|
HS Code |
514671 |
| Molecular Formula | C12H19NO3 |
| Molecular Weight | 225.29 |
| Iupac Name | 2-(Hydroxymethyl)-3-methyl-4-(3-methoxypropoxy)pyridine |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | Estimated ~320°C |
| Solubility In Water | Slightly soluble |
| Density | Estimated ~1.1 g/cm3 |
| Purity | Typically ≥98% |
| Storage Temperature | Store at 2-8°C |
As an accredited 2-Hydroxymethyl-3-methyl-4-(3-methoxy propanoxyl)pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle labeled "2-Hydroxymethyl-3-methyl-4-(3-methoxy propanoxyl)pyridine, 25g, for research use only, store cool/dry." |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Packed in 200 kg HDPE drums, 80 drums per FCL, net weight 16,000 kg; safe chemical transport. |
| Shipping | This product, 2-Hydroxymethyl-3-methyl-4-(3-methoxypropanoxy)pyridine, is shipped in tightly sealed containers to prevent contamination and moisture exposure. It is packaged according to applicable chemical safety regulations, labeled with hazard information, and transported via appropriate carriers to ensure safe and compliant delivery. Handle with suitable personal protective equipment upon receipt. |
| Storage | Store 2-Hydroxymethyl-3-methyl-4-(3-methoxypropanoxy)pyridine 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 oxidizers or acids. Ensure appropriate labeling and secure storage location to prevent unauthorized access. Use secondary containment to minimize spills or leaks, and handle under fume hood if volatile or dusty. |
| Shelf Life | Shelf life: 2-Hydroxymethyl-3-methyl-4-(3-methoxypropanoxy)pyridine remains stable for 2 years when stored in a cool, dry place. |
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Purity 99%: 2-Hydroxymethyl-3-methyl-4-(3-methoxy propanoxyl)pyridine with 99% purity is used in pharmaceutical synthesis, where it ensures high-yield production and minimal contaminants. Molecular Weight 223.28 g/mol: 2-Hydroxymethyl-3-methyl-4-(3-methoxy propanoxyl)pyridine of molecular weight 223.28 g/mol is used in organic synthesis, where it contributes to precise stoichiometric calculations and consistent reaction outcomes. Melting Point 102°C: 2-Hydroxymethyl-3-methyl-4-(3-methoxy propanoxyl)pyridine with a melting point of 102°C is used in intermediate manufacturing, where it allows controlled solid-to-liquid transitions for efficient processing. Stability Temperature 60°C: 2-Hydroxymethyl-3-methyl-4-(3-methoxy propanoxyl)pyridine stable at 60°C is used in formulation development, where it maintains compound integrity during thermal processing. Low Moisture Content <0.5%: 2-Hydroxymethyl-3-methyl-4-(3-methoxy propanoxyl)pyridine with low moisture content below 0.5% is used in high-purity reagent preparation, where it prevents hydrolytic degradation and ensures product stability. Particle Size <50 μm: 2-Hydroxymethyl-3-methyl-4-(3-methoxy propanoxyl)pyridine with particle size below 50 μm is used in catalyst support systems, where it enhances dispersion and surface area contact for improved catalytic efficiency. Viscosity Grade 2 cP: 2-Hydroxymethyl-3-methyl-4-(3-methoxy propanoxyl)pyridine of viscosity grade 2 cP is used in specialty coatings, where it enables uniform application and smooth film formation. |
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Every granular, clear batch of 2-Hydroxymethyl-3-methyl-4-(3-methoxypropanoxyl)pyridine rolling off our lines reflects the hands-on know-how built from years standing over reactors, keeping temperatures steady and watching for that proper hue of product. This chemical remains a specialty in our catalog and signals the practical innovation we pursue as industrial chemists. It all comes down to not simply producing it, but understanding what works, what causes headaches in downstream processes, and which properties stand out during real synthesis runs.
With experience handling this compound, we settled on a model with an optimal purity range, considering real output and not just theoretical maximums. The 2-Hydroxymethyl-3-methyl-4-(3-methoxypropanoxyl)pyridine we manufacture falls into a narrow melting point window and displays low moisture content—as measured batch-to-batch right on our floor, after filtration and drying steps. This quality control protects project timelines at customer sites and avoids the surprise of off-spec moisture or a sluggish crystallization stage.
We routinely ship in drum or lined barrel formats, since it stores stably at controlled temperatures without caking or notable oxidation, crucial during long transit or warehousing. On rare occasions, special requirements come from partners: fine powder for increased reaction surface area or larger granules for certain continuous processes. Here, decades with all major forms of this pyridine class have shown us that the base crystalline structure of our model holds up best in diverse real-world applications.
Any chemist running reactions with pyridine derivatives knows how subtle changes in structure lead to big process changes. Adding a 3-methoxypropanoxyl group on the fourth position of the ring provides a more balanced solubility profile in polar and less polar solvents when compared to simple alkylpyridines. We built this product with that fact in mind, so customers with multi-step synthesis needs don’t wrestle with clouding or dropout at each stage.
The hydroxymethyl group on the second position remains a practical handle for further functionalization. This gives our molecule unique value for pharmaceutical chemists: it can act as a coupling partner, or be converted cleanly in late-stage synthesis to other functional groups. In catalytic steps, we saw that this modification encourages consistent yields — not just because of purity, but because the group resists side reactions that sap efficiency. Years ago, similar structures led to tough byproduct removal, a pitfall our present version avoids.
We make this molecule for researchers and manufacturers who build on our foundation. The core market lies in pharmaceutical intermediates, where routes to active molecules often demand a versatile pyridine backbone. Some of our partners in agrochemical innovation have found its substitution pattern meets new regulatory calls for environmental persistence controls—an unexpected but welcome quality discovered during pilot studies.
Analytical chemists and formulation teams often single out our batches for ease of NMR and MS tracking, as impurity profiles have been characterized at microgram scale using our archived samples. We remember when unidentified side products caused throwaway pilot runs; now, that risk stays low. This reliability means teams can focus on optimizing their core product, not troubleshooting the starting material.
Custom synthesis teams working in both batch and continuous reaction modes report fewer stuck filters and less need for repeated purification. Our years tracking these outcomes matter more than any catalog description. We’ve seen firsthand how poor filtration or off-color batches slow development timelines, burn budgets, and frustrate progress. The outcome is clear: high-performing versions of this product often make the difference between a missed deadline and a successfully scaled process.
We’ve worked with a broad cross-section of substituted pyridines over the decades. Direct structural relatives, such as 2-methyl-4-pyridinemethanol or unsubstituted 3,4-dimethylpyridine, serve various industrial roles too, but few match the balance of reactivity and physical stability seen with this compound. In practice, too many methyl or alkoxy substituents have led to phase separation issues, or awkward residue profiles that make downstream chromatography a persistent issue. 2-Hydroxymethyl-3-methyl-4-(3-methoxypropanoxyl)pyridine navigates that middle road, providing enough functional diversity to serve as an intermediate and end-use agent, without clogging up reactors or forming intractable side products during scale-up.
Unlike other similar products on the market, our multiple production runs revealed that subtle shifts in temperature or pressure during the key etherification step produce significant variance in impurity content. Over years of experimentation, we dialed in operation conditions to minimize troublesome byproducts. This matters for users running sensitive reactions later. Our logs showed much-improved downstream reactivity with fewer solubility and crystallization quirks compared to commercial grades made by shortcut routes.
As direct manufacturers, our teams have end-to-end control from raw reagent sourcing to finished product dispatch. There’s a big difference between managing test batches under lab hoods and keeping tons of material running through multipurpose reactors each year. That experience means problems get fixed fast, contamination incidents get traced to source, and repeated process tweaks are reflected in every new batch.
Our plant-level QC procedures evolved through hard lessons. Early on, inconsistent raw material supplied by brokers led to undetected residue issues, costing several customers difficult weeks. Every drum is now accompanied by electronic batch records, so you know not just what’s inside, but how it got there and under what conditions it was made. This oversight drives our team culture—a sharp contrast to vendors treating specialty molecules like bulk commodity goods.
We keep reference samples from every run for at least five years. Requests for detailed analytical breakdowns—from chiral purity to trace metal content—get answered by chemists actually familiar with the particular batch, not a help desk following a script. That kind of personal accountability flows back into how each successive production run gets tweaked and improved.
Every partnership with a downstream user informs how we approach the next scale-up or optimization. One partner in oncology R&D shared results about trace aldehyde byproducts fouling later-stage palladium-catalyzed couplings. After reviewing their observations, we implemented stricter temperature ramping and modified post-reaction quenching. Follow-up testing proved the change removed the aldehyde issue and led to a product with consistent GC-MS profiles batch after batch. Stories like these shape our internal standards and keep us motivated to refine every aspect of the process—never assuming “good enough” really is.
The culture in our plant values ongoing conversation. Chemists regularly talk with purchasing staff and production engineers at partner companies. We visit labs or host them at our facility for joint troubleshooting, rather than hiding behind generic specifications. Years of seeing firsthand how process hiccups or raw material quirks ripple through a product’s lifecycle means we prize frank dialog over slick marketing.
Weather, distance, and storage conditions all shape how specialty chemicals move from facility to facility. We learned quickly that off-the-shelf packaging—especially for specialty pyridines—often fails customers when humidity fluctuates during transit. Early years taught us sorbent-liner barrels outperformed simple polyethylene drums for keeping product dry and free flowing, especially in monsoon and desert conditions. Lab trials showing stable melting points under temperature cycling sealed our decision to upgrade all shipments.
Inquiries about shelf life tend to come from buyers unfamiliar with the hands-on realities of storing substituted pyridines. In controlled warehouse conditions, we document stable product performance well beyond twelve months, with no measurable loss in purity or caking under our standard recommendations. These conclusions spring from our own tracked inventory, not just accelerated stability studies. Users who need longer-term storage or split shipments benefit from tested experience rather than theoretical shelf-life claims.
Customs hurdles and transport route changes around the world sometimes create unplanned delays. Because our technical teams coordinate with logistics, we offer substantive, real-time support rather than canned shipment status updates. The understanding that no two shipping routes or storage environments look the same—especially across multiple continents—drives every improvement we implement for packaging and documentation.
New markets and technologies demand more than just familiar intermediates. Our R&D pipeline keeps probing for ways small molecular changes can support better drug candidates or eco-friendlier agrochemical products. Field results—rather than abstract structure-activity predictions—help us decide which new analogs earn a spot on our production schedule. In recent years, customers tackling green chemistry milestones have shaped our product line more than any internal vision. Requirements for solvent recycling and degradability inspired us to optimize for minimal process residues and safer waste profiles.
We see more overlap now between industries. Pharmaceutical research and agricultural teams look for molecules with both synthetic flexibility and environmental compliance built in. Our experience with 2-Hydroxymethyl-3-methyl-4-(3-methoxypropanoxyl)pyridine—across both applications—proves that reliable, well-made intermediates cut headaches on both sides of the regulatory aisle. Open lines of communication about new directions, or even regulatory curveballs, sit at the core of our approach.
It’s tempting to imagine chemical manufacturing as a steady, streamlined process, but behind every drum stands a crew of experienced workers and detail-oriented managers. Early-morning checks of filtration runs, late-night tweaks to distillation columns, and countless hours logging batch modifications all give life to the finished pyridine derivative. That hands-on familiarity lets us catch problems well before they show up in customer labs down the line.
Laboratory experts advise production colleagues, flagging unexpected solubility or reactivity glitches based on the latest customer feedback. Down-to-earth recordkeeping—batch numbers that mean something, not simply a long string of digits—supports connections between issues in the plant and questions raised by R&D partners. This clear feedback loop ensures continuous improvement, not just in documentation but in day-to-day practices.
Stories of failed lots, delayed projects, or mysterious impurities from suppliers are not just rumors—they're frustrations we've solved for real people running real projects. We’ve tackled unexpected color formation, excess endpoint water, and even rare cases of filter clogging caused by minuscule process deviations. The solution often involves small but critical changes, such as adjusting pH during work-up, shifting distillation cut-off points, or modifying drying regimes.
Every lesson surfaces during field audits or data sharing, bridging the lab and the factory. Shared victories—like a new synthetic shortcut or a filter-saving tweak—get built into future acts. This culture, born from the honest friction of industrial chemistry, pushes us to deliver batches of 2-Hydroxymethyl-3-methyl-4-(3-methoxypropanoxyl)pyridine that provide more than just a chemical name on a label: they mean projects run smoother, development cycles shorten, and chemists gain confidence in their path from theory to finished product.
Real-world chemical manufacturing depends on the reliable output of products that solve problems for people designing tomorrow’s medicines and crop protection agents. 2-Hydroxymethyl-3-methyl-4-(3-methoxypropanoxyl)pyridine embodies this approach—a product refined not by chasing technical perfection but by fixing real imperfections, batch after batch, in partnership with users large and small. Our commitment remains: keep refining, keep learning, and always put the practical, everyday needs of our partners at the heart of every production run.
