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HS Code |
310005 |
| Iupac Name | 2-(Methylamino)methylpyridine dihydrochloride |
| Molecular Formula | C7H11N2 · 2HCl |
| Molecular Weight | 197.09 g/mol |
| Cas Number | 138375-11-6 |
| Appearance | White to off-white crystalline powder |
| Solubility In Water | Freely soluble |
| Melting Point | 214-218 °C (decomposition) |
| Storage Conditions | Store at 2-8°C, tightly closed |
| Ph | 4.0-6.0 (10% aqueous solution) |
| Synonyms | Alpha-methyl-2-picolylamine dihydrochloride |
| Structural Formula | C7H11N2 · 2HCl |
| Ec Number | NA |
| Hazard Statements | Irritant |
As an accredited 2-Pyridinemethanamine,a-methyl-, dihydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging is a 25g amber glass bottle, tightly sealed, clearly labeled with hazard warnings for 2-Pyridinemethanamine, α-methyl-, dihydrochloride. |
| Container Loading (20′ FCL) | 20′ FCL: 2-Pyridinemethanamine, α-methyl-, dihydrochloride loaded in sealed drums/cartons, 10-14 MT net weight per container. |
| Shipping | 2-Pyridinemethanamine, α-methyl-, dihydrochloride is shipped in tightly sealed containers to prevent moisture ingress and degradation. It is packed according to chemical safety regulations, labeled as a laboratory reagent, and typically dispatched under ambient conditions, unless otherwise specified. Appropriate hazard labeling and paperwork accompany each shipment to comply with transport regulations. |
| Storage | 2-Pyridinemethanamine, α-methyl-, dihydrochloride should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area. Keep away from moisture, heat, and incompatible materials such as strong oxidizers. Store at room temperature and avoid exposure to direct sunlight. Ensure proper labeling and keep out of reach of unauthorized personnel. |
| Shelf Life | Shelf life of 2-Pyridinemethanamine, α-methyl-, dihydrochloride: Typically stable for 2 years when stored in a cool, dry place. |
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Purity 99%: 2-Pyridinemethanamine,a-methyl-, dihydrochloride with a purity of 99% is used in pharmaceutical intermediate synthesis, where it ensures high-yield and low impurity formation. Melting Point 210°C: 2-Pyridinemethanamine,a-methyl-, dihydrochloride with a melting point of 210°C is used in fine chemical manufacturing, where it provides thermal stability during high-temperature reactions. Molecular Weight 193.09 g/mol: 2-Pyridinemethanamine,a-methyl-, dihydrochloride with a molecular weight of 193.09 g/mol is used in analytical standard preparation, where it guarantees accurate calibration. Particle Size <50 µm: 2-Pyridinemethanamine,a-methyl-, dihydrochloride with particle size less than 50 µm is used in formulation development, where it enhances solubility and homogeneous dispersion. Stability Temperature up to 150°C: 2-Pyridinemethanamine,a-methyl-, dihydrochloride with stability temperature up to 150°C is used in controlled-release drug production, where it maintains compound integrity under process conditions. pH Stability 3-7: 2-Pyridinemethanamine,a-methyl-, dihydrochloride with pH stability between 3 and 7 is used in buffer system studies, where it maintains consistent reactivity across varying pH environments. |
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At our production facility, we spend plenty of time with specialty amines, and 2-Pyridinemethanamine, α-methyl-, dihydrochloride has steadily built a reputation among our customers for its reliability in research and industry. Working with this compound daily, our process and quality control teams have seen up close how slight variations in precursor purity, moisture levels, and temperature can affect the quality of each lot. The physical form we aim for—a dry, crystalline solid—offers consistent weight and easier handling. Our chemists check every batch’s melting point and water content, because real-world lab work punishes suppliers who get these wrong.
In-house, we reference our own internal model number but focus more on what matters for users: reliable assay, defined melting range, and tight controls for trace impurities. We keep the active content above 99.0%, minimizing organic and inorganic residues that could interfere with catalysis, coupling reactions, or pharmacochemical synthesis. Most labs ask for a clear Certificate of Analysis—that’s something our analytical team delivers with spectra and validated test results, not generic claims.
Our crystallization and purification lines are designed to produce dihydrochloride salt, which remains stable under standard conditions. Unlike variable base forms or alternate salt versions, the dihydrochloride delivers both predictable solubility and resistance to hydrolysis. We routinely store it in HDPE drums lined with protective bags to keep out humidity, avoiding caking and decomposition from the moment it leaves our building.
Over years of supplying academic labs, contract research, and pharmaceutical development shops, two features draw repeat requests for 2-Pyridinemethanamine, α-methyl-, dihydrochloride: its role as a key intermediate and its reactivity profile.
Small changes in the amine structure have big downstream consequences. α-Methylation on the aminomethyl side chain means researchers can build on a chiral center or introduce more steric hindrance. In medicinal chemistry, chemists look for scaffolds that offer flexibility without inviting side reactions. Standard pyridinemethanamine lacks the extra methyl group, so its reactivity—and any selectivity in asymmetric synthesis—differs significantly. This version lets process chemists avoid extra steps later, especially when aiming for chiral or tailored pharmaceuticals.
We see most purchasing volume come from fine chemical and pharmaceutical companies tailoring ligands or building heterocyclic compounds. Recently, a few agrochemical labs reached out for the same compound when looking to modify nitrogen-containing frameworks for new active ingredients. The amine group, especially in the dihydrochloride salt, reacts cleanly with a range of acyl, alkyl, or sulfonyl chlorides. Developers appreciate that they can rely on batch-to-batch consistency, especially for multi-step syntheses.
Our technical support has fielded questions from research teams optimizing microwave-assisted reactions, looking to minimize byproducts during scale-up. It’s clear from conversations that one of the biggest frustrations among users comes from unexpected color changes or insoluble residues after storage. Early batches a decade ago sometimes suffered from trace metal contamination, which we addressed by upgrading our synthesis line and switching to stainless contact surfaces. Monitoring these details ensures downstream purity, which our customers keep pointing out is not always true when sourcing from traders or re-packagers unfamiliar with the production process.
Experience has shown that this salt form brings practical advantages over the base. Free amines often draw in moisture during storage or handling, changing both appearance and activity. Dihydrochloride salts, by contrast, pack tightly and pour well, making them easier to weigh, dissolve, and dose, especially outside the glovebox environment. Solubility in water and alcohols is higher than some alternative salts, so no one has to spend extra time coaxing material into solution.
Compared to the non-methyl analog, α-methyl-dihydrochloride offers improved selectivity in routes leading to optically active products. Process chemists tend to prefer this version wherever direct methylation would risk overalkylation or racemization. Our production batches routinely support syntheses where regulatory filings require predictable impurity profiles. Older routes using base forms or monohydrochloride alternatives often suffer from inconsistent salt content, creating confusion when scaling up to kilo quantities. We avoid these headaches by running regular pilot-scale tests and confirming both salt ratio and hydration state.
Logistics matter just as much as synthetic details. Bulk chemicals, especially hygroscopic hydrochloride salts, can develop clumping if packaging is overlooked. We learned quickly that the trick is more than just moisture-barrier bags; filling at low ambient humidity and degassing packets prevent issues before they start. A few years back, a midsize customer struggled with repeated caked material from another supplier. Swapping in tighter process controls and advising on short-term storage eliminated repeat complaints and preserved the compound’s free-flowing consistency.
Customers developing new derivatives often send feedback about usability. One complaint: older or loosely packed salt tends to discolor or emit odor over time in humid climates. Our team tested different packaging solutions, eventually standardizing on double-lined containers. These choices cost more up front but have kept returned shipments at near zero, which, given the volatility of chemical markets, means better ongoing relationships.
Consistent output does not come from luck. Our plant sticks with a validated process, drawing from batch records going back years. Each lot gets a unique code for traceability, so users can match their application data to a specific synthesis. Infrared and NMR spectra confirm compound structure; mass spectrometry checks for sub-ppm impurities. Residual solvents, including acetone, DMF, or methanol, get checked using gas chromatography before batch release. Because some customer applications are sensitive to even trace side products, our monitoring stretches beyond minimum regulatory requirements.
Our on-site lab complements routine QC checks with kinetic and thermal degradation studies, so production doesn’t just meet a number on paper but matches the way compounds perform on a laboratory bench or in a pilot plant setting. This hands-on approach helps us notice any trend that could point to potential problems—no one wants surprises halfway through a synthetic campaign.
A handful of partners exploring next-generation APIs or agrochemical actives rely on 2-Pyridinemethanamine, α-methyl-, dihydrochloride for its balance between reactivity and stability. Its controlled reactivity means medicinal chemists can build libraries of analogs without repeated purification headaches, and its shelf-life under recommended conditions makes it suited for both small-scale screening and larger process validation lots. Being close to the manufacturing process, we hear from researchers who want custom documentation, specific salt forms, or even guidance on long-term storage. That feedback circles back into how we formulate, package, and ship.
Some research groups have moved from small bottles to multi-kilo drums over the years, as their success with the compound scaled with project expansion. Early-stage innovation often morphs into commercial development, so our production lines expand batch sizes based on forecasted demand, not guesswork. This flexibility distinguishes manufacturer supply from distributor drop-shipping, where warehousing and repacking obscure the quality chain.
Maintaining purity in nitrogen heterocycles means sweating the details—mineral acid concentrations, temperature holds during quenching, even the filtration rate on large-scale runs. Small slips in any of these areas can nudge impurity levels just enough to cause problems. Some of our process adjustments came from troubleshooting real customer complaints, such as strange NMR peaks after extended storage, which led us to retool our drying and packaging routine. Replicating quality at different scales remains a perpetual challenge, but over time, rigorous monitoring and feedback loops close the gap.
Chemists in preclinical and regulatory environments demand more than just a “white solid.” Without full traceability, there is risk in every synthesis step. Our own investment in analytical capabilities—full spectra on every batch, in-house and third-party cross-checks—reassures users that they can trace every gram from synthesis to end use. The regulatory world keeps raising the bar, making close cooperation between manufacturing teams and end users essential.
Chemicals rarely stay still. Customer feedback and new applications drive adaptation—ranging from more granular packaging options to salt forms tailored for specific solubility needs. As demand has shifted to high-throughput research teams, we introduced smaller fill sizes with tamper-proof certification. Bulk clients running continuous processes get drums with pre-weighed subpacks, reducing on-site handling risks. One of the consistent themes: direct communication with customers, many of whom cite issues with non-manufacturing-based suppliers that can’t answer basic technical or batch history questions.
Stricter environmental and safety concerns mean audits, choice of green solvents, and lifecycle management become more factually important. Our in-house team redesigned some steps to cut solvent usage and recover acid. These choices also help downstream users who must track every input for sustainability reports. The drive toward greener chemistry and traceable provenance rewards the producers who control every phase from raw material sourcing to packaged final compound.
It’s not rare for customers to relate stories of inconsistent results or unexplained impurities when buying from unknown sources. Actual production in our facility means we can answer technical questions about synthesis, batch stability, or compatibility with follow-on reactions. Traders or brokers may offer lower prices on apparent equivalents, but uncertainty on origin or process frequently leads clients back to direct-from-manufacturer supply. The tight control at every stage—upstream raw materials as well as downstream handling—translates directly into fewer failed batches, less lost time in research, and more reliable regulatory filings.
Instead of a “one size fits all” product sheet, our approach draws on regular conversations with academic and industrial users worldwide. Each year brings a handful of minor reformulations or packaging tweaks, all stemming from real-world feedback. This practical partnership means fewer surprises for end users, whether they need a 10-gram sample or a 20-kilo drum.
Being a chemical manufacturer brings daily reminders of the interplay between production, regulatory updates, and end use realities. Our focus keeps us tuned to shifting expectations: lower impurity thresholds, expanded regulatory disclosures, and pressure to document responsible sourcing. Real manufacturing experience reveals that these aren’t just buzzwords—they’re operating requirements. Over time, our process for 2-Pyridinemethanamine, α-methyl-, dihydrochloride has tightened to meet evolving standards without sacrificing yield or reliability.
Direct engagement with regulatory agencies and downstream clients keeps our process aligned with global expectations. For example, REACH or US FDA guidelines push for tighter impurity limits, which led us to upgrade analytic equipment and add orthogonal test methods. In turn, customers—especially those submitting INDs, DMFs, or patent filings—gain confidence from documentation that stands up to scrutiny, whether at mg or mt scale.
Real hands-on experience at the plant level means every change is felt immediately—material quality, process efficiency, and customer feedback cycle faster than through any distribution channel. Our teams share a practical understanding of what makes a batch perform or falter. We take direct calls when a customer struggles with solubility or unexpected color, and we adjust our own process based on outcomes, not just internal metrics.
In specialty chemicals, especially with pyridine derivatives, minute choices—like a washing solvent or filtration step—can mean the difference between analytical-grade material and something that confounds research work. Decades of hands-on technical know-how feed into each drum we ship. That’s not marketing—it’s a direct outgrowth of running, refining, and troubleshooting real-world processes under real constraints.
It’s always tempting to optimize processes around cost or perceived efficiency, but repeated interactions with scientists, process engineers, and regulatory teams highlight that value isn’t just in product pricing. It’s in the absence of inconvenient surprises and in the practical utility of a chemical under real lab or production conditions. End users speak up when material flows well, dissolves cleanly, and keeps its properties over time. They’re more vocal if any defect or suspected impurity crops up.
Manufacturing 2-Pyridinemethanamine, α-methyl-, dihydrochloride is as much about process discipline as technical capability. Every kilo tells a story of synthesis, testing, packaging, and feedback. We take pride when experienced researchers single out our batches for reliability. The partnership between manufacturer and user sets this product apart—rooted in transparency, built on shared technical expertise, and always open to evolution based on real-world feedback.
