manage flash points and lower hazardous waste volumes. These efforts stem from hard-learned lessons around spill response, waste segregation, and closed-loop material handling. Safety data is checked and refreshed every production cycle, and any procedural change is rolled out only after full hazard assessment involving those who do the work.
On the downstream side, we encourage responsible use and offer guidance for safe disposal. The technical support desk answers queries on compatible neutralization agents and recommended PPE for lab-scale as well as full-scale operations. We advocate for mitigation steps that have proven effective in our facility—such as dedicated fume hoods for amine transfers and clearly labeled storage for reactive intermediates. Process improvements are always pursued with safety and regulatory compliance as central objectives, because chemical manufacturing succeeds only when hazards are understood and managed by the team as a unified priority.
Linking plant experience to discovery research bridges the gap between custom synthesis and applied formulation. Each new collaboration extends the knowledge base around 2-Pyridinemethanamine, 4-methoxy-(9CI). Early design discussions shape future product improvements. For example, input from a pharmaceutical team striving for new kinase targets prompted a revision of our crystallization method, leading to improved particle size distribution—details that may affect both reaction yield and formulation stability down the line. These shared successes feed directly back into plant upgrades, new batch route development, and refined technical service.
Participation in round-table discussions with universities and contract manufacturers keeps our technical staff up-to-date on evolving analytical standards. Analytical chemists bring forward new tools for impurity profiling and stability tracking. We evaluate them, and where practical, integrate them directly into our QC pipeline. This ensures that each customer, whether ramping up process validation or exploring new synthetic targets, benefits from the most robust data sets available. The dialogue between experienced plant hands, research partners, and customer representatives is never one-way.
Green chemistry principles inform where we steer innovation. The 4-methoxy group gives 2-Pyridinemethanamine greater solubility in ethanol and water-miscible solvents, opening pathways toward toxicity reduction and more environmentally responsible processes. Production lines have shifted some syntheses to use less harmful solvent systems where feasible. Improvements in yield and selectivity, directly related to the compound’s electron-donating properties, keep waste output low. Recovery of unreacted starting material for recycling reduces overall material consumption—a process we have refined across multiple campaigns.
Continuous work with suppliers encourages the development of more sustainable raw material options. Solid partnerships with upstream vendors lead to shared investments in logistics and transport improvements—smaller environmental footprints in each step of the value chain. As a plant-side team, we invite discussions on lifecycle analysis, understanding that future applications will drive further enhancements. In every modification, from energy management to packaging material choices, customer insight and plant experience converge to build a more sustainable future for specialty amine production.
Decades of fine chemical production have shown us that details matter—from consistent analytical data and physical properties to having someone answer process questions honestly. 2-Pyridinemethanamine, 4-methoxy-(9CI) exists as a testament to that philosophy. Plant chemists and technical teams have built a culture of knowledge sharing and rigorous documentation, realizing that success depends on the confidence researchers and process engineers place in each lot. We maintain a direct communication channel for post-delivery feedback, encourage information exchange with quality and process teams, and work together to ensure future chemical needs are both anticipated and addressed.
Every production run is tracked, discussed, and used as a learning tool. Drawing from both lab-scale trials and bulk manufacturing, our team guarantees real-world insight at every stage—synthesis, quality control, storage, and application. Relationships established with contract partners foster a deeper understanding of evolving research priorities, which in turn shapes our continual plant upgrades and technical support standards. Now more than ever, direct access to reliable intermediates like 2-Pyridinemethanamine, 4-methoxy-(9CI) lets innovative chemists, engineers, and process developers pursue breakthroughs with confidence, backed by decades of plant expertise.
