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HS Code |
624265 |
| Chemical Name | Methyl 6-oxo-1,6-dihydro-3-pyridinecarboxylate |
| Molecular Formula | C7H7NO3 |
| Molecular Weight | 153.14 g/mol |
| Cas Number | 6974-32-9 |
| Appearance | White to off-white solid |
| Melting Point | 104-108°C |
| Solubility | Soluble in organic solvents such as ethanol, DMSO |
| Storage Conditions | Store at room temperature, away from moisture and light |
| Smiles | COC(=O)c1cccnc1=O |
As an accredited METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical is packaged in a 25g amber glass bottle with a secure screw cap and safety label displaying hazard and handling instructions. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 13.5 metric tons packed in 540 fiber drums, each drum containing 25 kg of Methyl 6-oxo-1,6-dihydro-3-pyridinecarboxylate. |
| Shipping | METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE ships in tightly sealed containers under ambient conditions. It is packaged according to regulations for non-hazardous laboratory chemicals, avoiding moisture and light exposure. Standard shipping services are used, with appropriate labelling and documentation to ensure product integrity and traceability during transit. Handle with care upon receipt. |
| Storage | Methyl 6-oxo-1,6-dihydro-3-pyridinecarboxylate should be stored in a tightly closed container, in a cool, dry, and well-ventilated area away from direct sunlight and incompatible substances such as strong oxidizers. Keep it at room temperature and avoid moisture exposure. Proper labeling and access restricted to trained personnel is recommended. Always follow relevant safety and handling guidelines for chemical storage. |
| Shelf Life | METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE's shelf life is typically 2-3 years when stored cool, dry, and protected from light. |
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Purity 99%: METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE of purity 99% is used in pharmaceutical intermediate synthesis, where it ensures minimal by-product formation and maximizes target compound yield. Melting Point 110°C: METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE with a melting point of 110°C is used in controlled solid-phase reactions, where it provides precise thermal process control. Molecular Weight 167.15 g/mol: METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE with molecular weight 167.15 g/mol is used in medicinal chemistry libraries, where it allows accurate molar calculations for high-throughput screening. Stability Temperature up to 120°C: METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE with stability temperature up to 120°C is used in heat-assisted synthesis, where it guarantees compound integrity during elevated temperature reactions. Particle Size <50 µm: METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE with particle size less than 50 µm is used in tablet formulation, where it enhances uniform mixing and dissolution rates. |
Competitive METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE prices that fit your budget—flexible terms and customized quotes for every order.
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Years of experience handling specialized organics have shown us that certain molecules push boundaries in drug development and material research. METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE (CAS 2942-59-8) demonstrates this with every batch. What might look like one stop along the pyridine derivative spectrum supports significant innovation further down the chain. Our facility maintains consistent control over synthesis parameters, and every container embodies the balance between molecular complexity and practical usability. Chemical researchers value reliability and repeatability above all, which is why we run continuous validation on our production line, never assuming one batch matches the last until every metric checks out.
Our firsthand involvement in pharmaceutical intermediates tells us how small molecular changes can make or break entire projects. METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE offers a precise contour in the pyridine series, making it a preferred substrate for further chemical modification. Research teams in both small and major companies work with this intermediate as a precursor for active drugs, fine chemicals, and sometimes even specialized agrochemicals. In our experience supplying materials to high-stakes projects, compounds at this oxidation state and methylation pattern often sit on the critical path for new molecular entities or complex heterocycle libraries. A missed specification delays an entire research program. Because of this, every order passes thorough spectral analysis, so process chemists avoid surprises later on their synthesis routes.
Many newcomers see close relatives like methyl nicotinate or methyl 3-pyridinecarboxylate and wonder where the differences lie. After thousands of kilograms shipped, the importance of the 6-oxo functionality stands out clearly. In practice, the presence of the oxo group at the 6-position and reduction at the 1,6-dihydro position create distinct reactivity when built into polycondensation reactions or nucleophilic substitutions. Techniques like selective derivatization or mild hydrogenation respond very differently to such molecular fingerprints. Over time, we have cataloged hundreds of requests from advanced labs specifically requiring the reactivity window that only this composition provides. Just as a single methyl group dramatically alters drug metabolism, these detailed differences change outcomes for researchers. We focus production on matching those needs so development timelines hold steady.
Controlling the synthesis of METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE isn’t routine. Pyridine derivatives often resist neat, controlled functionalization without introducing unwanted by-products. Decades spent tuning oxidizing conditions and separation methods taught us there is no shortcut to tight purity specifications. Large-scale runs sometimes uncover trace impurities detected only through high-resolution methods, pushing us to integrate new purification stages and adjust solvent systems. The investment in dedicated reactors for multi-step sequences paid off, especially in generating material that scales without hidden issues. Teams on our production floor know every detail—from maintaining constant temperatures to tracking subtle color changes during work-up—contributes to a difference synthetic chemists see and trust. These efforts save our customers repeat work, letting them push forward with confidence in their intermediates.
We commit to open analytical data for each batch leaving our site. Spectra and chromatograms confirm identities and rule out residual solvents or uncommon isomers, not as an afterthought but built into our daily routine. We’ve shared our validation method openly with partners in industry and academia, enabling their own QC teams to match or improve upon our standards. Our belief is that supply relationships built on reproducibility avoid “grey zone” ingredients, a topic that comes up too often in customer complaints about other sources. Decades in chemical manufacturing have demonstrated real risk in purchasing intermediates from less disciplined suppliers. Our documentation doesn’t just accompany the material; it reflects our ongoing dialogue with regulatory bodies and clients alike. Nothing undermines a project more than uncertain starting points, and we stand firm on that principle in every shipment.
Research literature and client conversations point to an expanding set of applications for 6-oxo-1,6-dihydro pyridine systems. Synthetic chemists employ our product in the construction of fused heterocycles where controlled reactivity determines overall project success. Industrial customers incorporate it as a module for combinatorial compound libraries, where even a single altered oxidation state changes environmental and biological fate. Universities reach out for this compound when screening enzyme reactions that require stable yet versatile heterocycles. Our technical support team often receives feedback about reduced step counts or fewer purification headaches compared to alternative intermediates. Feedback from global projects continues to shape how our molecule finds new homes across different sectors.
Years shipping to locations from seasonal climates to extreme tropics have underscored the importance of stability. Unlike some other methylated pyridinecarboxylates, this structure resists atmospheric moisture reasonably well, but we know for certain that improper packaging or tampering cuts shelf life dramatically. To counter this, our supply chain analysis led us to robust, multi-layer barriers and climate-adapted storage protocols. Not every customer looks at shipment inspection as closely as a pharma major, so we take full responsibility well before the point of delivery. We design every stage—right down to carton sealing and transit temperature monitoring—to keep the active ingredient unchanged by the time it reaches the lab. Attention to these overlooked logistics supports the broader lifecycle of any program depending on sensitive intermediates.
Direct conversations with process teams always bring new insight. Several partners pointed out that switching to our supply reduced variability in final yields and saved hours in post-reaction purification. Some moved away from bulk commodity versions after uncovering hidden side-products, which slowed their SAR campaigns. We have seen firsthand how post-synthesis chromatography steps shrink or disappear when these hidden impurities no longer exist. Because our people have spent their careers in chemical processes rather than just coordinating shipments, we build every improvement into the outgoing product and close these feedback loops in real time. Results show up not just in purity reports but in smoother project launches and fewer returns or technical complaints from customers around the world.
Plenty of procurement teams base their selections on raw spreadsheet cost. As the actual producer, we have learned no lowest-cost approach yields consistent, reliable output in complex syntheses like this. Multiple variables—ranging from reagent grade up through the experience level of our operators—influence net yield and the true cost to a project. Over time, we’ve worked with clients burned by previous savings attempts that led to delayed launches and regulatory setbacks. Our strategy remains grounded: supply those who value proven, robust material with full disclosure of production history and composition. We set prices based on the actual effort needed to deliver this standard, not to chase unsustainable market lows, because ultimately the end value appears in every downstream success our material enables.
Modern research increasingly requires detailed records stretching back to the earliest raw materials. We open our ledgers—including sources of starting compounds, entire synthesis routes, and stability data—to qualified partners seeking transparency. Our sales and support staff are trained to provide more than stock certificates; they are involved in real audits and can answer technical questions far beyond basic COA templates. Experience shows that open records catch subtle inconsistencies long before they become problems further along. Researchers count on this level of access, not only for regulatory filings but also for collaboration proposals, university-industry partnerships, and troubleshooting during technology transfers. We keep our traceability platform up to date and treat every document as part of quality, not an afterthought.
No production run looks identical in practice because client demands evolve. Some teams require extra purification, special handling, or innovative packaging formats for emerging applications. Our production setup brings agility—capacity for dedicated small volume lots, tailored drying cycles, and new documentation procedures on request. Unlike distributors, who filter options from various upstream sources, our technical staff works at the heart of synthesis and addresses custom requests directly, saving development teams precious time. Our R&D shop runs lab-scale simulations to evaluate new requirements, integrating practical changes into mainstream operations based on real-world feedback. Full control over every aspect of synthesis provides flexibility unmatched by brokers or repackagers whose focus stops with logistics.
Efforts to update chemical production for a greener future permeate every stage of our operation. Every audit and batch record considers waste reduction, solvent recovery, and energy optimization. Over the last decade, we replaced legacy methods that relied on high-toxicity reagents or problematic effluent streams with cleaner technologies. By reclaiming and reusing solvents where possible, we sharply cut our environmental footprint while still hitting exacting product specifications. Commitment to sustainable practice isn't a marketing slogan; it's an ongoing, audited process. Chemists leading future-facing industries recognize the perils of “wasteful” raw materials, and partner with us to ensure their footprints remain minimized through responsible sourcing. We support these projects, not only as a supplier, but as collaborators invested in environmental stewardship that won’t compromise purity or reliability.
We understand our place lies within an ecosystem of researchers, developers, and manufacturers driving new ideas. Feedback from early-stage pharmaceutical scouts and academic labs shapes our R&D and QC practices. By providing application notes, stability data in uncommon scenarios, and reaction pathway troubleshooting, we participate in advancing the field—not as a passive vendor, but as a true partner. Our technical representatives do more than fill orders; they join scientific roundtables, publish process notes, and exchange ideas directly with teams grappling with difficult syntheses. The impact shows in shared publications, improved product yields, and faster move-to-clinic timelines for health-related innovations. This feedback loop deepens trust and broadens the reach of our product in the scientific world.
We see new uses emerging regularly in the world’s leading papers and patent filings. While this molecule’s original role as an intermediate for pharmaceuticals holds strong, its entry into custom catalyst systems, ligand libraries, and even advanced material components illustrates a growing awareness of its adaptable structure. Over recent years, R&D spending across the globe shifted toward these multipurpose building blocks that open doors for new synthesis routes. Our experience puts us ahead of the curve in readying production and refining processes to meet surging demand long before shortages force suboptimal alternatives.
The biggest distinction between this product and lookalike intermediates turns on batch consistency, chemical traceability, and customer support. Raw purity percent is only one aspect. We invest heavily in process reproducibility, and we sign off on every lot with certificates backed by full chromatographic and spectroscopic evidence, not just a spreadsheet. Our customer service doesn’t just pass along catalogs or refer back to a factory; it delivers direct, technical engagement for troubleshooting and innovation. Decades of feedback have shown clients that these differences matter more over the course of a development program than any single line on a spec sheet, no matter how precise.
Real risks face anyone working with reactive heterocyclic compounds, especially those involving methyl esters and oxo groups. We build guidance into our service by sharing firsthand learnings—from proper PPE recommendations through to specific material handling suggestions based on actual incidents and batch histories. Our technical bulletins, updated every year, reflect changes in safety best practices and new findings from our long-term customer base. This approach prevents avoidable accidents and supports customers with guidelines that reflect experience, not theory. By coupling safety knowledge with real supply chain oversight, we enable projects to proceed without setbacks due to overlooked hazards.
Direct access to the manufacturer produces advantages that ripple out across labs, regulatory offices, and entire industries. We remain committed to honest, prompt feedback on technical challenges, and we proactively offer batch-specific documentation to meet region-specific regulatory submissions. Our international presence has shown us just how different real-world challenges can look—even for the same molecule—across borders and applications. We take pride in working directly with research managers and supply chain coordinators everywhere, cutting through layers of red tape and uncertainty. Our aim is to make each interaction as straightforward and productive as possible, so the actual science never loses ground to logistic puzzles.
Continued investment in infrastructure—automated process controls, in-process analytics, and expanded warehousing—means every year brings higher output capacity and faster turnaround times without loss of quality. Our commitment to reliable delivery and technical support opens new possibilities for our clients, letting researchers chase more ambitious targets with confidence in their upstream partners. This improvement never freezes into place; it moves daily through open dialogue, new raw material evaluations, and steady testing of process hypotheses to see what delivers genuinely better outcomes.
Every shipment of METHYL 6-OXO-1,6-DIHYDRO-3-PYRIDINECARBOXYLATE reflects years spent honing each process, learning from thousands of feedback cycles, and keeping priorities focused on real-world outcomes—accuracy, trust, and innovation. Our pride comes from seeing the impact our efforts provide to those on the cutting edge of science, whether for the next pharmaceutical breakthrough or a material built for tomorrow’s technologies.
