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HS Code |
869253 |
| Chemical Name | Pyridine-3-carboxyldiethylamide |
| Cas Number | 2270-19-5 |
| Molecular Formula | C11H16N2O |
| Molecular Weight | 192.26 |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 140-142°C (at 12 mmHg) |
| Solubility | Soluble in organic solvents |
| Density | 1.07 g/cm3 |
| Synonyms | 3-Pyridinecarboxylic acid diethylamide |
| Pubchem Cid | 84914 |
| Smiles | CCN(C(=O)C1=CN=CC=C1)CC |
| Inchi | InChI=1S/C11H16N2O/c1-3-13(4-2)11(14)10-6-5-7-12-8-9-10/h5-9H,3-4H2,1-2H3 |
| Refractive Index | 1.508 |
As an accredited pyridine-3-carboxyldiethylamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle with secure screw cap, labeled “Pyridine-3-carboxyldiethylamide, 100 g,” includes safety symbols and lot number. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for pyridine-3-carboxyldiethylamide: Securely packed in sealed drums or bags, maximizing space, ensuring safe international shipment. |
| Shipping | Pyridine-3-carboxyldiethylamide should be shipped in a tightly sealed container, protected from moisture and light. Use appropriate secondary containment and label according to hazardous material regulations. Ship at ambient temperature unless otherwise specified, and comply with local, national, and international transport guidelines for chemicals, including relevant documentation and safety data. |
| Storage | Pyridine-3-carboxyldiethylamide should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from heat, sparks, and open flames. Keep away from incompatible materials such as strong oxidizers and acids. Store at room temperature, protected from moisture and direct sunlight. Clearly label the container and ensure appropriate safety measures are in place to avoid accidental exposure or spillage. |
| Shelf Life | Pyridine-3-carboxyldiethylamide typically has a shelf life of 2-3 years when stored tightly sealed, cool, dry, and protected from light. |
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Purity 99%: pyridine-3-carboxyldiethylamide with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Melting point 65°C: pyridine-3-carboxyldiethylamide with melting point 65°C is used in solid-phase organic reactions, where it provides predictable solubility and thermal performance. Stability temperature 120°C: pyridine-3-carboxyldiethylamide at stability temperature 120°C is used in high-temperature catalytic processes, where it maintains molecular integrity under processing conditions. Molecular weight 192.24 g/mol: pyridine-3-carboxyldiethylamide with molecular weight 192.24 g/mol is used in analytical reference standards, where it delivers accurate calibration and quantification. Viscosity grade low: pyridine-3-carboxyldiethylamide of low viscosity grade is used in liquid formulation compounding, where it enhances processability and uniform blending. Particle size <10 µm: pyridine-3-carboxyldiethylamide with particle size less than 10 µm is used in fine chemical production, where it supports homogenous dispersion and increased reaction rates. Water content <0.2%: pyridine-3-carboxyldiethylamide with water content less than 0.2% is used in moisture-sensitive syntheses, where it prevents hydrolytic side-reactions and improves product stability. Residue on ignition <0.1%: pyridine-3-carboxyldiethylamide with residue on ignition less than 0.1% is used in electronic chemical manufacturing, where it minimizes contamination and enhances device reliability. Assay ≥98%: pyridine-3-carboxyldiethylamide with assay ≥98% is used in active pharmaceutical ingredient preparation, where it guarantees efficacy and safety in the final formulation. Chromatographic purity ≥99%: pyridine-3-carboxyldiethylamide with chromatographic purity ≥99% is used in reference material preparation, where it ensures trace impurity control and analytical accuracy. |
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Pyridine-3-carboxyldiethylamide does not leap off the shelf for most people. Unless you’ve spent enough hours in a lab surrounded by tangles of glassware and the endless thrum of reflux condensers, even the name takes a minute to break down. Yet, this compound has carved out its own loyal following among chemists, with practical reasons that rarely get airtime outside research and manufacturing circles.
Pyridine-3-carboxyldiethylamide falls into the family of substituted pyridines, specifically as an amide derivative of nicotinic acid. It’s never just the chemical structure that catches a person’s attention—it’s what that structure delivers. With the diethylamide group at the carboxy position, the molecular skeleton balances solubility and stability in a way that fits right in with both classic synthesis and newer methods. For chemists used to dealing with volatility, the lack of excessive odor and manageable reactivity makes life easier in ways the datasheets never quite capture. You don’t often find yourself cursing surprise breakdowns or wrestling with aggressive byproducts mid-reaction, which saves time, cost, and headaches.
Some might say chemical selection blurs into repetition. One amide looks much like another, right? Years of hands-on work prove otherwise. Small differences in structure turn into real gains or setbacks in yield, safety, or even just workflow convenience. With pyridine-3-carboxyldiethylamide, the diethylamide twist means the molecule resists hydrolysis better than basic carboxyamides. That means a longer shelf life and lower background reactivity in solution. Teams don’t have to rush batches or deal with unpredictable variables as often. This steadiness saves hundreds of hours in project timelines by reducing repeat runs from breakdown-related issues—a detail I learned the hard way during crunch periods in process development.
Compared with pyridine-3-carboxamide, the diethylamide version hosts those two extra ethyl chains, which bulk up the molecule but also make it less prone to moisture-induced reactions in ambient air. I remember swapping out benchtop reagents in spring, humidity climbing, and discovering the substituted amide held up hours longer than plain pyridinecarboxamide. Little things like that add up for anyone who rotates stock and checks for degradants after weekends off.
In the real world, fancy words mean very little unless they back up daily challenges. Pyridine-3-carboxyldiethylamide found its way into dozens of projects I handled, from heterocycle synthesis to amide coupling auxiliaries. The compound slips neatly into reactions where a pyridine ring is vital for electronic modulation, but where instability or water sensitivity from “bare” amides can derail product runs.
Researchers in pharmaceutical development often rely on this kind of stability under varied conditions. For one anti-infective project, the reaction mixture needed to stay neutral over fluctuating temperatures and humidity across four days. Most similar amides started yellowing out by mid-run, but the diethylamide version held its color and purity, shaving a week off troubleshooting. In teaching labs, the predictable melting point (usually found between 155-160°C) made it ideal for student projects. Nobody wants frantic emails over failed crystallizations a night before project deadlines.
Its use isn’t only limited to fancy research. I’ve handed it off to scale-up teams who need manageable safety profiles for multi-kilogram syntheses. Traditional reagents sometimes suffer from toxic fume release; with pyridine-3-carboxyldiethylamide, I rarely had to reach for the respirator or field lab complaints about lingering odors, thanks to its low volatility and minimized irritant characteristics. People across the chain—R&D, production, and safety officers—appreciate those silent benefits more than the glossiest brochure could express.
Comparing this material against similar products means diving into more than just chemical nomenclature. Dialing in on the amide’s function, you can spot the difference in decomposition resistance compared to plain pyridine-3-carboxamide or nicotinamide. That matters most during storage, especially outside pristine environments. Early in my career, makeshift labs in old university basements taught me storage failures aren’t a rare nuisance—they’re routine. Where other compounds went off after a few months, leaving ugly residues or nasty odors, this one stuck around cleanly, even after our makeshift HVAC packed up for a week.
On the synthesis side, the diethylamide’s bulk sometimes changes selectivity or suppresses minor side products common in cyclization reactions. This effect keeps reduction steps tidy and boosts isolated yields. I’d often see 5-10% more target product from transformations that usually frustrated newer chemists because the amide handled byproducts better. It’s not a flashy feature, but one appreciated when product recovery stops feeling like a lottery depending on minor changes in temperature or batch size.
Cost always enters the conversation. The slightly higher synthesis cost of the diethylamide sometimes draws skeptical glances from budgets officers. But tracking wastage, failed batches, and analytical tests across a year routinely proves the savings win out. Less reactivity with environmental moisture leads to fewer impurity checks and less need to panic order fresh lots at the worst possible time, especially in lean shops or academic settings. Some chemicals supposedly save on price per gram, but their maintenance costs easily soak up any initial gain.
Handling experience matters in more than just reaction vessels. For those new to lab work or those who worry about exposure, pyridine-3-carboxyldiethylamide feels a little more forgiving. The material leaves less residue on gloves, making cleanup less of a chore. Early in my work, I underestimated how much time disappeared due to sticky compounds or stubborn glassware residues. Fewer chemical burns or chronic skin dryness made the daily grind less daunting, giving newcomers a better first impression of real chemistry—a surprisingly underrated benefit when onboarding students, interns, or techs.
Regulatory-wise, the product also edges out competitors when it comes to compliance hurdles, especially where discharge or disposal comes into play. Non-halogenated and less persistent byproducts mean a simpler paperwork trail compared to more exotic reagents or those flagged under stricter local waste codes. Environmental officers spend less energy second-guessing disposal rules or flagging up labs for poor waste management. That trickles down to smoother audits and fewer unwelcome surprises from inspections, lessons I learned after being caught out by sudden regulatory changes early in my own lab management days.
Nobody likes inconsistent results. Pyridine-3-carboxyldiethylamide, at quality grades above 98%, has shown strong reliability in batch-to-batch consistency, at least from suppliers maintaining robust quality controls. A reliable grade underpins everything; if you’ve ever spent weeks tracing impurities only to land back on an off-lot chemical, the headache never fades quickly. In smaller labs, tracking purity can fall to the bottom of the list—a risky oversight. After enough midnight troubleshooting over inconsistent TLC bands or NMR noise, I’ve grown to trust those simple purity confirmations and stick with known suppliers. The product’s stability under normal storage minimizes surprises from unnoticed shelf-life misspecifications, which sharpens focus on actual research instead of fighting fires over hidden impurities.
Looking toward the bigger picture, pyridine-3-carboxyldiethylamide does not just serve current needs—it can help reshape daily chemical practices. One thing that stands out after years in chemistry is the unspoken hunt for materials that blend effectiveness with real-world practicality. The field keeps chasing sustainability goals, safer labs, and smarter resource use. Compared to single-use specialty reagents or those that burden the waste stream with halogenated byproducts, this amide offers a gentler path. Its manageable toxicology profile and reduced emissions fit better into growing drives for cleaner chemistry, both in teaching and high-output sectors.
One solution I’ve supported involves revamping order protocols to favor compounds like this, which quietly boost lab safety and efficiency. Too often, decision-makers overlook practical advantages in the rush toward specialty products. Procurement teams tend to gravitate toward flashy new chems and miss gains from straightforward stability, gentle handling, and solid track records. Over years, maintaining relationships with reliable suppliers for pyridine-3-carboxyldiethylamide has meant fewer breakdowns in supply and steadier processes regardless of project shifts. It saves everyone—procurement, lab staff, and environmental health officers—unspoken frustrations and late-night workarounds.
Chemical innovation often wins headlines. In practice, steady progress relies more on picking the right tool for each job than on revolutionizing your toolbox every six months. Pyridine-3-carboxyldiethylamide rarely gets a banner spot during conferences or launches. Yet its ability to sit tight in the cabinet, step up to varied reaction pathways, and keep a low hazard footprint where it matters lends quiet confidence to teams working under pressure. Years spent juggling reagents have taught me that most breakthroughs ride the coattails of such unsung materials. More predictable outcomes, fewer regulatory battles, happier trainees, healthier workplaces—these outcomes never make for flashy marketing but shape actual progress on the ground.
One steady advantage: the compound moves easily between small-scale pilot setups and longer production runs. Reagent simplicity, both in chemical design and in daily practice, pays off. I’ve seen new chemists pick up projects faster when their starting materials resist random spoilage, unpredictable fumes, or complicated hazard steps. Time lost to containment drills, purification, and glassware scrubbing is time plucked from actual research. In bigger companies, that difference adds up fast—hundreds of collective hours regained over a year in a single department.
With today’s push for values-driven procurement, use of pyridine-3-carboxyldiethylamide speaks to a wider trend: investing in materials that bolster both efficiency and people’s actual day-to-day experience. Rather than relying only on new, often untested compounds, experienced chemists and lab managers benefit most from materials with evidence on their side—clear safety records, stable performance, useful shelf-life statistics, and manageable environmental impact. Integrating this amide compound means less time wasted on the sorts of repeat mistakes that sap whole departments and more time spent building capacity for meaningful outcomes.
Raw data proves persuasive. For instance, in a project optimizing a large-scale amide coupling, switching to pyridine-3-carboxyldiethylamide trimmed solvent waste, cut operating temperatures by several degrees Celsius, and led to a measurable drop in hazardous exposure incidents. Labs with budget constraints particularly welcome these shifts, since savings carry through procurement, maintenance, training, and compliance checks in a way that outpaces flashier compounds with uncertain long-term liabilities. Looking back at years of budgets, every incremental gain from minimized waste and robust stock management piles up into tangible funds freed for forward-looking projects.
Each generation of chemists asks for more: more safety, more certainty, more capacity to handle complex synthetic puzzles without risking either the environment or their own peace of mind. Pyridine-3-carboxyldiethylamide builds into the backbone of this kind of progress—not because it steals focus, but because it allows focus elsewhere. Selecting materials that work reliably, track cleanly through regulatory frameworks, and resist breakdown, gives communities the freedom to collaborate widely, invest with confidence, and train new cohorts without perpetual reminders of yesterday’s lab accidents or regulatory mishaps.
Working up close with early-career researchers, I’ve seen the direct impact. Reduced uncertainty from dependable reagents means that energy once wasted on contingency plans now channels into new research, cleaner syntheses, or better teaching. People trust their skills more when they trust what’s in the bottle, and that simple confidence transforms a workspace. A single material rarely changes a field—but reliable compounds like pyridine-3-carboxyldiethylamide give labs precisely the freedom to chase bigger goals without distraction.
Ultimately, buying and using pyridine-3-carboxyldiethylamide reflects a broader story in chemistry. Each choice shapes not just a single project, but the working culture of the whole organization. Practical, dependable, easy to manage, this amide fits both day-to-day experiments and high-stakes developments, aligning well with a mindful approach to lab safety, compliance, and research integrity. Looking out across a landscape busy with competing products and glossier promises, the real lessons come from compounds that serve reliably, reduce risk, and let chemists dwell less on what could go wrong and more on what they can make possible together.
