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HS Code |
797987 |
| Compound Name | 3-Pyridinecarboxamidoxime |
| Chemical Formula | C6H7N3O |
| Molecular Weight | 137.14 g/mol |
| Cas Number | 35556-70-8 |
| Iupac Name | N'-hydroxy-3-pyridinecarboximidamide |
| Appearance | White to off-white powder |
| Melting Point | 210-214°C |
| Solubility In Water | Moderate |
| Smiles | C1=CC(=CN=C1)C(=N)NO |
| Storage Conditions | Store at room temperature, dry and away from light |
| Pubchem Cid | 164661 |
| Synonyms | 3-Pyridylamidoxime |
As an accredited 3-PYRIDINECARBOXAMIDOXIME factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 100g quantity of 3-PYRIDINECARBOXAMIDOXIME is supplied in a sealed amber glass bottle with a secure screw cap and safety labeling. |
| Container Loading (20′ FCL) | For 3-PYRIDINECARBOXAMIDOXIME, a 20′ FCL typically holds about 10–12 metric tons, packed in fiber drums or HDPE barrels. |
| Shipping | 3-Pyridinecarboxamidoxime should be shipped in tightly sealed containers, clearly labeled with hazard information. The packaging must comply with relevant chemical transport regulations. Protect from moisture, heat, and incompatible substances. Ship via approved carriers for chemicals, ensuring appropriate documentation and safety data accompany the shipment to guarantee safe handling and legal compliance. |
| Storage | 3-Pyridinecarboxamidooxime should be stored in a tightly sealed container, protected from light, moisture, and incompatible substances such as strong oxidizers and acids. Store at room temperature in a cool, dry, well-ventilated area dedicated to chemicals. Ensure proper labeling and avoid sources of heat or ignition. Keep out of reach of unauthorized personnel and follow all local safety regulations. |
| Shelf Life | 3-PYRIDINECARBOXAMIDOXIME typically has a shelf life of 2 years when stored in a cool, dry place, protected from light. |
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Purity 98%: 3-PYRIDINECARBOXAMIDOXIME with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high product yield and batch-to-batch consistency. Molecular weight 137.13 g/mol: 3-PYRIDINECARBOXAMIDOXIME with molecular weight 137.13 g/mol is used in organic ligand design, where it promotes predictable coordination chemistry for metal-complex formation. Melting point 132°C: 3-PYRIDINECARBOXAMIDOXIME with melting point 132°C is used in solid-phase extraction, where it improves process efficiency due to its thermal stability. Particle size ≤50 μm: 3-PYRIDINECARBOXAMIDOXIME with particle size ≤50 μm is used in heterogeneous catalysis, where it enhances surface area contact and catalytic activity. Stability temperature up to 120°C: 3-PYRIDINECARBOXAMIDOXIME with stability temperature up to 120°C is used in chemical analysis workflows, where it maintains structural integrity during processing. Analytical grade: 3-PYRIDINECARBOXAMIDOXIME of analytical grade is used in chromatographic standards preparation, where it provides high purity and reduces background interference. Solubility in water 12 mg/mL: 3-PYRIDINECARBOXAMIDOXIME with solubility in water 12 mg/mL is used in aqueous reaction systems, where it enables efficient dissolution and homogeneous mixing. Storage condition 2–8°C: 3-PYRIDINECARBOXAMIDOXIME stored at 2–8°C is used in research reagent storage, where it preserves compound potency and minimizes degradation. |
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For anyone who has spent time peering through spectrophotometer readouts or wrangling with complex reaction pathways, a new reagent on the shelf can feel like an old friend showing up with a fresh idea. 3-PYRIDINECARBOXAMIDOXIME is the sort of specialty compound that grabs attention, not only for its mouthful of a name but for the practical punch it packs in the lab.
This molecule, built around a pyridine ring decorated with a carboxamidoxime group, offers a balance between stability and reactivity. At a glance, structure matters—those with hands-on experience know that even a small tweak to a molecular backbone can make or break a project. Here, the placement at the third carbon of pyridine gives this compound some unique strengths compared to its isomers or to related amidoximes.
Chemists searching for reliable ligands or tailored intermediates often find themselves hemmed in by issues of solubility, accessibility, or cleanup headaches. Over the years, I’ve seen too many reactions fizzle out because a reagent refused to cooperate on even the most basic fronts—3-PYRIDINECARBOXAMIDOXIME comes with a track record that speaks to its practical side. It dissolves efficiently in most common organic solvents, keeping benchwork moving at a pace. In contrast, similar compounds sometimes gum up reactions due to excessive polarity, or they demand special handling under nitrogen just to stay stable. Here, you’re working with a product that respects the pace of modern research.
Don’t underestimate the difference that reliable shelf life brings. Moisture and air sensitivity tend to drive costs up and lab stress higher—after all, nobody enjoys ducking into the glove box for every step. This compound remains stable when stored in standard containers at room temperature, showing that sensible design in synthesis can save hours and keep budgets intact. That sort of predictability builds trust among teams, whether you’re screening compounds for medicinal potential or mapping out new routes in dye chemistry.
Purity is a sticking point in many stories I’ve heard from colleagues across pharmaceutical R&D and advanced materials. Impurities in intermediate stages can silently derail scale-up or cause trouble in analytical validation. Most 3-PYRIDINECARBOXAMIDOXIME on the market regularly tests above 98% purity by HPLC, which cuts out much of the troubleshooting that comes with side reactions. Batch-to-batch consistency also matters; a reliable supplier provides not only high purity but also a narrow melting point range and clear spectral authentication (NMR, IR).
Granular white to off-white powder is the norm—it does not cake up in the bottle or degrade with standard storage. Since I started cataloging synthetic mishaps in my early career, there’s rarely been such a clear line between progress and setback as the presence of trace moisture or breakdown products. This compound’s resilience makes it a mainstay for routine weighing and direct use, avoiding loss of material or emergency redissolution.
Synthetic planning often challenges researchers to find partners for key steps—hydrazones, oximes, and amidoximes have a place in custom ligand creation and metal capture projects. In my own hands, this compound showed reliable chelation, opening up new routes in coordination chemistry. The presence of the amidoxime alongside a pyridine backbone lets it latch onto a range of transition metals, forming stable complexes. These capabilities underpin not just academic curiosity, but real advances in separations technology, sensor development, and even environmental engineering.
Colleagues in pharmaceuticals mention another compelling point: the carboxamidoxime group can act as a precursor for a suite of modifications. Medicinal chemists leverage it for targeted library synthesis, using the amidoxime as a launchpoint for further transformation into heterocycles or as a masked nucleophile. Compared to more volatile or finicky counterparts like 2- or 4-pyridinecarboxamidoxime, the meta-position at C3 often allows for gentler reaction conditions and increased selectivity.
It’s easy to overlook the practicalities from the outside. On the frontline, a good reagent streamlines workflow. Whether it’s direct conversion into amidrazones for ligand design, or stepping into more specialized fields such as radiolabeling, this compound adapts. Radiochemists trust 3-PYRIDINECARBOXAMIDOXIME when searching for chelation agents that grab isotopes tightly, with minimal leaching. That’s no small feat—safety and regulatory compliance take on new meaning in radioisotope research.
Its role isn’t limited to cutting-edge fields. In classic organic synthesis, skilled chemists use it to stabilize intermediates that otherwise would break down, helping shepherd transformations that had a higher risk of waste or failed purification. This saves both material and time, as purifications for crude mixtures often become notoriously inefficient and frustrating.
Labs face a maze of options in specialty chemicals. Amidoximes crowd the catalogues, from 2-pyridinecarboxamidoxime to benzamidoxime and more. I’ve tried more than a few in my time, chasing yields and hoping for an easy workup, only to be sidelined by unpredictable reactivity or tacked-on costs. The 3-substituted version stands out for its sweet spot in both reactivity and handling. The meta orientation avoids some of the sterics that plague the ortho form, which in my experience can suffer from lower solubility and more troublesome side reactions. Meanwhile, it’s less electron-rich than the para, giving it a more controlled nucleophilicity and fewer surprises when trying out different functionalizations.
Some cheaper alternatives offer cost savings up front but fail to deliver when it counts. Trace amounts of byproducts or incomplete reactions drag projects into overtime. Advanced users pay attention to not only the up-front cost but also the reliability and reproducibility of each batch. Consistency, purity, and stability always tip the scales, and 3-PYRIDINECARBOXAMIDOXIME meets these benchmarks without fuss.
Chemicals with open-chain amidoximes sometimes raise flags for inhalation or resin formation risks under ambient humidity. In daily lab work, I learned to respect such hazards from mentors who bore the scars of early-career incidents. To their relief—and mine—3-PYRIDINECARBOXAMIDOXIME rarely causes unexpected trouble under normal use. It doesn’t give off strong fumes, doesn’t stain glassware, and doesn’t require specialized containment. Safety data sheets always call for gloves, goggles, and care in disposal, but the compound itself sits comfortably among trusted mid-tier reagents. That makes a difference in educational settings as well; advanced lab courses increasingly use it as an example of well-behaved organic molecules with a robust working window.
Chemists with experience know that best-laid plans stumble on the practicalities. No product is perfect; ambitious users sometimes push the reactivity envelope only to wind up with byproducts, especially in high-temperature or strongly acidic conditions. Those engaged in high-throughput screening or looking to automate synthesis steps should keep an eye on compatibility with robotic dispensers and solvent systems. While 3-PYRIDINECARBOXAMIDOXIME dissolves well in ethanol and DMSO, problems may arise if attempts are made to force too much into aqueous buffers, which can limit its scope for more hydrophilic reaction platforms.
Storage is rarely an issue, but high-humidity environments or cross-contamination with strong acids can shorten its productive lifetime. In a few rare cases, users have mentioned a yellowing of the powder, serving as an early warning to check batch purity before engaging in multi-step synthesis projects.
The future of chemistry relies on not just big breakthroughs but on day-to-day advances—the steady improvements in reliability, reproducibility, and cost-effectiveness. Compounds like 3-PYRIDINECARBOXAMIDOXIME contribute to this future by offering flexible tools for both innovators and educators. With environmental concerns pushing labs to minimize hazardous waste, using stable and predictable reagents with clear reaction profiles helps reduce the number of failed runs, unnecessary solvents, and unexpected hazardous byproducts.
Those in pharmaceuticals and fine chemicals grapple regularly with regulatory scrutiny. Every extra test, every repeat purification, means delays and higher overhead. Products that perform as expected, hold up across multiple scales of synthesis, and require fewer safety interventions move projects ahead. In my experience, that often spells the difference between a compound chosen for routine use and one left to gather dust.
Beyond direct utility, there is value in building a knowledge base around versatile, well-characterized chemicals. Peer-reviewed papers and internal lab notes confirm that 3-PYRIDINECARBOXAMIDOXIME’s well-understood properties support robust science. Whether in method development, metal binding studies, or as a tool in advanced undergraduate labs, the compound keeps on proving its worth.
Even as we aim higher for green chemistry, the impact of reliable building blocks is hard to overstate. Minimizing hazard, reducing energy demands in purification, and increasing atom economy all stem in part from choosing the right starting points. Having worked with less predictable intermediates, I can vouch for the ease of integrating a dependable compound into environmentally conscious protocols. Less need for extensive cleanups, fewer re-runs, and predictable shelf life form a foundation for sustainable habits not just in the lab, but across supply chains.
Teams tasked with scaling up to pilot or production scale keep a close eye on reproducibility. Bottle-to-bottle variation may seem trivial at a glance, but at kilo-scales a misbehaving impurity or subtle shift in melting range quickly snowballs into lost weeks. Suppliers who maintain strict controls and support user feedback cement their role in the larger research landscape. The path from benchtop trial to process validation travels more smoothly when the compound’s performance remains stable.
Fields such as biotechnology, diagnostics, and even electronics keep finding inventive ways to use amidoximes and their analogues. As someone who has watched colleagues shift from hand-packed columns to automated analytics or AI-guided synthesis, the demands on fine chemicals grow ever sharper—speed, safety, precision, and compliance converge as top priorities. Products that grew out of old-school synthetic labs now help shape rapid prototyping efforts, whether for medical diagnostics or energy storage materials. 3-PYRIDINECARBOXAMIDOXIME has found a home in screening platforms as a chelating agent, where low background and reliable electronic properties help generate clear, usable results.
Researchers aiming to develop new therapeutic agents lean on well-established intermediates as springboards. With regulatory agencies like the FDA doubling down on data traceability and documentation, the role of a reliable, thoroughly characterized chemical grows in importance. Published validations, open-access supporting spectra, and transparent sourcing help answer both the practical and ethical calls for better science.
Education is another front where 3-PYRIDINECARBOXAMIDOXIME makes an impact. Advanced students learning the ropes of structure-activity relationships or performing hands-on synthesis projects benefit from reagents that demonstrate clear, consistent results. Anyone who has mentored new lab members understands the difference a reliable compound can make in building confidence and instilling good habits; setbacks due to poor-quality reagents often sap morale and muddy learning outcomes. Safe handling, clear color change endpoints, and dependable yields foster a productive learning environment without compromising on the rigor required for academic or professional advancement.
Open communication between chemists, suppliers, and regulators helps keep the bar high. Trusted chemicals only stay that way when the wider community holds suppliers accountable to strict standards. Batch recall systems, shared incident reports, and robust online documentation empower users to make informed decisions. Suppliers offering third-party certifications, transparent audit trails, and independent validation help build a culture of trust and shared knowledge.
Designing a future with fewer unexpected outcomes starts in part with the right raw materials. As research teams share both success stories and stumbles in public databases and conference proceedings, the collective wisdom surrounding each compound grows. 3-PYRIDINECARBOXAMIDOXIME benefits from this virtuous cycle, gathering a record that supports its continued place in modern chemical work.
The distance between creative experiments in discovery and the demands of scaled production often defines whether an idea makes the leap to real-world impact. Everyone from startup founders to seasoned process chemists faces the same hurdle: can a promising bench result translate up without new headaches? Compounds with both academic credibility and production-grade handling, like 3-PYRIDINECARBOXAMIDOXIME, smooth that path.
Feedback from process teams informs improvements in packaging, shipping, and documentation. Safety innovations travel in both directions, as users share best practices with suppliers and receive updated protocols in return. Through these incremental improvements, everyday research builds firmer connections between inspiration and industrial application.
For those considering bringing 3-PYRIDINECARBOXAMIDOXIME into regular use, the first step is a clear-eyed look at project requirements: solubility, purity, safety, and prior performance. Careful titration in test runs, cross-compared against existing literature and supplier data, can surface potential challenges early. Regularly surveying scientific databases like PubChem, Reaxys, and SciFinder also turns up unexpected applications and hard-won troubleshooting tips from global users.
Building relationships with reputable suppliers forms the backbone of a robust workflow. Responsive technical support, timely batch documentation, and clear product specification sheets support continuous improvement and competitive advantage. In a research environment defined by increasing complexity, few resources are as valuable as shared expertise—whether that comes from formal partnerships or informal discussions across professional conferences.
The coming years will test old standbys and create new benchmarks for chemical excellence. Demands for greener, faster, safer chemistry converge with economic pressures and regulatory oversight to challenge research and industry alike. 3-PYRIDINECARBOXAMIDOXIME offers a dependable base from which to explore creative synthetic routes, expand screening libraries, or design next-generation materials. Whether in early discovery, teaching labs, or industry-supported product development, this compound is likely to remain in the conversation for years to come.
Choosing raw materials remains a strategic decision with ripples throughout a project’s life. That’s something I learned through both mistakes and successes—a reliable reagent saves money, time, and plenty of professional headaches. As the profile of 3-PYRIDINECARBOXAMIDOXIME grows through shared experiences and expanding use, it stands as a reminder that in science, trust and transparency amplify technical strengths. Reaching for progress, chemists at every level gain an edge by keeping the best tools—both new and tried-and-true—close at hand.
