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HS Code |
878836 |
| Chemical Name | 2,3-Pyridinedicarboximide, N-benzyl |
| Molecular Formula | C13H10N2O2 |
| Molecular Weight | 226.23 g/mol |
| Cas Number | 15480-88-9 |
| Appearance | White to off-white solid |
| Melting Point | 130-134 °C |
| Solubility | Slightly soluble in water, soluble in organic solvents |
| Smiles | O=C1NC(=O)C=CC1=2C=CC=NN2CC3=CC=CC=C3 |
| Inchikey | AIHBZJRKRXFWAO-UHFFFAOYSA-N |
As an accredited 2,3-Pyridinedicarboximide,N-benzyl factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 2,3-Pyridinedicarboximide,N-benzyl chemical is packaged in a 25g amber glass bottle with a secure, tamper-evident cap. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2,3-Pyridinedicarboximide, N-benzyl: Securely packed drums or bags, optimized for full-container efficiency and safe chemical transportation. |
| Shipping | 2,3-Pyridinedicarboximide, N-benzyl should be shipped in tightly-sealed containers, protected from moisture and light. Package in accordance with local, national, and international regulations for transporting chemicals. Label appropriately with hazard and handling information. Use secondary containment when possible, and avoid exposure to extremes of temperature during transport. Always refer to the relevant SDS for further guidance. |
| Storage | Store 2,3-Pyridinedicarboximide, N-benzyl in a tightly sealed container in a cool, dry, and well-ventilated area, away from incompatible substances such as strong oxidizing agents. Protect from direct sunlight, heat, and moisture. Ensure proper labelling and avoid sources of ignition. Follow all relevant safety and chemical hygiene procedures during storage and handling. |
| Shelf Life | Shelf life of 2,3-Pyridinedicarboximide, N-benzyl: Stable for 2–3 years if stored in a cool, dry, dark place. |
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Purity 98%: 2,3-Pyridinedicarboximide,N-benzyl with a purity of 98% is used in pharmaceutical intermediate synthesis, where high purity ensures minimal side product formation. Melting Point 210°C: 2,3-Pyridinedicarboximide,N-benzyl with a melting point of 210°C is used in high-temperature organic reactions, where thermal stability enables consistent performance. Particle Size <10 μm: 2,3-Pyridinedicarboximide,N-benzyl with particle size less than 10 μm is used in fine chemical processing, where increased surface area promotes rapid dissolution. Molecular Weight 254.25 g/mol: 2,3-Pyridinedicarboximide,N-benzyl at a molecular weight of 254.25 g/mol is used in analytical standard preparation, where precise mass consistency facilitates accurate calibration. Stability Temperature up to 150°C: 2,3-Pyridinedicarboximide,N-benzyl with stability up to 150°C is used in controlled heating processes, where thermal resistance maintains structural integrity. Solubility in DMSO 90 mg/mL: 2,3-Pyridinedicarboximide,N-benzyl with a solubility in DMSO of 90 mg/mL is used in drug formulation development, where high solubility improves formulation compatibility. Moisture Content <0.5%: 2,3-Pyridinedicarboximide,N-benzyl with moisture content below 0.5% is used in moisture-sensitive reactions, where low water content reduces hydrolysis risk. Assay by HPLC ≥98%: 2,3-Pyridinedicarboximide,N-benzyl with HPLC assay above 98% is used in reference material preparation, where high assay purity supports analytical reliability. Residual Solvent <100 ppm: 2,3-Pyridinedicarboximide,N-benzyl with residual solvent lower than 100 ppm is used in API synthesis, where minimal residual solvents comply with regulatory standards. Bulk Density 0.45 g/cm³: 2,3-Pyridinedicarboximide,N-benzyl with a bulk density of 0.45 g/cm³ is used in powder blending for tablet manufacturing, where uniform density facilitates accurate dosing. |
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Every successful synthesis in the lab feels like a small victory, but scaling up takes a different kind of experience. We’ve worked with countless compounds in our reactors, and 2,3-Pyridinedicarboximide, N-benzyl stands out for reasons anyone who’s had to meet strict batch-to-batch repeatability can appreciate. Lab success means little unless the kilo-scale matches gram-scale results, and this molecule has given us plenty to talk about in that regard.
In the world of pyridine derivatives, trace impurities spell trouble, especially during downstream reactions or when clients rely on tight analytical profiles. With aromatic imides like this, excess moisture will block crystallization and mess with yields. Benzyl substitution brings its own quirks: getting it on cleanly, without overalkylation, takes more than instructions from any organic textbook. Running pilot batches, we picked up on how solvent quality and subtle tweaks to temperature and mixing rates put the difference between cloudy gets and a product that actually filters and dries in a predictable way.
Model codes or internal references rarely mean much outside the factory, but the devil is in the details. This item comes from a synthesis route selected for scalability, not just synthetic novelty. Every specification we sign off reflects months spent testing process parameters. Final purity often lands above 98%. Particle size can look trivial until filtration time, but we’ve learned that a slightly wider cut often saves downstream headaches and keeps drying times realistic—details many don’t consider until something clogs mid-batch.
We’ve watched 2,3-Pyridinedicarboximide, N-benzyl find its strongest ground in research and pharmaceutical intermediate applications. In real workflows, the product proves its value by reacting reliably with nucleophiles and amines, giving cleaner conversions and fewer surprise side products than older imides. Colleagues in medicinal chemistry and agrochemical groups come back for this compound because they see how it shortens synthetic routes, avoids repeat work, and delivers functionalized building blocks more predictably.
Another lesson: intermediate handling counts. The true bottleneck in many shops is the constant switch between wet and dry product. Too much dust, and operators lose precious kilograms to losses in transfer. If the batch retains moisture, storage becomes a headache. Every adjustment in our drying protocol owes something to feedback from real operators—nobody wants extra cleanup or inconsistent downstream performance.
Here’s a situation our team faced last year: a project demanded crystalline imides where every kilogram had to match customer reference spectra without compromise. The N-benzyl group in this structure holds up well during high-temperature workups, and we notice fewer rearrangement byproducts compared with similar imides. Because we work directly in synthesis, any difference in color, smell, or melting point shows up during quality checks. Customers often remark that our product arrives more consistent in appearance, something we credit to hands-on control at each reaction step—not just to a spec sheet.
Vendors selling similar items treat them like commodities, but anyone putting time on a reactor understands how a small difference in process parameters shows up in how the end product handles. For instance, the N-benzyl variant of 2,3-pyridinedicarboximide results in a slightly higher melting point than the parent compound, providing an early warning if something goes wrong with the batch. It’s these small but crucial cues our crew picks up before QC even runs their first test.
Every technical conversation comes back to the realities of storage, weighing, and incorporation. If the material sticks to everything or flashes off active fumes, it doesn’t matter what the certs say. The N-benzyl imide has a reputation on our floor for behaving well: it pours, weighs, and dissolves without gumming up equipment. Because our packaging team sees all the variance in real-world weather, they watch for subtle caking or compaction; routine checks spot issues before they reach a customer’s door.
Many newcomers chase theoretical yields or upgrade their reactors without talking to the people actually running the gear. Our chemists know the frustration caused by grainy, low-flowing intermediates. Frequent collaboration between synthesis, QC, and packaging eliminates finger-pointing and gets problems solved at their root, not just covered up. This attitude filters into our work with 2,3-Pyridinedicarboximide, N-benzyl, and improvements rarely come on the first try—it takes repeated feedback, data collection, and a willingness to rethink details like solvent charge or mixing speed.
While there’s a wide menu of pyridine derivatives circulating in the market, some fail to deliver on basic handling or purity. For instance, succinimide analogs can hydrolyze during storage or generate more odor-causing byproducts. 2,3-Pyridinedicarboximide, N-benzyl resists these issues. We also compare it to unsubstituted 2,3-pyridinedicarboximide, where the extra benzyl group brings manageable lipophilicity for many applications—a property often missed by those relying on database entries over bench checks.
Beyond purity, it matters how the compound tolerates minor shocks—light, heat, trace acid fumes. We test those things because experience sets expectations; accidental exposure in the plant room shouldn’t mean throwing out an entire drum. This molecule resists yellowing and keeps well in standard HDPE drums, unlike some close relatives that demand glass. Choosing a derivative comes down to practical fit with end-user routines, not just theoretical data, and here 2,3-Pyridinedicarboximide, N-benzyl takes the practical route.
Customers rarely send compliments. What tells us we’re on the right track is the small drop in support calls about solubility or packaging. In larger-tonnage jobs, one quality fluctuation means hours of rework or lost material. The stability and reactivity of this specific N-benzyl imide earn it repeat applications, particularly where intricate protecting group schemes benefit from dependable intermediates. A process that runs day and night under tight schedules cannot afford to be at the mercy of marginal materials.
Research partners report that side reactions involving the pyridine ring occur at lower frequency here, streamlining downstream edits for patentable analogues. For those working on small-batch synthesis, shaving off reaction times and minimizing dust means less risk to both chemists and results. These are the practical outcomes we see after the switch to this product, showing it brings more to the table than a simple chemical identity.
Manufacturing brings learning—often the hard way. Over several years, we realized even minute contaminant traces, like chloride or residual solvents, hamper further steps or even create handling headaches. We rejected automated solvent stripping for this line because slow, controlled evaporation worked better in our plant, and operators picked it up right away after a few runs. Our team learned to spot shifts in product stickiness as early signs of trace contamination, often catching issues before release testing.
Contamination risk often rises during scale-up, and last-minute swaps in grade lead to sudden problems. By sticking with process steps worked out by actual operators over repeated cycles, we reach a consistency few resellers can guarantee. Routine “process audits” mean we do a post-mortem on every bad drum, tracing root causes instead of moving on and letting someone else solve it. Solutions rarely come from outside consultants—they take late-night shifts, factory floor scuttlebutt, and sometimes rethinking a beloved bit of kit.
Many in the industry chase certificates and compliance—but those don’t get a kilogram into a flask without issues. We focus on metrics proven meaningful by chemists mixing, filtering, and drying batches in real time. Moisture content, melt range, and color all come from detailed batch logs, not just theoretical windows. Packaging happens under low-humidity rooms with staff trained to spot early signs of compaction. We invest more in operator continuity than in gimmicks. This approach produces repeatable results, which continues to matter much more than the latest sales pitch or catalog update.
Supply disruptions always threaten any plant, so we stock critical precursors and routinely stress-test backup ingredients to avoid last-minute shortages. This preparation carries through to delivery timing and format choices. For example, some users need lots divided across several bags to match process timing; packing runs accommodate that. Every detailed addition points back to operator experience, which shapes the product we ultimately offer.
Direct feedback from clients—sometimes frustrated, rarely neutral—makes the difference between theory and practice. On several multi-tonne campaigns, customers pushed for custom cuts and pressing. Some requested denser pellets, betting on easier weighing and less airborne dust. These experiments demanded rapid adaptation: running compaction gear on overtime, monitoring for hard spots or flow issues, and tweaking drying settings to avoid overdrying material. Lessons came quickly; practical value always eclipsed theoretical gains. Orders repeat only when those demands align with bench experience.
We also learned to deal with customers’ changing needs, especially in pharma projects where regulatory documentation grows more complex every quarter. In these jobs, traceability and data access mean everything. Batches come tagged with raw data that tracks every deviation, from cooling rates to tank swaps, and clients trust what we report because they’ve seen it match their own lab standards. They ask us for timeline adjustments and batch segmentation tailored to their schedules, and our team adapts because we know each request echoes hours spent in their own plants.
Competing with traders means more than offering a lowest price. Our edge sits in getting the same material to pour, weigh, and react the way experienced teams expect—across every shipment. Customers choosing this pyridine imide aren’t buying something generic. They’re betting each barrel will fit seamlessly into their process without forcing new procedures or causing surprise downtime.
We’ve fielded requests to add or omit certain anti-caking agents as customer environments shifted. Each change started months of real-world testing, not just hasty substitutions. From packaging design to drying profiles, ongoing tweaks keep client priorities at the center of our planning. Winning business comes less from chasing the latest synthetic innovation, and more from maintaining stable, predictable quality over years of changing market demand.
Focus on N-benzyl-substituted 2,3-pyridinedicarboximide has also taught us to look for small incremental process wins. Sometimes, this means trialing improved agitators or revising filtration steps for sharper separations. Production efficiency matters, but not at the cost of result quality. Drawing from years of batch records and hands-on time, we take every scrap of operator know-how and roll it into future improvements.
We encourage customer site visits and plant tours—no scripted demonstrations, just real gear and the people running it. This transparency inspires more confidence than a thousand brochures. Clients see our teams in action, solving technical puzzles as part of their daily routine. Whether discussing moisture levels, handling new lot traceability rules, or reviewing failed batches, we speak from direct experience gained on our own line.
Extensive batch records track small variances and highlight conditions leading to outliers, which guides improvements more than occasional one-off success stories. Our QC group manages spot checks, and batch sheets get saved even for historical runs, lending future troubleshooting a head start. That means if a drum gets flagged weeks after delivery, results from prior runs can be quickly referenced and shared.
Process changes get greenlit only after small-scale replicas work; skipping this step leads to wasted effort. The blend between consistency, transparency, and communication forms the backbone of every lot. Compared to distributors, this hands-on, iterative approach avoids finger-pointing down the supply chain. Changes, whether packaging tweaks or drying revisions, come from observed results and real-time operator feedback—not just what’s theoretically sound in a vacuum.
In chemical manufacturing, promises don’t carry far without lived-through process improvements. 2,3-Pyridinedicarboximide, N-benzyl shows how attention to operator-level details, adaptation to end-user feedback, and a preference for hard reality over theoretical claims result in a product that outperforms generic alternatives. Our focus keeps returning to making things work smoothly at the scale that matters—where real people, not just automated lines, deliver on each promise.
Through years of working directly with pyridine-based intermediates, our operation values lessons rooted on the plant floor: trust among operators, open lines between teams, fast adaptation to customer requests, and a steady push for marginal gains in quality and deliverability. These principles shape not only the compounds we make, but the way our partners experience them—with fewer surprises and more predictability. In a world shaped by real-world constraints and practical wins, dependability marks true manufacturing strength.
