|
HS Code |
445657 |
| Iupac Name | pyridine-2-carboxamide |
| Molecular Formula | C6H6N2O |
| Molecular Weight | 122.13 g/mol |
| Cas Number | 872-85-5 |
| Appearance | white to off-white powder |
| Melting Point | 146-149 °C |
| Solubility In Water | Slightly soluble |
| Density | 1.24 g/cm³ |
| Pubchem Cid | 13473 |
As an accredited 2-aminocarbonyl-pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25g amber glass bottle, labeled “2-aminocarbonyl-pyridine,” features hazard symbols, CAS number, lot number, and supplier branding. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 16-18 metric tons of 2-aminocarbonyl-pyridine, securely packed in drums or bags on pallets, moisture-protected. |
| Shipping | **Shipping Description:** 2-Aminocarbonyl-pyridine is shipped in tightly sealed, inert containers to prevent moisture absorption and contamination. The chemical is transported under ambient conditions unless otherwise specified, ensuring compliance with relevant regulations for handling organic compounds. Proper labeling and documentation accompany the shipment to ensure safe handling during transit and upon delivery. |
| Storage | 2-Aminocarbonyl-pyridine should be stored in a cool, dry, and well-ventilated area, away from direct sunlight and incompatible substances such as strong oxidizers. Keep the container tightly closed and clearly labeled. Store at room temperature, and protect from moisture. Use appropriate chemical storage cabinets and ensure spill containment measures are in place to prevent environmental contamination. |
| Shelf Life | 2-Aminocarbonyl-pyridine typically has a shelf life of 2–3 years when stored in a cool, dry, and airtight container. |
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Purity 99%: 2-aminocarbonyl-pyridine with purity 99% is used in pharmaceutical intermediate synthesis, where high product yield and minimal impurity levels are achieved. Melting Point 150°C: 2-aminocarbonyl-pyridine with melting point 150°C is used in solid-state organic synthesis, where thermal stability during reaction is maintained. Molecular Weight 136.14 g/mol: 2-aminocarbonyl-pyridine with molecular weight 136.14 g/mol is used in drug discovery research, where precise stoichiometric calculations ensure formulation accuracy. Particle Size < 50 µm: 2-aminocarbonyl-pyridine with particle size < 50 µm is used in fine chemical manufacturing, where improved dissolution rates facilitate homogenous mixing. Stability Temperature up to 120°C: 2-aminocarbonyl-pyridine with stability temperature up to 120°C is used in high-temperature catalyst production, where compound degradation is minimized. |
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2-aminocarbonyl-pyridine stands out in the world of pyridine derivatives. Over the years, its versatility and reliability have made it a go-to compound for researchers and manufacturers who need more than just the basics from their materials. Speaking to colleagues and suppliers, it’s hard to find anyone who hasn’t crossed paths with this compound somewhere along their journey, whether during synthesis, formulation, or research in both academic and industrial settings. People often see 2-aminocarbonyl-pyridine listed among the so-called building blocks, but the story goes beyond its molecular formula.
My own experience began in graduate school, hunting for intermediates that bring both reactivity and selectivity. From the earliest days of testing reaction conditions to later work in process optimization, the dependable nature of 2-aminocarbonyl-pyridine—known for its distinct amide and pyridine functionality—has stood out. Whether in the pharmaceutical lab or the agricultural R&D facility, this compound plays supporting roles that can determine success or failure in downstream chemistry.
With so many grades of chemicals out there, it pays to recognize when a product offers both consistency and clarity in performance. 2-aminocarbonyl-pyridine is typically available in high-purity forms that fit seamlessly into organic synthesis plans. Users looking at the physical properties notice right away the pure crystalline appearance, a faint, pleasant odor, and smooth solubility behavior in polar solvents. Most researchers ask for purity levels upwards of 98 percent, and suppliers usually respond with specifications that surpass this threshold—reflecting years of improvements in purification techniques.
Physical specifications don’t just stay fixed on paper—they translate directly into how reactions unfold in real-world conditions. Melting points typically fall within a narrow range, a subtle assurance that what’s on the label really matches what’s in the bottle. That’s always been my test: does the actual material in hand stand up to the claims on the specification sheet? Repeatedly, 2-aminocarbonyl-pyridine meets expectations, letting chemists avoid time-consuming troubleshooting caused by off-grade or inconsistent supplies.
Significant advances in chemical synthesis relied on solid intermediates and reagents, and 2-aminocarbonyl-pyridine sits among those that made life easier for organic chemists. During early projects in pharmaceutical discovery, my team leaned into this material’s reactivity to assemble heterocyclic scaffolds—the kind that pop up again and again in bioactive molecules. Beyond the lab, companies working on crop protection agents and specialty dyes also reach for this compound. Its ability to participate in condensation and substitution reactions makes it a flexible tool in both combinatorial chemistry and process development.
I recall a specific moment in the lab when alternative building blocks kept throwing up roadblocks: side reactions, impurities, purification nightmares. Bringing in 2-aminocarbonyl-pyridine reshaped our workflow, cutting hours off our timelines and helping us avoid months of set-backs caused by less predictable intermediates. The practical message? Picking a reliable core piece like this lets you anticipate and manage synthetic routes rather than wrestle with uncertainty at every turn.
Chemists face choices about which building blocks to deploy, especially when efficiency and safety ride on the outcome. Looking at the broader landscape of pyridine derivatives, options like 2-aminopyridine, nicotinamide, or isonicotinamide pop up on supply lists. Each brings individual quirks to the table. For example, 2-aminopyridine tends to be more reactive in nucleophilic aromatic substitution but struggles in certain cyclization reactions. Nicotinamide and isonicotinamide carve out their own niches, especially in pharmaceutical settings, but their chemical flexibility can restrict possible synthetic avenues.
From experience, 2-aminocarbonyl-pyridine delivers a balanced combination of stability and controlled reactivity. Safety protocols—something every lab enforces without exception—feel manageable because its hazard profile doesn’t introduce severe or unpredictable risks. Reports from regulatory testing and academic evaluations support what many have observed firsthand: careful handling goes a long way, without the need to impose extraordinary restrictions.
Conversations with industrial partners often highlight the cost-benefit equation. Others find some pyridine derivatives swing toward higher costs or same-old supply interruptions. 2-aminocarbonyl-pyridine regularly offers solid availability, with prices reflecting its wide range of applications rather than artificial scarcity. The more one digs into user feedback, the clearer it becomes: this isn’t just another generic intermediate—it’s a workhorse that plugs into dozens of routine and specialty needs.
Modern drug discovery hinges on the ability to assemble complex structures with precision and reproducibility. 2-aminocarbonyl-pyridine brings versatility into the equation. Medicinal chemists use it in heterocycle formation, pushing the boundaries of what’s synthetically achievable in lead identification and optimization. Success stories in therapeutic class compounds—from kinase inhibitors to anti-infectives—often detail steps where this compound played a central role.
Outside the world of human health, researchers in crop protection value the material for similar reasons: flexible transformations, manageable byproducts, and clean conversion rates. One agriscience partner once described it as “the type of piece you script into a route when you want to avoid surprises.” That phrase stuck with me. Time and again, consistency has kept development programs on time and within budget.
Dye and pigment manufacturers have also unlocked pathways that benefit from the unique amide-pyridine framework. Stable color performance, controlled introduction of functional groups, and compatibility with green chemistry protocols make this compound a preferred starting point for specialty colorants. In university collaborations, I’ve watched graduate students build new molecule libraries that depend on 2-aminocarbonyl-pyridine for distinct selectivity and reactivity profiles. The spectrum of use cases keeps expanding as more groups recognize its value.
The demands of today’s chemical research don’t often leave room for trial and error. Project managers want answers yesterday; chemists need building blocks that do exactly what’s expected. One ongoing issue is the formation of diverse heterocycles—especially when targeting structures with tight purity and yield windows. Timelines get compressed, and every extra purification step adds costs and upstream headaches.
From countless late nights in the lab, the right starting material becomes more than just another reagent: it’s a form of insurance against failed reactions. 2-aminocarbonyl-pyridine earns its spot on supply lists by delivering clean conversion profiles and making downstream isolation steps more straightforward. The well-defined melting point and straightforward handling characteristics reduce variability, allowing teams to trust in the repeatability of their synthetic strategies.
Many development teams cite risk-mitigation as a reason to standardize on dependable intermediates like this one. Project budgets expand quickly when a chemical’s behavior changes batch to batch, and 2-aminocarbonyl-pyridine keeps those worries at bay. In my own experience, having to swap out similar reagents mid-project led to lost time. Once a team moved to this compound, production plans smoothed out. Others shared similar experiences at conferences and round-tables—the common thread being its knack for simplifying routes that might otherwise get tangled.
Over the years, global standards for sourcing and handling chemicals have become stricter and clearer. Regulatory documentation, traceability, and supplier transparency now serve as the backbone for purchasing decisions. 2-aminocarbonyl-pyridine’s widespread use means buyers can demand and receive up-to-date certification, clear provenance, and genuine transparency about how it’s manufactured and handled. This approach aligns with trusted sourcing practices and reflects industry-wide understanding of the value that clear, reproducible data brings.
Scientists and managers alike now look beyond just the technical sheet. Questions about manufacturing practices, waste streams, sustainability, and ethical stewardship frequently arise. Leading suppliers make it a point to publish data on purity, impurity profiles, and even batch-specific records, letting teams make informed choices. This transparency also reflects real-world accountability—if a problem crops up, it’s traced quickly and resolved directly with the supplier, not drowned in bureaucracy.
Confidence in chemical supply stems from seeing traceable, repeatable performance—and every team I’ve worked with would rather pay a fair price for reliability than gamble on cheaper, less consistent materials. More conversations around environmental and social impact only deepen the appreciation for partners who share information openly and deliver on their promises.
Anyone who’s spent time at the bench knows the realities of safe handling: spills, splash risks, and airborne particulates present every day. 2-aminocarbonyl-pyridine fits well within standard laboratory practices for pyridine derivatives. Gloves, goggles, and lab coats provide the expected level of protection. Compared to certain analogs, which may trigger stronger irritant or sensitizer concerns, this compound stays manageable with routine protocols. It doesn’t bring wild volatility or need elaborate containment, but it still deserves all the respect of every listed laboratory chemical.
Disposal practices stand at the intersection of regulatory compliance and professional responsibility. Teams need clear information to avoid accidental releases or improper filtration methods. Trusted vendors include material safety resources and keep channels open for follow-up questions. By working from a place of knowledge—reading the literature, referencing up-to-date MSDS, and connecting with supplier tech support—labs stay on the right side of both occupational health and environmental law.
Drawn from my own background, taking proactive steps when scaling up—using local exhaust, running small test batches before going to full synthesis, rechecking safety data—has prevented setbacks. Simple diligence pays off across hundreds of work hours that might otherwise vanish to cleaning up preventable incidents. With 2-aminocarbonyl-pyridine, teams put proven practices into motion and move faster as a result.
Chemical supply links have shifted rapidly over the last decade. Globalization and digital information sharing have changed not just how chemicals are sourced, but how people talk about quality, reliability, and loyalty. Suppliers grow stronger when they back their products with concrete track records, not just marketing slides. Through direct experience and feedback from peers, it’s evident that 2-aminocarbonyl-pyridine maintains a near-legendary reputation for reliability—standing out in a field often clouded by shifting specs and vapor-thin promises.
Shifting from a “just another reagent” mindset to treating core materials as vital components of business continuity changes purchasing strategies. Process engineers and procurement officers now weigh risk not just across price points but through the lens of customs clearance, compliance trends, and even geopolitical stability. 2-aminocarbonyl-pyridine, with its well-documented production methods and broad geographic availability, gives buyers a hedge against shocks that might cripple less widely available intermediates.
Direct feedback loops—using supplier customer support, industry working groups, and peer-reviewed technical data—transform raw experience into robust decision-making. I’ve watched supply teams go from firefighting delivery failures to maintaining tight, controlled stocks that support both regular and surge demand. It’s these supply chain lessons that keep essential chemistry on track.
Market volatility, regulatory shifts, and sustainability pressures all push teams to revisit their raw material choices. 2-aminocarbonyl-pyridine, with a footprint in so many synthetic routes, gives scientists and engineers a reliable piece of their process puzzle. It’s more than simple supply—a dependable building block underpins project momentum and opens creative avenues for discovery.
One overlooked angle is the role of digitalization in tracking and sourcing. More teams integrate digital supply management tools into their workflows, allowing for real-time purity verification and instant supplier ratings. Reliable documentation for 2-aminocarbonyl-pyridine, paired with digital inventory systems, keeps projects secure from unplanned delays. Many research groups, including my own, have benefited from these digital records when auditing results or planning new process campaigns. It saves both budget and stress when paperwork and physical stock always align.
Teams also look for proven safety and sustainability data, using this to improve not only compliance but also to enhance stakeholder trust. As supply chains grow more complex, decision-makers gravitate toward products that consistently pass regulatory and operational checks. Consistency here doesn’t mean limiting innovation—it actually supports smarter risk-taking because the foundational components stay rock-solid.
Current challenges demand action, not just awareness. One of the more stubborn issues is ensuring that every batch of 2-aminocarbonyl-pyridine brings the same performance as the last. While quality checks and robust documentation have come a long way, there’s still space for improvement. Investing in supplier partnerships that prioritize in-process controls and open communication channels creates opportunities for joint problem-solving—catching small inconsistencies before they become workflow killers.
Another area ripe for advancement lies in sustainability and circular production. As more teams prioritize green chemistry, opportunities rise for forward-looking suppliers to document and improve the environmental footprint of their production streams. I’ve watched organizations collaborate with vendors to shift toward solvent recovery, waste reduction, and closed-loop systems that minimize both exposure and downstream costs. In the long run, everyone benefits from a cleaner, leaner supply chain built around trust and innovation, not just minimum regulatory tick-boxes.
Training and knowledge sharing represent another frontier. Seasoned chemists and process managers help their teams avoid known pitfalls—passing on tips that shortcut months of paperwork and troubleshooting. Encouraging open access to updated safety guides, application notes, and reaction optimization tips pays dividends in faster upskilling and slimmer error margins over project lifecycles.
Across disciplines and industries, 2-aminocarbonyl-pyridine proves the enduring value of carefully selected building blocks in chemical science. Its predictable, reproducible behavior forms the bedrock for confident process design and brings momentum to innovation programs in pharmaceuticals, agriculture, specialty chemicals, and advanced research. Integrated supply chains, robust documentation, and a deep catalog of in-field experience ensure the compound continues to anchor forward-thinking chemistry. Teams that build their processes around reliable, well-characterized inputs like this can focus their energy where it matters—delivering better solutions, faster and with fewer hurdles along the way.
