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HS Code |
272930 |
| Iupac Name | 2-methoxy-4-methylpyridine-3-carbonitrile |
| Cas Number | 17440-24-9 |
| Molecular Formula | C8H8N2O |
| Molecular Weight | 148.16 |
| Appearance | Solid or crystalline powder |
| Melting Point | 78-82°C |
| Solubility | Slightly soluble in water, more soluble in organic solvents |
| Smiles | COC1=NC(C)=C(C#N)C=C1 |
| Inchi | InChI=1S/C8H8N2O/c1-6-2-3-10-8(11-2)7(4-9)5-6/h2-3,5H,1H3 |
| Pubchem Cid | 3298616 |
| Logp | Estimated around 1.5-2 |
As an accredited 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 100 grams of 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI), sealed with a tamper-evident cap and labeled for laboratory use. |
| Container Loading (20′ FCL) | 20′ FCL container loading: Securely packed drums of 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI), ensuring safe, efficient bulk chemical transport. |
| Shipping | Shipping for 3-Pyridinecarbonitrile, 2-methoxy-4-methyl- (9CI) requires secure, chemical-resistant packaging and proper labeling, following relevant hazardous materials regulations. Transport should be via approved carriers, with documentation including Material Safety Data Sheet (MSDS). Ensure protection from moisture, heat, and incompatible substances during transit to maintain safety and chemical integrity. |
| Storage | **3-Pyridinecarbonitrile, 2-methoxy-4-methyl-(9CI)** should be stored in a tightly closed container, in a cool, dry, well-ventilated area away from incompatible substances such as strong oxidizers. Protect from heat, light, and moisture. Store at room temperature or as otherwise specified by the manufacturer. Ensure proper labeling and keep away from sources of ignition. |
| Shelf Life | Shelf life of 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI): Stable for 2–3 years if stored in a cool, dry, tightly sealed container. |
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Purity 98%: 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) with purity 98% is used in pharmaceutical intermediate synthesis, where high purity ensures minimal by-product formation and consistent reaction yields. Melting Point 56°C: 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) with a melting point of 56°C is used in agrochemical formulation processes, where controlled melting behavior supports precise blending and uniform product distribution. Molecular Weight 146.16 g/mol: 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) with molecular weight 146.16 g/mol is used in fine chemical manufacturing, where accurate molecular mass enables straightforward stoichiometric calculations and process scalability. Stability Temperature 120°C: 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) with stability up to 120°C is used in high-temperature organic reactions, where thermal stability ensures integrity of the compound throughout processing. Particle Size <50 µm: 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) with particle size less than 50 µm is used in solid formulation systems, where fine particle distribution supports homogeneous mixing and enhanced dissolution rates. |
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On this production line, we have seen the core role 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) plays in pharmaceutical innovation, crop science, and specialty chemicals. For over a decade, our facilities have manufactured this compound to serve labs and plants that rely on precise building blocks for breakthrough molecules. Its clean profile and reproducible properties come from strict process controls and deliberate solvent choices, shaped by feedback from experienced research chemists and process engineers. Colleagues in R&D often request this compound thanks to the tight limits on related substances and moisture level, which support downstream coupling reactions without excess purification steps.
Production batches of 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) consistently pass spectral and chromatographic verifications on our instruments. Each lot produces consistent peaks across NMR and HPLC tests—with residual solvents and water content tracked for every drum. Our operations have invested in upgraded purification units and inline monitoring, achieving reproducible performance even during long campaign runs. Finished material leaves the facility as a white to off-white crystalline solid, free-flowing and easy for automated or manual handling. Strict documentation and batch traceability have been demanded by partners conducting regulatory filings, so every shipment includes a full disclosure of analytical data. These records come from direct measurement, not estimates.
We work directly with synthetic chemists using 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) as a precursor for fused heterocycles and functionalized pyridines. Its well-defined structure—containing the nitrile, methoxy, and methyl groups on the aromatic system—lets researchers precisely modify scaffolds required for pharmaceutical leads or advanced agrochemicals. The electronic and steric effects of its substituents guide predictable reactions with nucleophiles, enabling coupling, cyclization, and reduction steps without unexpected byproducts. Development teams have reported that material from our reactors provides lower impurity loads compared to mixed-source commercial lots. This removes hours of troubleshooting out of product launch schedules and helps guarantee reliable scale-up.
Over the years, we've seen demand for this pyridine derivative grow among manufacturers of crop protection compounds, pharmaceuticals, and performance materials. In the pharmaceutical sector, teams often leverage 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) to prepare intermediate scaffolds for kinase inhibitors or central nervous system agents. Its particularly clean reactivity profile means teams can install amine or carbonyl substituents at the cyano position using standard catalytic conditions. Toxicology screening groups have flagged fewer carryover impurities from our product, which has reduced time spent on purification and improved analytical clarity in finished APIs.
Agrochemical developers have called out the material's compatibility with green chemistry protocols, thanks to predictable downstream processing and relatively mild reaction conditions. Nitrile-containing pyridines often form the backbone for industrial herbicides or fungicides, and our variant offers an ideal blend of electron donation and steric bulk for functionalization. For advanced material engineers, the clean solid-state form supports direct use in custom polymers, OLED precursors, and electronic intermediates. Feedback from users in all sectors has influenced minor process adjustments every year, tightening particle size distribution and lowering extractables.
Scaling this compound from bench to pilot plant taught hard lessons. Early on, we faced challenges with exothermicity and byproduct control during the introduction of the methoxy function. Continuous process improvements—guided by plant operators and bench scientists—led us to closed reactors, optimized solvent choices, and staged temperature ramps. This means kilo and ton-scale orders now deliver material with the same spectral fingerprints as the analytical reference samples received by pilot teams. Customers switching from mixed-batch traders have called out the reduced batch-to-batch drift and trace impurity consistency. For multi-ton projects, such as active ingredient manufacturing or contract custom synthesis, reliable delivery prevents supply chain hiccups and lets our partners focus on their own process improvements.
There is a significant difference between material produced on a laboratory scale and what leaves an industrial plant. Trialing 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) from various resellers and traders, we’ve encountered inconsistencies: one lot arrived with water content over specification, another showed yellowing after storage. Some were off-white with detectable solvent residues that complicated downstream coupling. By manufacturing in-house and running full traceability, we have eliminated such guesswork. Incoming raw materials, reaction conditions, and post-reaction cleanups all factor into reproducibility. Operators retain authority to flag any off-normal conditions, and regular site audits identify improvement opportunities. The result is a solid track record, proven by shipments to regulated markets and internal retention samples.
Based on our experience, the best results come from storing 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) in airtight, light-shielded containers at room temperature. We've seen it withstand global shipping routes and seasonal temperature swings without clumping or decomposing. This means material shipped to Europe or North America from our facility arrives unchanged, even after weeks in transit. Labs handling sensitive coupling reactions appreciate the slow uptake of atmospheric moisture, keeping batch-to-batch results steady. Regular process validation, supported by reference standards, ensures no hidden changes creep in over time.
Field application makes a difference. We have supported several clients troubleshooting deprotection and cyclization chemistry, where minor amounts of trace solvents or over-dried samples changed reaction times or selectivity. Our technical service team works one-on-one with users to adjust protocols—such as pre-conditioning on silica or small solvent washes—based on years of hands-on lab runs. The fine crystalline form we produce avoids bridging in feeders, and its stability under Schlenk line or atmospheric conditions means no need to rush charges. For pilot plant start-ups, direct samples and collaborative technical notes streamline transfer, bypassing repeated trial and error.
Every improvement implemented comes from concrete feedback. After a major pharma partner detected subvisible particles during large-scale crystallization, we overhauled filtration lines and implemented in-process particle monitoring, cutting downstream filtration costs. A seed developer flagged rare color shifts under direct sunlight, prompting us to improve UV protection during storage. In one incident, a product manager highlighted minor but persistent off-odors traceable to a supplier change of starting material; we leveraged historical batch data and reinstated a tighter source policy. These changes came not from theoretical modeling but practical field issues—each driving more robust, trustworthy product.
Chemically, 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) offers a combination of physical and electronic characteristics not present in simple pyridinecarbonitriles. The methoxy group at position 2 increases nucleophilicity compared to straight cyano-pyridines. At the same time, the 4-methyl group reduces the risk of polymer formation during downstream substitution, increasing the success rate of selective transformations. Colleagues working on more basic 3-pyridinecarbonitrile have reported greater challenges controlling regioselectivity and reactivity, which can result in final product mixtures. Our in-house comparative studies show narrower melting point spread and superior storage stability versus more substituted analogues, likely due to reduced propensity for self-condensation or moisture sensitivity.
In practice, this means end-users working with our product spend less time on scrubbing impurities and can scale reactions directly. Small modifications in the core allow us to offer derivative pyridine intermediates—sulfonated, halogenated, or with alternate ether substituents—but the core 2-methoxy-4-methyl configuration sees the most demand for medicinal and agrochemical scaffold development. Product managers evaluating switching from a generic nitrile report fewer reworks and less unplanned downtime when shifting to our process-controlled material, pointing to direct cost and efficiency gains.
Investment in greener process chemistry defines our production strategy. We have transitioned to non-chlorinated solvents and optimized nitrilation steps to minimize process waste. We run closed-loop solvent recovery on our lines, reducing both costs and environmental footprint. Studies at our site show this has cut hazardous waste output by over 35% in recent years, while final product meet or exceeds global purity expectations. End-users developing molecules subject to environmental or worker safety regulations benefit from our documentation and validated production protocols, helping de-risk their own filings and regulatory pathways.
Improved energy efficiency and lower emissions have also helped us maintain relationships with customers committed to corporate social responsibility. By choosing direct manufacturing partners who invest in process transparency, they gain early notice of supply changes, ongoing technical support, and auditable records—advantages not available through fragmented sourcing or brokerage. We regularly share our site-specific carbon metrics and energy consumption trends with key supply partners, building trust and predictability.
Global supply disruptions—like those experienced during recent transportation bottlenecks—have tested every chemical supply chain. Our direct manufacturing model allowed us to keep supplying 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) without the extended outages seen among resellers reliant on re-packing or trans-shipment. By maintaining finished inventory, dual-qualifying sources of key starting materials, and training an in-house technical support group, we’ve helped partners avoid project delays. On more than one occasion, R&D and procurement collaborators have told us that supply reliability trumped any short-term price fluctuation, especially for compounds central to multiple synthesis programs.
For long-term projects, such as lead optimization or scale-up to clinical manufacturing, access to the same lot or process-consistent material means faster decision-making and lower analytical risk. We provide periodic inventory and forecast updates, helping customers plan purchases ahead of known maintenance turnarounds or seasonal slow-downs. By linking the timing of shipments to specific customer production campaigns, outages are avoided and downstream plant assets run more efficiently.
Our processes run in view of rigorous QA/QC systems, yielding data we share with partners on request. Raw analytical output and batch synthesis records go beyond minimal regulatory requirements, supporting customers in GMP or critical-path applications. Several innovation-focused companies now require original manufacturing documentation on every shipment, a shift from outdated habits of anonymous, trader-sourced supplies. Our in-house chemists maintain open communication—discussing process drift, suggesting process modifications for new applications, and offering solutions backed by hands-on troubleshooting. This culture of shared technical problem-solving sets direct manufacturing apart from mere distribution.
Process chemists and project managers drawing on our experience often save days’ worth of troubleshooting and are able to launch new campaigns more smoothly. We continually update process guides and application notes based on cumulative user experiences, folding improvements back into plant operations as well as end-user documentation. In cases where applications shift—such as moving from medicinal chemistry pilot scale to full manufacturing—our teams adjust sampling, packaging, and analytic reporting to support evolving needs.
Market expectations for high-value intermediates rise each year. Our site’s commitment to sustainable, repeatable production stems from a decade of independent audits, customer feedback, and continual retraining. We subject every campaign to pre-shipment verification for elemental impurities, water content, and byproduct profiles. These controls, backed by retention samples and integrated batch records, equip our customers with the data needed for their own regulatory filings or due diligence. Periodic surprise audits by key accounts keep our teams vigilant and encourage openness and consistency. Senior technicians and junior staff are trained side by side, reinforcing values of quality, transparency, and safe operation.
We take end-user observations seriously. Feedback drives real change on the shop floor—whether it’s ease of opening packaging, improvements to labeling for traceability, or optimization of batch sizes to better match consumption rates. Our teams have answered requests for alternate packaging dimensions to fit new automated dispensing setups. When international climate changes affected shipping stability, we developed upgraded external packaging. In every case, results flow back to future batches, creating a product that evolves with the needs of a specialist user base.
Sourcing from a direct manufacturer, rather than a trader or logistic aggregator, keeps the feedback loop short. We speak the same process language as application chemists and scale-up engineers; we understand the cost and time implications of requalification or lot variability. We share these realities in every customer conversation and aim to offer not just a reagent, but a platform for productive chemistry and reliable planning. Through years at the reactor and close collaboration with field teams, we've constructed a production model responsive to scientific rigor and real-world project needs.
Manufacturing 3-Pyridinecarbonitrile,2-methoxy-4-methyl-(9CI) is more than a technical exercise; it’s a partnership with innovators across industries. Our track record comes from investment in process, people, and open communication—not speculative trading or repackaging. As project timelines tighten and quality standards rise, we remain committed to the ongoing refinement and transparent supply of this indispensable intermediate. Each improvement and process safeguard grows from the real-world needs of our partners, keeping us focused on what matters most: enabling scientific and commercial progress, batch after batch.
