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HS Code |
348719 |
| Iupac Name | 1-Ethyl-6-hydroxy-4-methyl-2-oxo-1,2-dihydropyridine-3-carbonitrile |
| Molecular Formula | C9H10N2O2 |
| Molecular Weight | 178.19 g/mol |
| Appearance | Solid |
| Chemical Class | Pyridine derivative |
| Functional Groups | Carbonitrile, Hydroxy, Methyl, Keto, Ethyl |
| Smiles | CCN1C=C(C#N)C(=O)C(C)=C1O |
| Inchi | InChI=1S/C9H10N2O2/c1-3-11-5-7(4-10)9(13)6(2)8(11)12/h5,12H,3H2,1-2H3 |
| Storage Conditions | Store in a cool, dry place |
As an accredited 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging contains 10 grams of 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile in a sealed amber glass bottle. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 320 drums, each 50 kg net, HDPE drums, total net weight 16,000 kg, securely palletized and wrapped. |
| Shipping | Shipping for 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile is typically conducted in tightly sealed containers, protected from light, moisture, and extreme temperatures. The chemical is packed according to local and international regulations, ensuring safe transit. Appropriate hazard labeling and documentation accompany each shipment for safe and compliant delivery. |
| Storage | Store 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile in a tightly sealed container, protected from light and moisture. Keep in a cool, dry, and well-ventilated area, away from incompatible substances such as strong oxidizing agents. Ensure proper chemical labeling, and limit access to trained personnel. Follow all relevant safety and handling guidelines for organic compounds. |
| Shelf Life | Shelf life: Store in a cool, dry place, protected from light and moisture; stable for at least 2 years under proper conditions. |
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Purity 98%: 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile with 98% purity is used in pharmaceutical synthesis, where it ensures reliable yield and consistent compound quality. Melting Point 186°C: 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile at a melting point of 186°C is used in solid formulation development, where it provides thermal stability during processing. Particle Size <20 µm: 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile with particle size below 20 µm is used in fine chemical production, where it enables uniform dispersion in reaction mixtures. Molecular Weight 190.18 g/mol: 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile specified at 190.18 g/mol is used in quantitative analysis, where it allows accurate dosage calculation and process control. Stability Temperature up to 120°C: 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile with stability up to 120°C is used in heated reactor operations, where it maintains structural integrity under elevated temperatures. Assay ≥99%: 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile with an assay of at least 99% is used in high-purity reagent applications, where it delivers optimal reactivity and reproducibility. |
Competitive 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile prices that fit your budget—flexible terms and customized quotes for every order.
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From the beginning, every step in synthesizing 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile reflects our experience as manufacturers. In chemical production, an intimate grasp of the process changes everything—from purity to stability, from cost-effectiveness to how easily our customers can integrate the product into their workflows. We have spent years refining our processes for this compound, tailored to meet practical demands out in the field, in research settings, or on the production line.
Scaling up from a laboratory batch to industrial production rarely goes smoothly the first time. Over the years, we've learned which reaction conditions give more predictable yields and which purification methods avoid material losses or trace impurities. For 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile, precise control of temperature and solvent composition keeps by-products in check, preserving batch-to-batch similarity. We measure impurities with high-performance liquid chromatography, and when we spot outliers, we investigate causes, whether mechanical, procedural, or due to raw material variation.
Strict quality assurance empowers researchers and manufacturers who need reliability instead of surprises. We have seen how one irregular lot can throw off entire research cycles or frustrate formulators in downstream applications. Commitment to this hands-on discipline creates the trust that customers have come to expect from us—not from paperwork, but from the track record seen in every box or drum delivered.
Each application calls for different purity levels or presentation formats. Pharmaceutical research teams, for example, demand high-purity material, usually above 99%, with moisture below a tight threshold. Industrial clients, working in agrochemical or fine chemical synthesis, might prefer a slightly more flexible grade if it saves cost or speeds up lead times. These distinctions have only become clear over years of conversations with clients who speak plainly about their targets and headaches.
We supply 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile as a powder in a range of standard pack sizes, but special requests for alternative packaging or bulk shipments happen frequently. Our facilities handle requests for kilograms to hundreds of kilograms, grounded in safety standards and environmental stewardship; what matters is practical reliability in transport and handling, especially if the application requires minimal contamination from storage media.
Real-world inquiries rarely follow textbook scenarios, which is why we spend so much time listening to our customers and tracking industry workflows. In our experience, this compound sees most of its use as a synthetic intermediate. Researchers and process chemists utilize its unique framework—the pyridine ring with these substitutions—when seeking to assemble larger, more complex molecules for pharmaceuticals, crop protection, or specialty chemicals.
Why does this structure matter? The ethyl and methyl groups, along with the hydroxy and cyano functionalities, open possibilities for selective reactions. Teams working on heterocyclic compounds use this intermediate as a building block, modifying it further to introduce functionality relevant to activity in biological or industrial environments. Rather than serving as a finished product, this material fits into synthetic plans as a robust, reliable link in a longer chain of steps.
In some programs, we have seen this compound extended by nucleophilic substitutions at the cyano group or by oxidation or reduction at the hydroxy and oxo moieties. This flexibility explains its sustained demand among advanced intermediates and methods reported in the literature. Feedback from users shows that impurities matter, as trace residues can derail synthesis or interfere with downstream purification. Knowing this, our technical staff focus on minimizing unrelated side-products and monitoring every batch for consistency.
We have manufactured a wide variety of pyridine derivatives over the years, each with its chemistry and quirks. Not every compound behaves the same in real-life processes, no matter how similar they look on paper. Compared to structurally related compounds—such as unsubstituted pyridine-3-carbonitriles or different dihydropyridine isomers—our product distinguishes itself by where its functional groups sit and how they influence reactivity.
Addition of the ethyl group provides greater lipophilicity, which is relevant for certain active molecule precursors in the agrochemical and pharmaceutical industries. The specific placement of hydroxy and methyl groups has a pronounced effect on aromaticity and tautomerism, making this compound less likely to cause side reactions compared to analogs lacking regiochemical control. Practical projects experienced significant differences in solubility and reactivity because of these substitutions—a lesson we learned through troubleshooting with partner scientists confronting bottlenecks in their own labs.
Some manufacturers offer similar molecules where the substituents are shuffled or absent. Those differences matter because reactivity diverges: a missing hydroxy group can close off a synthetic route; the absence of the ethyl groups leads to shifts in partition coefficients critical for separation and formulation. Our product stands out not just for what it contains, but for the way our process preserves the orientation and purity required for these demanding tasks.
Questions about handling and storage always come up in direct conversations with our clients. We aren't distant suppliers; our technical support team has worked in our own production plant, and they understand why conditions like dry storage and temperature control aren't just boxes to tick—they're necessary to protect the material's integrity from shipment to end use. Exposure to light and moisture can cause slow degradation, so we use moisture-proof, light-shielded packaging. Fine chemicals like this don't stay stable indefinitely, so freshness counts.
We've responded to unique requests: on occasion, customers need custom batch documentation, additional quality reports, or tailored testing protocols. Each of these comes from the need to pinpoint sources of variability or to satisfy regulatory filings, and our on-site labs are built for these tasks. As a result, we have developed a culture of responsiveness, with chemists and plant operators ready to dive into new questions instead of leaving them to paperwork alone.
No chemical production should ignore environmental impacts. Over the years, we've invested in waste management, volatile organic compound recovery, and safe solvent handling. It's not just regulatory pressure that drives these changes—operator feedback has led to several improvements in how we ventilate, capture off-gassing, and minimize chemical exposure. This doesn't always make for flashy advertising, but in practice, safer plants mean less downtime, fewer incidents, and more consistent output.
Safety sheets and procedures reflect practical incident data collected over years of operation. Where spills occurred, we've modified containment. If a batch showed traces of metal contaminants from reactor wear-and-tear, new equipment or cleaning protocols followed. We understand first-hand that safety and purity aren't static requirements, but moving targets needing daily attention.
Ten years ago, few researchers outside of specialty pharmaceutical companies sought this compound. Recent advances in medicinal chemistry and crop sciences expanded its uses, and we adapted. Increases in scale or purpose—such as larger pilot projects or environmental chemistry applications—meant we had to revise our equipment, documentation, and supply chain relationships. As patents shift and generic manufacturers enter new markets, our clients value suppliers who can not only keep up but see changes coming before headaches develop downstream.
This compound has featured in research exploring kinase inhibitors, anti-inflammatory properties, and more, according to industry publications. While we do not pursue drug development ourselves, we listen carefully to researchers reporting yields, by-product formation, or purification challenges with related molecules. That two-way street means we upgrade our process to limit those same bottlenecks for future batches.
Some customers use this molecule for library synthesis or as a starting point for scaffolds bearing diverse pharmacophores. Others build new agrochemical actives, betting on the unique reactivity of the dihydropyridine core. Still others use it in contract research settings, where clients may never know every step of the process, but must rely on the expertise of the manufacturers who provide the foundation.
Supporting these projects requires more than sending a sample with a certificate of analysis. We've learned that securing supply chains, responding to urgent batch requests, and providing proactive notice of regulatory or customs changes defines modern chemical supply. Our staff keep ears to the ground for shifts in market demand, and our inventory planning reflects seasonal or project-driven fluctuations.
As a manufacturer, our relationship with this molecule doesn’t end with the last filtration. Troubleshooting, scale-up bottlenecks, or product consistency problems come through our door every week. What sets us apart from traders or distributors is the practical knowledge of what works—or doesn’t—in the plant. Subtle changes in source materials, reactor temperature, or solvent recycling create variations not obvious on a paper specification, but glaring when hundreds of kilograms must be delivered on schedule at uniform purity.
We invite customers to tour our facilities, audit our processes, and challenge our staff with questions. Not every batch runs perfectly; not every yield hits the theoretical maximum. What we bring to the table is an open record of adapting, improving, and learning—traits that only develop in the trenches of real production, not in abstract office presentations.
The best advances in the fine and specialty chemicals world emerge when manufacturers and users collaborate. We serve as a sounding board for customers advancing new syntheses or overcoming specific hurdles. On several occasions, research partners asked for feedback on alternative solvents, reaction temperatures, or crystallization steps using our product. By drawing on our manufacturing logs and historical data, we can advise on what’s feasible, saving others time and resources.
Practical feedback loops also inform raw material selection. For 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile, we chased more reliable starting materials after seeing inconsistent impurity patterns tied to suppliers upstream. This led us to invest in qualifying and monitoring raw material vendors more closely. Picking the right starting compounds changed our impurity profiles for the better and led to leaner, more confident downstream processes.
We have seen shifts in regulatory environments, both for export and for use in finished products, especially as guidelines change for toxicology testing, environmental impact, or supply chain transparency. Experience tells us that compliance is never static—it requires continuous updating of submission documents, tracking origin, and adapting to new market-access demands.
Even when regulations tighten, advance notice allows us to plan process improvements or raw material substitutions with minimal disruption. Over time, this minimizes the risk of recalls, rejected shipments, or stalled projects. Our documentation staff monitor these trends not as a sideline but as a critical part of our business, because regulatory confidence directly shapes the fortunes of everyone in the chain—right down to the scientists using a flask on the bench.
Most of our best customer relationships started with a straightforward inquiry about quality or timing, then deepened as mutual trust developed through on-time shipments and batch consistency. Repeat clients become partners, sharing the successes or setbacks they encounter in applications for 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile. Their feedback sets the agenda for our process improvements and guides investment in plant upgrades or additional analytical equipment.
We have found that openness about process limitations and willingness to troubleshoot, even post-sale, keeps partnerships productive. Many of the improvements present in our current offerings grew from precisely these collaborations, where technical teams and manufacturing experts sat down to dissect issues, pinpoint root causes, and implement practical fixes.
Experience dealing with global suppliers taught us that not all supply chains treat quality, traceability, or documentation with the same rigor. Challenges we’ve encountered from outside sources include ambiguous impurity profiles, delayed shipments, or paperwork mismatches that can strand batches at customs. By controlling our process end-to-end, we sidestep these common pain points, passing those benefits to downstream users—especially when timelines are tight and regulatory checks demand airtight documentation.
Some customers initially sought lower-cost products from non-manufacturing intermediaries, only to return when faced with product recalls or failed syntheses. Long-term users value cost transparency, predictable delivery, and ease of communication—factors that don’t show up on a simple product specification sheet.
The evolution of specialty chemicals like 1-Ethyl-6-Hydroxy-4-Methyl-2-Oxo-1,2-Dihydropyridine-3-Carbonitrile does not stop at a single product launch or process update. Every year brings new applications, new industry needs, and improvements demanded by real-world users. We watch for emerging requirements from regulatory agencies, sustainability pressure from customers, and shifting research directions among our client base.
Practical advances—whether in purification, yield, packaging integrity, or supply logistics—come from hands-on engagement with both facility operations and end-users. We invest in lab upgrades, staff training, and close cooperation with both customers and upstream suppliers so that each batch meets expectations for quality, consistency, and reliability.
Our direct manufacturing experience, ongoing technical dialogue, and willingness to adapt set the tone for how we produce and deliver this vital intermediate.
