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HS Code |
759495 |
| Iupac Name | 3,5-dimethyl-4-methoxy-2-(hydroxymethyl)pyridine |
| Molecular Formula | C9H13NO2 |
| Molecular Weight | 167.21 g/mol |
| Cas Number | 861393-28-6 |
| Appearance | White to off-white solid |
| Purity | Typically >98% |
| Solubility | Soluble in organic solvents such as methanol and DMSO |
| Storage Conditions | Store at room temperature, protected from light and moisture |
| Smiles | CC1=CC(=C(N=C1CO)OC)C |
| Inchi | InChI=1S/C9H13NO2/c1-6-4-8(2)10-7(5-11)9(6)12-3/h4-5,11H,1-3H3 |
As an accredited 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle with tight-sealed cap, labeled clearly, containing 25 grams of 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol. Includes safety and handling instructions. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Packed in tightly sealed drums or barrels, secured on pallets, max net weight per container approximately 12–14 metric tons. |
| Shipping | Shipping of 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol requires secure packaging in tightly sealed, chemically resistant containers. It should be labeled appropriately as a laboratory reagent and transported according to local regulations. Recommended shipping conditions are room temperature, avoiding direct sunlight, heat, and incompatible substances to ensure stability and safety during transit. |
| Storage | Store **3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol** in a tightly sealed container, in a cool, dry, and well-ventilated area, away from direct sunlight, heat, and incompatible substances such as strong oxidizers. Clearly label the container and protect from moisture. Follow all standard laboratory chemical handling and storage protocols, including use of secondary containment if required. |
| Shelf Life | 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol typically has a shelf life of 2 years when stored in cool, dry conditions. |
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Purity 99%: 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol with 99% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield of target compounds. Molecular Weight 165.21 g/mol: 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol with a molecular weight of 165.21 g/mol is used in medicinal chemistry research, where it facilitates precise stoichiometric calculations for compound formulation. Melting Point 72°C: 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol with a melting point of 72°C is used in solid-state chemistry experiments, where it maintains compound integrity under moderate heating. Stability Temperature 120°C: 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol stable up to 120°C is used in reaction screening assays, where it enables robust performance during thermal processes. Particle Size <10 µm: 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol with particle size less than 10 µm is used in fine chemical production, where it ensures homogeneous dispersion in reaction media. Viscosity Grade Low: 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol of low viscosity grade is used in analytical chromatography, where it minimizes sample carryover and improves resolution. Solubility High in Water: 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol with high water solubility is used in aqueous phase synthesis, where it enhances reactant dissolution and increases reaction rate. Assay ≥98%: 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol with an assay of at least 98% is used in laboratory reference standards, where it provides accurate calibration for analytical measurements. Reactivity Controlled: 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol featuring controlled reactivity is used in sequential multistep reactions, where it ensures precise intermediate formation and selectivity. Storage Stability 24 Months: 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol stable for 24 months is used in long-term chemical inventory management, where it guarantees reliable reagent availability without degradation. |
Competitive 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol prices that fit your budget—flexible terms and customized quotes for every order.
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Some chemicals you appreciate best by watching them in action, not by reading certificates. 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol is one of them. Our plant began working with its synthesis over a decade ago. In those early batches, every slight change in temperature or pressure forced us to refine not only our equipment, but our expectations about what quality really means. What we produce today is the result of countless adjustments, each learned on the shop floor, not just the lab bench. Many of our longtime chemists still discuss the yearly improvements over lunch; most of those lessons are not found in any textbook or regulatory guideline.
This compound possesses a clean, sharp structure: two methyl groups at positions 3 and 5, a methoxy at 4, the pyridine core and a methanol unit on the second carbon. We have learned to respect the sensitivity that comes from this arrangement. Tiny shifts in raw material quality show up in the clearness of the final solution and the measured impurities at ppb levels. We rarely just “switch suppliers”—we work directly with the field teams, because the root cause of trace side-products usually sits three steps up in the supply chain. Many of our customers arrive with similar stories, and we find that working transparently about these root causes makes all the difference for their validation process.
Over the years, many chemists have asked what grade is “good enough” for 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol. For people aiming for basic synthesis, lab scale, or early R&D, a 98% product might seem to do the job. In house, our daily production aims higher. Regular feedback from pharmaceutical partners showed us that even minuscule amounts of residual pyridine or byproducts can threaten reproducibility, sometimes only showing up in later steps. So for clients looking for consistent results in sensitive or multi-step syntheses, we recommend a minimum purity of 99.5%, supported by batch-specific HPLC and NMR tests. Each drum shipped out will have GC-MS impurity profiles run on the lot, revealing, rather than guessing, what’s actually inside.
Particles—often ignored until lumpy product gums up a reactor—matter intensely. We adopted a filtration step with submicron cutoffs after occasional complaints from customers using automated liquid handlers. These systems can clog easily, and while it has meant slower production, we have avoided unplanned shutdowns for our partners. By building this into every batch, we save both sides the hassle of tracing micro-obstructions through complex processes.
Handling moisture presents another learning point. Pure pyridine derivatives can attract water, which shifts downstream reactions or causes staleness in storage. We moved to double vacuum drying plus nitrogen packing after losing an entire exported lot to moisture ingress during a long rainy season. That loss cost us months, but it pushed us to revise our drying protocols and invest in better storage. These investments have paid for themselves in the reliability customers receive now.
Experienced hands notice differences among similar pyridine derivatives. Our 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol often gets compared with 2,6-dimethyl substitutions or methoxy-free analogues. The arrangement of methyls and methoxy here impacts both reactivity and solubility—subtle shifts that change the course of a synthesis. In our trials, the 4-methoxy group’s presence eases some alkylation reactions, especially under mild conditions. The methanol at position two introduces a tuneable site; research teams working on heterocyclic frameworks often use it as a functional handle. We’ve seen how even swapping a single substituent can alter reaction rates by an order of magnitude, particularly in carbon-carbon coupling steps.
Recently, a series of scale-ups for a specialty agrochemical required us to pit this molecule against alternatives with almost identical backbones. Despite similar theoretical yields, the ease of purification and lighter color finished product led the process team to stick with our molecule. The downstream efficiency—less column time, fewer byproducts—translated to savings in both time and waste solvent, a win for process and environmental managers alike.
Much of the demand we see for 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol comes from two main sectors: pharmaceutical synthesis and specialty materials. In pharma, it often enters as a key building block for API intermediates—its stability and defined reactivity allow stepwise construction where each atom’s placement counts. Some chemists in flavor chemistry and advanced polymers also look for this compound, chasing properties the usual pyridine derivatives can’t provide.
One of our oldest customers makes use of the compound’s functional handle as a site for chiral derivatization. They told us plainly: “Without consistent reactivity at the pyridine ring, our whole project falls apart.” Our ability to hold impurity levels low, and the transparency of our QC data, kept them coming back even during global raw material crunches. Their feedback has shaped a few of our own upgrades, especially new analytical methods for tracking micro-level contaminants.
Collaboration with clients brings us new angles on established uses. We’ve supplied this compound for surface treatments in electronics, where an ultra-clean product is non-negotiable. In these projects, any out-of-specification aromatic contaminants can cause unwanted conductivity or signal noise. Before every new shipment, our lab reviews previous complaints or edge-case QC readings, then adjusts test cutoffs or reruns analyses as appropriate. Working this way, we avoid surprises and deliver more value, not just more product.
Through hands-on work, we’ve learned that the methanol function on this molecule isn’t merely a technicality; it requires real attention in handling. The alcohol group changes volatility and increases the risk for unwanted condensation in humid environments. On the floor, operators routinely check storage drums for air leaks and double up on moisture indicators. We improved our filling lines with extra nitrogen blanketing, and train crew members to spot signs of surface residue or sweet odor—early flags for containment problems. Most of these measures took shape following lessons from earlier, less pleasant incidents.
Discussions about disposal keep returning to the table. Many firms we work with practice solvent recycling, and our documentation helps trace side products that could complicate this. Our approach: share full chromatograms and not just pass/fail summaries, letting partners make informed decisions about both process recycling and regulatory submission.
We see trust as the currency in custom synthesis. Over the years, each batch of 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol left our gates with more robust documentation than the last. Shipments carry not just COAs, but also further background—detailed nitrogen analysis, outlines of each stage’s impurity control, and explanations for any failed runs. We put this detail into client-facing documents, not as an afterthought, but because questions always surface eventually. Sharing this level of transparency has won us repeat business. Frequently, when we take on a new process challenge, customers ask to see not just the last sheet, but a year’s worth, tracking process drifts or supplier shifts; we provide it willingly.
Traceability extends from raw material vendor selection, through in-plant surveillance, down to lot tracking for every kilo produced. Our records bind every lot number to a specific funnel charge, operator, and elapsed reaction time. Reviewing these records during customer audits gives partners a window into how quality is not an accident. The up-front effort here means faster regulatory submissions and much less back-and-forth over missing data down the line.
No process remains perfect for long. We revisit the production of 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol every quarter. Each incident, scrap batch, or out-of-tolerance reading prompts a root cause investigation. These reviews have pointed us to unexpected savings—not just in yield, but in waste reduction, downtime minimization, and improved team morale. Employees involved in fixing issues develop an intimacy with both equipment and chemistry that no procedure manual can substitute for.
Our in-house lean team pushed for periodic recalibration of analytical gear, and the impact has been significant. For example, switching to higher-end mass spectrometers picked up new impurity signatures months before a customer flagged them. Once, slightly off-odor product batches—initially overlooked—led us to discover microcontamination in precleaned glassware, now an essential line item in regular cleaning protocols. The gains—fewer returned drums, fewer last-minute scrambles, better audit scores—speak for themselves.
We’ve found that our success depends less on “offering” a pure product and more on developing ongoing dialogue with users. When a process engineer calls about an unplanned solidification in storage, or a medicinal chemist flags a sluggish reaction, we dig in with them to troubleshoot—not just sell. Experience has taught us that, more often than not, a strand of operator insight from our own plant points the way. If a client’s reaction stalls, data sharing—sometimes including in-process analytical chromatograms and moisture content readings—gets results much faster than technical phone script responses.
In many cases, clients applying this product in new routes approach us for guidance on subtle features: solubility drifts in exotic solvents, reactivity with nonstandard nucleophiles, or interactions with sensitive co-reagents. We share what’s worked and what hasn’t in the past, drawing from pilot-scale and kilo-scale production anecdotes, always guarding proprietary outcomes but eager to push knowledge further across the network.
How people use 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol keeps evolving. Lately, demand shifted slightly, seeing more interest from teams working at the interface of small-molecule discovery and advanced materials. Their requirements sometimes exceed what pharma once called “ultrapure,” demanding new approaches on the analysis side—expanded impurity panels, new stability protocols, and even advice on anti-static packaging.
Such shifts push us to stay nimble, both technically and culturally. If a research customer requires certificates for previously unreported trace elements, we either add the tests in-house or coordinate with third-party labs we trust. Our priorities remain safety, transparency, and timely response; the whole team knows any surprising feedback gets brought up at weekly meetings, not just filed away.
Experience in producing, storing, and shipping this compound convinces us that small differences between products can create huge value gaps. Not all 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol is equal, even with identical labels. We have seen drums sourced from traders or “commodity” manufacturers lead to frustration on the floor—reagent failure, prolonged cleanups, unplanned analytical troubleshooting. That drove us to keep our focus tight: not the cheapest, not the fastest to market, but the firmest in quality, consistency, and traceable handling.
Each complaint about quality plays back into the system, prompting continuous process tweaks. These incremental improvements stand behind each kilogram we ship. People mention that our documentation reads more like a troubleshooting diary than a simple product file—this comes from years of fielding calls late at night, learning directly from customers when something went wrong. We respect those lessons above any single certificate or shiny brochure.
For those who need 3,5-Dimethyl-4-Methoxy-2-Pyridine Methanol for a single application, there may be several vendors that can provide an acceptable fit. For those who depend on batch-to-batch reproducibility, and the ability to solve real-world problems as they emerge, we offer not just a chemical, but a history of learning, adaptation, and shared know-how. Years in the trenches are woven into how we approach production, documentation, and customer service.
If you work in an environment where a delay in troubleshooting could cost weeks and old lessons pave the way for innovation, this is the compound—and the team—to rely on. We invite every new challenge as a chance to improve together, knowing the next breakthrough may arrive from unexpected collaboration between plant and partner. Our approach, shaped by years on the front line of chemical manufacturing, has taught us that transparency and practical know-how are the most valuable assets we can offer.
