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HS Code |
111606 |
| Chemicalname | 4-Acetyl-3-aminopyridine |
| Casnumber | 37148-48-4 |
| Molecularformula | C7H8N2O |
| Molecularweight | 136.15 g/mol |
| Appearance | Off-white to light brown solid |
| Meltingpoint | 72-75 °C |
| Boilingpoint | No data available |
| Solubility | Soluble in DMSO, slightly soluble in water |
| Purity | Typically ≥98% |
| Iupacname | 1-(3-aminopyridin-4-yl)ethan-1-one |
| Smiles | CC(=O)C1=C(C=CN=C1)N |
| Synonyms | 4-Acetyl-3-pyridinamine |
As an accredited 4-ACETYL-3-AMINOPYRIDINE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 4-Acetyl-3-aminopyridine is packaged in a sealed 25g amber glass bottle with tamper-evident cap and chemical label. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 4-ACETYL-3-AMINOPYRIDINE: Securely packed in fiber drums, palletized, with moisture-proof lining, maximizing space efficiency and safety. |
| Shipping | 4-Acetyl-3-aminopyridine is typically shipped in tightly sealed containers to prevent moisture and contamination. It should be transported under ambient conditions unless otherwise specified, avoiding extreme temperatures and direct sunlight. Proper labeling, along with adherence to local, national, and international regulations for handling chemicals, is required during shipping. |
| Storage | 4-Acetyl-3-aminopyridine should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible materials such as strong oxidizing agents. Keep the storage area free from moisture, and avoid exposure to direct sunlight. Always follow appropriate chemical safety procedures, including the use of personal protective equipment when handling the compound. |
| Shelf Life | 4-Acetyl-3-aminopyridine typically has a shelf life of 2-3 years when stored in a cool, dry, and dark place. |
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Purity 98%: 4-ACETYL-3-AMINOPYRIDINE with a purity of 98% is used in pharmaceutical intermediate synthesis, where high purity ensures reduced side reactions and higher overall yield. Melting Point 115°C: 4-ACETYL-3-AMINOPYRIDINE with a melting point of 115°C is used in organic synthesis processes, where controlled melting behavior enables precise thermal processing steps. Particle Size < 10 µm: 4-ACETYL-3-AMINOPYRIDINE with particle size less than 10 µm is used in fine chemical formulations, where small particle distribution enhances solubility and reactivity. Moisture Content < 0.5%: 4-ACETYL-3-AMINOPYRIDINE with moisture content below 0.5% is used in sensitive catalytic cycles, where low water presence prevents unwanted hydrolysis and ensures consistent reaction rates. Stability up to 80°C: 4-ACETYL-3-AMINOPYRIDINE stable up to 80°C is used in industrial scale synthesis, where thermal stability maintains compound integrity during processing. Assay ≥ 99%: 4-ACETYL-3-AMINOPYRIDINE with an assay greater than or equal to 99% is used in high-precision analytical research, where high assay levels guarantee reproducible experimental outcomes. Residue on Ignition < 0.1%: 4-ACETYL-3-AMINOPYRIDINE with residue on ignition less than 0.1% is used in preparation of injectable drug substances, where minimal inorganic contaminants ensure biocompatibility. |
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The world of fine chemicals moves quietly behind the buzz of high-tech labs and innovation headlines. Yet, without these specialty compounds, much of what drives progress stalls. 4-ACETYL-3-AMINOPYRIDINE belongs to this league. It's not a name that rolls off the tongue for most people, but for chemists, researchers, and manufacturing experts, it stands as a vital building block.
After years of working with diverse small molecules and sitting through too many lunchroom debates about chemical purity and reaction selectivity, I've seen firsthand how a single compound like 4-ACETYL-3-AMINOPYRIDINE can shape productivity and outcomes. If you land a batch with consistent quality, research tends to go smoother, and projects inch closer to success. Nobody likes surprises in their synthesis, especially in pharmaceutical or material sciences.
Talking about this compound usually centers around its structure and how that structure opens doors. 4-ACETYL-3-AMINOPYRIDINE combines a pyridine ring with acetyl and amino groups fixed at precise positions—if you care about reaction sites, you know why that matters. That 3-amino location impacts how the molecule behaves, whether in organic synthesis or more advanced pharmaceutical work. The acetyl group offers a useful “handle” for further transformation. Unlike unsubstituted pyridines, which often struggle with selectivity, this molecule offers a predictable, manageable path forward.
People sometimes ask about purity grades and physical appearance. Production methods affect the form, but what matters most for users is batch-to-batch consistency. Typical high-purity batches of 4-ACETYL-3-AMINOPYRIDINE are pale or off-white, crystal-like solids with a stated melting point and solubility profile. If you’re in the lab, you want compounds that handle easily—spill one bottle, you’ll know the difference between a sticky, hygroscopic mess and a solid that measures cleanly every time.
Specialty chemicals rarely get the limelight, but they lay the groundwork for pharmaceutical discovery, material innovation, and even electronics. This compound’s standout feature lies in its versatility. Chemists put its functional groups to work, tweaking molecular structures or piecing together new drug candidates. For those working in medicinal chemistry, the placement of the amino and acetyl groups allows for both nucleophilic and electrophilic reactions, which opens up creative routes that aren’t possible with simpler compounds. It tends to slot comfortably into longer synthetic routes, acting as a precursor that’s both stable and active enough to participate where you want it—not where it might cause side reactions.
This niche role helps researchers avoid pitfalls. I’ve worked on teams where an ill-chosen intermediate set whole projects back months. Once, after several false starts in a synthetic scheme, switching to 4-ACETYL-3-AMINOPYRIDINE created a shortcut that avoided protection and deprotection steps. Fewer manipulation steps usually mean improved yields, less waste, and tighter budgets—things you really appreciate if you’ve ever tracked project burn rates.
People looking to distinguish high-quality material from subpar options can pay close attention to the way this compound stores and behaves under regular lab or plant conditions. Poorly made versions break down in humidity, lose weight or color, or arrive with inconsistent melting points. Reliable sources report tight characterization data and offer HPLC or NMR spectra for peace of mind. The difference is more than academic—if you scale up synthesis, inconsistencies multiply into batch failures and regulatory headaches that no one wants.
A lot of companies offer pyridine derivatives. The shelf in the stockroom might look similar at a glance—compounds with different chains or substituents, promising a range of reactivities. In my experience, some cousins of 4-ACETYL-3-AMINOPYRIDINE can complicate life with unpredictable side reactions or unstable intermediates. For example, 2-acetylaminopyridine won’t react the same way, and 3-aminopyridine alone lacks the subtle reactivity balance for targeted transformations. The dual presence of acetyl and amino groups makes this molecule more than another catalog number. Engineers and chemists leverage this balance for precision—something that pays off whether developing an active pharmaceutical ingredient or assembling conductive polymers for electronics.
Each variant in this chemical family reflects a compromise between stability, reactivity, and intended application. While some options push for higher reactivities that lead to safety concerns or storage headaches, 4-ACETYL-3-AMINOPYRIDINE walks the line—stable enough for long-term storage, yet ready for transformation as soon as the protocol calls for it. This difference stands out in reliability and peace of mind during both research and production.
Most commentary about specialty chemicals gets buried in data tables. But in day-to-day use, I've seen 4-ACETYL-3-AMINOPYRIDINE valued for speeding up research timelines and keeping costs manageable in demanding projects. It shows up as an intermediate for pharmaceuticals, stepping stones to anti-infective agents or neuromodulatory drugs. It also acts as a core material for pigments and specialty coatings, where stability across processing steps matters just as much as reactivity in the flask.
In pharmaceutical production, purity is non-negotiable. Residual solvents, side-products, and metal contaminants add regulatory risk. Trustworthy sources for 4-ACETYL-3-AMINOPYRIDINE address these issues head-on, often publishing independent test results to support their quality claims. Researchers who use this compound often prefer suppliers who can back up their claims instead of those who simply offer the lowest price. That’s based on many years watching people chase short-term savings, only to regret it during final-product analysis, validation, or scale-up.
Material scientists and electronics companies care about thermal stability, compatibility with other materials, and electrical properties, depending on application. For pigments or specialty coatings, clean intermediates like this help prevent color drifting or unexpected degradation. Electronics teams focus on functional groups that fine-tune conductivity, solubility, or mechanical strength. Flexible compounds like this let engineers adjust their recipes without tossing out a year’s worth of development or blowing up the budget.
Turning to quality for a moment: anyone who’s ever faced an unexpected reaction byproduct or traced a failure back to a contaminated intermediate knows the importance of trust. Good suppliers share thorough documentation—think full NMR and HPLC purity analysis, and not just a promise. They publish particle size distribution if relevant, and often include stability curves for those running longer processes or large-scale reactions. Long-term users I know gravitate toward those with a reputation for responsiveness if a batch ever needs investigating. The time savings and frustration prevention add up quickly.
On the safety side, familiarity with the dos and don’ts of handling pyridine derivatives counts for a lot. 4-ACETYL-3-AMINOPYRIDINE, while not the most toxic compound on the shelf, demands the same respect as any fine chemical. Standard lab safety—ventilated hoods, gloves, and eye protection—adds peace of mind, and handling protocols tend to be straightforward. Folks who work with this molecule regularly keep material safety data handy, but the most significant factor remains the purity and history of the batch.
Anyone considering new suppliers or switching intermediates will want to pay attention to sourcing strategy and logistical bottlenecks. A couple years back, global supply chain hiccups hit specialty chemicals, causing delays and price spikes. Chemicals with critical roles, like 4-ACETYL-3-AMINOPYRIDINE, drew extra scrutiny. Teams that had built strong vendor relationships and requested full documentation stayed ahead, even through rocky shipping seasons.
Long-term partnerships with reputable suppliers reduce surprises. I’ve worked in organizations burned by counterfeit material or gray-market sources. It’s tempting to trim costs by going with unknown suppliers, but the risks multiply down the line—missed deadlines, quality assurance failures, regulatory action, even product recalls. In regulated fields, traceability and transparent records matter. Real suppliers work with full chain-of-custody data, and they keep customers informed about raw material changes or force majeure events so that disruptions cause fewer headaches.
Some teams will also calculate total cost of ownership beyond the sticker price. They weigh how often a chemical causes re-runs or failures in downstream purification, and how often staff spend time troubleshooting sources. The less your time is eaten by chasing down weird spots on an NMR or explaining batch inconsistencies to your boss, the more time you have to innovate. 4-ACETYL-3-AMINOPYRIDINE, bought from a well-documented and consistent supplier, minimizes those headaches.
It’s easy to overlook the human side of chemistry. Long days in the lab become less stressful when you know the tools at hand deliver as expected. Reliable specialty chemicals give researchers space to focus on designing experiments instead of micromanaging every reagent. For the graduate students and research techs using 4-ACETYL-3-AMINOPYRIDINE as a synthetic pivot point, every trouble-free batch means extra clarity for data interpretation and more confidence in published results.
Feedback cycles drive improvement. Users who share details about successful or failed reactions help both peers and suppliers fine-tune batches and anticipate common pitfalls. Communities—both online and professional societies—often exchange tips about emerging applications or unpublished tricks to coax better performance from this molecule. It makes for a dynamic ecosystem, one where reliable supply chains and responsive suppliers play just as big a part as formal publications.
Technological advances in synthesis have raised expectations, but basic compounds still matter. As AI-driven drug discovery, high-throughput screening, and automated material design tools grow, the demand for clean, predictable input chemicals like 4-ACETYL-3-AMINOPYRIDINE keeps rising. Machines can process thousands of hypotheses a day, but poor-quality reagents jam the system. A focus on reliable specialty compounds frees up human and computational creativity, instead of forcing everyone to debug the basics.
Continuous improvement comes less from chasing new hero molecules than from refining old processes. Labs and companies that audit their supply chains and put pressure on suppliers for tight quality control raise the entire game. Modern verification tools—real-time spectroscopy, digital batch tracking, rapid impurity profiling—give buyers leverage. The goal is to make stories of contamination or inconsistency part of the past.
Groups like the American Chemical Society, major pharmaceutical consortia, and electronics industry working groups regularly recommend standards and best practices for both buyers and sellers. Commitment to compliance and transparency pays dividends too, since downstream customers trust those who exceed basic regulatory requirements. In my own experience, choosing a documented, traceable supplier avoided repeated failures and regulatory delays that ate up valuable launch windows.
Teams investing in new applications for this molecule—like next-generation therapeutics or smart materials—know that slow, steady improvements in input consistency make innovation less risky. If trends continue, more industries will move toward tighter documentation, with digital batch certificates and real-time inventory tracking making it easier to predict and avoid issues. Already, many innovators factor in data access when choosing material—real-time sharing of purity, origin, and storage data trims downtime and lets researchers pivot quickly when market or regulatory conditions change.
Quality gaps and sourcing headaches are never fun. For those invested in steady results, solutions start with clear communication and long-term vision. Open feedback channels allow users to flag emerging lot-specific quirks before they spiral into large problems. Close cooperation with suppliers—along with written expectations for regular testing and documentation—builds a partnership model, not just a customer-vendor transaction.
Research and development managers who share learnings across sites see faster process optimization. When lab techs in different countries identify a better way to store or dissolve 4-ACETYL-3-AMINOPYRIDINE, spreading that knowledge keeps everyone moving forward. Standardizing how chemicals are received, logged, and tested on arrival also helps. This is especially true in regulated markets, where traceability and auditability control a project’s fate.
A few teams try advanced digital inventory systems that link incoming shipments with automated quality control data. Real-time notifications of subpar shipments make replacement or switching much smoother. The result feels less like putting out fires, more like streamlined progress toward ambitious targets—new drugs, better materials, creative products.
Government and industry groups have also stepped up on safety. Encouraging a culture of process safety brings down incident rates, makes regulatory inspections more predictable, and fosters a mindset of problem-solving rather than blame-shifting. Regular training, transparent reporting of near-misses, and investment in good lab infrastructure combine to keep people safe and projects on track. Products like 4-ACETYL-3-AMINOPYRIDINE play their part in this story, supporting a culture of small wins that add up to bigger ones.
Watching the specialty chemical space change over the past years, it’s clear that the old days of quick-and-dirty intermediates won’t cut it. Market demands, regulatory scrutiny, and the needs of a new generation of researchers continue to push the bar higher. 4-ACETYL-3-AMINOPYRIDINE, thanks to its stability, flexibility, and trusted performance, should remain a staple on the research shelf and in innovative processes.
As more fields, from green chemistry to advanced electronics, seek unique properties from their input materials, chemicals that offer both reliability and room to maneuver will stay in demand. New synthesis routes, purification protocols, and digital documentation tools keep the playing field level for both small startups and giant multinationals. Those willing to share insights and push for better standards—buyers and suppliers alike—help make sure products work as promised, projects hit their targets, and science moves forward with fewer unwanted surprises.
For all its technical name and understated role, 4-ACETYL-3-AMINOPYRIDINE stands as a reminder that progress depends on many hands, careful processes, and a commitment to quality at every step.
