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HS Code |
209568 |
| Product Name | 2-Methoxypyridine-5-carbonitrile |
| Purity | 97% |
| Chemical Formula | C7H6N2O |
| Molecular Weight | 134.14 g/mol |
| Cas Number | 52707-30-3 |
| Appearance | Off-white to light brown solid |
| Melting Point | 60-65°C |
| Solubility | Soluble in organic solvents (e.g., dichloromethane, ethanol) |
| Smiles | COc1ncccc1C#N |
| Inchi | InChI=1S/C7H6N2O/c1-10-7-5-6(4-8)2-3-9-7/h2-3,5H,1H3 |
| Storage Conditions | Store at room temperature, keep container tightly closed |
As an accredited 2-Methoxypyridine-5-carbonitrile 97% factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25-gram amber glass bottle, sealed with a screw cap, labeled "2-Methoxypyridine-5-carbonitrile 97%," includes safety and handling instructions. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Securely packs 2-Methoxypyridine-5-carbonitrile 97% in sealed drums/cartons, maximizing space, ensuring safe international transport. |
| Shipping | 2-Methoxypyridine-5-carbonitrile 97% is shipped in tightly sealed, chemically resistant containers to ensure product integrity during transit. Packaging complies with standard safety regulations for chemical transport. The shipment should be kept in a cool, dry place and handled with appropriate protective equipment. Expedited delivery options are available if required. |
| Storage | 2-Methoxypyridine-5-carbonitrile (97%) 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 the container tightly sealed to prevent moisture ingress. Store at room temperature and follow standard laboratory safety protocols for handling potentially toxic or irritant chemicals. |
| Shelf Life | 2-Methoxypyridine-5-carbonitrile 97% typically has a shelf life of 2 years when stored in a cool, dry, and dark place. |
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Purity 97%: 2-Methoxypyridine-5-carbonitrile 97% is used in pharmaceutical intermediate synthesis, where high purity ensures minimization of by-product formation. Melting Point 72-75°C: 2-Methoxypyridine-5-carbonitrile 97% is used in organic synthesis reactions, where a defined melting point enables controlled processing conditions. Stability Temperature up to 120°C: 2-Methoxypyridine-5-carbonitrile 97% is used in heat-dependent reaction protocols, where stability maintains compound integrity during prolonged heating. Molecular Weight 136.13 g/mol: 2-Methoxypyridine-5-carbonitrile 97% is used in analytical research, where precise molecular weight enables accurate stoichiometric calculations. Low Moisture Content: 2-Methoxypyridine-5-carbonitrile 97% is used in moisture-sensitive formulations, where low water content prevents hydrolysis and preserves functionality. |
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Handling 2-Methoxypyridine-5-carbonitrile 97% day in and day out brings a certain appreciation for its core strengths, especially once you’ve seen how customers put it to the test in labs and processing environments. This isn’t simply another specialty chemical—it’s a staple for a reason. Its structure combines a methoxy group at the two position and a nitrile at five, which opens doors for a range of downstream transformations. People ask about differences and grade, but having run batch after batch myself, a purity of 97% provides that sweet spot: it’s clean enough to avoid headaches in sensitive syntheses, but cost-effective compared to ultra-purified grades where trace impurities add more to your budget than your final product.
Our production lines have handled pyridine derivatives since demand surged in the mid-2000s, so we’ve seen the product’s transformation from a “niche” intermediate into a backbone for pharmaceutical and agrochemical research. Nearly every week, we field questions about process consistency between batches, solvent retention, and scalability to support gram-to-kilogram transitions. By maintaining reactor conditions within tight windows—especially temperature ramps and vacuum control—our team ensures the %97 specification holds, whether a client runs exploratory reactions or scales up for preclinical trials. We often see researchers pivoting between 2-Methoxypyridine-5-carbonitrile and related compounds, like the methyl or ethyl ethers at other ring positions, and the practical learnings from actual processing tell a story that goes beyond usual spec sheets.
Working from raw material selection through finished product, small differences in impurity profiles change how the intermediate reacts down the line. Impurities show up in NMR and HPLC profiles, and when they exceed 3%, the risk of failed runs climbs, especially for libraries of heterocycles or advanced pyridine cores. This is a real issue in pharma approaches where avoidance of side reactions saves time and resources. Our batch quality control, layered with both chromatographic and titration checks, clamps down on off-spec. I remember a customer desperately chasing a byproduct ghost in a pilot run until we traced it to a slightly over-reacted upstream material from another supplier. Reliable conversion, ensured at a 97% standard, becomes an insurance policy for process chemists and analysts.
You see the value of lot-to-lot consistency most clearly not from a chart, but instead from the emails about completed syntheses, successful couplings, and “no surprises” workflow handoffs. Every researcher wants fewer deviations in downstream reactions. Spec meets reality in the time saved troubleshooting unwanted peaks or loss in yield. By sticking close to raw materials we’ve vetted ourselves and staying involved in every reactor charge, our team has first-hand knowledge about where to be vigilant—monitoring parameter drift, solvent dryness, and filtration artifacts. You learn fast that purity is a promise customers keep you accountable for, every kilogram at a time.
Sourcing a reagent with a "97%" tag means something concrete in the daily life of a bench chemist. There’s always the temptation to buy higher-purity grades, but unless you’re running exacting analytical-grade reactions, that extra percentage point only boosts cost, not practical outcome. We supply the 97% grade for flexible use—good enough for most medicinal chemistry scaffold builds, biaryl couplings, and esterifications where minor non-polar residuals won’t sabotage your pathway. We set the model by our spec: 2-methoxy substitution confirmed via NMR integration, pyridine core purity and nitrile presence checked by both IR signals and GC/MS cleanout. Chromatograms stay sharp in every lot.
I’ve walked factory floors where less stringent specs crept up at the expense of project progress. In practice, technical goals drive specification, not vice versa. For folks working on scalable processes, that means minimal batch-to-batch variations, no polymorphic suprises, and absence of byproducts that could trip up a downstream hydrolysis or amination step. Production experience tells you what typical contaminants look like: run-longer side-chain scission, marginal ring alkylations, and polar trapping. Our repeated analytical runs root out those traces, so you don’t have to second-guess your input before every reaction. It’s less about dogmatic purity, more about reliability from one drum to the next.
Direct customers sometimes compare 2-Methoxypyridine-5-carbonitrile against more familiar options like 2-Methoxypyridine itself, its methyl derivatives at different ring positions, or unsubstituted nitrile variants. Based on actual experience with test and scale-up runs, the ortho-methoxy plus para-nitrile combo shows higher selectivity in cross-coupling and condensation reactions. That’s because the electronic distribution strongly favors functionalization at ring sites away from the methoxy and nitrile, giving better yields and a more controlled product slate. Chemists reaching out to us after parallel screens routinely report steadier results and easier purification profiles.
Onsite teams have handled both 95% and so-called “high-purity” 99% versions—if trace polar byproducts or solvent residues matter, 99% sometimes makes sense. But, in day-to-day use, the difference between 95% and 97% makes the biggest practical jump. The 97% grade clamps down on non-polar and polar trace side-products, which often float in the impurity window of lower grades and can show up later in stress testing or accelerated stability work. You get the performance metrics you need, without paying for overkill. For high-throughput labs or early-stage screening, 95% may tempt from a price perspective, but my time at the bench showed how easily those few points spook a reaction outside tolerance—struggling with cleanup, inconsistent intermediates, or unidentifiable peaks in a mass spec profile.
The main users call for both reliability and adaptability—neither comes easy without hands-on experience. Academic labs, contract research organizations, and colorant manufacturers approach the intermediate from different technical angles. Those in pharma are after swift SAR cycles, often loading small-scale runs through automated synthesizers, then transitioning to tens or hundreds of grams in a hurry. They count on a product that doesn’t change its tuning; every deviation means lost days and extra HPLC runs to confirm real changes in molecular output instead of artefacts.
We’ve worked closely with customers scaling bench discoveries to pilot lots. Most seek an intermediate that stands up to long-hour reactions, repeat extractions, and the occasional need for extra purification. Each time, they’re looking to avoid the batch-to-batch drift that can creep in if you don’t control synthesis stage-by-stage. From my side of the reactor, seeing the same clear solution and crystalline solid out of every run, knowing that upstream feeds—cyanation precursor, methoxy donor—have been validated through supplier audits, makes the positive difference. There’s no shortcut but to stay close to every production stage—sampling off the filter, adjusting pH, and watching the runoff—to make sure the intermediate reaches the customer as expected.
Customers push us for details because it affects their daily work directly. One recent discussion involved troubleshooting a hydrogenation that wouldn’t proceed. We traced the issue to a trivial side contaminant present in a competitor’s sample, a few percentage points higher than our 97% grade. Running split-sample reactions showed our product outperformed alternatives, saving the user hours in column workup and giving a cleaner chromatogram. They shifted all their batches to our 97% grade before moving into scale-up. That’s the type of feedback that shapes our process: real use, not just abstract guarantees.
Our support team relays what they hear from researchers almost every week: consistent behavior in basic conditions, tight melting-point windows, no strange odors from decomposed side-products. Everyone wants assurance there’s minimal “lot drift” in their results. By tracking every drum back to its batch and logging every adjustment, from the minor tweaks in drying to pressure readings in vacuum transfer, we keep outcomes repeatable. I’ve tasted the frustration of getting “almost right” intermediates and spending more time correcting than progressing; that frustration drives our commitment to this grade’s consistency.
One hidden value people find in this intermediate is smoother purification downstream. The 2-position methoxy helps reduce tar formation in condensations and aminations, and the 5-carbonitrile makes for easier quench and separation whenever someone’s running hydrolytic cycles or reducing to primary amines. The product’s statistical “sweet spot” at 97% purity limits extraneous polymeric side-products that would otherwise ride along in your next transformation. We fine-tune temperature and solvent loading at every processing step, not as a box-ticking exercise, but to make sure these benefits stick with the end-user.
Customers tend to move from bench trials to kilo-scale campaigns if the first few syntheses go smoothly. We get calls asking for extra kilograms once early tests clear; less time lost on post-reaction cleanup or impurity chasing convinces even the cost-focused clients. You won’t find much patience for repeated filtering or tedious crystallization tweaks in a live project timeline—nobody does. Past experience running dozens of transformations shows that a reliable, well-vetted 97% grade cuts out most preventable batch delays by keeping impurity levels predictable. Analysts can spend more hours on primary targets instead of obsessively tracking down deviations in their “reference” runs. This single fact preserves both resources and project timelines.
People on the outside often overlook what goes on inside a real manufacturing environment. Our workers have to manage exposure, safe handling, and the strict regulatory checks demanded by pharma and related markets. Anything in the pyridine family gives off a distinctive aroma—a constant reminder of the compound’s volatility. Continuous training keeps safety at the forefront; proper storage, careful transfer, and built-in containment lines are just part of daily life. Years on the line teach you that atmospheric variations—temperature swings, humidity—can impact storage or transport stability. Vigilance here keeps product upright, with no degradation or hidden polymerization upon arrival at the user’s bench.
From plant experience, I can say routine analytical checks flag problems before they reach a customer. Spot-testing for trace acid impurities, keeping an eye out for peroxide formation, and always logging lot histories ensure safety and quality compliance. A solid 97% grade meets strict in-house criteria, with periodic audits catching any drift before it impacts end users. All records match up, and each kilogram remains traceable with tight chain-of-custody, reflecting both regulatory demands and the trust our clients place in what we deliver.
Feedback cycles drive us to improve. Each year, we review production data, searching for patterns or recurring issues. R&D teams push new reaction routes or alternative solvents, nudging us toward even greater consistency or greener practices when feasible. As customers continue shifting into novel therapeutic areas or tweak manufacturing routes for competitive advantage, our facility adapts—sometimes with small tweaks in batch processing, other times by revisiting supplier partnerships or updating analytical benchmarks.
Through years of hands-on synthesis, team learning, and thousands of kilograms shipped, what stands out most is the practical value—not abstract properties or isolated numbers, but real agreements reached with each drum, each analytical report, and each project brought to completion. 2-Methoxypyridine-5-carbonitrile 97% keeps gaining traction because it delivers what companies, labs, and chemists want: predictable results, fewer interruptions, and the confidence to scale discovery into measurable production.
Manufacturing and supplying this intermediate ties together experience from both production and direct customer support. Every day, experienced workers bring firsthand knowledge to bear—making quick judgement calls on drying temperatures or extraction ratios, checking analytic results against past runs, and digging into complaints or improvement ideas from end-users. The real difference emerges not from marketing speak or neutral descriptors, but from the record of jobs run, syntheses carried out, and partnerships maintained with researchers and producers who rely on trustworthy supply.
This reliable, 97% grade product provides a well-balanced solution for those who expect robust performance under varied conditions. Keeping the standard high and the process transparent is about more than checking regulatory boxes—it’s about enabling project success for everyone along the chain, from the smallest research bench to the largest industrial pilot plant. Experience on the ground floor steers how it’s made and how it serves the diverse, ever-changing world of chemical research and development.
