|
HS Code |
762142 |
| Iupac Name | 2-ethoxypyrimidin-4(1H)-one |
| Cas Number | 65121-95-5 |
| Molecular Formula | C6H8N2O2 |
| Molecular Weight | 140.14 |
| Smiles | CCOC1=NC=NC(=O)N1 |
| Inchi | InChI=1S/C6H8N2O2/c1-2-10-6-7-3-4-8-5(6)9/h3-4H,2H2,1H3,(H,8,9) |
| Appearance | Solid (exact color can vary; generally off-white) |
| Solubility | Soluble in most organic solvents |
| Synonyms | 2-Ethoxy-4-pyrimidinol; 2-Ethoxy-4(1H)-pyrimidinone |
| Pubchem Cid | 85039 |
As an accredited 4(1H)-Pyrimidinone,2-ethoxy- (7CI,9CI) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed amber glass bottle containing 25 grams of 4(1H)-Pyrimidinone,2-ethoxy- (7CI,9CI), labeled with safety and chemical information. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 4(1H)-Pyrimidinone,2-ethoxy- (7CI,9CI): Safely drums or bags, maximizing 20-foot container capacity, ensuring secure, compliant chemical transport. |
| Shipping | Shipping of **4(1H)-Pyrimidinone, 2-ethoxy- (7CI, 9CI)** requires secure, well-sealed containers to prevent leaks or contamination. Packages must be clearly labeled, adhere to all relevant chemical transport regulations, and include Safety Data Sheets (SDS). Handle with care, and avoid extremes of temperature, moisture, or rough handling during transport. |
| Storage | **4(1H)-Pyrimidinone, 2-ethoxy- (7CI, 9CI)** should be stored in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible substances such as strong oxidizers. The container should be tightly closed and properly labeled. Protect from moisture and direct sunlight. Follow all local, state, and federal regulations for chemical storage and handling. |
| Shelf Life | 4(1H)-Pyrimidinone, 2-ethoxy- should be stored tightly sealed; shelf life is typically 2-3 years under cool, dry conditions. |
Competitive 4(1H)-Pyrimidinone,2-ethoxy- (7CI,9CI) prices that fit your budget—flexible terms and customized quotes for every order.
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Every day in our production facility, the search for reliability, purity, and consistency drives our work. Chemists know that a molecule like 4(1H)-Pyrimidinone,2-ethoxy- (7CI,9CI) isn’t just an abstract entry in a catalog: it’s the backbone for countless syntheses, a building block that supports both pharmaceutical innovation and research into new functional materials. Years of hands-on experience—producing, testing, and refining—have grown our understanding of what the market demands from a compound like this. The challenges go beyond getting the right structure on paper; they include scale-up, reproducibility from drum to drum, ease of handling, and, above all, the confidence a client gets from a trusted source.
Within the world of pyrimidine derivatives, each small modification opens the door to unique reactivity. The ethoxy group at the 2-position distinguishes this compound from other pyrimidinones, tuning both solubility and the kinds of reactions it supports. In typical synthetic pathways, this variant of pyrimidinone often slots in where control over hydrogen bonding, or specific polarity, produces cleaner reactions. For manufacturers like us, this detail changes the work done in purification—distilling, recrystallizing, and verifying every kilogram to meet quality benchmarks.
We manufacture this compound for customers who want predictable results in their labs. Chemists involved in medicinal chemistry value this version, particularly in the early stages where developing lead compounds demands speed and reliability. On the pilot plant side, material consistency ensures each batch of downstream product behaves identically in screening and development trials. The ethoxy-substituted pyrimidinone handles better than some of its methyl or unsubstituted cousins, thanks to differences in melting point and reduced volatility, which matters during weighing, storage, and transfer.
Manufacturing at scale teaches resilience. Running hundreds of liters of reaction brings out all the variables: temperature control, precise reagent addition, and minimizing by-products. Our facility employs flow reactors and modern purification columns, techniques proven to raise yields and shorten production cycles. Solvent recovery systems allow us to stay ahead of waste mandates. We collect and treat waste streams to keep emissions below the strictest thresholds, a point of pride among the team.
Repeated tests in our QC lab reveal how slight fluctuations—solvent ratios, reaction times, minor impurities in raw materials—can alter product quality. Unlike traders or resellers, we control every input and systematically implement process improvements. Over years of continuous operation, our production chemists have learned that direct observation, well-calibrated instruments, and honest communication between shifts mean fewer surprises and stronger supply reliability for our partners.
4(1H)-Pyrimidinone,2-ethoxy- stands out in medicinal chemistry. Research teams use it as a core fragment for antiviral, antibacterial, and anticancer programs. Purine and pyrimidine analogs often hold the key to new therapeutic mechanisms, whether as kinase inhibitors, nucleoside mimics, or RNA-targeting probes. What we provide isn’t just an off-the-shelf reagent; it’s a springboard for teams running high-throughput screens, structure-activity relationship studies, and scale-ups for preclinical trials.
Each specification, from moisture content to trace metal limits, reflects direct dialogue with researchers and process chemists. Their feedback loops back into batch records, making production more agile for the next run. Lab managers appreciate receiving a material whose identity matches the COA—NMR, HPLC, and mass spectrometry data checked not only for compliance, but for practical usability. Years of shipments to universities, CROs, and pharma companies taught us what questions matter before a bottle leaves the warehouse: how it dissolves in DMSO, how it filters, and if it holds up to bench storage.
The 2-ethoxy modification brings tangible advantages. In the plant, it means we can ship our product in ways that don’t require elaborate cooling or weighing procedures. The product’s slightly higher hydrophobicity secures better handling for organic-phase chemistry. Unlike unsubstituted pyrimidinone, which can display erratic flow properties, the ethoxy variant often forms a free-flowing crystalline powder, meeting the expectations of both automatic dosing machinery and bench chemists alike.
Process developers targeting nucleoside analog synthesis find this compound offers cleaner intermediate formation and improves yields in subsequent alkylation or coupling steps. Its reactivity supports broader options for derivatization, facilitating not just medicinal routes, but applications within agrochemical intermediates, heterocyclic pigment synthesis, and advanced polymer research. Laboratories optimizing reaction routes for patent filings or seeking to dodge prior art recognize value in a fine-tuned starting material. Our experience says: ‘less troubleshooting, fewer deviations’.
Handling experience tells a different story compared to the more common methyl and unsubstituted pyrimidinones. Plant operators notice fewer caking issues at scale and reduced static during transfers. End users see less variance from lot to lot, and compatibility with a broader set of green solvents, including bio-based ethers and esters, which fits shifting regulatory preferences in Europe, North America, and much of Asia.
Specifying a target purity on a data sheet doesn’t mean much unless it holds up in real work. For us, analytical chemists batch-release only what passes a detailed battery of physical and chemical tests. Everything, from melting point to residual solvents, is checked under conditions meant to mimic customers’ own workflows. Industrial clients ask for different grades—sometimes an R&D batch, sometimes a GMP-compliant lot for clinical use, always with transparency about trace elements or class 1 solvent residue.
Packaging plays into long-term stability. Over past projects, we shifted from traditional paper kegs and open-mouth cans to nitrogen-flushed, double-sealed containers. Chemists can open a pack and expect fresh, clump-free powder, no matter the region or season. Our plant logistics support small samples for development, pilot lots for process optimization, and bulk shipments for campaign manufacturing. Each shipment reflects accumulated field experience: reinforced liners to withstand long-distance air freight, rigid drums for seafreight, tamper-evidence on every unit—all points our end users demanded after years of hands-on troubleshooting.
Every major user faces constraints: timelines, budgets, regulatory shifts, and supply interruptions. Direct partnerships with manufacturers cut risks and simplify technical troubleshooting. Working one-on-one with process chemists has taught us the value of open feedback: cleaning up off-odors, reducing batch-to-batch discoloration, and supporting custom labeling for clinical traceability. A decade of operating as both producer and problem-solver helps us foresee bottlenecks. In emergencies—unexpected scale-up, shipment delays at customs, sudden demand from a partner’s clinical pipeline—we escalate, not evade responsibility.
Market demand for sustainable, low-waste processes keeps rising. Internally, we phased out problematic solvents and modernized waste management, shares learning with peers and customers alike. Recovered solvents return to the process, waste-stream analytics inform our next engineering upgrade. Collaboration with vendor partners ensures our supply chain resists shocks from both global logistics issues and sudden raw material disruptions.
For customers developing controlled pharmaceuticals or specialty polymers, regulatory transparency matters. Material traceability doesn’t end with a Certificate of Analysis—it goes all the way back to batch logbooks, raw material quality, and operator training records. Direct-from-plant delivery means every shipment can be traced, questioned, and, if necessary, improved. Over years, client audits, joint investigations into out-of-spec lots, and shared R&D projects have shaped our continual improvement practices.
Chemistry doesn’t stand still, and neither does production. Over the years, our team has worked closely with customers seeking more sustainable routes for this pyrimidinone. Replacing hazardous reagents, recapturing solvents, and automating hazardous steps have transformed not just our plant, but also client processes downstream. We built feedback from process users into our operating procedures, swapping outdated purification steps for safer, more reliable ones. With every process revision, we balance yield, purity, and environmental targets against what matters most to users—consistency, cost, and throughput.
Process development supports more than just one compound. Learnings translate across our catalog, where adjustments in agitation, charging sequence, or isolation technique lift outcomes for other heterocycles. Modern computer modeling joins old-school operator experience to keep the wheels turning efficiently. Customers can expect shorter lead times and the ability to specify custom impurity profiles or particle-size distributions to match their unique applications.
The main market for 4(1H)-Pyrimidinone,2-ethoxy- remains in pharmaceutical research. Sourcing teams and bench chemists need well-characterized core fragments for high-throughput screening libraries and lead identification programs. Our compound often appears as a precursor in nucleoside analog synthesis, kinase inhibitor development, and exploratory routes to new antibiotics and antivirals. Beyond pharma, pigment specialists and agrochemical developers pick this compound for its reliable reactivity and flexibility in functionalization, enabling exploration of new products outside conventional chemical spaces.
Feedback from academic labs, especially those supporting graduate and postdoc research, demonstrates demand for highly consistent, easy-to-use chemicals. Young researchers learning to develop new pathways rely on materials that behave as expected—no sticky residuals, no off-colors, straightforward spectral confirmation. Since university budgets rarely extend to expensive controls, dependable quality reduces repeat runs and improves overall research efficiency.
Process chemists developing ton-scale campaigns highlight the value of secure, direct supply. Our technical service teams support process transfer, troubleshooting, and real-time data sharing—going beyond a transactional relationship to a partner role. We share handling guides, application notes, and post-run reviews so process data inform wider improvements. Our ultimate measure of value comes from projects where customers ship back feedback—sometimes complaints, often praise—and both get pooled to shape future lots.
The market holds plenty of intermediaries, brokers, and generic offerings. In our experience, direct plant production grants unique advantages: visibility into raw material sourcing, real-time process control, and immediate quality adjustments. Equipment investment is substantial—modern chromatography lines, solvent recovery, and containment—but the tradeoff is minimal deviation and direct control over both lead times and material quality. Our operators calibrate every batch for end-user application, not just on-paper specification.
We don’t see ourselves as just a source, but as partners. Our background includes on-site troubleshooting at customer plants, exchanging findings during investigational audits, and resolving transport issues directly. Inconsistent product appearance, hard-to-dissolve cake, or impurity spikes aren’t inconveniences—they’re problems that warrant direct fixes at the source. Over time, the open exchange builds a knowledge network spanning both supplier and customer sides of the table.
Each successful lot, each repeat order, and every improved process step stems from listening to users’ real frustrations and aspirations. We encourage early engagement, whether to supply a research batch or scale a validated process, because what leaves our loading dock will pass through many hands before it finds its final place in a novel drug, a specialty material, or an innovation yet unimagined.
For those seeking deeper supply chain resilience and faster access to technical support, partnering with a primary manufacturer leads to results. We draw upon practical plant experience to share evidence-based improvements. Regular site visits, continuous process upgrades, and direct dialogue with end users have collectively refined our production and delivery model. Each improvement aims to eliminate risk for our customers—whether speeding up delivery or ensuring compliance with a new regulatory regime.
We see requests from both established pharma giants and ambitious startups. Their needs overlap: reliable materials, transparency from lab notebook to safety data, and a partner ready to consult before the next scaling step. Our operations and logistics teams aim for no surprises, no ambiguous COA entries, no missing critical data. If a leg of the journey—customs in an emerging market, a last-minute switch to air instead of sea—alters plans, we adapt in real time.
As rules tighten on chemical sourcing and traceability, we document every step from raw material origin to finished product shipment. In-plant monitoring, robust recordkeeping, and robust labeling keep compliance simple for downstream users. We contribute directly to green chemistry initiatives, investing in technology that shrinks our carbon footprint and cuts hazardous byproducts. Open communication channels with regulatory consultants and customers make compliance smooth and jointly achievable.
Our technical teams provide all necessary data packs, from batch analysis to extended impurity details, so regulatory submissions happen without last-minute scrambles for missing documents. Investments in greener production methods allow our clients to stay ahead, not just in product performance, but in corporate responsibility and downstream environmental impact.
4(1H)-Pyrimidinone,2-ethoxy- fits emerging applications in data storage, electronic materials, and advanced composites. Research partnerships keep us aware of what the market dreams up next. Material scientists reach out for tunable heterocycles to serve as backbone structures for OLEDs, organic photovoltaics, and smart coatings. Agrochemical developers pursue the same reliability seen by their colleagues in pharma—easy scaling and cleaner byproducts during synthesis.
Each partnership, each technical inquiry, reinforces the benefits of maker-buyer transparency. By answering tough questions, opening our doors to audits, and joining in method development, we help customers take full advantage of what 4(1H)-Pyrimidinone,2-ethoxy- can do. Upfront consultation avoids missteps; process support shortens production cycles.
From the operator measuring the morning’s first drum, to the analytical chemist approving final release, our company’s experience shapes every lot of 4(1H)-Pyrimidinone,2-ethoxy- (7CI,9CI). We take pride in working shoulder-to-shoulder with partners, troubleshooting by phone or on-site, and applying both new technology and trusted practices to keep chemistry moving forward.
Our commitment shows through measurable outcomes—consistent assay, low moisture content, and delivery that meets timelines. End users around the globe contribute to continuous improvement, helping us anticipate future demands and enhance what we make. We welcome challenging projects, out-of-the-box applications, and real-time collaboration. Every drum, every gram, stands as proof that grounded, practical chemical manufacturing moves ideas from theory to application—today and into the future.
