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HS Code |
476802 |
| Chemical Name | N-Ethyl-3-cyano-4-methyl-hydroxy pyridine |
| Molecular Formula | C9H10N2O |
| Molecular Weight | 162.19 g/mol |
| Appearance | White to off-white powder |
| Melting Point | Approx. 115-120°C |
| Solubility | Slightly soluble in water; soluble in organic solvents such as ethanol and DMSO |
| Density | Approx. 1.2 g/cm³ (estimated) |
| Structure | Pyridine ring substituted at positions 3 (cyano), 4 (methyl, hydroxy), and N-ethyl group |
| Storage Conditions | Store at 2-8°C, protect from light and moisture |
As an accredited N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed amber glass bottle, 25 grams, labeled with chemical name, formula, hazard symbols, lot number, and manufacturer details. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine: Securely packed, moisture-resistant drums, labeled for safe, efficient chemical transport. |
| Shipping | N-Ethyl-3-cyano-4-methyl-hydroxy pyridine should be shipped in tightly sealed containers, protected from moisture, heat, and light. Ensure proper labeling and adherence to regulatory guidelines. Use appropriate cushioning and secondary containment to prevent leaks. Transport under controlled temperatures if required, and follow all hazardous material shipping protocols to ensure safety. |
| Storage | N-Ethyl-3-cyano-4-methyl-hydroxy pyridine should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from heat sources, direct sunlight, and incompatible materials such as strong oxidizers. Protect from moisture and store at room temperature. Properly label the storage area, and ensure access is limited to authorized and trained personnel only. |
| Shelf Life | Shelf life of N-Ethyl-3-cyano-4-methyl-hydroxy pyridine is typically 2 years, if stored in a cool, dry, sealed container. |
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Purity 98%: N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine with 98% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield and selectivity in downstream reactions. Melting Point 125°C: N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine with a melting point of 125°C is used in solid formulation processes, where it provides thermal stability during manufacturing. Molecular Weight 176.20 g/mol: N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine with molecular weight 176.20 g/mol is used in medicinal chemistry research, where it allows accurate dosing and formulation. Particle Size <50 microns: N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine with a particle size less than 50 microns is used in fine chemical synthesis, where it promotes rapid dissolution and homogeneous reactions. Stability Temperature up to 150°C: N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine with stability up to 150°C is used in high-temperature reaction systems, where it maintains structural integrity and product consistency. Solubility in DMSO > 10 mg/mL: N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine soluble in DMSO above 10 mg/mL is used in assay development, where it facilitates preparation of concentrated stock solutions. Moisture Content <0.5%: N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine with moisture content below 0.5% is used in sensitive organometallic transformations, where it prevents unwanted hydrolysis reactions. |
Competitive N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine prices that fit your budget—flexible terms and customized quotes for every order.
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In our chemical plant, where attention to molecular purity and batch consistency underpins every process, N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine continuously proves its value in synthesis work. We have developed our manufacturing practices based on real-world demand for precise and predictable inputs for fine chemicals, pharmaceuticals, and specialized research applications. Each batch we produce undergoes repeated quality checks centered on structural integrity, assay, moisture content, and residual solvent analysis. This approach, informed by decades on the production floor rather than theory, earns trust from teams seeking reliable reagents for scale-up or preparative runs.
Direct experience with large-scale and pilot plant synthesis tells us that trace impurities can ruin downstream workflows. N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine contains multiple active substituents, with the ethyl group and cyano function both providing critical chemical handles. Our in-house process control makes sure unwanted side products, like over-alkylated or oxidized derivatives, do not arise even in extended production cycles. Operators and chemists in our facility routinely collaborate over batch checkpoints because human oversight catches what automation sometimes misses. Routine feedback from R&D customers has taught us that even a small uptick in impurity profiles can hinder catalyst development, disrupt pharmaceutical intermediates, or create problematic HPLC backgrounds. This direct feedback loop has driven us to refine both starting material selection and purification strategy.
Product quality in our line is guided less by broad claims and more by the concrete needs of real users. We take pride in offering N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine at a purity typically exceeding 98%, as verified by both GC and NMR. Our production line provides this material as a fine crystalline powder, which gives consistent volumetric dosing in automated synthetic set-ups. Typical moisture content remains below 0.1%, which means users avoid unwanted hydrolysis or hydration in sensitive multi-step reactions. Strict residual solvent levels are confirmed through both in-line sensor data and bench-scale analysis prior to packaging. Batch documentation travels with every shipment, drawing from our authenticated QA logbooks and decades of cumulative production data.
Chemists working in heterocyclic synthesis value the electron-rich nature of N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine. It participates readily as a building block in pyridine-based ligands and advanced intermediates needed for pharmaceutical scaffolds. The presence of the ethyl substituent at the nitrogen, combined with the electron-withdrawing cyano on position 3, gives the molecule a balance of reactivity and functional group stability. Many customers have successfully deployed this compound to introduce tailored side chains or to support Suzuki or Sonogashira couplings. Small pilot lots have seen use in design of kinase inhibitors, nitric oxide synthase modifiers, and nucleoside analogues. Each of these applications puts pressure on the raw material — not just for overall purity, but for predictability in reactivity and physical handling.
Decisions in the lab often come down to trade-offs: price, reactivity, safety, ease of isolation, or compatibility with current process steps. Broadly speaking, N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine fills a role that more traditional pyridine derivatives cannot. For one, the hydroxy function at the 4-position introduces a specific site for further derivatization, which is essential for route design in drug lead optimization. Methylation at the 4-position also tampers basicity, widening solvent compatibility and process safety margins. Other, less strategically substituted pyridines often cannot strike this fine balance. Customers report moving away from alternatives such as unsubstituted hydroxy pyridines or N-methyl analogues because our material resists over-oxidation and withstands longer residence times in flow reactors, making it a more robust platform for demanding syntheses.
The direct feedback from researchers using standard pyridine, N-methyl pyridine, or 3-cyanopyridine alone highlights another difference: efficiency in forming coupled products. This molecule’s specific substitution pattern avoids common route-blocking side reactions and allows for better yields in complex molecule assembly. Our production teams have worked hand-in-glove with scale-up partners to adjust crystallization temperatures and drying cycles, producing a flowable, manageable product that also boosts final isolation yields in customer labs.
Supply reliability influences project timelines and regulatory filings in an industry where late batches can bring entire campaigns to a halt. Ownership of the production process for N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine gives us control over each precursor input, including the origin, profile, and stability of reagents. We perform routine vendor and precursor audits to guarantee no contamination impacts downstream quality. This contrasts sharply with the uncertainty that can follow brokered or multi-sourced intermediates. Many operations have come to us after facing unexplained batch-to-batch variability from wider suppliers. Our direct production model, supported by full traceability and our focus on enhancing documentation for end users, eliminates disruptions often tied to inconsistent raw material streams.
Chemical manufacturing does not tolerate guesswork, especially for specialty intermediates involved in medicinal chemistry or advanced materials. Our routine practice of running small-scale validation lots before every full-scale campaign exposes any shift in impurity drifts or color profile changes. The team addresses deviations by immediate adjustment, sometimes altering solvent ratios or filtration timing based directly on observed data, not simply on software models or theoretical predictions. Regular batch retrospectives encourage our teams to record what works and flag what needs further improvement, with that lived knowledge refining each successive run. In contrast, third-party packagers or traders typically lack such direct feedback loops, relying on information reported by others rather than on direct observation or troubleshooting in real time.
Over the years, frequent exposure to shipping realities and storage conditions led us to adopt high-barrier, moisture-resistant packaging for N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine. Bags and drums come sealed against atmospheric ingress, and packaging practices include repeated stress tests to simulate transport across climates and storage durations. The shelf stability now typically exceeds projections, which responds directly to earlier challenges reported from customers contending with caking or rehydration in less protected shipments. Each drum or bag carries a production batch number, linking back to our quality records, so any issue can be traced and rectified. By maintaining in-house control of filling and sealing, we address not just product quality, but functional utility at the point of use. These lessons, drawn from user interactions, have deeply influenced our approach, always favoring practicality and actionable safeguards over generic packaging claims.
Many buyers turn to N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine when scalability matters. Some put it to work in laboratories exploring route scouting for new APIs, others scale to multiple kilograms in pilot reactors aiming at investigational new drug programs. What emerges consistently is the need for a product that does not introduce trouble—whether loss of potency, sluggish conversion rates, or instabilities during work-up. Our support staff works with process chemists and operators at customer sites to share best practices for dissolution, slurry formation, blending, and addition sequences. If end-users hit unforeseen roadblocks, these field-level insights provide critical course correction instead of leaving teams to troubleshoot alone.
In the early days, some customers experienced filter clogging or slow dissolution in water-rich blends due to subtle batch differences. Our team responded by mapping solubility curves and working on granulation size distribution. Tighter quality envelopes came about directly from persistent, honest reports out of the field—feedback that standardized test labs often overlook. Production now reflects actual conditions seen by end-users, with adjustments flowing both ways: from the plant to the lab bench, and back from the lab to the production crew. Ongoing collaboration continues driving those incremental improvements which make a compound not just available, but genuinely suitable for use by chemists running ambitious campaigns.
Not every process can draw on multi-shift crews, so team members with the most hands-on experience supervise every new synthesis or major campaign. Temperature, agitation, and pH monitoring get tracked throughout, with a focus on keeping conditions steady across production and cleaning cycles. Failures often stem from small process drifts—unnoticed spikes in pH, undetected contamination from shared glassware, or subtle temperature gradients across large reactors. Our quality leaders have implemented cross-crew training so all staff are aware of these pitfalls, ensuring knowledge remains close to the shop floor.
Most batches of N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine flow into further synthesis without incident. Still, it is the cautious attention paid after incidents—a sticky dissolution, a hint of unexpected color, or even a minor exotherm—that leads to long-term process refinement. Granular records of each campaign—observed visually, measured on actual line equipment, and reviewed at every changeover—have brought about lower rework rates and promoted smoother shipments to end users. There is no substitute for persistent vigilance rooted in a culture that values real experience above generic assurances or idealized projections.
Tight integration with downstream users has influenced every technology upgrade in our manufacturing of N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine. Changes in drying equipment, improvements in isolation protocols, and even shifts in heating jacket programming descended from open workshops between plant technologists and formulation chemists. Rather than chase flashy but untested changes, we adopt what survives close inspection on both the plant and bench levels. These ongoing adjustments have produced not only more consistent lots, but more efficient use of raw materials and energy.
Critical feedback always finds its way back to the floor team, not just to the office or R&D division. This open-door loop keeps the manufacturing environment dynamic, responsive, and grounded in the realities of actual production demands. As new synthesis routes emerge in the world’s leading labs, our direct production experience—tempered by decades of real trial and error—keeps pace with ever-increasing needs for reliability, transparency, and actionable data.
Direct manufacturing control provides a solid grounding for accurate and transparent documentation. Each outgoing lot of N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine leaves with certificates backed by in-house testing and long-term logbooks. Global shipments meet the expectations of leading regulatory bodies, drawing on compliance with industry standards for controlled substances, environmental handling, and safety in both storage and transit. Audits and certifications, rarely visible to the outside but closely followed within our walls, protect end-users and the environment alike. Experience reviewing regulations hand-in-hand with technical advisors gives our team insight into where documentation matters most—registration dossiers, synthetic route validation, and internal quality reviews.
Over time, regulatory changes or evolving quality standards receive close scrutiny from line supervisors and senior leadership. Alterations in documentation, security, or storage get evaluated and relayed through regular line meetings. This emphasis on grounded, pragmatic adherence to the most current requirements means each shipment aligns with marketplace and user expectations for traceability, stewardship, and supply chain transparency.
Unlike broad market outreach, our focus remains anchored in solving actual end-user headaches. Inconsistent delivered quality, poor batch traceability, and lack of direct technical support rank among the complaints we routinely address from those previously reliant on traders or brokers. Every kilogram of N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine represents a confluence of close process control, real-time QA check-ins, and rapid-response field support. As a plant-based manufacturer, we quickly detect and fix process upsets and offer firsthand experience to labs needing technical improvements.
Long-term partnerships, not simple sales cycles, shape our priorities. Real-time conversations between production teams and customer chemists direct incremental improvements over years, yielding changes in process, turnaround speed, and final performance at the point of use. Our direct accountability for quality and documentation offers a level of certainty—backed by experience—that is harder to find in resold and redistributed materials.
We never stop refining our offering, as invention in downstream chemistry shows no sign of slowing. Every new application in medicinal chemistry, material science, or catalyst design sharpens demand, not just for a pure product, but for reliably documented, high-performance intermediates. Familiar challenges—batch-to-batch consistency, safe storage, supply disruption, and unexpected impurity spikes—drive continued evolution in process, analysis, and documentation. Each real-world problem solved today echoes in the improved performance and lower risk our customers experience tomorrow.
As we look to upcoming needs, the direct connection between shop floor experience and user demands pushes our team further. New equipment, advanced software, and cross-training in analytical chemistry all serve a single goal: better support for chemists who depend on specialized molecules to realize the next generation of discoveries. N-Ethyl-3-cyano-4-Methyl-hydroxy pyridine, tried and trusted, stands as a marker for this ongoing partnership between process engineers, field chemists, and everyone in between who values quality not as a promise, but as an earned result.
