|
HS Code |
691407 |
| Iupac Name | N,N'-(1-Methyl-1,2-ethanediyl)bis(3-pyridinecarboxamide) |
| Cas Number | 857036-28-1 |
| Molecular Formula | C15H16N4O2 |
| Molecular Weight | 284.32 g/mol |
| Appearance | Solid |
| Solubility | Soluble in DMSO, DMF, partially soluble in ethanol |
| Smiles | Cn(CNC(=O)c1cccnc1)C(=O)c2cccnc2 |
| Inchi | InChI=1S/C15H16N4O2/c1-19(10-15(21)13-6-2-8-17-12-13)11-14(20)16-9-5-3-7-18-4-9/h2-8,12H,10-11H2,1H3,(H,16,20)(H,17,21) |
| Storage Conditions | Store in a cool, dry place, tightly sealed |
| Pubchem Id | 18117984 |
As an accredited 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical is packaged in a sealed, amber glass bottle containing 25 grams, labeled with hazard symbols and product identification details. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis-: Typically loaded in 25kg fiber drums, totaling about 8-10 metric tons per 20-foot container. |
| Shipping | Shipping for **3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis-** requires packaging in tightly sealed, chemical-resistant containers. The product should be labeled according to relevant chemical safety regulations. It should be transported under ambient conditions unless otherwise specified, with proper documentation and handling precautions to ensure safe arrival at the destination. |
| Storage | 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizers. Protect the chemical from moisture, heat, and direct sunlight. Proper labeling and secondary containment are recommended to prevent accidental release and ensure safe handling. |
| Shelf Life | Shelf life of 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- is typically 2–3 years if stored in cool, dry conditions. |
|
Purity 98%: 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high product yield and minimal impurity formation. Melting Point 110°C: 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- with a melting point of 110°C is used in medicinal compound formulation, where controlled melting facilitates precise blending and integration. Molecular Weight 271.31 g/mol: 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- of molecular weight 271.31 g/mol is used in analytical research, where accurate mass contributes to reliable quantitative analysis. Stability Temperature 60°C: 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- stable up to 60°C is used in industrial process development, where thermal stability enhances storage and handling safety. Solubility in DMSO >10 mg/mL: 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- with solubility in DMSO >10 mg/mL is used in biological assay preparation, where high solubility allows for concentrated stock solution preparation. |
Competitive 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615371019725 or mail to sales7@boxa-chem.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: sales7@boxa-chem.com
Flexible payment, competitive price, premium service - Inquire now!
On the manufacturing floor, the name 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- refers to more than a string of chemical terms. Years of hands-on experience have shown how a single molecular tweak can open up new functions and applications for a compound. In our line, watching the entire process, from steady raw material feed to finished, high-purity outputs, reveals the difference between theoretical chemical potential and practical performance.
Producing this molecule consistently depends not only on raw material selection but also on skillful process adjustment. We leverage both modern analytical instrumentation and a trained eye for detail earned on the shop floor. Every batch undergoes a set of checks—chromatography profiles, melting point verification, water content determination—to ensure real-world purity and batch-to-batch stability. Customers in fine chemicals, pharmaceutical intermediates, and other valuable industries lean on those standards. The only way they can trust the quality is if we see the process through from start to finish, replacing artifice and speculation with deliberate, controlled synthesis.
In our work, molecular design translates directly to function. The 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- molecule stands apart because of its dual amide functionality linked through a methylated ethylene bridge. This combination imparts distinctive solubility and compatibility characteristics. Downstream, these features save blending efforts or enable easier formation of stable formulations, which practitioners appreciate when chasing reliable performance without repeat surprises.
We've observed that structural differences, even within the pyridinecarboxamide family, dictate the chemical’s behavior in rigorous conditions. This specific connectivity enhances stability and modifies interaction profiles with other ingredients. That’s not just a theoretical claim—feedback from process engineers in pharmaceutical and agrochemical plants confirms repeatable improvements compared to simple monoamide analogs or linear linkers. Over time, hearing these candid field reports influences how we optimize process control settings to preserve these desirable traits batch after batch.
Traditionally, 3-Pyridinecarboxamide derivatives serve as valuable intermediates in the synthesis of more complex active compounds. In our experience, formulations that rely on N,N'-(1-methyl-1,2-ethanediyl)bis- substitution benefit from increased robustness in the presence of strong bases or acids—an edge in multi-step syntheses. As a manufacturer, we witness first-hand the pressures chemists face to minimize downtime and troubleshooting. Delivering an intermediate with vetted stability properties eases pressure points at job sites, speeding up campaigns and keeping costs on target.
Key users in pharmaceuticals and specialty chemicals often arrive asking for proof beyond a spec sheet. They bring their own analytical data, propose stress tests, and expect honest discussion about both strengths and possible limitations. Watching pilots move from flask to kilo lab, we document both expected and surprising results. Sometimes, improvements stem from small changes in process temperature or solvent purity, which go unmentioned in technical brochures but matter deeply to final product performance.
Scaling laboratory procedures up to manufacturing scale isn’t always seamless. Temperature control, mixing times, and reagent addition subtleties all matter. Early in our journey with this compound, a pilot batch exposed temperature spikes that left traces of byproduct. Instead of dismissing this as a minor glitch, our team overhauled the heat transfer setup and verified new process controls. Adjustments like these turn up in lower impurity levels and easier downstream purification, benefits any downstream processor will spot. A manufacturer lives by repeatable excellence—scaling up with full awareness of how real equipment and real people influence each run.
We often consult directly with partners moving from process development to commercial runs. Our engineers share best practices for transferring procedures, forewarning about batch viscosity shifts or phase-separation challenges unique to this bis-amide structure. Several customers revisited their solvent choices after trying standard batch workups and running into isolation difficulties. When a technical call helps them resolve stubborn bottlenecks and improve yield, that hands-on help is worth more than a glossy product bulletin.
Practical chemistry always comes back to purity. Even trace impurities can sabotage multi-step syntheses, trigger unexpected interactions, or force expensive purification later. Unlike distributors guessing at upstream conditions, we know every input, every temperature hold, every filtration stage. Our largest customers, sensitive to even minor quality shifts, regularly audit our plant and bring their own quality control teams. Their analysis typically confirms that controlled, transparent manufacturing practices beat assumptions or market reputation.
Recalling an instance where a large pharmaceutical client flagged a trace impurity, we traced the source to a reagent lot—prompting direct supplier engagement and more rigorous batch documentation. These stories drive home how the real impact of what leaves our plant travels far beyond the shipping dock. In niche markets, a half-percent gain in purity can mean the difference between regulatory approval and an expensive investigation. Our commitment to openness and willingness to adapt processes comes from seeing how our day-to-day choices shape customers’ results months or years later.
Any compound with broad industrial applications brings responsibility along with opportunity. Over decades of manufacturing, we’ve learned that the right controls—containment, ventilation, personal protection—safeguard not just products, but people. We’ve invested in inventory tracking, long-term storage studies, and a set of standardized work practices based on lessons from equipment incidents and near-misses in the past. Tough environmental audits prompted upgrades in exhaust handling and broader testing of plant emissions.
Our work doesn’t end when a drum rolls out the door. Fielding calls from customers about storage, shelf life, or transportation incidents leads to process reviews, corrective actions, and sometimes new training for material handlers inside and outside the plant. Direct feedback from emergency response teams fed into new labeling and repackaging standards—details that go a long way toward maintaining trust with partners who rely on timely, accurate shipments with traceable histories.
Anyone in our shoes knows there’s no shortage of pyridinecarboxamides, but not all offer the same mix of processability, solubility, or reactivity. Experience shows that N,N'-(1-methyl-1,2-ethanediyl)bis- substitution leads to a more compact molecule, decreasing water uptake and improving shelf stability, especially in humid conditions. Customers with production lines in tropical or marine climates report notably lower rates of caking and degradation compared to linear or non-methylated bis-amide options.
Differences also emerge during large-scale chemical syntheses. Straight-chain analogs sometimes show lower chemical resistance or can suffer from greater reactivity with co-formulated agents, which leads to more frequent interruptions or unexpected maintenance. By focusing on structure-performance relationships, our development lab demonstrated quantifiable reductions in byproduct formation during hydrogenation and condensation steps, directly traced to this product’s unique backbone. Customers interested in green chemistry or waste reduction find these points attractive—fewer side reactions mean less to dispose of later down the line.
In real-world manufacturing, flexibility counts. This chemical’s dual amide functionality, coupled with the subtle influence of the methyl and ethylene groups, supports a wider performance window across more applications. Synthetic chemists appreciate repeatable results without the need for constant solvent swaps or temperature juggling. Listening to end-user engineers, we learned that this broader utility cuts both direct production costs and the less visible costs of troubleshooting and plant slowdowns.
The pharmaceutical sector values reliable, high-purity intermediates—one inconsistency in an intermediate can unravel an entire product launch. Meanwhile, crop protection and specialty polymer companies use the same material as a key building block, where downstream robustness translates into fewer field failures or product recalls. Our approach draws from these stories, refining our synthesis methods to meet or exceed customer performance expectations while being ready to tackle challenges if specifications or regulations change partway through a project lifecycle.
Market requirements grow more complex every year. End-users ask for cleaner products with traceable sourcing and proof of responsible handling. At the plant, this means improving both upstream vetting of reagents and downstream minimization of waste. Early efforts cut chemical discharges with in-process recycling and stricter waste handling, but further success took deeper partnership with suppliers and regulatory bodies. Documenting each production step, sharing full analytical reports, and accepting outside audits form part of our ongoing commitment to sustainability.
More customers are now evaluating chemicals with an eye towards environmental persistence and industrial hygiene. Although this compound typically breaks down without forming persistent toxins, we continue to refine production runs to keep minor byproducts in check. Revising protocols after learning from field incidents, we prioritize containment, safe handling, and transparent communication—not just because regulators demand it, but because plant operators, logistics teams, and end-users deserve confidence in every package we ship.
Mass-market commodity sellers make general claims about product benefits without much direct involvement. In contrast, we see firsthand how choices about raw material procurement, process refinement, and analytical controls reach all the way to the end-user. By showing our work and inviting customer technical teams to see detailed production logs, we establish trust that forms the backbone of repeat partnerships.
Occasionally, customers request process modifications to align with unique project goals. We invite those discussions and factor direct feedback into process development, achieving targeted impurity profiles or shifting physical properties to aid their manufacturing setups. From impromptu joint troubleshooting sessions to longer-term collaborative R&D, we respond not just by describing offerings, but by adjusting and documenting real changes on the production line.
A manufacturer’s role often extends into helping customers bridge bench-scale ideas with industrial-scale needs. Our own development chemists test production-ready versions of 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis- across a range of reaction types, anticipating practical issues that can trouble scale-ups. Reporting small issues—unexpected foaming, phase separation, unusual color formation—lets our partners adapt and plan, rather than react to late-stage surprises.
Collaborative testing with pilot plant partners provides valuable feedback that cannot always be predicted from literature or small-scale trials. Adjusting stoichiometry, solvent selection, or filtration timing yields marginal gains, translating to higher throughput, more robust yields, and leaner purification for downstream users. As a manufacturer, we see the impact of those details every day, and our customers have come to expect open communication about challenges and adjustments.
Regulatory frameworks continue to evolve, requiring adaptive documentation and traceability on every production run. From responding to new toxicology standards to producing audit-friendly records, compliance has grown in both importance and complexity. We invest in regular training and system upgrades to ensure traceability—because delayed responses to regulators can cost customers valuable market access.
Customers increasingly look for suppliers prepared to answer detailed questions not just about chemical structure, but also about process sustainability, waste handling, and long-term safety. The ability to provide real analytical reports, share proof of change notifications, and collaborate openly gives us an edge. Those interactions form the core of our business—rooted not in claims, but in a demonstrated track record.
Years of making 3-Pyridinecarboxamide, N,N'-(1-methyl-1,2-ethanediyl)bis-—and its relatives—have taught us that the smallest process changes ripple downstream, affecting partners around the world. Whether helping a biotech startup hit timelines or advising a multinational on global shipping logistics, the lessons we draw from direct manufacturing experience inform every recommendation, adaptation, and improvement.
By being honest about process limitations and open about both strengths and challenges, we build the trust needed for long-term collaboration. Delivering consistent, well-characterized chemical products takes more than routine—it requires ongoing engagement with changing industry expectations, openness to criticism, and a readiness to adjust every time facts on the ground shift. The result is more than a product: it's a relationship based on shared success, earned one production batch at a time.
