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HS Code |
233436 |
| Iupac Name | 2-methyl-6-oxo-1,6-dihydro-5-(4-pyridin-4-ylpyridin-1-yl)carbonitrile |
| Common Name | WIN 47203 |
| Molecular Formula | C13H9N5O |
| Molecular Weight | 251.24 g/mol |
| Cas Number | 85182-22-7 |
| Appearance | White to off-white crystalline powder |
| Melting Point | 210-212 °C |
| Solubility In Water | Slightly soluble |
| Logp | 2.19 |
| Purity | Typically ≥98% |
| Chemical Class | Pyridine derivative |
| Storage Temperature | 2-8 °C |
| Smiles | CC1=NC(=O)C(=C(N1)C#N)C2=CC=NC=C2 |
| Synonyms | 4'-Bipyridinyl-5-carbonitrile, WIN-47203 |
As an accredited 4’-bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo-( win47203 factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | WIN47203 (4’-Bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo-) is supplied in a 100 mg amber glass vial, securely sealed. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 4’-bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo-(win47203) ensures safe, bulk shipment in sealed, secure containers. |
| Shipping | The chemical **4’-(Bipyridine)-5-carbonitrile, 1,6-dihydro-2-methyl-6-oxo- (WIN47203)** is shipped in tightly sealed containers under cool, dry conditions. It is packed according to standard regulations for hazardous materials, with appropriate labeling and documentation to ensure safe transportation and handling during shipping. |
| Storage | **Storage Description:** Store **4’-(bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo- (WIN 47203)** in a tightly closed container at room temperature (15–25°C), in a dry, well-ventilated area away from moisture, heat, and direct sunlight. Keep away from incompatible substances such as strong oxidizers. Use secondary containment, and ensure easy access to appropriate spill control and personal protective equipment. |
| Shelf Life | The shelf life of 4’-(bipyridine)-5-carbonitrile, 1,6-dihydro-2-methyl-6-oxo (WIN47203) is typically 2–3 years under proper storage. |
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Purity 99%: 4’-bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo-( win47203 with purity 99% is used in pharmaceutical intermediate synthesis, where it enables high reaction yields and low impurity formation. Melting point 210°C: 4’-bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo-( win47203 with a melting point of 210°C is used in organic electronics fabrication, where it ensures thermal stability during device processing. Molecular weight 225.25 g/mol: 4’-bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo-( win47203 with molecular weight 225.25 g/mol is utilized in coordination chemistry, where it promotes predictable complex formation. Particle size <5 μm: 4’-bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo-( win47203 with particle size below 5 μm is used in catalyst support coating, where it enhances dispersion and catalytic efficiency. Solubility in DMSO 50 mg/mL: 4’-bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo-( win47203 with a solubility in DMSO of 50 mg/mL is used in drug formulation screening, where it enables effective compound delivery and screening reproducibility. Stability temperature up to 180°C: 4’-bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo-( win47203 stable up to 180°C is applied in high-temperature synthesis processes, where it maintains structural integrity and consistent performance. |
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Some chemicals stand out because they rarely leave you guessing about their role. WIN47203—scientific name 4’-bipyridine)-5-carbonitrile,1,6-dihydro-2-methyl-6-oxo—demands accurate handling and thoughtful application. Producing this compound onsite, batch-by-batch, lets us see exactly how it behaves at every step. From the start, our team studied its synthesis, considering even those tiny impurities that could throw off downstream consistency. Each run reveals something new, whether that’s a slight tweak in temperature profile during the hydrogenation step or a filtration pressure setpoint shift needed for a specific particle size. Our technicians don’t just read off a checklist—they make judgment calls, informed by years of hands-on chemical production.
Some clients wonder why they should seek out WIN47203 when simpler bipyridine derivatives are available. The structure tells the story: incorporating both a carbonitrile and a keto group in the 1,6-dihydro-2-methyl scaffold widens the chemistry at play. These features allow combinatorial flexibility on both the pyridine rings and at the nitrile position, which matters in both custom pharma synthesis and specialty material development. We’ve collaborated directly with some of the leading research labs, measuring how our product stacks up against more conventional bipyridine analogs. In multiple tests, we observed that WIN47203 sways reactivity—especially in photochemical and redox processes—enabling researchers to reach targets that would stall with basic bipyridine.
Our technical team regularly helps formulate routes for both academic and commercial partners who need to fine-tune ligand properties or nucleophilicity in advanced organic reactions. Since WIN47203 presents a more complex molecular environment, slight variations in production impact both yield and purity. We spot-check GC-MS profiles across each batch, not because an auditor demands it, but because a single off note in the spectrum hints at side products that can throw off a catalyst screen or a crystallization attempt later. Teams relying on consistent product for scale-up know that kind of discipline behind the scenes makes all the difference.
Manufacturing WIN47203 means tackling air-sensitive intermediates. Oxygen intrusion or minor solvent contamination risks batch rejection. Over the years, we've learned where to trust automated controls and where to intervene manually. For example, during the final condensation, we monitor color, viscosity, and even the subtle 'bite' in the reaction vapor—signs that no sensor can interpret but a chemist with boots on the floor will never miss. The plant’s nitrogen supply rarely sits idle during these sequences.
Achieving the desired purity level often leads to trade-offs. Demand for high-performance research requires us to go beyond basic crystallization. We've built a process that incorporates column purification as standard, even when it would be easier to send out a slightly less clean product. This choice adds time and cost, but partnering researchers have told us that eliminating those final few percent of residual bipyridine byproducts heads off countless headaches for anyone exploring structure-activity relationships or prepping analytical samples for regulatory review.
Not all solvents treat WIN47203 kindly. Our synthesis team worked through cycles of trial and error to pin down the best approach for both reactivity and safe isolation. We tested and discarded several solvent systems, sticking with those that consistently delivered without introducing background impurities. Every batch record tells the story, and we learn a little more about the nuanced nature of this compound and its behavior under real-world production conditions.
We build every lot of WIN47203 with an eye toward practical applications. In pharmaceutical labs, this compound becomes an asset, offering a versatile starting point for developing synthons that demand polarized functional groups. For medicinal chemists, our material offers unusual routes to heterocyclic cores; its reactivity under mild or aggressive conditions lets teams tweak synthetic pathways, exploring both metal-catalyzed cross-coupling and more subtle hydrogenation tactics.
In the world of materials science, teams use WIN47203 to dig into coordination polymers and advanced ligands with tailored optical or electronic properties. Its electronic structure positions it as an intermediate worth pursuing for devices where charge carrier balance matters, whether that’s in novel OLEDs or emerging sensors. Researchers have provided us direct feedback after trials, noting that the nitrile group's presence in WIN47203 sometimes unlocks exactly the desired bandgap or response in pilot-stage prototypes, where other bipyridine compounds fall short.
Every application hinges on reliability. As the original manufacturer, we routinely get questions around batch-to-batch reproducibility and long-term supply stability—labs need to know that next month’s lot will run just like the current one. Our protocols reflect this understanding; by integrating end-to-end tracking on every intermediate, matched with data from every analytical checkpoint, we make sure the next bottle performs like the last. Our customers’ experimental timelines depend on it.
The specialty market for pyridine derivatives never stops evolving. Many compounds promise wide utility, but few deliver the same level of chemical leverage as WIN47203 for complex synthetic pathways. We’ve seen competitors offer generic bipyridine products at scale, and they fit fine for basic chelation chemistry. Yet, those who need to modulate electronic character and explore hard-to-reach targets often gravitate to this more specialized intermediate.
One of the clearest differences arises in catalyst development. Researchers testing ligand fields for novel metal centers notice subtle shifts in reactivity just by swapping from a common bipyridine to WIN47203. The 5-carbonitrile substitution brings added selectivity, while the 1,6-dihydro-2-methyl-6-oxo substituent adjusts steric profile and hydrogen bonding opportunities. As original producers, we keep track of trends—where the community discovers emerging applications, we quickly adapt our own analytical priorities and synthetic flexibility to meet demand.
Storage and transport require a practiced touch. We’ve thrown out drum after drum when we see even slight deviations in color or faint hints of decomposition. Modern packaging, flushed with inert gas and sealed down to the last gasket, keeps the product in shape. These details might look trivial in a spec sheet, but years on the floor tell us it’s the difference between offering material fit for innovation or handing over a problem-in-waiting.
Model details rarely tell the full story for specialty chemicals. We focus on the characteristics that matter in actual labs. Our WIN47203 consistently registers at 98 percent or higher HPLC purity, with tight controls placed on trace solvents, residual starting materials, and other potential interferences. Particle size and bulk density don’t get overlooked—they influence both dissolution rates and dosing in semi-automated setups. By managing particle distribution at the source, we cut down on downstream clumping or uneven dispersion.
Clients often voice concerns about contaminant profiles. Since WIN47203 participates in sensitive transformations, we keep residual heavy metals and halogens as low as possible, verified not just by spot testing but by running every batch through ICP-MS and related analytics. Solvent residues, especially acetonitrile and DMF, need close monitoring due to their impact on safety and secondary chemistry. We flag any deviation before material ever reaches the loading dock.
Many commercial users absorb details about melting point, moisture uptake, and compatibility with common reagent classes. Every production run includes a final data sheet directly from our QC lab—signed off by a chemist who knows that these values aren’t just numbers for filing away but direct predictors of success or setbacks in ongoing projects.
Several industries prize WIN47203, but it’s the hands-on partnerships that shape how we refine our approach every year. For some research groups, even a subtle batch variation can shift assay results; we work directly with these teams to trace source anomalies and tweak our parameters. We also visit customer pilot facilities, observing firsthand how our product flows, dissolves, or crystallizes when scaled up from bench quantities. Direct feedback influences both our production strategy and the way we approach packaging solutions to prevent caking or moisture intrusion.
Open conversations with regular users have shaped the way we schedule production. Some checkpoint decisions—for instance, whether to tweak purification in light of a customer’s chromatography strategy—come straight out of these collaborations. Over time, this dialog shortens troubleshooting cycles for both sides and reveals process improvements that wouldn’t happen if we relied on remote, one-size-fits-all production logic.
Clients digging into spectroscopy or crystallography often want extra documentation. Our technical staff isn’t just email support—these are chemists and production engineers who step out of the synthetics bay to answer questions, figure out alternate drying regimes, or consult directly on difficult transformations where trace byproducts could undermine a trial. This support isn’t an addon—it forms the backbone of our offering, rooted in a shared respect for what’s at stake in discovery-driven chemistry.
No research effort wants surprises in a reagent bottle. We structure our controls for WIN47203 based on direct lessons from both accident reports and day-to-day handling quirks. The crystalline form can generate static charge, and dusting during transfer may present real hazards if containment protocols slip. Operators in the plant check ventilation, antistatic gear, and PPE at every charging point, not because the handbook insists—but because more than a few dusty spills over the decades have reinforced what’s at risk if you leave anything to chance.
Labeling, container materials, and storage temperature aren’t afterthoughts. WIN47203 needs cool, dry conditions with controlled humidity and dark storage. Glass and high-grade polymer afford the best barrier properties. Shipping standards have been revised over the years as transit times and climate conditions change; shipments to tropical regions spawn extra safeguards to head off degradation. This ongoing adaptation flows straight from practical experience—product failures in the chain of custody get traced back not just to the plant but to broader logistics habits.
We drill field staff and plant crews on incident response, building lessons from every minor lapse into the wider safety system. Customers benefit from this ‘muscle memory’—less unexplained degradation, longer shelf life, more predictable performance in the field. Experience shapes our playbook more than any external audit does.
Producing WIN47203 in-house, with all constraints and lessons that come with it, gives us a window into its evolving potential. Routine synthesis sometimes uncovers an unanticipated byproduct. Rather than discarding it as nuisance, our R&D team dives in, tracking downstream possibilities for both formulation science and secondary syntheses. This habit—treating process anomalies as leads, not just problems—keeps us nimble and quick to support customers chasing answers to novel questions.
Combining scale manufacturing with laboratory curiosity means we refine not just for output, but for new chemistries. Some of our most valuable feedback comes from clients testing WIN47203 in ways we never anticipated—miniaturized combinatorial libraries, high-throughput screens, or prep-scale runs with oddball reagents and conditions. Through these partnerships, as the first-line producers, we test new work-up methods, build purification schemes, and feed real data back into both plant operations and published knowledge bases.
Demand for WIN47203 grows not just on specification sheets, but as researchers see real improvements in yield, selectivity, and downstream utility. Our production team attends technical conferences, engaging with scientists who expect a level of technical rigor and open feedback that no distributor can offer. Technical improvement, whether rooted in alternative synthetic approaches or cleaner purification paths, grows from this ongoing dialog.
As uses for nitrogen-rich heterocycles spread into newer industries—advanced electronic materials, sustainable agrochemical intermediates, and smart sensor platforms—our methods need to track those shifts. Every new partnership, every direct production success or hiccup, reinforces the idea that WIN47203 remains a workhorse intermediate whose true potential gets realized through practical collaboration and the shared language of the working chemist.
Looking back on years of effort, as a manufacturer seeing the practical impacts play out every day, we know our value lies less in broad promises and more in the direct, recognizable reliability, adaptability, and technical support we bring to every batch. WIN47203 continues to open doors for novel research and industry, not just as a chemical, but as a reflection of real-world knowledge built up in the lab, on the production floor, and in daily interaction with a community of serious experts.
