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HS Code |
932826 |
| Iupac Name | 2-amino-4-methylpyridine-3-carbonitrile |
| Molecular Formula | C7H7N3 |
| Molecular Weight | 133.15 g/mol |
| Cas Number | 20360-14-1 |
| Appearance | White to off-white solid |
| Melting Point | 105-108 °C |
| Solubility In Water | Slightly soluble |
| Smiles | CC1=CN=C(C#N)C=N1N |
| Inchi | InChI=1S/C7H7N3/c1-5-2-10-7(9)6(3-8)4-11-5/h2,4H,1H3,(H2,9,10) |
| Pubchem Cid | 373040 |
| Storage Conditions | Store in a cool, dry place |
As an accredited 3-pyridinecarbonitrile, 2-amino-4-methyl- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The product is packaged in a 100-gram amber glass bottle with a tamper-evident cap and clear hazard labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Typically loads up to 12 metric tons of 3-pyridinecarbonitrile, 2-amino-4-methyl- packed in 25kg bags. |
| Shipping | **Shipping Description:** 3-Pyridinecarbonitrile, 2-amino-4-methyl- should be shipped in tightly sealed containers, protected from light and moisture. Transport according to all applicable regulations for hazardous chemicals. Label packaging with proper chemical identifiers and hazard warnings. Ensure compatibility with other shipped materials and provide documentation for safe handling and emergency procedures. |
| Storage | **3-Pyridinecarbonitrile, 2-amino-4-methyl-** should be stored in a tightly closed container in a cool, dry, well-ventilated area, away from incompatible substances such as strong oxidizing agents. Protect from moisture, heat, and direct sunlight. Store at room temperature, and ensure good ventilation to avoid accumulation of vapors. Follow standard chemical hygiene and safety protocols during storage and handling. |
| Shelf Life | 3-Pyridinecarbonitrile, 2-amino-4-methyl-, typically has a shelf life of 2-3 years if stored properly in a cool, dry place. |
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Purity 98%: 3-pyridinecarbonitrile, 2-amino-4-methyl- with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and product reliability. Molecular weight 133.15 g/mol: 3-pyridinecarbonitrile, 2-amino-4-methyl- with molecular weight 133.15 g/mol is used in agrochemical development, where defined stoichiometry enables precise formulation. Melting point 132°C: 3-pyridinecarbonitrile, 2-amino-4-methyl- with melting point 132°C is used in solid-state organic synthesis, where its stability at elevated temperatures improves process safety. Particle size <50 μm: 3-pyridinecarbonitrile, 2-amino-4-methyl- with particle size less than 50 μm is used in catalyst preparation, where enhanced dispersion increases catalytic efficiency. Stability temperature up to 160°C: 3-pyridinecarbonitrile, 2-amino-4-methyl- with stability up to 160°C is used in high-temperature reactions, where its stability prevents decomposition and loss of material integrity. Water solubility <0.1 g/L: 3-pyridinecarbonitrile, 2-amino-4-methyl- with water solubility less than 0.1 g/L is used in hydrophobic formulation systems, where low solubility aids controlled release properties. |
Competitive 3-pyridinecarbonitrile, 2-amino-4-methyl- prices that fit your budget—flexible terms and customized quotes for every order.
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Daily life on our production floor revolves around detail, precision, and the steady hum of responsibility. In the world of fine chemicals, you can’t hide from your processes, your raw material choices, or your end users’ expectations. With 3-pyridinecarbonitrile, 2-amino-4-methyl-, these principles shape every batch.
Over the years, we’ve seen a shift among our partners in pharmaceuticals, agrochemicals, and specialty chemical sectors looking for more specialized pyridine derivatives. This compound, recognizable by its methyl group at position four, its amino group at two, and the nitrile function off the ring, has found a series of important applications in synthesis and downstream chemistry. Manufacturing it means more than pushing a reaction to completion. It means controlling quality at each step, right from catalyst choices down to filtration and packaging. This is not an accident of automation but the result of experience, human oversight, and real-world troubleshooting.
Among all the products that concern pyridinecarbonitrile chemistry, 3-pyridinecarbonitrile, 2-amino-4-methyl- requires special attention to isomerization and impurity management. We learned early that the position of substituents on the ring plays a role in reactivity and shelf-stability — you only notice these differences if you’re responsible for what arrives in a user’s flask months down the line. Sometimes small variances in impurity profiles become the difference between a viable pharmaceutical intermediate and a costly purification headache. Our production team keeps methods fixed — not in a static way, but with disciplined batch documentation and in-process sampling. Our team leads don’t just sign off on paper; they walk the lines, talk to operators, and adjust based on real trends, not lab theory alone.
From years of analyses, we’ve found that keeping color metrics under tight controls, while not always a regulatory requirement, results in downstream processes that are more predictable. We use this experience to keep our purity typically above 98 percent, offering specifications for water, heavy metals, and select isomeric impurities when customers request. These aren’t just numbers — they’re the result of concrete production habits, not a slide on a sales presentation.
End users often look at 3-pyridinecarbonitrile, 2-amino-4-methyl- through the lens of a single process: a coupling reaction, or as a coupling partner in heterocycle assembly. The carbonitrile group opens doors to several reaction types, including nucleophilic additions, condensations, or even direct amide synthesis. In pharmaceuticals, its structural arrangement allows medicinal chemists to build complex scaffolds efficiently, particularly in areas where classical pyridine chemistry doesn’t offer enough scope.
But the manufacturer’s view doesn’t end at the functional groups. We field requests about granulation, handling, and stability — not just the molecule, but the way it arrives in the drum or bag, and how it behaves over time. Chemists appreciate a crisp, free-flowing solid, so we spend time minimizing residual moisture and preventing clumping. Our finishers operate with this user experience in mind. Not every challenge appears in a textbook; often, it’s a phone call from a lab tech who can’t dissolve a lump, or a partner scaling up a process and finding out about the “small” differences between powder and crystalline forms.
Plenty of pyridinecarbonitriles exist on the market, but not all serve the same role in synthetic chemistry. The methyl group at the four-position and the amino at two shape both chemical reactivity and final product usability. In our experience manufacturing related compounds, these changes make genuine differences in solubility, melting point, and how aggressively the product will participate in subsequent reactions.
Consider the difference from simple cyanopyridines: 3-pyridinecarbonitrile shows a distinct profile, but once you add the amino and methyl substituents in particular positions, reactivity opens up, especially with respect to amide and heterocyclic formation. The amino group at the ortho to the nitrile allows for straightforward ring closure or nucleophilic substitutions not available on its unsubstituted siblings. These nuances come to the surface if you’ve spent enough time checking real-world cyclization success rates and working through downstream transformations. This isn’t just incremental chemistry — it’s the difference between quick route selection and extended process optimization.
In practice, we start every campaign by auditing incoming raw materials. Poor input leads to batch instability; that isn’t just a theoretical risk. We’ve had to trace product variability all the way back to off-spec precursors. That forced us to build a closer relationship with primary suppliers and diversify our sourcing strategy. We document each raw material batch, tie it to a production lot, and conduct analytical tests before moving into the reactor. That means when a user needs a particular specification, we can trace back every step — not only for regulatory reasons, but because we’ve seen the impact of shortcuts.
Reactor operation isn’t hands-off, either. Real chemistry involves occasional foaming, unexpected heat release, or subtle color shifts that tell the operator something is not quite at setpoint. Our operators don’t just watch dials — they read the reactions as they proceed, making adjustments on the ground, not sending a memo up the management chain. Some software packages help, but hands and eyes still matter in scaling fine chemicals.
As the manufacturers, logistics is less about ticking a box and more about maintaining product viability. For 3-pyridinecarbonitrile, 2-amino-4-methyl-, packaging matters. Exposure to environmental moisture or reactive metals can affect stability and introduce impurities, so we go beyond minimum packing. We use lined, sealed containers, inspect each batch for visual clues before shipping, and include batch-specific handling notes. Customers in more sensitive application areas, such as pharmaceuticals or electronic intermediates, expect nothing less.
We’ve taken feedback seriously. If there’s a hardening problem in transit, we look at how the compound was filled, whether air was present, if temperature swings caused any changes. Some batch problems have led us to tweak packing or invest in more robust liners. Experience here makes a world of difference; it’s not just a matter of ticking off a packaging checklist.
Our engagement doesn’t end once a drum leaves the gate. We routinely field process troubleshooting calls, and we share analysis data and insights from pilot plant campaigns. Laboratory chemists often face changing regulatory landscapes or switch project priorities quickly. As a manufacturer, we maintain flexibility to adjust production schedules or tweak lot sizes for developing markets.
We also learn from these cross-industry conversations. Several years ago, a surge in demand from agricultural chemical producers pushed us to optimize filtration and drying stages. We modified our micronization methods and reduced heavy metal contamination, using in-house data and customer feedback. This didn’t just make our product more competitive; it lowered waste and improved throughput across several campaigns.
Standard practice includes issuing certificates of analysis, but we find that goes only so far. True quality assurance backs every claim with traceable documentation, retains samples for dispute resolution, and checks incoming returned goods for actual defects. In our labs, analysts run more than one method for identification and purity — including HPLC, GC, and NMR in select cases. Instruments flag anomalies, but troubleshooting rests on experienced chemists. Without real cross-checking, you run the risk of missing subtle byproducts that can affect end-use results.
For 3-pyridinecarbonitrile, 2-amino-4-methyl-, the most relevant parameters besides purity include moisture content, residual solvents, and specific trace impurities arising from upstream synthesis. These are not arbitrary picks: chemists actually see the impact of these in scale-up or downstream performance. We don’t just take customer specs at face value but consult with their technical teams to match requirements that go beyond the basic certificate parameters.
Modern chemical manufacturing grapples with sustainability demands that are not going away. Solvent recycling, catalyst recovery, and waste treatment all cut into margins but pay off in long-term viability. We track every waste stream, separate organic and aqueous layers, and invest in scrubbers and containment. It’s not marketing fluff — regulatory visits and self-audits keep these measures grounded in reality. Product-specific upgrades include switching to less hazardous byproducts and adjusting our purification schemes to maximize yield at lower environmental cost.
For 3-pyridinecarbonitrile, 2-amino-4-methyl-, practical sustainability means maximizing atom economy in key steps, controlling nitrogenous waste, and mole-for-mole improving conversion without ballooning energy usage. As energy costs rise and waste compliance tightens, we keep process engineers in regular contact with those on the production floor for feedback loops. We have learned to scale greener routes and not revert to classical less-efficient syntheses out of convenience.
Every year, priorities in the specialty chemicals market evolve. Our development team keeps a close watch on feedback from both R&D and day-to-day plant operations. We invest in pilot testing for new raw material suppliers, alternate reaction pathways, and advanced analytical methods. Our improvement philosophy borrows as much from practical operator experience as it does from formal research — often, a shift in stirrer design or a tweak in heat exchanger usage can yield greater returns than expensive equipment retrofits.
Some improvements have come from fielding customer complaints that lead us to discover subtle bottleneck points, like filtration aides or transfer line configurations. The lessons are cumulative; this hard-won field knowledge is baked into every change, with documented results. Larger process changes roll out through qualification batches, bringing floor technicians into the design and rollout process.
Navigating regulations is part of our manufacturing routine. Product traceability, compliance with Good Manufacturing Practice, and regular audits by external bodies aren’t abstract boxes to check. Each regulatory shift often forces process upgrades, not always with immediate return, but always with an eventual impact on customer trust and product quality. Our staff spend time in training sessions, stay informed on global chemical restrictions, and read the fine print every time a new guideline comes out.
For pyridine derivatives destined for pharmaceutical applications, finer scrutiny applies. We conduct extra studies on extractables and leachables, conduct stability studies under variable storage conditions, and keep batch archives for years. This approach shields both us and our clients from unpleasant surprises during regulatory inspections or product recalls.
Times change, and so do global supply routes. We’ve weathered bottlenecks due to shipping delays, force majeure from upstream suppliers, and swings in raw material pricing. Our approach involves holding buffer stock, qualifying multiple sources, and direct negotiation with key suppliers. For niche products like 3-pyridinecarbonitrile, 2-amino-4-methyl-, it’s not a question of finding the lowest price but ensuring the right material lands on the production floor, on time, and with verified pedigree.
Sometimes we get caught up in world events, like port slowdowns or regulatory pauses in a region where a key precursor is sourced. In these cases, adaptation isn’t theoretical; it relies on staff working overtime, cross-functional teams managing inventory, and a willingness to delay production rather than compromise on material quality.
Safety is real, not theoretical for us. Years ago, an unexpected exotherm during a batch run taught us what overlooked process data can mean for workplace incident rates. Since then, we conduct regular refresher training, invest in new monitoring equipment, and encourage staff to report near-misses as rigorously as actual incidents. Our maintenance team keeps a record of every system check, looking for signs of degradation and responding long before failures occur.
For compounds like 3-pyridinecarbonitrile, 2-amino-4-methyl-, dust control, proper PPE, ventilation, and secondary containment lines are taken seriously. Safety procedures include acute exposure guidelines communicated on the floor, not just posted in a break room. Real-world safety wins come from staff buy-in, not just compliance manuals.
The road from lab curiosity to production mainstay takes more than inventive chemistry. Our R&D staff evaluate not just potential synthetic routes but also real yield, byproduct management, and adaptability to plant conditions. Sometimes, tried-and-true reactions don’t transfer well to the kilo or ton scale, running into runaway side reactions or separation issues that a bench chemist never sees. We bridge that knowledge gap, running scale trials in collaboration with customers and feeding results back into future campaigns.
In the last several years, emerging end uses in battery and electronics sectors have prompted tweaks in downstream purity and special impurity controls. Our ability to adapt stems less from formal documentation and more from stubborn, firsthand problem solving.
As the people who actually produce 3-pyridinecarbonitrile, 2-amino-4-methyl-, we understand the stakes beyond just molecule counts. Each batch influences the success of further innovation in medicine, crop science, electronic materials, and more. Our pride isn’t in the paperwork but in knowing that a pharmaceutical process runs smoothly, a product shelf is stocked reliably, and customer chemists get results they depend on.
The process is not simple, but the rewards are real. We stake our reputation not just on purity numbers, but on adaptable service, problem-solving under pressure, and a commitment to safety and sustainability forged on the production floor. Experience teaches that every batch can surprise you, but preparation, honest communication, and an unbroken chain of responsibility keep both our product and industry partners progressing.
