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HS Code |
881622 |
| Iupac Name | 2-cyano-4-pyridinecarboxylic acid hydrazide |
| Cas Number | 55266-14-3 |
| Molecular Formula | C7H6N4O |
| Molecular Weight | 162.15 |
| Appearance | White to off-white powder |
| Solubility | Soluble in polar solvents such as DMSO and DMF |
| Synonyms | 4-Pyridinecarboxylic acid, 2-cyano-, hydrazide; 2-Cyanoisonicotinic acid hydrazide |
| Smiles | C1=CN=CC(=C1C(=O)NN)C#N |
| Inchi | InChI=1S/C7H6N4O/c8-3-5-1-2-10-4-6(5)7(12)11-9/h1-2,4H,(H2,9,11,12) |
As an accredited 4-Pyridinecarboxylicacid,2-cyano-,hydrazide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed 100g amber glass bottle with tamper-evident cap, labeled with chemical name, hazard warnings, batch number, and storage instructions. |
| Container Loading (20′ FCL) | 20′ FCL container loads 14 metric tons of 4-Pyridinecarboxylic acid,2-cyano-,hydrazide, securely packed in 25 kg drums. |
| Shipping | **Shipping Description:** 4-Pyridinecarboxylic acid, 2-cyano-, hydrazide is securely packaged in a sealed, chemically resistant container. The shipment complies with hazard and labeling regulations, includes a Material Safety Data Sheet (MSDS), and is transported via ground or air with temperature control if required, ensuring safety and integrity during transit. |
| Storage | 4-Pyridinecarboxylicacid,2-cyano-,hydrazide should be stored in a tightly sealed container in a cool, dry, and well-ventilated area, away from incompatible substances such as oxidizers and acids. Protect from moisture, direct sunlight, and heat sources. Properly label the container and handle using appropriate personal protective equipment to avoid inhalation, ingestion, or skin contact. |
| Shelf Life | Shelf life of 4-Pyridinecarboxylic acid, 2-cyano-, hydrazide: Stable for at least 2 years if stored dry, cool, tightly sealed. |
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Purity 98%: 4-Pyridinecarboxylicacid,2-cyano-,hydrazide with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield of target heterocyclic compounds. Melting Point 180°C: 4-Pyridinecarboxylicacid,2-cyano-,hydrazide with a melting point of 180°C is used in solid-phase organic reactions, where it provides enhanced thermal stability during processing. Molecular Weight 177.16 g/mol: 4-Pyridinecarboxylicacid,2-cyano-,hydrazide with a molecular weight of 177.16 g/mol is used in drug discovery research, where precise molecular incorporation improves lead optimization. Particle Size ≤ 50 μm: 4-Pyridinecarboxylicacid,2-cyano-,hydrazide with particle size ≤ 50 μm is used in fine chemical formulations, where uniform dispersion increases reaction efficiency. Solubility in Dimethylformamide: 4-Pyridinecarboxylicacid,2-cyano-,hydrazide with high solubility in dimethylformamide is used in solution-phase synthesis, where complete dissolution accelerates reaction rates. Stability Temperature up to 120°C: 4-Pyridinecarboxylicacid,2-cyano-,hydrazide stable up to 120°C is used in high-temperature coupling reactions, where chemical integrity is maintained under heat stress. |
Competitive 4-Pyridinecarboxylicacid,2-cyano-,hydrazide prices that fit your budget—flexible terms and customized quotes for every order.
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Producing 4-Pyridinecarboxylicacid, 2-cyano-, hydrazide calls for a careful approach rooted in hands-on chemical practice. At our facility, we work with raw pyridine derivatives every day. Years of batch optimization have shaped a process that delivers this compound with reliable purity. Chemically, this molecule stands out due to its hydrazide function attached to a pyridine ring with a cyano group at the 2-position. In layman's terms, that basic structure opens a world of reactivity, lending itself well to research and diverse synthetic purposes.
Our model for this product, labeled as 4PCA-2CN-HZ, encapsulates our commitment to both batch and continuous manufacturing standards. Over time, painstaking chromatography and rigorous TLC monitoring have made it possible to offer this hydrazide consistently above 98% purity, as verified by our in-house HPLC and NMR analysis. That level of quality springs from direct feedback between staff on the plant floor, laboratory chemists, and customers at the benchtop. We listen, troubleshoot, and refine every cycle.
Scaling 4-Pyridinecarboxylicacid, 2-cyano-, hydrazide production comes with practical challenges. This compound might seem straightforward on paper, but real-world chemistry throws surprises. Moisture management and reaction temperature have been two stubborn hurdles. As a manufacturer, every production run teaches lessons: hydrazides show a tendency for hydrolysis if water traces creep in during synthesis or even post-synthesis handling. By investing in sealed systems and real-time moisture analysis, we cut down on byproduct formation—lowering both waste and costs.
The cyano group demands its own attention. Early attempts produced batches with minor but stubborn side products stemming from incomplete cyano introductions. Fine-tuning pH and using premium-grade starting materials solved the problem. Maintaining tight control over the cyano group’s location and overall electron distribution makes this variant much more suitable for advanced applications, especially in medicinal chemistry and intermediate synthesis.
Researchers value this hydrazide most for its role in heterocyclic chemistry. The presence of both the hydrazide and cyano groups in one molecule delivers a unique spectrum of possible downstream products. In the lab, it often acts as a versatile synthon—a building block for even more complex structures. In our experience, its popularity has grown especially in organizations engaged in pharmaceutical lead generation. One major reason: it enables efficient construction of bioactive heterocycles that would otherwise demand multi-step or poorly yielding routes.
Staff at our plant see samples heading out the door not just to drug developers, but also to agrochemical firms and specialty material labs. This stems from the compound’s appeal as a functional group input for diverse transformations, such as condensation reactions and cyclizations. Years ago, we received repeat requests for lot-specific customizations. By now, our QA team’s logs reflect hundreds of successful deliveries supporting synthesis of hydrazides, hydrazones, and even custom pyridine derivatives beyond drug scaffolds.
Among the array of pyridinecarboxylic acid derivatives, this particular hydrazide stands out for its dual functionalization. Simple pyridine-4-carboxylic acid derivatives lack the reactive punch provided by both the cyano and the hydrazide groups. Chemists working with esters or amides of pyridinecarboxylic acid might notice a narrower set of reactivity—especially during the synthesis of heterocyclic compounds.
Direct comparisons with other hydrazides on the market reveal another advantage: our process avoids high-residual solvents, and we conduct thorough residual solvent testing and drying. Given how hydrazides often form stubborn hydrates, subpar batches elsewhere might end up with inconsistent weights or performance—issues we’ve learned to minimize through targeted testing and vacuum drying protocols.
From synthesis to shipment, every staff member at our facility brings a practical approach. We run mock-up pilot batches before scaling up, watching for slight shifts in color or melting point that could signal impurity. Analytical chemists, not just line operators, review data from every batch. The strong relationship with downstream researchers has shown us that minor impurities can impact both biological results and reaction outcomes. Adjusting our purification—sometimes as simple as swapping a solvent or tweaking a final recrystallization—has made a measurable difference in our clients’ success rates.
Through years of ongoing feedback, we discovered that some customers needed even higher purities for specialized screens. That nudged us to install in-line detectors and invest in more advanced column chromatography setups. Today, all shipments leave with comprehensive COAs, including NMR, HPLC, and moisture reports right from our own instrument suite, not a third-party lab. This level of transparency isn’t a luxury for us; it’s a learned necessity after seeing firsthand how subtle specification lapses disrupt research schedules.
Consistency comes from direct oversight and relentless evaluation. We never outsource key steps or hand off processes to suppliers with weak QA. Sourcing reagents from audited vendors means we catch issues before they begin. Even then, every batch starts with a full in-house assessment of the base materials. All operators run through training programs that stress both safety and process control. The result: uniformity in appearance, melting point, and purity specifications batch after batch.
Handling the finished 4-Pyridinecarboxylicacid, 2-cyano-, hydrazide also demands attention. Hydrazides can cake or clump if exposed to even modest humidity. We invest in high-grade bottles and tamper-evident seals, and track storage delivery conditions year-round. Once, a shipping oversight led to a compromised lot—after that, we implemented real-time temperature and humidity monitoring for all outgoing shipments. These steps, while sometimes costly, have virtually eliminated customer complaints related to physical stability.
With hydrazides, hazardous exposure risk isn’t hypothetical. Over years of batch work, our safety committee documented increased incidents tied to improper PPE or open-access handling. We set comprehensive procedures: closed-system transfers wherever possible, mandatory glove use, and local exhaust at every point of open operation. Monthly training refreshers keep staff vigilant, since mishaps don’t always stem from process, but often from inattention.
Solvent recovery and process waste have driven innovation. Our most experienced operators suggested several batch tweaks that cut down waste, leading to material savings and a cleaner process. Over time, these employee-driven improvements have reduced overall solvent consumption by 30 percent, helping both the bottom line and our regulatory profile. As a chemical manufacturer, we own our local footprint and comply with regulatory standards not just for compliance but from real respect for the communities we work in.
Industry researchers and scale-up teams prefer to work with producers who control every step—not just middlemen pushing product from warehouse shelves. With this hydrazide, requests for technical advice keep coming in. Our staff includes chemists who have run thousands of grams of this exact compound. Unlike a catalog offer, these conversations steer real-world syntheses, storage best practices, and even troubleshooting post-purchase challenges. We answer not with canned responses, but with detail from practical test runs and scale-ups performed on our own benches.
Few routine orders arrive without special requests. Some ask for repackaging to avoid oxygen ingress, others need supplementary testing for specific applications like radiolabeling or chiral synthesis. By owning both the knowledge base and the means of production, we can realistically accommodate these demands. Being the actual manufacturer, we’ve also had opportunities to collaborate more deeply, sharing data and even process tweaks to refine downstream chemistry for partners in pharmaceuticals and agricultural chemistry.
Not every shipment or production run goes by the book. Hydrazide chemistry doesn’t always scale as smoothly as theory predicts. Exothermic reactions at kilogram scales demand careful control. One time, a batch ran hotter than expected due to a subtle solvent lot variation. The team responded with a full lot-specific review and equipment upgrades on reaction temperature monitoring. As we’ve learned repeatedly, vigilance on the plant floor saves product and prevents waste.
End-use reports sometimes uncover issues that don’t show up in QC. Medicinal chemistry labs might see unusual reactivity or a byproduct above a specific threshold that impacts their work. We treat every one of these field reports as a development opportunity. Where data calls for it, we adjust our purification or tweak drying protocols to nip future issues in the bud. Each challenge closes the loop between manufacturing and applied science, drawing on years of staff know-how and real-world use cases.
Demand for 4-Pyridinecarboxylicacid, 2-cyano-, hydrazide won’t disappear. With new therapies and crop science projects reaching development, requests keep rising for both standard and custom grades. We track feedback from every shipment and analyze industry literature to anticipate new needs. Observing market trends and research breakthroughs, we make regular process reviews a fixture and not a chore.
Process innovation matters. Transitioning from batch to semi-continuous methods for this hydrazide cut down lead times and increased flexibility. Teams in both manufacturing and QA report faster turnaround while keeping to strict specification controls. Having control over both process and logistics means adjusting to customer demand in real time, not weeks too late. Achieving this capability came from investing in staff and equipment, never from chasing shortcuts.
At core, producing 4-Pyridinecarboxylicacid, 2-cyano-, hydrazide challenges us to keep learning. The differences between this and a generic hydrazide product go beyond paperwork and catalog numbers. The specifics of cyano-substitution, reactivity tuning, and purity demands have pressed us as a team to refine every process checkpoint. Whether our product finds life in a new therapeutic molecule, a catalyst, or agrochemical innovation, it started on the production line with practical chemical problem-solving and old-fashioned curiosity.
Direct interaction with end users continues to shape everything we do. By staying close to both the science and those applying it, we recognize issues before they become costly mistakes. Each improvement springs from real feedback—an approach that delivers value to scientists across disciplines. Our commitment isn’t just to specs and certifications, but to the long-term progress of chemical science. From raw material to delivered product, every gram represents a chapter in an ongoing story shared by those who make and those who use.
