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HS Code |
587757 |
| Chemical Name | 2-Aminopyridinecarboxylic acid methyl ester |
| Molecular Formula | C7H8N2O2 |
| Molecular Weight | 152.15 g/mol |
| Cas Number | 55069-50-8 |
| Appearance | White to off-white solid |
| Melting Point | 60-64°C |
| Solubility | Soluble in organic solvents such as ethanol and dichloromethane |
| Smiles | COC(=O)c1ccccn1N |
| Inchi | InChI=1S/C7H8N2O2/c1-11-7(10)5-3-2-4-9-6(5)8/h2-4H,1H3,(H2,8,9) |
| Purity | Typically ≥98% |
| Storage Temperature | Store at 2-8°C |
As an accredited 2-Aminopyridinecarboxylic acid methyl ester factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 2-Aminopyridinecarboxylic acid methyl ester is packaged in a 25g amber glass bottle, tightly sealed for moisture and light protection. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Standard 20-foot containers packed with securely sealed drums or bags of 2-Aminopyridinecarboxylic acid methyl ester. |
| Shipping | 2-Aminopyridinecarboxylic acid methyl ester is shipped in tightly sealed, chemical-resistant containers to prevent moisture and contamination. It should be kept in a cool, dry place and protected from direct sunlight. Appropriate labeling and documentation are provided, and all regulations for transport of specialty chemicals are strictly followed to ensure safety and compliance. |
| Storage | 2-Aminopyridinecarboxylic acid methyl ester should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from sources of ignition and incompatible substances such as strong oxidizers. Protect the chemical from moisture, direct sunlight, and heat. Proper labeling and adherence to local chemical storage guidelines are necessary to ensure safety and product stability. |
| Shelf Life | 2-Aminopyridinecarboxylic acid methyl ester typically has a shelf life of 2 years when stored in a cool, dry place. |
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Purity 98%: 2-Aminopyridinecarboxylic acid methyl ester with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimized impurities in target compounds. Molecular weight 152.15 g/mol: 2-Aminopyridinecarboxylic acid methyl ester with molecular weight 152.15 g/mol is used in medicinal chemistry research, where accurate molar calculations enable precise compound formulation. Melting point 88–91°C: 2-Aminopyridinecarboxylic acid methyl ester with melting point 88–91°C is used in solid-state chemical reactions, where stable handling under mild temperature conditions is achieved. Stability temperature up to 60°C: 2-Aminopyridinecarboxylic acid methyl ester stable up to 60°C is used in storage and transport processes, where product integrity is maintained over time. Particle size <50 µm: 2-Aminopyridinecarboxylic acid methyl ester with particle size <50 µm is used in fine chemical formulation, where rapid dissolution rates and homogeneity are critical. Water content ≤0.5%: 2-Aminopyridinecarboxylic acid methyl ester with water content ≤0.5% is used in moisture-sensitive reactions, where side reactions caused by water are minimized. Refractive index 1.524: 2-Aminopyridinecarboxylic acid methyl ester with refractive index 1.524 is used in analytical detection protocols, where reliable identification and quantification are required. Flash point 138°C: 2-Aminopyridinecarboxylic acid methyl ester with a flash point of 138°C is used in laboratory procedures, where improved handling safety is ensured. |
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Day after day, we face the same question—what truly makes a specialty chemical stand out beyond a line item on an order? Working directly with 2-aminopyridinecarboxylic acid methyl ester, we see the value not just in purity, but in what creative, efficient manufacturing unlocks for the people who rely on it. Sitting in the control rooms, checking reactor temperatures, monitoring the flow of each batch, we develop more than a routine. The feedback flowing from downstream partners drives our next tweaks. Chemistries like this one teach patience, precision, and the art of small improvements.
2-Aminopyridinecarboxylic acid methyl ester models more than a mouthful of functional groups. As a manufacturer, you see how every extra NMR or HPLC run clarifies the path—one methyl group in the wrong place and synthesis stumbles. Here, every decision echoes across volumes, from solvent choices to filtration steps. This compound requires conditions that balance gentle heating against loss of yield—raw observations from tanks, not textbook diagrams, chart the ideal settings. Color, odor, melting point: these aren’t just checks on a list, but clues that guide batch adjustments in real-time.
Stories circulate about exotic intermediates, but only a short list earns loyalty in real-world production. 2-Aminopyridinecarboxylic acid methyl ester hits that tier for its sustained demand in building blocks for pharmaceuticals, especially across heterocyclic frameworks. Step into a customs warehouse or a multipurpose reactor hall. Teams trust this ester to deliver reliable yields when developing APIs, and crisp conversions during scale-up. Its primary amine and methyl ester functionalities allow practical derivatization—no acrobatics, no mystery. In the hands of synthetic chemists, our product provides a predictable springboard, letting process chemists push from bench proofs to metric-ton scales.
Growing up around stainless kettles, you come to respect the reality that high purity in every drum isn’t a happy accident. Trace moisture and rogue isomers can sabotage downstream reactions; costly reworks follow. We don’t default to purity promises either—each lot fights for its numbers. Recrystallizations, distillation passes, tight control of downstream contamination—these define our workflow, not leisurely pursuits of perfection. If a microbatch doesn’t clean up to expectation, the loss hurts, but fixes come fast. In this way, specifications move from abstract values to targets for process control, achievable not by accident, but by design.
2-Aminopyridinecarboxylic acid methyl ester typically leaves our plant as a crystalline solid, white to off-white, with a molecular weight that chemists can rely on. Purity readings above 98%, levels of single-digit ppm moisture, and process traceability matter because users notice the difference on their lines and in their yields. These numbers do not float unattached. Technicians run hands over insulation, adjust flow controllers, and debate the next maintenance window, all with the silent promise that each label means something. These touches back specifications with action, not just forms.
Every year more intermediates crowd the field, vying for a role in early-stage pharma pipelines. Our direct observations show one persistent trend—a compound like 2-aminopyridinecarboxylic acid methyl ester carves out a place by combining manageable reactivity with compatibility in established synthetic methods. Analogous compounds, such as 2-aminopyridine or its acid itself, put more strain on process controls, show moisture instability, or challenge storage. Methyl esterification yields a structure just stable enough to store and ship, yet responsive enough to undergo further chemical transformation without heroic conditions.
Safety is never just paperwork here; it grows from direct handling experience. Working with methyl esters brings a familiar set of risks—volatile organic content, reactive sites, and the ever-watchful need to keep exposure in check. Our team shifts through the protocols for glove selection, fume extraction, and spill response. This eases downstream users’ burden when the product shows up at their door, with SDS and batch records grounded in factory realities, not cut-and-paste safety manuals.
On the phone with a lead process chemist at a pilot plant, frank feedback comes through—yields track batch-to-batch, or an impurity trend surfaces with more concentrated solutions. We don’t trade words to win business; we adjust production parameters, tweak storage conditions, and share minor tweaks to documentation. These calls teach far more than standard QC tests. They shape what comes off the line next week, leveraging real failures to root out preventable variability. Success here is not declared; users make it plain when a batch performs quietly, as expected, linking reliability to confidence in scaling-up critical drug substances.
Pharmaceutical synthesis makes up the lion’s share of demand for 2-aminopyridinecarboxylic acid methyl ester. We get steady orders from teams developing new classes of kinase inhibitors and anti-infective agents. The molecule serves as a sturdy building block for constructing more elaborate heterocyclic architectures. Its adaptability comes not only from the amine’s reactivity—allowing clean coupling or protection-deprotection cycles—but also from the ester group, designed to be transformed under mild or robust hydrolytic conditions. We talk to researchers in labs with a different focus, such as agrochemicals or pigment intermediates, who also use this ester to seed exploratory routes. It earns its keep by offering familiar, predictable reactivity without drama, whether in milligrams or multi-kilogram lots.
Years do not pass uneventfully in the factory. Each batch teaches. Even with an established process map, seasonality creeps in—ambient humidity, minor feedstock impurities, new equipment calibration. Adjustments become routine, like shifting addition times or rebalancing solvent volumes. We keep detailed operational logs because memory fails under pressure, and quietly success rides on remembering last season’s workaround during a cold snap or heat wave. Downstream partners sometimes want tighter specifications or a solvent switch. Instead of static production, we cycle back and try new crystallization techniques or swap drying agents, validating these changes with our actual data, not just theory.
Walking the production floor, you learn shortcuts cost more than they save. We have watched what happens when competitors race to the bottom on price—shortchanged intermediates clog columns, clients lose days tracing errors, and trust evaporates. Real-world penalties for a quick fix teach lessons that auditors never capture in their checklists. Here, investing in materials and maintenance, though it may squeeze margins, preserves client relationships cycle after cycle. Price per kilo fades compared to the real cost of rework, downtime, or, worst of all, a recall.
Demand curves flow and ebb with changing regulations, patent cycles, and chemistry’s shifting frontiers. Ten years ago, most of our batches fed generic drug production. Now, more orders enter from upstart biotechs and research institutes, working on the next line of small-molecule therapeutics. Automation has improved how we monitor and manage runs, but hands-on experience still solves the thorniest issues—nobody trains a sensor to spot the off-smell early in distillation. The real value grows in this blend of lived knowledge and the fidelity of new instruments.
Regulatory rules do not pause for manufacturing convenience. Every year, trace impurities make headlines, and authorities adjust permitted thresholds. We act fast—batch documentation, impurity profiling, and quick turnaround for compliance all become part of the job. Traceability tools, contemporary analytical methods, and a culture of accountability define our response. These practical habits shrink the gap between changing external rules and what leaves our warehouses.
Sustainable production talk fills annual reports, but progress comes down to adjustments in chemistry, utility usage, and waste management. We recover solvents, run energy audits, and send less to the burner each year. Incremental improvements, like changing reaction pH or adjusting catalyst loading, matter more than corporate pledges. People on the line see the difference through lower waste barrels and fewer gas alarms. The win accumulates over years, not quarters.
This methyl ester does not exist in a vacuum. Its job is to serve as a launchpad, letting innovators in medical chemistry, agriculture, and materials science build more complex products with confidence. We see the payoff in new clinical candidates, patent awards, and crop protection advances that draw from foundations like ours. The pride comes not from the molecule itself, but from making visible, reliable progress possible at far ends of global supply chains.
Facing a shelf of similar pyridine derivatives, choice does not hinge on a single trait. Chemists call for performance under defined conditions. One batch may need the faster hydrolysis rate of the methyl ester, another customer takes comfort in long-term stability during summer transports. Storage temperature, solubility limits, and reactivity all drive the calculus, not just on paper but from their historical data. We provide actual batch histories—even noting issues uncovered during stress tests—to let users decide with more certainty, rather than promises that fade under process reality.
Direct communication, not cut-and-paste e-mails, achieves solutions. We stay open to shop-floor visits, custom sample runs, and post-shipment calls questioning every detail. This open channel lets us catch and correct the unexpected slip, or scale up a great finding from one plant to serve another. Spec sheets travel digitally, but real trust builds across years of transparent problem-solving and plain-speaking honesty. Our engineering team, customer support, and delivery drivers all share in the expectation that mistakes happen, but honest correction secures lasting partnerships.
We meet with R&D weekly, comparing new synthetic routes and reviewing supplier feedback. Breakthroughs come when a fresh grad suggests a bolder catalyst swap, or a seasoned foreman points out heat transfer limitations in a key tank. The goal: remove pain-points for downstream users, cut lead times, and keep contaminant levels falling. The motivation is clear—be the source clients return to, not because of inertia, but because they remember every improvement we made at their urging. Gradually, differences between our product and a generic shipment become lessons in manufacturing priorities, not just minor ingredients lists.
Working at the source, responsibility lands heavily. Customers see a finished product, but every bag, drum, and tanker reflects hundreds of decisions rooted in skill, caution, and candid learning. 2-aminopyridinecarboxylic acid methyl ester earns loyalty not from flashy marketing, but from batches that enable repeatable chemistry and minimize interruption. As technology and chemistry continue racing forward, the same ethic persists: do the small things right every day, and both new and long-standing partners benefit in ways that outlast cycles and market fads. Our commitment is measured not by volume moved, but by the steady, unwavering trust of those who rely on what we make. The difference we see between our product and others is not only on the COA, but in the voices of chemists and production managers who build their breakthroughs—from the practicality and reliability sourced at our plant floor.
