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HS Code |
377302 |
| Name | 1,3-Dimethyl-6-aminouracil |
| Molecular Formula | C6H9N3O2 |
| Molecular Weight | 155.16 g/mol |
| Cas Number | 39181-46-5 |
| Appearance | White to off-white solid |
| Melting Point | Approx. 190-192 °C |
| Solubility | Soluble in water and ethanol |
| Smiles | Cn1cc([NH2])c(=O)n(C)c1=O |
| Purity | Typically ≥98% |
| Storage Conditions | Store at room temperature, away from light and moisture |
As an accredited 1,3-Dimethyl-6-Aminouracil factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 25 grams of 1,3-Dimethyl-6-Aminouracil, securely sealed, labeled with hazard warnings and product information. |
| Shipping | 1,3-Dimethyl-6-Aminouracil is typically shipped in tightly sealed containers, protected from light, moisture, and incompatible substances. The packaging complies with relevant chemical shipping regulations to ensure safety during transit. Proper labeling, handling, and documentation are provided, with temperature and hazard considerations based on the chemical’s Safety Data Sheet (SDS). |
| Storage | **1,3-Dimethyl-6-Aminouracil** should be stored in a tightly closed container, in a cool, dry, and well-ventilated area. Protect it from moisture, direct sunlight, and sources of heat or ignition. Store away from strong oxidizing agents and incompatible substances. Label the container clearly and keep it in a designated chemical storage area, following all relevant safety guidelines and regulations. |
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Purity 98%: 1,3-Dimethyl-6-Aminouracil with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high-yield reaction efficiency. Melting Point 285°C: 1,3-Dimethyl-6-Aminouracil with a melting point of 285°C is used in heat-stable formulation processes, where it provides enhanced thermal resistance. Stability pH 7: 1,3-Dimethyl-6-Aminouracil exhibiting stability at pH 7 is used in aqueous buffer solutions, where it maintains chemical integrity over extended periods. Molecular Weight 168.17 g/mol: 1,3-Dimethyl-6-Aminouracil with a molecular weight of 168.17 g/mol is used in structure-activity relationship studies, where it allows precise molecular modeling. Particle Size <10 μm: 1,3-Dimethyl-6-Aminouracil with particle size below 10 micrometers is used in nanoparticle drug delivery systems, where it improves dispersibility and bioavailability. Storage Stability 24 Months: 1,3-Dimethyl-6-Aminouracil with storage stability of 24 months is used in long-term bulk storage, where it guarantees consistent product quality. Solubility in DMSO 20 mg/mL: 1,3-Dimethyl-6-Aminouracil with solubility in DMSO of 20 mg/mL is used in in vitro biological assays, where it enables effective compound screening. UV Absorbance λmax 265 nm: 1,3-Dimethyl-6-Aminouracil with UV absorbance peak at 265 nm is used in analytical detection protocols, where it ensures sensitive quantitative analysis. |
Competitive 1,3-Dimethyl-6-Aminouracil prices that fit your budget—flexible terms and customized quotes for every order.
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In the world of fine chemical manufacturing, clear advantages often show up quietly—stability, consistent assay, and practical handling. 1,3-Dimethyl-6-aminouracil stands as an excellent example. Our shop floor has produced this intermediate for years, leaning on direct feedback from teams in pharmaceuticals, plant protection, and specialty dye industries. Experience shows that working with this uracil derivative means saving time during downstream reactions, improving conversion rates, and reducing headaches linked to contamination or off-specification lots. We know the feel, smell, and hue of a pure batch. Even before loading the reactor, our operators can read tiny changes in the crystalline profile and preempt trouble.
The distinguishing factor for this compound comes down to careful control at every stage. Time in production has taught us that raw material quality and the way we manage solvents define the repeatability of each lot. Years ago, we struggled through batches that crystallized unpredictably or refused to dissolve as needed—it cost us real money and customer trust. Through hard-earned adjustments in monitoring temperature and pH, tweaking our purification protocol, and steering away from over-oxidation, we raised purity to a range that nearly always exceeds 99%. Our in-house analytical chemists run HPLC and NMR before final release—not due to paperwork, but because it heads off expensive rework for downstream partners.
Our standard model of 1,3-dimethyl-6-aminouracil fits the most common synthetic requirements, offered as a fine white to off-white crystalline powder. Molecular formula C6H8N4O2, with an average molecular weight of 168.2. Particle size control keeps settling and mixing straightforward in most settings—key for partners running continuous batch processes or pilot-scale production. Moisture levels stay consistently below 0.5%, thanks to low-humidity drying protocols that our technical team refined after battling caking during longer shipping times. Our close management of residual solvents and strict sieving give clients confidence for GMP routes, where consistency beats over-optimization.
We do not rely on off-the-shelf raw stock. Instead, sourcing teams—people with a decade or more in our business—work directly with upstream producers. That reduces exposure to inconsistent intermediate quality, which once caused some costly project delays. In our labs, we sample and test all inputs before the first reactor kicks off. If a batch doesn’t meet profile, we reject it on the spot. These checks feel burdensome at times but pay off when every container lands on a client’s loading dock matching agreed specs.
Most differences between uracil derivatives emerge in the plant, not the catalogue. Unlike alternatives such as unmodified uracil or mono-methyl versions, 1,3-dimethyl-6-aminouracil holds its own under harsher conditions. Its solubility in polar solvents like dimethyl sulfoxide and N,N-dimethylformamide streamlines reflux or coupling processes. Our customers in active pharmaceutical ingredient manufacturing see cleaner conversions with less byproduct formation due to stable amine and methyl groups. Fewer cleanup steps mean less solvent use, less re-work, and better margins.
Some manufacturers overlook the knock-on effects of batch-to-batch variability. We learned this lesson the hard way years back, after a series of spotty lots triggered recall-worthy color discrepancies in dye intermediates. Since then, our QA process zeroes in on even minor visible and assay differences, flagging any drift before a shipment leaves the warehouse. Over time, our operators and QC specialists have turned quality control from a compliance exercise into a point of pride—these aren’t abstractions, but material improvements we see in repeat orders and fewer complaints.
A big practical distinction reveals itself in storage and handling. 1,3-dimethyl-6-aminouracil keeps shelf stability in standard sealed drums. We don’t see the same degradation or clumping over time that sometimes plagues mono-methyl analogs. That lets our logistics partners move smaller or larger lots as client needs shift, without rushing to fill new orders or worry about active loss.
Our technical support group, staffed by veterans who have worked both on the shop floor and in the lab, fields questions fast—usually from engineers or process chemists troubleshooting scale-up work. Knowing exactly how this compound reacts in both bench and full plant settings spares precious project time. We’ve consulted on everything from stepwise process design to material compatibility, and gathered more insight with each collaboration.
1,3-Dimethyl-6-aminouracil isn’t a headline-maker but remains essential across multiple industrial applications. Medicinal chemistry teams value its reliable amine reactivity and manageable melting point, opening doors to new antifolate analogs and other pyrimidine-based actives. Formulators in the dye sector like how clean its chromophore attachment steps run, cutting waste. We’ve watched its adoption grow among agrochemical researchers, who pick this material for its higher yield with substituted rings and reduced risk of unproductive side reactions. Recent feedback from one of our long-term clients led us to further dial in moisture control—a simple change, but one that upped conversion rates by a measurable margin in their pilot line.
The research and development world can’t afford repeated setbacks from unpredictable materials. Our own in-house projects sometimes encounter surprises, and those lessons migrate straight into production. For instance, earlier attempts to cut corners on secondary amine purification caused fouling in customer reactors. Peers noticed, shared their experience of similar issues from other sources, and we corrected course by introducing a new stage of recrystallization. These real-life fixes improve long-run usability for everyone relying on this molecule.
On the academic side, teams synthesizing novel nucleoside analogs or DNA-binding ligands find a stable supply of 1,3-dimethyl-6-aminouracil hard to secure elsewhere. Quick delivery and batch tracking help keep research moving ahead, especially with changing protocols or reagents. Small differences in melting behavior or solubility ripple out into overall project timelines; that’s tangible for postdocs and professors counting every grant hour.
Our production approach grew up alongside tightening global standards and growing requests for transparency. We’ve adopted leaner, safer working methods not only for regulatory peace of mind, but to protect our colleagues and end users down the chain. Standard batch sizes cover demand from research scale up to multi-ton commercial runs, with custom splitting and labeling options. Nothing replaces face-to-face troubleshooting: our team meets regularly with downstream users, factory managers, and logistics partners to hear what actually works—or doesn’t—outside the lab.
Years in this trade have shown us that good intentions aren’t enough. Shipping a clean, consistent product offers more than compliance; it invites trust over many orders. Changes in the market—shifting demand, the squeeze for higher purity, even sudden regulatory tweaks—ask us to adapt. A scalable, flexible process builds in enough room to grow without sacrificing repeatability. Automation gets more attention these days, but we rely just as much on the wisdom of operators who’ve caught a problem by smell, touch, or sight before machines report it.
Safety remains our baseline concern. 1,3-Dimethyl-6-aminouracil avoids the volatility and toxicity of some related uracil derivatives, making it easier to handle safely in the plant and during shipping. We developed site-specific training modules after an incident reminded us how quickly basic mistakes could escalate; new hires work shoulder to shoulder with senior technicians until they master both the steps and the “why” behind every precaution. Close calls in handling—fixable with the right approach—drove home that high-purity doesn’t excuse cutting corners on safety.
Partner feedback shapes everything. Several years back, one of our largest pharmaceutical buyers pointed out that even minor spikes in ash content during winter shipments affected catalyst performance in their synthesis. We assigned a senior chemist to track every step, adjusted the purification loop to identify the root cause, and saw the performance issue drop sharply in subsequent quarters. Small line-item tweaks—tweaking heat transfer fluids, updating drum liners—started paying off in smoother downstream handling for others as well.
Documentation, often dismissed as paperwork, becomes much more in practice. Certainty in the certificate of analysis means shipment after shipment matches what’s on the page. Over the years, our clients pushed us toward more thorough lot tracking and transparent reporting, especially when bridging R&D and commercial scales. That process sometimes uncovers underlying inefficiencies, prompting us to fix them earlier rather than risk a costly project slip.
The shift toward more sustainable production comes from both inside and outside our shop. Internal audits look for cleaner solvent recovery and alternatives to waste-heavy steps, while environmental reporting keeps these gains honest. We’ve reclaimed more raw material each quarter through hard-won changes. Input from overseas buyers, increasingly under environmental pressure, drives us to refine water and waste handling so that good stewardship doesn’t compete with profitability.
Logistics loops back into the equation. A batch that ships too soon without internal signoff runs the risk of causing expensive supply chain hiccups. Real-world hiccups keep us humble—one season’s infrastructure delays or a missed customs update remind us never to take smooth deliveries for granted. Our team preps each lot with repackaging as needed, documents customs and chemical WHMIS requirements, and then supports receivers with clear instructions. Every missed connection costs real money, time, and trust; we fight hard to prevent those losses.
The natural temptation is to look for shortcuts in manufacturing—especially when commodity pressures cut margins. We’ve resisted that urge by consistently reinvesting in plant upgrades, analytical equipment, and worker training. This philosophy doesn’t deliver overnight returns but keeps us relevant in a tight, competitive space. Bringing 1,3-dimethyl-6-aminouracil into this culture fosters a habit of reliability. Our technical leads meet monthly to audit reactions, challenge old protocols, and chase scrap down to its source.
Feedback cycles spiral across our supply chain—sometimes starting in a user’s small-batch lab, other times from logistics teams juggling difficult routes. We’re open about problems, documenting setbacks as well as wins. Years of collaboration have shown us that sharing knowledge across teams lowers repeat mistakes. Several process improvements grew out of a client’s unusual project or a transport hiccup, which we solved through calls, emails, and on-site visits. We use these stories in internal training to bring new staff up to speed quickly, keeping their learning anchored in real-world challenges instead of just standard operating procedures.
Investing in better analysis tools—upgrades to LC-MS, automation in powder handling, and tighter calibration—paid back in fewer customer complaints and stronger quality records. Our biggest improvements arrived through iterative small changes—not sweeping overhauls. Chasing six-sigma perfection opened up better ongoing business than one-time silver bullets. Incremental learning pays off, especially in a field where new challenges land with every order.
Over the years, relationships built on consistent product quality trumped price-only deals. Clients rely on us for capability and honest troubleshooting, not empty marketing talk. The proof often surfaces in unexpected places—a research chemist launching a new project starts with our material based on a colleague’s referral, or regulatory teams request extra documentation and find our process easy to follow. Repeat business comes not just from product purity, but clear communication and willingness to address challenges head-on.
Handling growth in specialty chemical demands tested our adaptability. New regulations and sustainability targets keep shifting the demands. Rather than waiting until forced, we’ve worked early with customers and compliance specialists to interpret what’s coming next, tweak labeling, or adapt to new export restrictions. The push for lower carbon footprints challenged our team to refine solvent loops and energy use, showing that staying ready matters more than playing catch-up after the fact.
Human capital underpins every successful batch. Much of the expertise in manufacturing 1,3-dimethyl-6-aminouracil rests with operators, chemists, and technical support staff who remember failed runs and client calls and use those lessons to guide the next process tweak. Their know-how distinguishes a trustworthy lot from a problem shipment. Sharing everyday production stories—both wins and mishaps—brings new colleagues up to speed and forges the culture that keeps customers coming back.
Manufacturing 1,3-dimethyl-6-aminouracil forges a long-term commitment to reliability, adaptation, and partnership. We forge our process improvements and adjustments in direct response to field experience, real orders, and actual user feedback. The road continues, demanding continued vigilance, honest self-examination, and ready engagement across scientists, operators, logistics teams, and customers alike. Each successful lot reflects years of accumulated lessons, practical know-how, and a collaborative stance—lifting the reliability of chemical supply in a shifting world.
