|
HS Code |
156845 |
| Chemical Name | Pyridine-3-carboxamide oxime |
| Cas Number | 1007-26-7 |
| Molecular Formula | C6H7N3O |
| Molecular Weight | 137.14 g/mol |
| Appearance | White to off-white crystalline powder |
| Melting Point | 172-175°C |
| Solubility In Water | Moderately soluble |
| Boiling Point | Decomposes before boiling |
| Pubchem Cid | 11980 |
| Inchi | InChI=1S/C6H7N3O/c7-6(10)4-2-1-3-8-5(4)9/h1-3,9H,(H2,7,10) |
| Smiles | C1=CC(=CN=C1C(=O)N)N=O |
| Synonyms | 3-Pyridinecarboxamide oxime, Nicotinamide oxime |
| Density | 1.28 g/cm3 |
| Storage Conditions | Store in a cool, dry place |
As an accredited PYRIDINE-3-CARBOXAMIDE OXIME factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | PYRIDINE-3-CARBOXAMIDE OXIME is packaged in a 25-gram amber glass bottle with tamper-evident seal and clear labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Securely packs Pyridine-3-Carboxamide Oxime in sealed drums or bags, optimizing space and ensuring safe international transport. |
| Shipping | PYRIDINE-3-CARBOXAMIDE OXIME is shipped in tightly sealed containers to prevent moisture and contamination. The chemical is packaged in accordance with relevant safety regulations and labeled appropriately for handling. During transit, temperature and stability requirements are maintained to ensure product integrity. Standard shipping documentation and Material Safety Data Sheets (MSDS) are provided. |
| Storage | **PYRIDINE-3-CARBOXAMIDE OXIME** should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area, away from direct sunlight and sources of ignition. Keep it isolated from incompatible substances such as strong oxidizing agents. Proper labeling and access control should be maintained, and personal protective equipment should be used when handling the compound to ensure safety. |
| Shelf Life | Shelf life of pyridine-3-carboxamide oxime is typically 2–3 years if stored tightly sealed in a cool, dry, dark place. |
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Purity 99%: PYRIDINE-3-CARBOXAMIDE OXIME with purity 99% is used in pharmaceutical synthesis, where it ensures high yield and minimized impurity formation. Molecular weight 137.12 g/mol: PYRIDINE-3-CARBOXAMIDE OXIME with molecular weight 137.12 g/mol is used in analytical reagent preparation, where accurate stoichiometry in reaction design is achieved. Melting point 168°C: PYRIDINE-3-CARBOXAMIDE OXIME with a melting point of 168°C is used in solid-state formulation studies, where it provides thermal stability during processing. Particle size <50 μm: PYRIDINE-3-CARBOXAMIDE OXIME with particle size less than 50 μm is used in homogeneous blending for tablet manufacturing, where enhanced dissolution rates are realized. Stability temperature up to 120°C: PYRIDINE-3-CARBOXAMIDE OXIME with stability temperature up to 120°C is used in chemical intermediates production, where it maintains reactivity under controlled thermal conditions. Water solubility 12 g/L: PYRIDINE-3-CARBOXAMIDE OXIME with water solubility of 12 g/L is used in aqueous-phase catalysis, where consistent substrate availability is maintained. Appearance white crystalline powder: PYRIDINE-3-CARBOXAMIDE OXIME as a white crystalline powder is used in laboratory assay development, where visual confirmation and purity assessment are facilitated. Assay by HPLC ≥98%: PYRIDINE-3-CARBOXAMIDE OXIME with HPLC assay ≥98% is used in custom chemical synthesis, where reliable composition consistency is required. |
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In a crowded world of organic chemicals, PYRIDINE-3-CARBOXAMIDE OXIME doesn’t always steal the spotlight. It quietly fills an important gap in synthetic chemistry and pharmaceutical production. To understand why people from diverse sectors care about this compound, just think about the way it connects challenge and possibility: it’s a bridge, not an endpoint. Those in labs, pharmacies, and manufacturing plants recognize that some molecules just unlock doors others only knock on.
PYRIDINE-3-CARBOXAMIDE OXIME stands out due to its distinct functional group: the oxime. This group means more than just a small tweak of a carbon chain—it opens up reactivity for very specific transformations. Synthesis teams rely on such features for building blocks that drive bigger, costlier reactions. Each time someone needs to move past the limits of stock chemicals, molecules like this make new targets approachable.
This isn’t just academic. Over the last decade, oxime derivatives have played an instrumental role in medicinal chemistry innovation. They show up in everything from enzyme inhibitors to molecules designed to bind tricky protein targets. Even outside of pharma, oximes often help stabilize other molecules or protect sensitive parts from overreacting in a big soup of reagents.
Purity matters. Anyone who has spent hours troubleshooting reactions knows that a poorly purified batch can mean the difference between success and wasted time. Industry standards for PYRIDINE-3-CARBOXAMIDE OXIME usually demand high purity—think 98% plus. What this really means is fewer headaches later. Less effort filtering out unknowns, cleaner signals under NMR, reproducible yields. Most reputable suppliers produce it as a solid, often as a white to off-white powder. It dissolves in solvents like water, ethanol, and some chlorinated hydrocarbons, which helps chemists play around and fine-tune it in living systems or harsh chemical baths.
Once upon a time, in university labs and industrial sites, I watched people struggle with hygroscopic substances, powders that clumped at the slightest whiff of humidity. PYRIDINE-3-CARBOXAMIDE OXIME rarely brings those complaints. It stores easily at standard cold-room temperatures. The lack of fuss—no need for vacuums or dry boxes—makes it approachable while cutting down on specialty storage costs. The crystalline structure also handles routine mixing, weighing, and solution prep without much physical breakdown.
Compared to closely related molecules, which sometimes bleed sticky oils or give off biting odors, this compound’s stable, solid-state helps researchers focus on results rather than constant lab-cleaning or wasted solvent. People who understand the realities of industrial scale-up appreciate these details. Minor differences in ease-of-use snowball into measurable savings across weeks or years.
Organic chemistry students spot oximes in textbooks for their role in the Beckmann rearrangement. In practice, PYRIDINE-3-CARBOXAMIDE OXIME demonstrates just how much versatility lies in this simple transformation. Medicinal chemists value it as a core intermediate: the compound provides a clean template to attach different chemical “arms” that search for biological activity. Here, the N-oxime functional group opens up further choices, letting teams attach, swap, or remove substituents using old-school and modern catalytic methods alike.
Researchers pushing forward antimicrobial or anti-inflammatory agents come back to pyridine-based scaffolds again and again. SAR (structure-activity relationship) studies often start with libraries built around solid, accessible molecules like this one. In one study I worked on, swapping in oximes on a pyridine ring changed the binding affinity by two orders of magnitude—a result you’d miss if you restricted yourself to classic carboxamides or simple hydrazides. Publication after publication points to the value of oximes for bypassing certain metabolic deactivation pathways as well.
Material science isn’t left out, either. PYRIDINE-3-CARBOXAMIDE OXIME slips into coordination chemistry, forming bite-sized ligands for exploratory catalysis. With the push in green chemistry for more sustainable, less expensive transition-metal catalysts, this unassuming compound now finds new fans among those designing earth-abundant metal complexes. Its specific binding properties also allow it to serve as a probe for detecting trace metals—a trick leveraged in both industrial quality control and environmental labs.
Anyone who has compared catalogues knows it’s easy to get lost in a sea of similar names. So, what gives PYRIDINE-3-CARBOXAMIDE OXIME real value? It comes down to how it stacks up to alternatives like PYRIDINE-2-CARBOXAMIDE OXIME or substituted pyridine rings. Every lab learns, sometimes the hard way, that a single ring-position shift can throw synthetic strategies out the window. With the 3-position carboxamide oxime, reactions involving nucleophilic attack or coordination to metals show different selectivity and strength compared to 2- or 4-position molecules. This means more than trivia. For process chemists scaling up, saving just a few percent yield, or hitting the right crystallinity for final product isolation, can mean a project’s success or shelving.
For novice chemists, the apparent similarity between these molecules invites shortcuts that often end in frustrating detours. In my experience, time saved at the ordering desk rarely balances time lost in the purification column if you pick the “almost right” compound. PYRIDINE-3-CARBOXAMIDE OXIME earns its keep when you want specific reactivity, especially in the face of subtle challenges in selectivity or crystallization.
Over the last five years, sourcing trends have shifted. Global supply disruptions and increased scrutiny on upstream chemicals remind buyers to check the origins and manufacturing robustness behind each compound. With PYRIDINE-3-CARBOXAMIDE OXIME, established supply lines and a relatively straightforward synthesis keep it competitive. The most consistent sourcing comes from suppliers who not only list purity specs but also provide data on trace metal content and batch-to-batch reproducibility. Ask around long enough, and you’ll hear horror stories about inconsistency hurting whole project timelines.
To this day, I recommend that buyers look for supply partners with solid documentation practices. A well-maintained certificate of analysis, genuine chromatograms, real spectra—these details count when you’re troubleshooting an ambiguous mass spec result, or validating a patent claim. Trusted suppliers have little to hide and can back up their paperwork quickly. Regulatory compliance and transparent batch records go far in reassuring both team members and regulators, especially in high-stakes pharmaceutical projects.
Price tags tempt. In an effort to stay within budget, decision makers often sacrifice a few points of purity or documentation. That trade-off bites back, especially when moving from gram-scale experiments in the university lab to kilo-scale production in industry. In situations I’ve seen, murky batch records or minor contaminants caused costly shutdowns and weeks of revalidation. The initial price difference usually vanishes in the face of lost time and labor.
That said, PYRIDINE-3-CARBOXAMIDE OXIME remains an affordable workhorse. Most leading suppliers price in alignment with similar small-molecule intermediates, without an undue markup compared to analogs. The cost benefits become obvious once you factor in its ease of storage, low humidity sensitivity, and consistent handling properties, all of which reduce hidden labor and storage costs across a production cycle.
Safety in laboratories and plants often revolves around the strict handling rules set by a compound’s volatility, toxicity, and persistence in the environment. PYRIDINE-3-CARBOXAMIDE OXIME presents as a relatively manageable substance. All chemicals deserve respect, but this compound rarely draws special hazard attention compared to more volatile pyridine derivatives or oxime hydrochlorides. Users report mild to moderate irritation with accidental exposure—gloves and eye protection are basic protocol. The material’s low dustiness reduces accidental inhalation risks, especially in comparison to ultra-fine powders that float and linger in the air.
Disposal is governed by local regulations regarding nitrogen heterocycles, but in most jurisdictions this molecule doesn’t count as especially dangerous waste. For large-scale disposal, trusted vendors and recycling programs make it possible to track waste from cradle to grave, preventing environmental headaches down the road. Reports from environmental monitoring show low environmental accumulation given prompt, controlled disposal.
In a push for greener chemistry, some manufacturers are exploring bio-based or catalytic routes to synthesize pyridine oximes. Should these methods move from pilot plant to mainstream production, the carbon footprint and hazardous waste profile of PYRIDINE-3-CARBOXAMIDE OXIME could improve even further, aligning with global moves toward sustainable process chemistry.
You learn quickly that no two synthesis runs ever follow the textbook. PYRIDINE-3-CARBOXAMIDE OXIME offers peace of mind for newcomers and pros alike. Organic chemists compliment the ease of reaction monitoring—TLC, HPLC, and LC-MS tracking prove straightforward, thanks to strong UV absorbance and clear chromatographic separation. In scale-up plants, the compound behaves predictably in both batch and flow processes, with few surprises related to decomposition or isomer formation.
Medicinal chemists appreciate that its aromatic pyridine core resists unwanted photolytic changes, a key advantage when storing samples over months. Biologists who work with low-dose screens spot less false positive interference compared to some more “interactive” analogs that tend to engage protein targets broadly and unpredictably. These on-the-ground endorsements tell a more honest story than marketing material ever could.
Students and early-career scientists coming to grips with multipurpose heterocycles often trip up on practical details. The best resources blend catalog data with genuine testimonials. Some plant chemists note that filtration runs smoothly, while process engineers say heating and cooling cycles haven’t crashed yields through decomposition or side product formation. Teaching labs appreciate its limited odor profile—a small but important win for maintaining a pleasant learning environment.
Mentoring undergraduate students through mixed unknowns, I’ve watched them start anxious and end the semester with confidence, thanks to simple, reliable chemicals like PYRIDINE-3-CARBOXAMIDE OXIME. These experiences build lifelong comfort with more advanced and finicky analogs down the road. Familiarity with small differences at the molecular level pays off for those moving from basic coursework to advanced research or process development roles.
Though PYRIDINE-3-CARBOXAMIDE OXIME might look like a solved problem, its core chemistry inspires ongoing research. Teams studying new catalysts or next-generation therapeutic scaffolds churn out patents and preprints building off this structure. As drug discovery moves into ever-tougher territory—targeting protein-protein interactions, breaking resistance pathways—demand rises for robust, flexible chemical families.
Innovation isn’t always splashy; steady progress depends on access to chemical “reliable gear.” As machine learning and AI tools predict new targets and chemical combinations, foundational blocks like this one grow ever more essential. Demand for transparency, traceability, and sustainable chemistry will likely steer producers toward greener process improvements, stronger documentation, and tighter analytical controls.
Small- and mid-sized biotech startups especially will bank on ready access to high-purity intermediates, since their limited budgets encourage smart, reliable choices up front. Expect to see more collaborations across supply chain partners, as parties large and small move to meet regulatory scrutiny with hard analytical data, not just promises.
Looking at the global market, three fronts stand out for improvement: analytical reliability, environmental sustainability, and transparent supply lines. No single entity solves these overnight, but coordinated goals help avoid repeating mistakes of the past.
Better batch analytics start with robust quality control. Chromatographic purity isn’t enough—labs benefit from expanded NMR panels, trace metal analyses, and full spectral libraries. Motivated suppliers who invest in these areas build trust, saving time and money for their partners.
To answer calls for greener chemistry, some companies tweak their processes for lower emissions and less hazardous byproducts. Whether through novel catalysts, alternative solvent systems, or recycling programs, incremental improvements make measurable differences as adoption becomes widespread.
For the buyer, due diligence matters. Open conversation between production, procurement, and downstream users ensures that unmet needs get addressed before small inconveniences turn into deal breakers. Buyer-supplier partnerships, not adversarial negotiations, set the stage for long-term productivity.
In the end, PYRIDINE-3-CARBOXAMIDE OXIME represents more than just a catalog row or a chemical name. For practitioners, it’s a steady hand in the unpredictable world of chemical reactions and research deadlines. Well-made, well-documented building blocks propel innovation, reduce frustration, and help scientists learn from each experiment. Whether in the hands of a budding student or a veteran in process development, a reliable compound makes all the difference. The story of PYRIDINE-3-CARBOXAMIDE OXIME illustrates how progress comes from molecules as much as ideas—from proven tools, well used, by people who demand more from their materials every day.
