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HS Code |
396517 |
| Iupac Name | 2-Acetylpyridine-3-carboxylic acid |
| Molecular Formula | C8H7NO3 |
| Molar Mass | 165.15 g/mol |
| Cas Number | 5460-93-9 |
| Appearance | White to off-white solid |
| Melting Point | 153-156 °C |
| Boiling Point | No data available |
| Solubility In Water | Slightly soluble |
| Density | No data available |
| Smiles | CC(=O)C1=cc=cnc1C(=O)O |
| Pubchem Cid | 2822658 |
| Flash Point | No data available |
As an accredited 3-Pyridinecarboxylic acid, 2-acetyl- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging is a 25-gram amber glass bottle with a secure screw cap, labeled "3-Pyridinecarboxylic acid, 2-acetyl-". |
| Container Loading (20′ FCL) | 20′ FCL container loads 15 metric tons of 3-Pyridinecarboxylic acid, 2-acetyl-, packed in 25kg or 50kg drums. |
| Shipping | `3-Pyridinecarboxylic acid, 2-acetyl-` is shipped in tightly sealed containers to prevent moisture absorption and degradation. It is typically handled as a non-hazardous chemical, but standard precautions should be observed. The package is labeled for laboratory use, with documentation provided for safe handling and storage. Transport follows applicable regulatory guidelines. |
| Storage | 3-Pyridinecarboxylic acid, 2-acetyl- should be stored in a tightly closed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizers. Protect from moisture, heat, and direct sunlight. Ensure proper labeling and access is limited to trained personnel. Store away from food and drink. Use secondary containment to prevent accidental release. |
| Shelf Life | 3-Pyridinecarboxylic acid, 2-acetyl- typically has a shelf life of 2–3 years when stored in a cool, dry, sealed container. |
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Purity 98%: 3-Pyridinecarboxylic acid, 2-acetyl- with 98% purity is used in pharmaceutical synthesis, where it ensures high yield of targeted intermediates. Melting point 156°C: 3-Pyridinecarboxylic acid, 2-acetyl- at a melting point of 156°C is used in organic reactions requiring controlled thermal processing, where it provides consistent phase transition behavior. Molecular weight 163.15 g/mol: 3-Pyridinecarboxylic acid, 2-acetyl- with a molecular weight of 163.15 g/mol is used in analytical method development, where it facilitates precise stoichiometric calculations. Particle size <50 µm: 3-Pyridinecarboxylic acid, 2-acetyl- with particle size less than 50 µm is used in fine chemical manufacturing, where it promotes rapid dissolution and uniform dispersion. Stability temperature up to 110°C: 3-Pyridinecarboxylic acid, 2-acetyl- with stability temperature up to 110°C is used in catalyst formulation processes, where it maintains chemical integrity under reaction conditions. Water content <0.2%: 3-Pyridinecarboxylic acid, 2-acetyl- with water content below 0.2% is used in moisture-sensitive chemical reactions, where it prevents unwanted hydrolysis. |
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Every day on the production line, we handle compounds that serve quietly in the background of countless breakthroughs. Over time, many of our team members have grown closely familiar with 3-Pyridinecarboxylic acid, 2-acetyl-, which many chemists know as 2-acetyl nicotinic acid. With years of experience behind us, we rarely stop to marvel at how a single tweak on a pyridine ring sets the tone for whole new avenues in chemical research, drug synthesis, and material science.
The structure stands out. On the pyridine backbone—a six-membered aromatic ring containing nitrogen—an acetyl group binds to the 2-position and a carboxylic acid rests at the 3-position. Its formula might look modest, but we’ve seen it surprise colleagues with how this arrangement tunes both reactivity and solubility. A shift from the 3-acetyl to the 2-acetyl position changes more than just a number on a label; it sets in motion a different pattern of electron movement across the ring, which guides the compound into niches the 3-acetyl isomer can’t reach.
On our shop floor, we see how accuracy matters. Each batch goes through precise control—white to pale yellow crystalline powder, melting point hovering close to what the theory predicts. Staff check every gram for water content, residual solvent, and purity, making sure the HPLC readings align with typical standards for advanced fine chemicals. Labs and researchers trust us with work that can’t tolerate subpar lots, so extra care goes into filtration, drying, and packaging.
It’s hard to overstate how slight variances in physical appearance signal differences inside. We’ve watched a few experienced chemists run quick tests as soon as the bag opens; a clumpier powder often means residual moisture or solvent. Over years of manufacturing, we’ve fine-tuned drying cycles and blend times to produce a batch that pours clean, with no lumps that frustrate downstream work. And it’s never lost on us how something that looks pure but falls outside impurity targets will later create headaches in synthesis lines.
3-Pyridinecarboxylic acid, 2-acetyl- shows up in dozens of pathways. Medicinal chemists lean on it for more than one reason. The compound forms a solid scaffold for exploring anti-tubercular agents, anti-inflammatory prototypes, and ligands for transition metal complexes. We’ve worked closely with process chemists who value the position of the acetyl group, since it can be easily adjusted without causing side reactions that take weeks to sort out.
In one case, a pharmaceutical project team arrived onsite looking for larger-than-usual quantities. They’d identified 3-Pyridinecarboxylic acid, 2-acetyl- as a starting point for a medicinal chemistry campaign, arguing that the electron-donating effect of the acetyl group sped up acylation steps without triggering unwanted rearrangements. This direct, practical insight drove us to improve our crystallization steps. By reducing batch-to-batch variation, they built their libraries confidently, and we found another reason to keep raising our internal bar.
Away from the intense focus of medicinal chemistry, academic labs order drums for research into metal chelation and catalysis. The specific position of the acetyl group has made this compound preferred for advanced coordination chemistry, letting researchers dial in selectivity for certain transition metals. We get direct feedback from PhD students—sometimes struggling with solubility issues or needing a cleaner crystalline product for NMR studies. Their comments help us see the impact clarity and thoroughness in production make downstream.
A question that often surfaces is why not just use 3-acetyl or 4-acetyl analogs? Over time, we’ve built up a sense for the nuances. With the acetyl on the 2-position, the group sits ortho to the nitrogen atom. This geometric reality changes bond angles and reactivity in a way that’s both subtle and crucial. For instance, it tends to favor chelation to metals in a bidentate manner, unlike the para- (4-) or meta- (3-) acetyl configurations that often act more as spectators in coordination chemistry.
A customer once tested the 3-acetyl version against the 2-acetyl we make, under identical catalytic hydrogenation conditions. The outcome was clear: 2-acetyl made for easier reduction, a cleaner NMR profile, and higher yields. This sort of outcome turns what might have been a marginal decision into a preference for our specific compound.
We’ve also watched how regulatory filings for new drugs scrutinize starting material consistency. A single isomer shift—sometimes less than 1%—can spell hours of test reruns. That’s why the difference between our 2-acetyl derivative and similar-looking products matters. The fine points of its chemical identity have real-world impact that cascades well beyond the initial flask.
Stakeholders expect more than high purity or technical data. They want to know each lot has a paper trail. In our plant, every vessel, drum, and storing area gets barcoded. Technicians log time, cleaning records, and conditions during each critical stage. We never leave it to memory. This obsessive approach comes not just from regulatory necessity, but from the memory of a few close calls early in our history: a single misplaced drum, a record skipped, leading to hours of detective work. We turned those tough lessons into robust daily habits.
Every year, requirements become more precise. End users want to see impurity profiles. For this, we keep a library of historical data from every run, in case something one year seems unusual the next. Chromatograms, spectral files, and full QA notes are never deleted. This tradition builds more than compliance; it helps our team understand our own process drift, and steers planning for improvements.
We see a wide split between customers: some want small, carefully packed bottles; others need bulk drums. Each scale brings its own set of headaches. Small orders leave no room for error—one speck of dust, one mislabeled vial, and a researcher loses precious time. Our staff rotate on these lines not just for variety, but to keep attention sharp.
Scaling up for industrial users, issues change. Powder flow, packing density, drum liners, sealing, and even labeling take center stage. Years ago, a shipment intended for humid zones failed because of a minor packaging flaw. That day, we changed our process, adding more robust desiccant protocols and running environmental stress tests. Every lesson like this hardens our procedures.
It is easy to think that a few milligrams spared here or there do not influence a project. Reality says otherwise. We’ve heard from end users who realized post-hoc that an offhand process tweak upstream changed the outcome of a late-stage reaction. In the world of scientific fabrication, consistency pays the largest dividends.
Over years of making 3-Pyridinecarboxylic acid, 2-acetyl-, our team has also watched how environmental demands grow stricter. Early on, many plants—including ours—struggled not only with safe disposal, but with unintentional leaks or accidental emissions. Some synthesis steps release nitrogenous byproducts, which our scrubber systems now handle swiftly.
Periodic audits push us to new standards. We keep emissions data, monitor water use, and re-invest in both waste water treatment and air quality systems. Not every change brings immediate savings, but over the long term, they save both at the balance sheet and in community relations. Some improvements sprang directly from staff suggestions rather than outside mandates—like our recycled solvent stream, which now accounts for nearly half of our internal cleaning and flushing cycles.
One day, a sharp-nosed operator noticed a slight, persistent odor in the drying room. Later, we found a hairline crack in a gasket, invisible to the eye. Regular team huddles let us surface problems like these quickly, supporting a culture where “good enough” never sets the bar.
Manufacturing rests on people. Our most consistent lots come from teams who have worked together for years. It shows in the way a new staff member asks about the temperature readout on a reactor, in the conversations on the color tint of a fresh batch. Training matters, but so does experience on the shop floor.
We rely less on automation and more on repeated, deliberate practice. A skilled technician will notice the difference between a smooth-flowing batch and a sluggish one, often before instruments register an out-of-spec signal. We depend on these skilled eyes and hands, and it keeps our product at a level where customers rarely call back with a problem.
Our work does not end on shipment. Feedback from academic and industrial researchers helps us understand what truly matters. Many reach out describing unexpected issues: solubility shifts, color variations, or minor impurity peaks. These direct messages bypass vague product questionnaires, cutting straight to the technical heart of real-world chemistry.
We keep a logbook by every production line. Any unusual event, from a slight filter clog to an unexpected batch color, gets noted. Reviewing these logs, we’ve uncovered trends missed by automated systems. Sometimes, a small tweak—pruning a cleaning solvent or varying mixer speed for a few minutes—makes an outsized difference in purity and customer satisfaction.
Every batch presents a chance to improve. Early in our production history, we struggled with minor contamination. Though purity readings fell into spec, some customers still detected background signals in advanced analyses. Direct exchanges with researchers pointed out traces picked up from glassware or earlier process steps. This feedback pushed us to invest in better cleaning protocols, including extra baked-out glassware and the use of non-reactive liners for drums.
Improvements grow through repetition. Over months and years, even small steps toward less carryover, faster drying, or finer granulation multiply returns in satisfaction and cost reduction. Internal team competitions—awarding those who spot process gaps or propose workable improvements—keep ideas fresh and execution sharp.
Over recent years, demand for 3-Pyridinecarboxylic acid, 2-acetyl- has shifted as new fields tap into its reactivity. As anti-infective research heated up, we ramped capacity, running extra shifts and keeping delivery times reliable. This sometimes meant running at the limit of logistics: coordinating with supply chain partners, securing raw materials far in advance, and doubling checks for each outgoing lot.
Some trends rise and fall, but a core segment of research, catalysis, and pharmaceutical development stays steady. New entrants appear every year, often bringing fresh demands for documentation, certification, and process transparency. Our ability to supply repeatable, reliable lots—together with a willingness to share technical background—makes us a valued partner in these competitive spaces.
Each container we pack forms a link in a larger chain of innovation. We feel accountable not only for purity specs, but for the performance and trust that customers build on. A small flaw in a single shipment can derail weeks of work in a partner lab. That reality weighs heavier than any regulatory rulebook.
We keep older bottles from each lot archived, along with full batch records, just in case a query or discrepancy pops up years later. This internal tracking protects users, but also lets us learn when patterns emerge over time. Customers who trust our process continue sending challenging projects our way.
For all the process effort, 3-Pyridinecarboxylic acid, 2-acetyl- earns its keep through the progress it enables. Researchers use it as a step toward new drugs and catalysts that reach actual patients and industry solutions. Our production, no matter how routine it appears, ends up as a foundation for results that resonate beyond plant walls.
Those of us in manufacturing rarely see the headline breakthroughs. We see, instead, the day-to-day reality of precision work. Each batch that ships clean, meets spec, and arrives on time quietly advances hundreds of downstream efforts. We take pride in our role. We know, through customer calls, technical updates, and continual feedback, that our part in manufacturing 3-Pyridinecarboxylic acid, 2-acetyl- supports real, tangible outcomes.
Our work with 3-Pyridinecarboxylic acid, 2-acetyl- continues to evolve. New synthesis routes are under evaluation, aiming at even higher purity, greener outputs, and greater scalability. Research into novel applications for the compound keeps flowing in. As markets change, our plant adapts. Methods toughened by years of trial, feedback, and collaboration reinforce our place as a stable partner in this segment.
We don’t approach manufacturing as a commodity business, despite what outside observers might think. Each product, each batch, and every improvement builds toward a larger purpose: empowering science to move further, faster, and with more certainty. 3-Pyridinecarboxylic acid, 2-acetyl- doesn’t just fill a chemical catalog; it stands as proof that real craftsmanship in manufacturing yields tools for genuine innovation. Scientists, engineers, and researchers rely on details only visible with time and care—the work we commit to with each and every order.
