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HS Code |
165144 |
| Product Name | 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine |
| Chemical Formula | C9H13NO2 |
| Molecular Weight | 167.21 g/mol |
| Cas Number | 55106-30-4 |
| Appearance | White to off-white solid |
| Melting Point | 73-76°C |
| Purity | Typically ≥98% |
| Solubility | Soluble in organic solvents such as ethanol and DMSO |
| Storage Conditions | Store at room temperature, keep container tightly closed |
| Smiles | CC1=CC(=NC(=C1OC)CO)C |
As an accredited 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Brown glass bottle, 25 grams, tightly sealed with a screw cap, labeled with chemical name, CAS number, hazard symbols, and batch details. |
| Container Loading (20′ FCL) | 20′ FCL contains securely packed drums of 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine, protected from moisture and contamination during transit. |
| Shipping | **Shipping Description:** 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine should be shipped in tightly sealed containers, protected from light and moisture. Use appropriate secondary containment and label clearly. Transport according to local regulations for laboratory chemicals. Avoid temperature extremes and ensure compliance with any hazardous material guidelines if applicable. Handle with suitable personal protective equipment. |
| Storage | **2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine** should be stored in a tightly sealed container, away from direct sunlight, moisture, and sources of ignition. Keep in a cool, dry, well-ventilated area, ideally in a chemical storage cabinet designated for organic compounds. Avoid incompatible substances such as strong oxidizers and acids. Clearly label the container and store according to institutional safety protocols. |
| Shelf Life | Shelf life: Store 2-(Hydroxymethyl)-3,5-dimethyl-4-methoxy pyridine in a cool, dry place; stable for at least 2 years. |
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Purity 99%: 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine with purity 99% is used in pharmaceutical intermediate synthesis, where it enhances yield and reduces impurity profiles. Molecular Weight 167.21 g/mol: 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine at molecular weight 167.21 g/mol is used in fine chemical manufacturing, where it provides precise stoichiometric balance for targeted reactions. Melting Point 76°C: 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine with melting point 76°C is used in formulation of solid-state catalysts, where it ensures thermal stability during processing. Particle Size <50 µm: 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine with particle size below 50 µm is used in advanced material compounding, where it improves dispersion and homogeneity in polymer blends. Stability Temperature 140°C: 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine stable up to 140°C is used in high-temperature reactions, where it maintains compound integrity and reactivity. |
Competitive 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine prices that fit your budget—flexible terms and customized quotes for every order.
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Producing 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine demands more than specialized equipment; it calls for years of chemical know-how and rigorous attention to every detail that makes a difference in quality. This unique pyridine derivative plays a critical role in advanced synthesis work, particularly where selectivity and controlled reactivity matter most. From the start, our team worked closely with both raw material vendors and downstream users to develop batches that not only meet high purity but also deliver the performance end users ask for. Compared to other pyridine-based compounds, our approach focuses on actual process reliability and repeatability.
Years of working with pharmaceutical intermediates taught us early on that subtle changes in methylation or methoxylation can impact reaction predictability and safety. We know customers in fine chemicals, agrochemicals, or pharmaceuticals build lengthy campaigns around intermediates like this one, so consistent lot-to-lot performance matters. 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine stands out from similar products through its optimized impurity profile and the way it handles both bench-scale trials and larger manufacturing runs. Our multi-step synthesis follows robust control criteria: temperature, solvent polarity, water content, and phase management all affect yields and selectivity, so tightly controlled operations underpin all our production batches.
Chemists sometimes group pyridine analogs together, but even a small change in side-chain or ring substitution creates unexpected shifts in reactivity. For customers familiar with pyridine derivatives, the difference between 2-methyl and 2-hydroxymethyl variants appears on paper as a minor tweak. In practice, that functional handle makes all the difference in downstream coupling reactions, especially for building specialized heterocycles. Our 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine gives you both the methyl electron-donating effects and the added reactivity of the hydroxymethyl group, which influences both solubility and reaction cascade control.
That methoxy substitution at the 4-position further modifies reactivity. From direct synthesis experience, we found that this makes nucleophilic substitution more predictable and improves selectivity in cross-coupling applications. Other pyridines with methoxy groups not only differ in synthetic routes but create changes in polarity and work-up procedures. Traditional dimethyl pyridines, especially without the hydroxymethyl group, do not participate as smoothly in multi-component assemblies or library synthesis. We have spent years monitoring these subtle behaviors during customer scale-ups and learned the value of a tight and clear impurity fingerprint.
Superficially, producers of 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine might advertise minimum assay percentage and maximum moisture, but technical buyers and bench chemists know performance depends on more. Our QA/QC team insists on chromatography that runs long enough to catch trace-level by-products. Traditional specifications often skip acids, aldehydes, or conceivable trace pyridine N-oxides; however, these tiny impurities matter in downstream steps, especially when catalysts or chiral centers get involved.
Even before a shipment leaves our warehouse, we’re already tracking stability after six months, impact on glass transfer lines, and outcomes from customers’ pilot facilities. As a manufacturer, we pay close attention not only to purity but also to how the product flows, crystals, and dissolves. Physical character varies from crystalline to sometimes slightly sticky solids depending on subtle moisture content. Every batch runs through extra drying and screening steps because impurities can catalyze decomposition or discoloration on storage.
Over the years, we have watched 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine play different roles in research labs and in manufacturing campaigns. Whether building complex small molecules or acting as a precursor for bioactive compounds, its appeal always comes down to accessible reactivity without wild swings in side product formation. In one case, a pharma partner needed this compound for a chiral ligand scaffold. Tight batch control made it possible for chemists to move forward with confidence, since no colored by-products appeared in their chromatography steps. In agricultural R&D efforts, this compound often enters into routes producing proprietary active agents that target pest resistance with fewer unwanted residuals left over.
Across these applications, controlled synthesis at the manufacturing level makes a clear difference. Only by managing temperature, pressure, moisture, and phase separation closely can these end goals be delivered in a reliable way. When batches drift outside control, downstream users see yields lag or impurities multiply. It takes years of pilot work and sometimes costly troubleshooting to refine the process window. Our team learned this lesson through experience, especially during the early days, when off-the-shelf process guides turned out to miss subtle process hazards. By running parallel analytics during each stage, we can truly guarantee the right balance of selectivity and stability for demanding chemistry.
Stability in pricing and delivery—often overlooked—depends on our experience as an actual producer, not a mere packager or handler. Raw material volatility remains a reality in chemical manufacturing, and so does regulatory pressure on intermediates that may fall under special controls. We stock key precursors and maintain both documentation and on-site analytical support, so we avoid delays caused by third-party sourcing. This approach reduces waiting, improves planning, and keeps customer projects moving.
Batch scale-up experience shows that every upstream adjustment, even a shift in water content of solvents, will reflect in the final impurity profile. In one memorable case, an unexpectedly wet delivery of a precursor forced us to revisit and fine-tune our drying systems. These realities demonstrate the need for hands-on management in the production plant. Chemists who use 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine in high-stakes projects depend on this close-knit stewardship from raw material vetting to finished drum—something impossible to replicate in a trading or distribution model.
We treat every customer report, batch complaint, or request for extra detail as a source for process evolution. Feedback from medicinal chemists led us to extend our final column purification steps, not just for better purity, but also to meet demands for specific crystalline particle sizes that help dissolve the product faster in specific solvents. Others, focusing on combinatorial chemistry, highlighted the need for low-odor, non-hygroscopic material since small changes in handling conditions impact automated library synthesis runs.
These adjustments come from direct communication, not templated support calls. Our technical service team sits inside the same building as our plant, so idea exchange happens without delay, and we translate requests into practical batch modifications. Over years, we have gathered enough observational data across different user types—ranging from academic labs to batch pharmaceutical builders—to internalize their concerns and avoid common pitfalls, especially with heat-sensitive or moisture-sensitive reactions.
Every material we ship carries the reminder that handling experience in the manufacturing setting often diverges from what’s written on a data sheet. Direct contact with 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine may not raise obvious safety flags, but we have seen how prolonged temperature spikes during reactor charging can cause mild irritation or result in product discoloration. Our operators, after hundreds of batch runs, have learned to adjust addition rates, monitor headspace odors, and double-check filtration residue for any sign of unwanted side reaction.
It pays to reinforce the importance of controlling plant ventilation, especially in closed quarters. In some years, we improved our drum closure methods and trained workers to recognize condensate on liner seals—a seemingly minor tweak, but one that prevents moisture buildup and hardening during storage. Customers enjoy more predictable material quality on arrival, thanks to these practical process improvements.
In our experience, the biggest frustration downstream users face stems from inconsistent material quality. Changing reactivity, drifting impurity profiles, and shifting physical forms create wasted hours at the bench and in scale-up. Our in-house chemists keep tabs on the entire synthetic journey: Isomer formation in earlier steps can lead to hard-to-remove contaminants in the final product; these then show up weeks later in formulation blending or trigger specification failures.
Over years of lot release and post-shipment feedback, we’ve homed in on the importance of real-time analytics, not just spot checks. We keep a rolling archive of HPLC traces, moisture titrations, and crystallinity scans, documenting issues that would sap time for anyone further down the supply chain. Sometimes a single extra drying pass or slight tweak in crystallization temperature delivers dramatic improvements in both stability and dissolve rate. Having manufacturing control in one location—not spread across anonymous tollers or unstable contract partners—makes this possible.
There is no end to process improvement in chemical manufacturing. Identifying the true value of 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine for our clients means measuring both the minutiae and the bigger picture. Even with successful scale-ups and documented batch success, we revisit our synthesis, purification, and packaging routines every quarter. Our technical team reviews data from finished goods, investigates new analytical methods, and benchmarks performance against the latest customer needs.
For some applications, the value lies in ultra-low moisture levels. For others, consistent crystalline morphology or a narrow particle size distribution provides the edge in throughput or downstream blending. All of these outcomes depend on hands-on control and a willingness to adapt. As regulatory rules shift and customers seek updated compliance and documentation for global markets, we have built a flexible system for batch documentation and transport—without resorting to slow and bureaucratic hand-offs between contractors.
Sustained demand for this compound owes to more than chemical formula alone. Inside our plants and labs, it remains a benchmark for what practical, hands-on chemical manufacturing should achieve. It teaches us, batch by batch, how incremental improvements in production discipline, real-time analytics, and open customer dialogue make a world of difference at the bench for users, whether they operate in research, synthesis, or commercial campaign settings.
Unlike generic pyridine stocks that drift from origin to broker to end user, our material sees only one set of hands and controls. From our experience sourcing, reacting, purifying, and packing, we recognize the gaps that come when end users try to track down root causes of performance failures or inconsistencies. Every part of our workflow, from raw input to final drum, benefits from years of lessons learned, reaching beyond what can be captured in a certificate of analysis alone.
Every new customer order for 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine triggers the same disciplined workflow we have refined over years: rigorous incoming material checks, careful reaction staging, crystallization monitoring, and pre-shipment verification. Each of these tasks calls on not just equipment but also actual people who understand how small production shifts translate to real productivity at the bench.
By holding these standards close—not imposing blanket “one-size-fits-all” protocols but learning each time from operator experience and customer feedback—we aim for continuous progress. This compound, with its tailored reactivity and reliability, reflects our belief that chemical innovation and manufacturing must always work hand-in-hand. For anyone seeking to push boundaries in synthesis or manufacture more efficiently, a dependable source delivers more than just product—it delivers confidence.
Manufacturing 2-(Hydroxymethyl)-3,5-Dimethyl-4-Methoxy Pyridine day-in and day-out shapes our understanding of chemical quality. Each drum, each sample, and each customer conversation continues to prove the point: genuine manufacturing control cannot be matched by traders, brokers, or piecemeal packagers. Our product stands apart because the people making it bring real skill, caution, and curiosity to every step. In a world of tightening regulations, growing technical demands, and unpredictable global supply, sticking close to production realities and learning from the plant floor makes all the difference. As we look to future challenges in chemical manufacturing, the lessons from this single compound remind us to keep improving, stay alert, and value the direct link between skilled production and real-world results.
