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HS Code |
305169 |
| Chemical Name | 2-Amino-6-pyridinecarboxaldehyde |
| Molecular Formula | C6H6N2O |
| Molecular Weight | 122.13 g/mol |
| Cas Number | 27348-78-9 |
| Appearance | Light yellow to beige solid |
| Melting Point | 85-88 °C |
| Solubility | Soluble in water and organic solvents like ethanol |
| Purity | Typically ≥98% (commercial) |
| Smiles | C1=CC(=NC(=C1)N)C=O |
| Inchi | InChI=1S/C6H6N2O/c7-6-2-1-5(4-9)8-3-6/h1-4H,(H2,7,8) |
As an accredited 2-Amino-6-pyridinecarboxaldehyde 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 25-gram amber glass bottle, sealed with a screw cap, and labeled "2-Amino-6-pyridinecarboxaldehyde." |
| Container Loading (20′ FCL) | 20′ FCL container typically loaded with securely packed drums or bags of 2-Amino-6-pyridinecarboxaldehyde, ensuring safe chemical transport. |
| Shipping | 2-Amino-6-pyridinecarboxaldehyde is typically shipped in tightly sealed containers to prevent moisture and air exposure. It should be labeled according to hazardous material regulations and transported in compliance with all safety guidelines. Ensure secondary containment, avoid extreme temperatures, and handle with appropriate personal protective equipment during shipping and receiving. |
| Storage | 2-Amino-6-pyridinecarboxaldehyde should be stored in a tightly sealed container in a cool, dry, and well-ventilated area, away from light, moisture, and incompatible substances such as strong oxidizers and acids. Ensure the storage area is equipped for safe chemical handling and properly labeled. Avoid exposure to air and humidity to prevent degradation or unwanted reactions. |
| Shelf Life | 2-Amino-6-pyridinecarboxaldehyde should be stored tightly sealed, protected from light and moisture; typical shelf life is 2–3 years. |
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Purity 98%: 2-Amino-6-pyridinecarboxaldehyde with purity 98% is used in pharmaceutical intermediate synthesis, where high-purity ensures optimum product yield and minimal impurities. Melting Point 92°C: 2-Amino-6-pyridinecarboxaldehyde with a melting point of 92°C is used in heterocyclic compound formation, where thermal stability during reactions is critical for product consistency. Molecular Weight 136.13 g/mol: 2-Amino-6-pyridinecarboxaldehyde of molecular weight 136.13 g/mol is used in organic building block applications, where defined molecular mass aids in precise stoichiometric calculations. Water Solubility 12 g/L: 2-Amino-6-pyridinecarboxaldehyde with water solubility of 12 g/L is used in aqueous phase synthesis protocols, where efficient dissolution streamlines reaction efficiency. Storage Stability up to 24 Months: 2-Amino-6-pyridinecarboxaldehyde with storage stability up to 24 months is used in chemical inventory management, where extended shelf life reduces material waste and procurement frequency. Particle Size <100 µm: 2-Amino-6-pyridinecarboxaldehyde with particle size under 100 µm is used in high-performance thin-layer chromatography, where fine particle distribution enhances separation accuracy. Reagent Grade: 2-Amino-6-pyridinecarboxaldehyde of reagent grade specification is used in analytical research laboratories, where certified quality supports reliable experimental results. Flash Point 135°C: 2-Amino-6-pyridinecarboxaldehyde with a flash point of 135°C is used in controlled solvent extraction methods, where improved handling safety is ensured during processing. |
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Walk through any research lab or chemical plant, and you'll find a constant search for building blocks that reliably drive innovation forward. Among the unsung heroes, 2-Amino-6-pyridinecarboxaldehyde stands out for solid reasons. It doesn’t shout the loudest in the world of fine chemicals—yet behind the scenes, it quietly shifts whole projects from theoretical promise to tangible results. Whether blending its core into drug molecules or wielding it for specialized organics, I’ve seen first-hand how this compound’s versatility gives chemists practical control over their workflows. What makes it so useful isn’t just the structure on paper, but the way it blends reactivity and selectivity without cranky side reactions derailing process flows.
2-Amino-6-pyridinecarboxaldehyde’s skeleton looks simple, but the real story starts with the subtle balance between its amino group and the aldehyde at opposite ends of the ring. This set-up unlocks a special kind of duality. The molecule offers coupling points for both nucleophilic and electrophilic attacks, making it a dream for stepwise assembly. Synthetic chemists reach for this aldehyde when other options are either too rigid or too prone to unwanted cross-reactions. I’ve watched colleagues in pharmaceutical development swap out other reagents for this one, sidestepping purification headaches and trimming days from multi-step routes. Its formula, C6H6N2O, gives a neat weight and structure—light enough for easy manipulation, yet stable through demanding reaction conditions.
Every product in the lab shelf lineup comes with a story—a reason for staying front and center instead of gathering dust on the back row. With 2-Amino-6-pyridinecarboxaldehyde, it’s the accuracy and predictability that makes it a favorite among bench chemists and production engineers. Peptide synthesis, heterocycle construction, and API intermediate manufacture all find new efficiency with this building block. In medicinal chemistry, the compound often anchors combinatorial libraries, delivering diversity through straightforward modifications. API innovators often gravitate toward it because its functional groups withstand many protecting and deprotecting conditions without splitting apart or forming tars.
There’s no shortage of similar molecules on the market. Look at alternatives like 2-aminopyridine or plain pyridinecarboxaldehydes lacking that balanced pairing of functionalities, and you see important gaps. Some lack the right mix of reactive handles, locking chemists into narrow reaction channels that choke innovation. Others introduce complications—byproducts, impurities, or short shelf lives. In my own lab experience, switching back and forth between this aldehyde and related pyridines drove home how much time can be lost to work-up steps or repeat purifications. 2-Amino-6-pyridinecarboxaldehyde brings a welcome reprieve by letting teams move from bench top to larger scale with fewer headaches, greater reliability, and rarely a batch lost due to rogue side products.
Versatility in formulation and reliability across lab and industry settings mark this molecule as more than just another off-the-shelf chemical. In drug discovery, teams tap this aldehyde for scaffold hopping, where minor tweaks lead to major changes in activity or solubility. The molecule anchors dye syntheses and agricultural discovery projects, helping teams chase after new herbicide candidates or diagnostic agents. Its clear, light-yellow appearance gives confidence in purity without constant rechecking—and that counts for something in a world where one poor-quality intermediate can ruin a whole synthesis cycle.
Handling chemicals means more than just dumping powder in a flask—it comes down to predictability and safety. 2-Amino-6-pyridinecarboxaldehyde is easy to weigh, dissolve, and integrate into multiple solvent systems, allowing updates on the fly without the scrambling that other aldehydes can trigger. Reliable melting point and solid-state consistency means storage is straightforward—my experience tells me that, unlike fussier analogues, this molecule doesn’t clump or degrade, even in variable humidity across seasons. Safety protocols always matter: with strong ventilation and personal protective equipment, teams minimize inhalation and skin exposure risks, same as with any aldehyde. But here, the crisp crystalline nature also helps lower the risk of dust formation, making lab handling a smoother experience.
It’s easy to fall into the trap of judging a chemical solely by its catalog description: purity, melting point, solubility. The real value of 2-Amino-6-pyridinecarboxaldehyde emerges in use. In my own work bridging research discovery and pilot-scale production, consistency from gram to kilo batches stood out as a strength. No last-minute surprises; no need to re-tune whole processes for new lots. As teams moved toward scale-up, troubleshooting became less about fixing the intermediate and more about optimizing yield. This reliability streamlines not just syntheses, but the paperwork, regulatory tracking, and quality documentation that follow every commercial chemical.
It’s not only the pharmaceutical industry that benefits. From materials development—where the molecule enables tailored ligands and catalysts—to agricultural technology, the value extends wherever medicinal chemistry principles drive new product pipelines. The aldehyde finds a home in academic labs, where it allows creative pilot studies, and in industrial R&D suites, where time and repeatability pressure every decision. New graduates get their hands on it in classrooms and internships, learning the ropes without the anxiety that comes from erratic or sensitive reagents. That confidence matters—especially when rushing to hit project deadlines or troubleshooting a stalled sequence at the eleventh hour.
Relying on a single intermediate, no matter how reliable, doesn’t solve every bottleneck. Chemistry is often about trade-offs. Some end-users want even lower trace impurity levels or tailored crystalline forms for optimized flow characteristics. Here, partnering with experienced suppliers becomes crucial. Labs with in-house QA and QC can collaborate directly, sharing feedback to continuously improve each lot—an approach I’ve found far more effective than chasing the latest “miracle molecule” on the market. Addressing environmental impact also matters: waste management, safe handling recommendations, and process minimization round out the discussion for any responsible team introducing new intermediates.
The chemical industry faces rising pressure to trim waste, reduce emissions, and prove chain-of-custody for every ingredient. Molecules that shorten synthesis steps, minimize solvent swaps, or deliver cleaner downstream profiles aren’t just about cost—they support sustainable practices that regulators and communities demand. 2-Amino-6-pyridinecarboxaldehyde helps here: shorter pathways and fewer side products mean less hazardous byproducts hitting the waste stream. Choosing intermediates that tick both the performance and safety boxes streamlines compliance and cuts down on the need for energy-hungry reprocessing. In my time consulting with sustainability teams, these integrated gains repeatedly emerged as the difference between a project that scales and one that fizzles.
Scientific literature credits 2-Amino-6-pyridinecarboxaldehyde with key roles in multicomponent reactions and complex heterocycle construction. Journals document its use in synthesizing kinase inhibitors, fluorophores, and specialty ligands—a testament to cross-sector adoption. Customer feedback on procurement reviews highlights the ease of integration, noting reduced process variability and improved batch records. In industry trend reports, usage climbs amid broadening patent activity, signaling the molecule’s expanding fingerprint in commercial innovation.
Teams looking to the next stage of process improvement often search for more than mere cost savings. They seek out stability, reproducibility, and a trusted supply chain that supports diagnostic reagents, pilot molecules, or large-scale product lines. 2-Amino-6-pyridinecarboxaldehyde meets these needs through real-world application. I’ve been part of transition teams moving from older, less predictable intermediates to this compound—reducing out-of-spec events and freeing up time for developing new hits rather than fighting known issues. Consistent particle size, clear physical identification, and the ability to process under both acidic and basic conditions mean less downtime and more usable data.
Looking at the wider picture, the next decade promises new breakthroughs driven by combinatorial and automated synthesis. Intermediates like 2-Amino-6-pyridinecarboxaldehyde fit naturally into these workflows, plugging into robotic synthesizers or scale-up reactors without tricky compatibility concerns. Research groups pushing AI-driven drug discovery or new material science applications include it for the simple reason: no hidden surprises. The repeatability allows data-driven optimization and greater confidence as teams tackle ever more complex molecules in shorter timeframes. These incremental gains help maintain trust not just in a single product, but in the whole chemical enterprise.
Chemistry is as much about people as products. Choosing reliable intermediates removes stress from every step in the pipeline, freeing researchers to focus on creative tasks that drive genuine progress. Over the years, I’ve watched talented teams rally around good tools, building momentum that levels up projects and keeps innovation flowing. With 2-Amino-6-pyridinecarboxaldehyde, this reality plays out every day: fewer setbacks, tighter documentation, and faster routes from whiteboard to finished product.
As chemistry evolves, new educational efforts hinge on up-to-date materials. 2-Amino-6-pyridinecarboxaldehyde earns its place in teaching labs and advanced coursework, where students learn not only mechanistic principles but the importance of clean, repeatable reactions. Peer-reviewed articles, textbooks, and online modules reference its balanced reactivity and common use in method development. Trainers and mentors appreciate reliable results for troubleshooting and demonstration, encouraging safe, mindful laboratory practice from day one.
Procurement teams evaluate more than price tags—they weigh the track record of timely delivery, customer service, and supply continuity. 2-Amino-6-pyridinecarboxaldehyde sits high on reorder lists because experience proves that batches arrive as promised, without the variability that can throw critical campaigns off track. Open communication between suppliers and chemists closes the feedback loop, yielding continuous improvements and tailored support. During recent years—marked by global shipping crunches and raw material volatility—I’ve seen labs prioritize habitual winners in reliability, solidifying this compound’s role as a backbone molecule for ongoing campaigns.
The demands facing chemical product development only grow tougher. Regulatory expectations, consumer safety, and evolving technical requirements all force chemists to refine their toolkit. 2-Amino-6-pyridinecarboxaldehyde stands up under scrutiny, not because it promises to solve every problem, but because experience and evidence confirm a record of consistency. Teams integrating it into drug, dye, and agrochemical programs report higher hit rates and lower incidence of rework, supporting tighter timelines and more innovative solutions. This steady performance ensures it will remain an essential choice wherever next-generation synthetic chemistry unfolds.
Walking through the history of 2-Amino-6-pyridinecarboxaldehyde, the evidence makes a strong case for its continued relevance across an array of settings. By uniting predictable reactivity, strong physical integrity, and the trust built through years of use, this compound offers a path toward more resilient, responsible, and innovative chemical processes. In a field where one weak link can undo months of effort, choosing intermediates with proven value pays dividends—both in results and peace of mind for everyone along the chain. My own journey alongside seasoned colleagues has shown time and again that careful product selection shapes not only the immediate experiment, but often the future arc of discovery itself.
