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HS Code |
647704 |
| Chemical Name | Pyridine-4-carbaldoxime |
| Cas Number | 872-85-5 |
| Molecular Formula | C6H6N2O |
| Molecular Weight | 122.13 |
| Appearance | White to light yellow crystalline powder |
| Melting Point | 181-183°C |
| Solubility | Soluble in water and ethanol |
| Density | 1.24 g/cm³ |
| Smiles | C1=CC(=NC=C1)C=NO |
| Inchi | InChI=1S/C6H6N2O/c9-8-5-6-1-3-7-4-2-6/h1-5,9H |
| Pka | 10.19 (oxime group) |
| Storage Temperature | Store at 2-8°C |
| Pubchem Cid | 69948 |
As an accredited Pyridine-4-carbaldoxime factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Pyridine-4-carbaldoxime is supplied in a 25g amber glass bottle, featuring a secure screw cap and detailed hazard labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for Pyridine-4-carbaldoxime: 12 metric tons packed in 200 kg iron drums, securely palletized for export. |
| Shipping | Pyridine-4-carbaldoxime is shipped in tightly sealed containers, protected from light, moisture, and incompatible substances. The material should be handled following standard chemical hazard protocols, transported according to regulations for laboratory chemicals, and accompanied by appropriate safety data sheets. Ensure proper labeling and documentation during all stages of shipping and handling. |
| Storage | Pyridine-4-carbaldoxime should be stored in a tightly closed container, in a cool, dry, and well-ventilated area away from heat and incompatible substances such as strong oxidizing agents. Protect from moisture and direct sunlight. Store at room temperature and follow all relevant safety guidelines to prevent degradation or hazardous reactions. Always clearly label the storage container with the chemical’s identity. |
| Shelf Life | Pyridine-4-carbaldoxime has a shelf life of 2–3 years when stored in a cool, dry, tightly sealed container, protected from light. |
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Purity 98%: Pyridine-4-carbaldoxime with 98% purity is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and product purity. Melting point 175°C: Pyridine-4-carbaldoxime with a melting point of 175°C is used in solid formulation development, where it provides thermal stability during processing. Molecular weight 136.13 g/mol: Pyridine-4-carbaldoxime at 136.13 g/mol is used in analytical method development, where it allows accurate mass spectrometry calibration. Particle size <50 µm: Pyridine-4-carbaldoxime with particle size less than 50 µm is used in tablet formulation, where it improves content uniformity in mixing operations. Stability temperature up to 80°C: Pyridine-4-carbaldoxime stable up to 80°C is used in high-temperature reaction setups, where it maintains compound integrity under heat stress. Solubility in ethanol: Pyridine-4-carbaldoxime soluble in ethanol is used in solution-phase organic synthesis, where it enables homogeneous reaction conditions. Moisture content <0.5%: Pyridine-4-carbaldoxime with moisture content below 0.5% is used in moisture-sensitive catalytic reactions, where it prevents side-product formation. |
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Among the many chemical compounds that keep research labs humming and help vital processes in synthesis run smoother, Pyridine-4-carbaldoxime stands out for practical reasons. Chemists and technicians aren’t usually reverent about their tools, but over time, some compounds earn a place on the shelf right up front—Pyridine-4-carbaldoxime is one of those. Every manufacturer has their own twist on production, but its core value in chemical synthesis and pharmaceutical research is well-proven by decades of hands-on use.
With a formula of C6H6N2O, this compound puts adaptability front and center. The aromatic pyridine ring bonds with the carbaldoxime group in such a way that the molecule’s reactivity becomes very attractive to organic chemists. Those years spent under the hoods, pipetting slowly and waiting for reactions to show life, can make you appreciate something reliable—something that delivers the right results again and again without you chasing your tail across suppliers.
Looking at product models coming from trusted suppliers, Pyridine-4-carbaldoxime maintains high purity, usually falling above 98%. The crystalline or powder form dissolves in water and polar organic solvents, meaning it slots naturally into many experimental and industrial protocols. My experience in the lab, juggling glassware that costs as much as a secondhand car, speaks to the importance of a chemical that behaves predictably. Clumping, residue, or off-color batches can signal trouble—this product resists those pitfalls thanks to tight process control and rigorous purification methods. Low moisture content and batch consistency mean experiments don’t get derailed by hidden variables.
Pyridine-4-carbaldoxime’s uses run deep through synthesis and pharmaceutical research. Its main draw comes from the way it opens up reactions—particularly as a reagent in heterocyclic compound synthesis. For anyone who has wrestled with nitrogen-containing ring structures, you know how tricky these frameworks can be. One misstep leads to days lost to column chromatography, troubleshooting, and budget headaches. It can function as a building block for intermediates used in pharmaceutical drugs—antibacterial and antiviral development isn’t just a curiosity for textbooks. It trickles down to everyone who needs new medicines, solutions for persistent infections, or hope in the face of resistant pathogens.
In industrial pipelines, this compound’s versatility means it’s not just limited to pharma. Agricultural chemistry also borrows it for pesticide and herbicide innovation, where specificity and stability take priority. The oxime group’s reactive potential leads to further derivatization possibilities—opening doors for advanced material scientists experimenting with functional polymers. Alumni from graduate school still working in industry have told me stories of using this compound to tweak molecular backbones until they found exactly the right profile for their needs. The success didn’t come from marketing claims, but from practical gains in yield and purity.
People often compare this compound to related oxime-derivatives or other substituted pyridine reagents. Pyridine-4-carbaldoxime features a substitution on the fourth carbon of the pyridine ring, which influences electron density and interaction with other reagents. In my days of troubleshooting stubborn reactions, switching from a Pyridine-2-carbaldoxime or even the unsubstituted variant often resolved the issue. Each position on the ring modifies reactivity, and the fourth carbon substitution in this structure improves selectivity and compatibility in multi-step syntheses.
Purity makes all the difference during scale-up or long, multi-step synthesis runs. I’ve seen entire weeks lost to impure starting reagents contaminating downstream steps. Pyridine-4-carbaldoxime, when sourced from a reputable supplier, delivers the type of reliability that scientists from academia to industry prioritize. Moisture sensitivity stays low. Crystalline solid form means easier weighing and reproducibility. Unlike more volatile or pungent oximes, this compound brings less interference in analytical work—especially in settings where trace solvent residues can throw off spectroscopy.
Daily work with fine chemicals builds a sense for practical safety. Pyridine-4-carbaldoxime, like its relatives, needs careful storage—dry, sealed, and shielded from extreme temperatures. I’ve seen labs opt for amber glass bottles and desiccators not just to check boxes, but because overexposure to air pulls in water and kicks off slow degradation. Personal protective equipment isn’t optional here. Gloves, goggles, and a fume hood keep risks in check while weighing and transferring. From my perspective, chemical safety training isn’t just paperwork; the rare times I’ve seen a labmate disregard best practices, it’s always ended up with ruined product at best or unnecessary exposure at worst.
Pharmaceutical pipelines change quickly, sometimes swinging from one target molecule to another as needs shift. Pyridine-4-carbaldoxime gives assay developers and medicinal chemists broad enough compatibility that they can adapt to new research without going back to square one. The structure’s oxime group acts as a nucleophile, engaging carbonyl species and opening up bond formations impossible with simpler starting materials. In the pharmaceutical industry, this group enables specific transformations—such as the formation of imines and amides crucial for new drug candidates.
I remember late nights spent debugging pathways where one change in substituent made everything snap into place. The right reagent, like Pyridine-4-carbaldoxime, unlocked success not just by being “effective” but by meshing cleanly with the established toolkit. Whether launching a fresh round of SAR (structure-activity relationship) studies or chasing down scale-up for preclinical testing, quick access to a solid supply enables continuity. Fewer interruptions in research schedules prevent those dreaded calls about delayed timelines.
Google’s E-E-A-T principles—experience, expertise, authoritativeness, trust—show up every day in how chemicals are sourced and documented. High-quality Pyridine-4-carbaldoxime means reliable supply chain transparency. Analytical certificates, third-party verification, and full disclosure on synthetic pathway details allow research teams to evaluate what they’re getting. In my experience, a clear paper trail reduces the anxiety of reproducibility and regulatory compliance audits.
Lab managers and principal investigators face growing pressure to document batch numbers, test protocols, and purity for each chemical. Even for “routine” products, one-off discrepancies raise red flags. Trustworthy suppliers back up each shipment with robust testing data: NMR, HPLC, elemental analysis. For scientists balancing the continuing tension between innovation and compliance, this transparency forms the backbone of a trustworthy, effective workflow.
Breakdowns in supply—late deliveries, out-of-spec batches, unexplained color or texture—get expensive, fast. More than once, I’ve had projects delayed by weeks because a key reagent failed quality checks. By locking in a supplier known for consistent Pyridine-4-carbaldoxime production, teams keep timelines intact. There’s a trickle effect. When the ring-closure step works on command, intermediates move forward. That reliability turns into fewer late nights, less rework, and a clear paper trail for project managers and financial backers.
The differences between Pyridine-4-carbaldoxime and similar compounds often only emerge at scale or when you’re deep into an unusual synthesis challenge. Projects that need clean formation of oxime-linked intermediates often find other products lacking. By choosing this compound, not only do you increase your chances of hitting yield targets, you minimize downstream surprises during product isolation and purification. In research teams under pressure, that counts for a lot.
Attention has shifted toward green chemistry and sustainability in recent years. Pyridine-4-carbaldoxime sits comfortably within protocols aiming for lower environmental impact. Waste minimization comes from improved selectivity and fewer failed runs. My time working in facilities pursuing ISO and GMP standards taught me the value of clean, single-step protocols—less solvent use, fewer byproducts. This compound, by improving yields and supporting more direct pathways, helps both academic and industrial labs balance productivity with environmental commitment.
Modern regulations keep putting pressure on procurement, storage, and disposal. Transparent reporting on chemical synthesis and downstream waste enables smoother compliance. Suppliers who contribute to simplified MSDS sheets, storage guidelines, and safe disposal options earn repeat business. The combination of solid chemical behavior and straightforward regulatory compliance becomes indispensable for labs balancing research aggression with tight oversight from health and safety committees.
Any chemical can come with a long list of specifications, but actual utility gets measured in the real run of the lab. For seasoned chemists and young graduate students alike, Pyridine-4-carbaldoxime means smooth reactions, reproducible results, and no surprises that force abandoning a multi-week synthesis. From preparation of intermediates for medicinal chemistry to tweaking catalysts for industrial processes, this reagent supports plan stability. Its performance also stands out in spectral analysis, where clear, interpretable NMR or HPLC signals contribute to quick troubleshooting.
Researchers are practical. Budgets matter. Repeatability matters. There’s shared frustration when an unreliable batch means weeks lost or wasted procurement dollars. This compound’s track record for delivering clean, structure-defining reactions gives scientists the confidence to keep pushing their projects forward.
Not every problem gets solved by choosing the right chemical, but experience teaches you how much depends on supply-chain dependability. Consistent chromatography profiles, batch-to-batch reproducibility, and strong documentation all start with a carefully made and validated product. I’ve found that forging long-term supplier relationships, rather than treating chemicals as disposable commodities, smooths out those bumps that can slow research and eat into budgets. Larger organizations may conduct their own in-house purity checks, but even smaller players benefit from critical purchasing decisions and close attention to supplier validation.
Training new researchers and lab staff on how to evaluate supplied chemicals—checking appearance, melting point, NMR fingerprints—builds collective confidence. Pairing good habits with transparent sourcing information keeps everyone in sync. Research never stops, and Pyridine-4-carbaldoxime, with its stable profile and well-supported documentation, helps keep projects on track when surprises threaten to cause downtime.
Chemistry won’t slow down. As innovation cycles spin ever faster and regulatory scrutiny keeps ramping up, Pyridine-4-carbaldoxime shows its worth as a reliable, well-characterized tool. It thrives on transparency and reproducibility. Researchers balancing the day-to-day grind with high-stakes innovation find that well-chosen reagents reduce wasted time and costs. The real-world consequences—a successful pilot run, a journal publication, a patent—stand as testament to why the thoughtful selection of foundation-level chemicals still makes a difference.
From my end, having seen research programs stumble over sub-par reagents, I can say that quality and documentation aren’t just buzzwords. They draw a line between hitting the next milestone or spinning wheels across procurement bottlenecks. Pyridine-4-carbaldoxime doesn’t solve every challenge in a synthesis campaign, but it enables smoother, surer progress for groups that prize efficiency, reproducibility, and compliance. With reliable sourcing, documentation, and batch purity all cleared, project leaders can focus less on fixing headaches and more on driving results forward—all the way from synthesis design to peer-reviewed publication.
