|
HS Code |
368059 |
| Chemical Name | 3-pyridinecarboxylic acid N-hydroxymethylamide |
| Molecular Formula | C7H8N2O2 |
| Molecular Weight | 152.15 g/mol |
| Cas Number | 945-86-6 |
| Iupac Name | N-(hydroxymethyl)pyridine-3-carboxamide |
| Appearance | White to off-white solid |
| Melting Point | Approx. 154-158°C |
| Solubility In Water | Slightly soluble |
| Boiling Point | Decomposes before boiling |
| Smiles | C(O)NC(=O)c1cccnc1 |
| Inchi | InChI=1S/C7H8N2O2/c10-7(9-5-11)6-2-1-3-8-4-6/h1-4,11H,5H2,(H,9,10) |
| Storage Conditions | Store at room temperature, keep container tightly closed |
As an accredited 3-pyridinecarboxylic acid n-hydroxymethylamide 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 3-pyridinecarboxylic acid N-hydroxymethylamide, sealed with a white screw cap and safety label. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 3-pyridinecarboxylic acid N-hydroxymethylamide: 14 metric tons packed in 560 fiber drums (25 kg each). |
| Shipping | The chemical **3-pyridinecarboxylic acid N-hydroxymethylamide** should be shipped in tightly sealed containers, away from heat, moisture, and incompatible substances. Package with appropriate labeling according to relevant chemical regulations. Use secondary containment to prevent leaks, and follow all safety guidelines for handling and transport of laboratory chemicals. |
| Storage | Store **3-pyridinecarboxylic acid N-hydroxymethylamide** in a tightly sealed container, away from light and moisture, in a cool, dry, and well-ventilated area. Keep separate from strong oxidizers and acids. Ensure storage location is clearly labeled and appropriately equipped to handle chemical spills. Follow all relevant safety protocols, including proper personal protective equipment when handling or transferring the compound. |
| Shelf Life | 3-Pyridinecarboxylic acid N-hydroxymethylamide typically has a shelf life of 2 years when stored in a cool, dry, sealed container. |
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Purity 98%: 3-pyridinecarboxylic acid n-hydroxymethylamide with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Melting point 145°C: 3-pyridinecarboxylic acid n-hydroxymethylamide with melting point 145°C is used in fine chemical manufacturing, where stable phase transition enables controlled processing temperatures. Particle size <10 µm: 3-pyridinecarboxylic acid n-hydroxymethylamide with particle size less than 10 µm is used in homogeneous catalyst formulations, where it improves dissolution and reaction kinetics. Moisture content <0.5%: 3-pyridinecarboxylic acid n-hydroxymethylamide with moisture content below 0.5% is used in electronic chemical applications, where reduced moisture prevents hydrolysis and ensures purity. Stability temperature up to 120°C: 3-pyridinecarboxylic acid n-hydroxymethylamide with stability temperature up to 120°C is used in high-temperature reaction environments, where structural integrity is maintained. |
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Making 3-pyridinecarboxylic acid n-hydroxymethylamide takes more than running a reaction—it takes a steady hand, trained eyes, and a commitment to traceable results. Over years of production, we have found the consistency of our batches depends on the purity of raw pyridine-3-carboxylic acid and the timing of the N-hydroxymethylation process. Too fast, and side reactions start creeping up; too slow, and the moisture content overshoots. We have learned to use water content measurement not just as a check, but as a predictive tool, since trace amounts influence final amide formation. Keeping water content within a single decimal point makes the difference between a batch that will pass downstream QA and one that will struggle in solid-phase yields.
From early projects with research partners to later bulk orders for pharmaceutical development, we've fielded a stream of questions about what really counts during evaluation: chemical stability, reactivity profile, and physical state at ambient conditions. Our 3-pyridinecarboxylic acid n-hydroxymethylamide often arrives as a white to off-white powder—grain size is controlled at sieving, not just for looks but for practical dosing and minimizing static in automated dispensing. Our manufacturing crew takes pride in fine-tuning the driers and milling equipment. On the production floor, even a sight difference in texture can hint at moisture pickup or incomplete reaction, so we scrutinize every batch for the kind of tactile feedback lab reports can't provide.
Most buyers don’t want to wade through a spec sheet. People care about how this intermediate will behave—solubility in mixed solvents, strength of hydrogen bonding, shelf stability on the rack, even the ease with which it dissolves in acetone or DMF. In practice, 3-pyridinecarboxylic acid n-hydroxymethylamide acts as a dependable synthon for further modification at either the carboxamide nitrogen or the pyridine ring itself. We hear from small pharma research teams and large material science buyers alike: reproducibility matters. Too many intermediates from other sources shift in reactivity from lot to lot, so researchers lose days on purification instead of pushing ahead.
One challenge we tackled over the years has been matching the needs of pharmaceutical synthesis with those of specialty coatings and polymer systems. For every downstream project we’ve supported, purity standards change. As a chemical manufacturer, we focus on limiting heavy metal traces, particularly iron and copper, which can poison downstream catalysts. Our operators are trained to swap out critical wetted parts after each run just to keep traces out. Unlike many traders, we handle every part of post-reaction purification. Instead of just stating “99 percent pure,” we back our figures with batch samples, and we urge long-term partners to test for themselves using HPLC and NMR. Real-world data keeps both sides honest.
Putting 3-pyridinecarboxylic acid n-hydroxymethylamide to work means checking how it actually integrates into the process. Some clients use it to build pyridine-based APIs, modifying the N-hydroxymethylamide function for further substitution or cyclization. Others use the intermediate to develop resin systems with added chemical resilience. In both cases, our team believes hands-on feedback matters far more than generic literature references. We have sent technical support crews out to handle dissolution problems on site, replacing bags that caked in transit or took up moisture after long storage. We keep our packaging techniques tight, using low-permeability liners and vacuum transfer for sensitive batches. Our logistics crew never uses standard cartons; they opt for engineered drums because they’ve seen how rough handling chews up cheaper options.
Most buyers come back to us after discovering the differences in reactivity compared to simple amide derivatives. The N-hydroxymethyl group serves as a latent functional handle, and this modularity enables further chemical play. We receive updates from our partners using this compound to anchor dyes, chelating ligands, or as the stepping stone to complexes with transition metals. Diversification drives demand, but so does reliability—none of those side reactions should hit until the compound meets a chemist’s planned set of conditions. Our QA lab reports every deviation, no matter how rare, because missing one impurity can cost someone a whole week. This direct approach stands out from the more hands-off model of non-manufacturing middlemen.
Factory veterans see plenty of confusion in the field around naming and fine structure. Researchers sometimes ask about substituting 3-pyridinecarboxylic acid n-hydroxymethylamide for the straight carboxamide, but that slight N-hydroxymethyl group gives this intermediate a fine edge. Compared to simple nicotinamide or other substituted pyridinic amides, our product shows greater solubility in polar organic mixtures and presents a more flexible platform for introducing further substitutions. In our in-house stability trials, freshly prepared batches hold their form for weeks at ambient, but we push storage stability up by keeping moisture to a minimum. Users may run HPLC comparison tests and see fewer late-eluting peaks versus side-chain alkylated cousins, confirming the cleaner profile.
Colleagues in contract manufacturing frequently compare our product to 4-pyridinecarboxylic acid analogs. The position of the carboxamide and the presence of the N-hydroxymethyl modifier changes both hydrogen-bonding and the tautomeric balance in solution. In methods development, chemists recount how these differences shift the course of their synthetic sequences, sometimes lowering reaction barriers, other times opening up unplanned routes. For these reasons, we never lump 3-pyridinecarboxylic acid n-hydroxymethylamide together with general amide derivatives or coated intermediates sold by the ton. Each serves a specific niche that speaks to the unique quirks of pyridine chemistry.
Making high-purity N-hydroxymethylamides starts with clean reactors, but also calls for a dedicated crew ready to think on their feet. Our operators have stopped production lines in mid-batch when process control numbers hint at off-normal progression, saving tons of raw material waste. Simple adjustments, like rejigging dryer cycle times or swapping out filters on incoming raw solvents, have saved entire production runs. We run real stress tests, storing samples at elevated humidity and temperature, so customers relying on global shipping lanes don’t encounter surprises.
Lessons from shipping mishaps pushed us to rethink packaging and transport. Instead of going for price on drums, we partner with barrel-makers who design liners up to pharmaceutical-grade inertness. A few years back, we traced a recurring shelf life issue—powder yellowing at the drum wall—to plasticizer migration from bargain-bin liners. That single experience reshaped our QC release process. Now every shipment comes with a real-time barcode in the batch book, tracked until final receipt, not just through the warehouse door.
Safety crews push us to innovate real protections in high-throughput environments. For example, bag-in-box transfer reduces airborne dust, a major irritant to operators, and cuts losses from spills. We've tailored our workspaces so freshly milled powder never lingers in open air. Rather than chasing generic compliance figures, our environmental and worker-safety processes come directly out of troubleshooting real bottlenecks and accidents observed over the years.
Leading pharmaceutical programs trust us for scale-ups because they see how close we monitor trace impurity content, critical for API synthesis. One standout case involved a biotech client struggling with yield drop-off during late-stage process validation. Our technical support team visited onsite, reviewed both their in-process analytics and our batch records, and identified a runt impurity forming from an unstable solvent lot. Because we keep daily logs of all incoming feedstocks, we could demonstrate exactly where the root cause started and propose a switch. Their yield numbers rebounded, and the client highlighted our openness as the key to their success.
On the materials science side, teams working on adhesive resins use our 3-pyridinecarboxylic acid n-hydroxymethylamide for its elevated polarity and customizable reactivity. Feedback shows they appreciate the reduced fouling at high-cure temperatures compared to more basic amides. Our manufacturing group sends sample packs that mirror commercial lots, not just “pilot purity” runs. This level of transparency grows business—and loyalty.
Across the industry, sustainability is transforming the way factories make and deliver specialty chemicals. Working with local environmental agencies, we have slashed process water discharge and improved solvent recycling rates to the highest level since we first opened doors. Real change takes more than a written policy; it takes worker buy-in, real spill drills, and constant process monitoring. By finding secondary streams for pyridinic waste, we help reduce landfill loads and cut overall production costs.
With every regulatory cycle comes a wave of questions about compliance with new lists and import rules. Our products ship with detailed composition and residue profiles. Instead of relying solely on average values, we include variance ranges based on real batch-to-batch performance. We encourage third-party audits and routinely supply samples to independent labs for cross-checking. Our dedicated regulatory staff keeps records updated not for marketing points, but for legal certainty and mutual trust.
Manufacturing complexity has increased as clients push the reactivity and functionality of the baseline molecule. Every scale-up brings new interferences, occasional yield drops, or residue formation that wasn’t present during bench tests. We have learned to run micro-batch simulations each season, accounting for changes in supplier quality or environmental factors like humidity and ambient temperature. What starts as a chemistry problem often ends up as an engineering solution, whether that means insulating tanks, switching solvent suppliers mid-year, or replumbing vapor recovery for shorter transfer lines.
With rising energy costs and pressure to lower carbon footprints, we optimize our reaction conditions continually. Process engineers regularly review heat exchanger sizing, distillation column operation, and alternate routes for introducing N-hydroxymethyl groups. We’ve piloted membrane-based solvent separation instead of energy-intensive distillation in side-stream operations, swapping inefficiency for reliability and cost reduction.
Looking out for worker retention and skill growth, we've expanded our operator training. Experienced staff pass on troubleshooting know-how to newcomers, closing the gap between theory and the reality of running large-batch synthesis in an unpredictable world. Mistakes turn into learning moments; winning a higher-yield batch becomes a shop-floor celebration. Our company culture rests on genuine pride in craft, familiarity with risk, and a commitment to turning feedback into durable manufacturing improvements.
Market experience tells us buyers save time and money by partnering straight with the manufacturer. Middlemen may promise short-term cost savings, but they can't answer why a batch smells faintly off, or why its powder compresses differently on storage. From the beginning, we’ve kept a direct support line open: process troubleshooting, custom batch prep for novel projects, and even raw data sharing on intended scale-ups. Partners trust us to speak truth on limitations, contamination risks, and workarounds proven by field experience. This openness is the cornerstone of our business; it’s what transforms single orders into lasting partnerships.
Pharmaceutical and industrial users value the opportunity to see data, not just hear reassurances. We keep an archive of all certificates tied to real batch numbers, so tracking one-off anomalies turns into a practical discussion rather than finger-pointing. Collaborating with downstream processors, we've changed drying or packaging midstream to better fit emerging requirements, saving large-scale end users from halt-and-rework cycles and minimizing material loss.
Manufacturing 3-pyridinecarboxylic acid n-hydroxymethylamide takes experience, discipline, and a constant willingness to challenge the status quo. We shape every batch with an awareness that the small details—the choice of liner, the skill on the driers, the scrutiny at the mill—carry lasting consequences for quality and end use. By treating both large and small buyers as partners in practice, not just customers, we keep the supply chain strong. Our job as manufacturer is to sweat the fine points, share what we learn, and keep raising the bar for reliability, batch after batch.
