|
HS Code |
361531 |
| Chemical Name | N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide |
| Molecular Formula | C14H14N2O |
| Molecular Weight | 226.28 g/mol |
| Cas Number | 101383-94-0 |
| Appearance | White to off-white solid |
| Melting Point | 115-119°C |
| Solubility | Slightly soluble in water; soluble in organic solvents |
| Smiles | Cc1cccc(C)c1NC(=O)c2ccccn2 |
As an accredited N-(2',6'-Dimethylphenl)-2-pyridinecarboxamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed amber glass bottle containing 25 grams of N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide, labeled with hazard warnings and product details. |
| Container Loading (20′ FCL) | 20′ FCL loaded with securely packed drums of N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide, ensuring safe, stable, and efficient chemical transportation. |
| Shipping | Shipping of **N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide** requires secure, leak-proof packaging and labeling in accordance with chemical transportation regulations. The substance should be transported in a cool, dry environment, away from incompatible materials. Appropriate documentation, including Safety Data Sheets (SDS), must accompany the shipment to ensure safety and compliance with local laws. |
| Storage | N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide should be stored in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible substances. Keep the container tightly closed and protect from moisture and direct sunlight. Store at room temperature, and avoid exposure to strong acids, bases, and oxidizing agents to ensure chemical stability and prevent degradation. |
| Shelf Life | Shelf life of N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide: Stable for 2-3 years when stored in a cool, dry, tightly sealed container. |
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Purity 98%: N-(2',6'-Dimethylphenl)-2-pyridinecarboxamide with purity 98% is used in pharmaceutical intermediate synthesis, where high purity ensures minimal side product formation. Melting Point 146°C: N-(2',6'-Dimethylphenl)-2-pyridinecarboxamide with melting point 146°C is used in solid-state formulation studies, where thermal stability facilitates process handling. Molecular Weight 240.30 g/mol: N-(2',6'-Dimethylphenl)-2-pyridinecarboxamide with molecular weight 240.30 g/mol is used in drug design, where defined mass aids accurate dosage calculations. Solubility in DMSO: N-(2',6'-Dimethylphenl)-2-pyridinecarboxamide with high solubility in DMSO is used in in vitro screening assays, where enhanced dissolution promotes reliable bioactivity tests. Particle Size <10 μm: N-(2',6'-Dimethylphenl)-2-pyridinecarboxamide with particle size under 10 μm is used in dispersion formulations, where fine particles improve uniformity of mixtures. Storage Stability up to 25°C: N-(2',6'-Dimethylphenl)-2-pyridinecarboxamide with stability up to 25°C is used in long-term chemical storage, where consistent performance is maintained over time. UV Absorption λmax 315 nm: N-(2',6'-Dimethylphenl)-2-pyridinecarboxamide with UV absorption maximum at 315 nm is used in analytical calibration standards, where precise detection enhances quantification accuracy. Assay by HPLC ≥99%: N-(2',6'-Dimethylphenl)-2-pyridinecarboxamide with HPLC assay not less than 99% is used in API final product control, where analytical purity guarantees batch-to-batch reproducibility. |
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Manufacturing complex amides like N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide places us on the frontline of innovation in specialty chemicals. Years spent refining our process have shown us the difference that a well-designed molecule makes when you start with the right inputs and target the right performance for real-world applications. Synthesizing this molecule is never about just ticking boxes—it’s about knowing how each reaction condition and purification step will affect its properties and its value to customers who actually push chemistry further, whether in research, discovery, or intermediate synthesis.
Our product routinely tests at purities exceeding 98%, which supports researchers and manufacturers who demand confidence at scale. Traces of residual solvents, isomeric byproducts, or water affect behavior in subsequent steps. We see this often: impurities from third-party suppliers cause headaches, so we adopted analytical protocols for each batch. Success comes from controlling every step in-house instead of relying on external processors. Our in-house team performs every part, from high-precision distillation of starting materials through isolation and drying, so our N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide meets the mark each time.
Not all synthetics are equal, even with the same chemical formula. Off-the-shelf or mass-market versions of this compound can fail in sensitive downstream reactions; minor batch variability often shows up as low yields or problematic crystallizations. Because we run much of the synthesis as a closed-loop process, our product never experiences the oxygen or humidity shifts that trigger unwanted side reactions. We verified over many months that this care really pays off in the field. Regular feedback from long-term partners in both pharmaceutical and fine chemical sectors credits our process with fewer troubleshooting cycles and less lost production time.
Our technical support team deals mainly with labs and factories aiming to unlock pyridine-based building blocks for advanced materials or pharmaceuticals. This amide functions as a key intermediate in a sequence of cross-coupling reactions or heterocycle assembly, lending itself to constructing functionalized targets that need high positional fidelity. Organic chemists using this compound often build on its core scaffold, converting it to ligands, biologically active agents, or specialty dyes. The methyl-protected aniline ring in our product proves especially robust during oxidative or metal-catalyzed steps; over time, we noticed far fewer protection/deprotection cycles and witnessed fewer rearrangement byproducts in partner applications.
Downstream in industrial settings, chemists appreciate reproducibility. Process chemists see value in the thermal stability of our amide under standard heating and solvent conditions. It maintains full structure without decomposition for a generous window above 230°C—this withstands the rigors of both bench-scale and pilot reactor runs. Plant technicians confirm that the granulated solid form transports and handles easily, with dust minimized through an optimized crystallization stage. We took pains to solve clumping and uneven particle size because these translate straight to hassle in automated dosing or material transfer systems.
Over the years, we tested a range of alternate N-aryl substituted carboxamides and compared their performance in diverse syntheses. Many look similar on paper but react differently under stress. The 2’,6’-dimethyl groups in our phenyl ring offer real advantages in selectivity versus unprotected phenyl analogs, protecting the amide bond against unwanted ring substitution in multi-step processes. Some customers used to settle for N-phenyl-2-pyridinecarboxamide when faced with inconsistent global supplies. As a manufacturer, we saw that switching to dimethyl-protected versions produced consistently higher yields in Suzuki and Buchwald couplings—a result confirmed by independent analytical labs. This shift cut process time and improved product isolation, making scale-up much more predictable.
Some competitors push generic products with lower lot-to-lot consistency. We keep full records and samples from every batch for traceability, letting process teams run with confidence from kilo to ton scale. Experience tells us that even subtle differences in methylation affect performance, something not always captured in public spec sheets. For example, batches from traders who blend product to meet minimum purity can behave unpredictably due to trace oxidants or uneven melting profiles. We fix standardization at the source by adjusting reaction kinetics and running continuous in-process analytics, avoiding last-minute post-production blending practices common elsewhere.
Many expect a product data sheet to answer all questions, but we learned real performance requires more. Each lot ships with chromatograms, NMR, and residual solvent checks, so users know exactly what enters their process. Routine elemental analysis dismisses the guesswork—our product’s carbon, hydrogen, nitrogen, and oxygen values always line up. Customers rarely ask about compliance because our output already aligns with main regulatory and REACH requirements, but we keep a technical record for full transparency. Product is shipped as a uniform off-white crystalline solid, with a bulk density tailored for automated handling in both lab and plant settings.
We took feedback directly from process engineers and academic labs about particle size, moisture content, and packaging weight, so each release meets the segment needs—whether it’s gram-scale samples destined for university projects or drum-level requests for commercial plants. Our method avoids micro-clumping that slows feeding machines, and each container uses a certified desiccant system to block atmospheric water pickup during shipping.
Scaling production of N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide isn’t just running a bigger batch; maintaining consistent temperature and mixing regimes means small lab tricks need careful translation to hundreds of kilograms. One of the common pain points involved side reactions once agitation or local temperature spikes intensified on larger vessels. We tackled this by retooling reactor shape and adjusting add rates, then scrutinized all outcomes with HPLC and NMR to lock in product conformity.
Waste minimization over the years proved challenging but critical. Routine solvent swap and recovery steps, together with precise temperature mapping through digital control systems, lets us reclaim significant solvent volumes and lower environmental footprint. These recycling steps feed into our pricing and leave customers less exposed to raw material shocks. Our continuous-flow purification module, retrofitted several years ago, cut out the bulk of manual rework and allowed closer control of byproduct levels.
Pharmaceutical researchers often share feedback about using our amide as a feedstock for new heterocyclic drug cores or as a tunable auxiliary in asymmetric transformations. They track how each batch handles in tactical transformations, because subtle impurities sabotage high-throughput screens or scale-out campaigns. We collaborate with a few core academic groups tackling new ligand libraries and heard about their frustration with variable supplier quality—not only purity, but handling and crystallinity. Our in-house crystalline form, with established melting and flow properties, brought confidence to these projects.
Material science groups reached out to us for derivatives aimed at optoelectronic prototypes and functional coatings. The methylation pattern in this amide amps up the electron density profile, leading to selective reactivity in high-energy environments. Our technical support shared practical data on compatible solvents, optimal storage conditions, and conversion rates in oxidative transformations, cutting the time our partners spent in trouble-shooting less tailored raw materials.
The regulatory scene keeps shifting, especially for intermediates feeding into active pharmaceutical ingredients or materials. Our plant maintains REACH-compliant logistics and tracks any evolving standards at the international level. Technical and regulatory teams double-check each outgoing lot against trace metal and halogen contamination, which downstream partners flagged as a growing concern for final product registration. We share all necessary documentation—certificates of analysis, tracking codes, and, when requested, genotoxic impurity profiles—at no extra cost, having learned that trust makes future collaborations run smoother. It’s about building reliability directly into the supply chain, not as an afterthought.
Almost every year, we encounter a new synthetic challenge from a partner working up a difficult sequence. When side reactions or product isolation issues pop up, only a manufacturer can retrace every step, compare analytical spectra, or adjust upstream purification to adapt. As the chemical industry shifted to remote procurement and more elaborate supply webs, we maintained direct ties to customers’ project leads. This means project deadlines are less at risk, since we can release a tailored lot quickly or adjust the process to eliminate a stubborn contaminant before it causes a multi-stage failure.
On multiple large-scale projects, customers told us how direct dialogue with chemists who know both synthetic and commercial routes shortened time-to-results. Trading companies and middlemen rarely share granular data on impurity profiles or flexibility in custom packaging, because they don’t control production assets. Our lab regularly hosts troubleshooting calls and data reviews, treating each inquiry as a process partnership rather than just a commercial transaction. We tap the same analytical tools—HPLC, GC-MS, IR, and thermal analysis—that our clients use, providing continuity in data and bridging gaps in regulatory or process understanding.
Sustainability and safety rank high on our agenda. Three years back, we phased out problematic solvents and transitioned to a two-solvent system validated for full recovery and reuse. Our facility runs waste streams through an in-house thermal oxidizer, keeping emissions below both local and international thresholds. Routine solvent and scrap minimization not only slashes costs, it ensures that companies downstream won’t inherit regulatory headaches linked to legacy pollution.
By listening to safety engineers and plant operators who actually use the product at scale, we fine-tuned the packaging. Each drum uses impact-resistant, anti-static liners, reducing dust and static hazard—a direct response to incident reports from early batch shipments. Our MSDS development and handling recommendations keep pace with evolving best practices. We also established an annual review system for process safety data, making sure operators have up-to-date hazard information based on real-world work, not old literature values.
The manufacture of N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide involves more than strict adherence to chemical recipes. It calls for listening to the practical needs of end-users, tuning every batch for real work, and pushing to reduce waste and simplify compliance. By keeping research, analysis, and production under one roof, we deliver consistency, transparency, and collaboration beyond what any repackager or trader can match. Across projects in pharmaceuticals, materials science, or specialty chemistry, we continue to invest in new process controls, greener technologies, and frequent client engagement. Every solution we engineer comes from direct manufacturing experience and a principle that value lies in usability, sustainability, and trust—not just in hitting a purity number or offering a low price.
Every year, new application requests and unexpected synthesis challenges shape our adaptation plans. Regular site visits with industrial partners, technical exchanges with university collaborators, and open review of ongoing projects all feed back into our process controls. As regulatory and technical requirements change, we upgrade our practice: from validation of trace impurity controls to progressive solvent use reduction. Instead of settling for baseline compliance, our commitment takes the shape of steady technical upgrades and responsive customer support, making sure each lot meets both current and anticipated demands.
As a company that builds from foundational chemistry through to hands-on troubleshooting, our door is always open to technical questions or novel project proposals. We support detailed process reviews to adapt N-(2',6'-Dimethylphenyl)-2-pyridinecarboxamide for unconventional chemistry or emerging applications. Whether improving throughput on established production or pioneering complex discovery research, our team stands ready to partner with specialists, adapt to new feedback, and share the experience we’ve gathered over years of direct manufacture. This is how we maintain and grow the trust of professionals worldwide who count on reliability, transparency, and the steady support only a manufacturer can offer.
