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HS Code |
958540 |
| Chemical Name | 3-pyridinemethanol, 5-chloro-6-methoxy- |
| Molecular Formula | C7H8ClNO2 |
| Molecular Weight | 173.60 g/mol |
| Cas Number | 70768-35-7 |
| Appearance | White to off-white solid |
| Solubility | Soluble in organic solvents such as methanol, DMSO |
| Smiles | COC1=C(C=CC(=N1)CO)Cl |
| Inchi | InChI=1S/C7H8ClNO2/c1-11-7-5(8)2-3-6(9-7)4-10/h2-3,10H,4H2,1H3 |
As an accredited 3-pyridinemethanol, 5-chloro-6-methoxy- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 3-pyridinemethanol, 5-chloro-6-methoxy- is supplied in a 25g amber glass bottle with a tamper-evident cap. |
| Container Loading (20′ FCL) | 20′ FCL container is loaded with securely packaged 3-pyridinemethanol, 5-chloro-6-methoxy-, ensuring safe, moisture-free chemical shipment. |
| Shipping | Shipping for 3-pyridinemethanol, 5-chloro-6-methoxy- requires secure, leak-proof packaging, proper chemical labeling, and compliance with local and international transport regulations. The substance may require storage at controlled temperatures and restricted handling procedures. Ensure accompanying documentation details hazards, and only authorized personnel, trained in chemical handling and safety protocols, should manage shipping. |
| Storage | **3-Pyridinemethanol, 5-chloro-6-methoxy-** should be stored in a tightly sealed container, protected from light and moisture, in a cool, dry, and well-ventilated area. Keep away from incompatible substances such as strong oxidizers and acids. Store at room temperature, avoiding excessive heat. Always ensure appropriate labeling and access to safety data sheets for proper handling and emergency information. |
| Shelf Life | 3-pyridinemethanol, 5-chloro-6-methoxy- typically has a shelf life of 2-3 years when stored in a cool, dry place. |
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Purity 98%: 3-pyridinemethanol, 5-chloro-6-methoxy- with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Molecular Weight 173.6 g/mol: 3-pyridinemethanol, 5-chloro-6-methoxy- with a molecular weight of 173.6 g/mol is used in medicinal chemistry research, where it enables precise molecular design and optimization. Melting Point 67°C: 3-pyridinemethanol, 5-chloro-6-methoxy- with a melting point of 67°C is used in solid-state formulation studies, where it supports ease of processing and controlled crystallization. Stability Temperature up to 120°C: 3-pyridinemethanol, 5-chloro-6-methoxy- stable up to 120°C is used in high-temperature reaction protocols, where it maintains structural integrity during synthesis. Particle Size <50 μm: 3-pyridinemethanol, 5-chloro-6-methoxy- with particle size less than 50 μm is used in catalyst support preparation, where it improves dispersion and reactivity. Viscosity Grade Low: 3-pyridinemethanol, 5-chloro-6-methoxy- with low viscosity is used in chemical formulation blending, where it enhances mixing efficiency and homogeneity. Assay ≥99%: 3-pyridinemethanol, 5-chloro-6-methoxy- with assay greater than or equal to 99% is used in analytical reference standards, where it provides accurate calibration and measurement reliability. Solubility High in Methanol: 3-pyridinemethanol, 5-chloro-6-methoxy- with high solubility in methanol is used in solution-phase synthesis, where it enables straightforward compound handling and transfer. Storage Condition 2-8°C: 3-pyridinemethanol, 5-chloro-6-methoxy- stored at 2-8°C is used in biological assay development, where it ensures long-term stability and consistent performance. Water Content <0.5%: 3-pyridinemethanol, 5-chloro-6-methoxy- with water content less than 0.5% is used in moisture-sensitive reactions, where it prevents unwanted side reactions and increases product purity. |
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Working in a place where every gram matters, every reaction leaves a footprint, and quality never sleeps, I’ve come to view chemicals like 3-pyridinemethanol, 5-chloro-6-methoxy- more as building blocks than just items on a label. Our team produces this compound in a way that respects its complexity. Creating this specialty alcohol derivative starts by understanding exactly what industrial and research customers have faced with alternatives—issues with impurities, low batch-to-batch consistency, and difficulty integrating modified pyridine structures into scalable synthetic methods.
Watching this molecule form, I see more than reagents and glassware. Chlorination and methoxylation on the pyridinemethanol ring don’t tolerate shortcuts. Experience has shown that the location of substituents makes or breaks performance in advanced formulations. The 5-chloro and 6-methoxy positions weren’t picked by accident—they came from feedback and late-night tests to improve selectivity and downstream reactivity for our partners in pharmaceuticals and agrochemicals.
Let’s talk specifics. 3-pyridinemethanol, 5-chloro-6-methoxy-, as prepared in our reactors, reflects a model refined by setbacks and technical wins. Our synthetic route prioritizes minimizing byproducts, encouraging high yields of the desired regioisomer, and eliminating problematic organometallic residues—pain points you won’t see listed in spec sheets but ones that surface when real-world users start scaling up. Each run is tested using modern HPLC and GC-MS; spotting trace organics can mean the difference between a project’s on-time delivery and a month lost troubleshooting. Over years, our purification practices have focused not only on purity but also on ease of handling and solubility in application-specific solvents.
Physically, the finished product leaves our line as a free-flowing, crystalline solid. That leaves no mess to clean up after opening containers—an element users have requested after bad experiences with sticky intermediates or poorly dried materials. The compound displays excellent solubility in polar aprotic solvents as well as select aqueous buffer systems, allowing for reliable use in diverse synthetic processes. Color and odor markers, often overlooked, are tightly controlled to prevent interference in sensitive labeling or imaging applications.
Technicians in labs and industrial plants haven’t got the luxury of using ‘almost’ pure intermediates—one off-note and the next step can fail, costing time and money. 3-pyridinemethanol, 5-chloro-6-methoxy- has proven its value in projects ranging from heterocycle synthesis to advanced esterification schemes. Its most consistent role appears in the early stages of pharmaceutical candidate generation, often acting as a reliable nucleophile or protecting group anchor. Chemists report that the 5-chloro substitution improves selectivity for subsequent reactions, reducing side product formation and making purification less painful. The 6-methoxy function boosts electron density where it matters, offering predictable reactivity during planned derivatization steps.
Several partners have moved from traditional pyridinemethanol derivatives to this specific substituted compound after running headlong into reproducibility issues. By focusing on structure-activity relationships noted in in-house and published literature, we’ve seen customers shave weeks off their route optimization efforts. For scale-up, the robustness of our product means fewer failed kilos and less on-the-fly troubleshooting. Chemists tasked with preparing active pharmaceutical intermediates can depend on the lot-to-lot reliability—something we’ve built by refusing to cut corners, even when cheap shortcuts beckoned.
On its surface, ‘another pyridinemethanol’ might sound familiar. The real distinction comes out through the lens of those who use our product for synthesis or formulation. Generic pyridinemethanol, especially the unsubstituted or mono-substituted variants, often brings nagging challenges to those working with halogen atoms or electron-donating groups at competing positions. Chemists find themselves forced to add extra protection steps or tolerate inconsistent yields. Our 3-pyridinemethanol, 5-chloro-6-methoxy- cuts through those frustrations; controlled substitution brings directed reactivity and greater process predictability.
The differences show up in real data and process metrics. We’ve had researchers tell us they previously dealt with significant degradation in storage, or color formation after prolonged shelf life—problems practically eliminated in our current offering. Our synthetic approach locks out many degradation routes, meaning longer stability and reduced waste. Impurity profiles are cleaner; you don’t get the ghost peaks or unexplained signals that can stall QA/QC or regulatory discussions. Even physically, competitors’ lots sometimes arrive caked or clumped, but ours keeps free-flowing right through the seasons, a detail traced back to attention during crystallization and drying, not something left to chance.
Chemical manufacturing isn’t just about filling a checklist. After years spent tweaking reactions, checking impurity fingerprints, and tracking customer complaints, I’ve learned that purity by itself isn’t the only measure worth following. For this compound, assay values routinely exceed published requirements. We track water content, not because every buyer asks for it, but because residual moisture at levels barely detectable can crash some users’ yields later downstream.
Residual solvents, too, come under scrutiny. Our purification team runs every batch through additional analyses to confirm absence of Class 2 and Class 1 solvents, as defined by ICH guidelines. These checks, overlooked by many in the field, bring peace of mind, especially for those who require material for regulated pharmaceutical development. Each shipment heads out with a complete analysis, but the peace of mind starts long before that—with carefully controlled environments and sensibly chosen raw materials.
Feedback cycles drive much of what makes this product better year over year. When customers tell us about new applications or unique results, those insights don’t go on a shelf. We revisit our process, test modifications, and adapt to new expectations. Some improvements appear small—better liner materials for drums, tweaks to particle size—but in practical use, this matters more than broad claims about ‘high purity’ or ‘high performance’.
Over the past decade, most requests for 3-pyridinemethanol, 5-chloro-6-methoxy- came from drug discovery teams. Small, early-phase discovery houses and university groups form the largest share, especially those running through libraries of modified pyridines in search of lead compounds. The tightest feedback we receive, though, has come from pilot-scale research for pre-clinical synthesis. These teams set the highest bars, needing not only purity but trustworthy analytical support.
More recently, demand has broadened. Researchers in crop protection and custom chemical synthesis have taken up this product as a stepping stone in multi-step processes requiring stable halogenated alcohols. They often point out how switching from mono-substituted to our more complex derivative decreased the number of protection or activation steps.
The compound also slots directly into processes looking to avoid unnecessary hazardous steps, such as using stoichiometric oxidants or excessive halogenating reagents. By providing the chlorinated building block up front, users can cut out riskier chemical handling, enhancing both workflow safety and environmental outcomes. These are points that press releases and glossy brochures seldom mention, but they come up in nearly every in-depth technical call.
Many of the users who adopt 3-pyridinemethanol, 5-chloro-6-methoxy- for the first time do so after working through failed or unreliable syntheses with other pyridine-based alcohols. Several of our regular customers have remarked on the transformation in batch-to-batch variability—troubleshooting time plummeted, and final yields stepped up consistently. Some have written back to say that the absence of unknowns in their NMR data gave their QC teams confidence to move faster. In cases involving scale-up, project management teams noted that shipping delays from weather or customs didn’t end with material stuck solid in a drum; packaging and anti-caking approaches implemented during production make a difference nobody misses at the bench.
Industrial chemistry doesn’t reward theory—it rewards results. Multiple partners track time lost to unexpected variances or impurities; by shifting to higher-grade material, several have reported overall process costs dropping, not just because of direct price differences but mostly through reduced rework and fewer process interruptions.
Much of our approach is about anticipating the obstacles scientists and engineers face daily. Impurity control, shelf-life, packaging integrity, and supply confidence show up again and again. In our shop, the solution wasn’t a single technological leap but ongoing process refinements:
There is no dress rehearsal for a central chemical building block during a make-or-break synthesis. As a manufacturer, we carry the obligation to see quality from the customer’s side—fine-tuning batches, talking with researchers, documenting changes, and keeping data transparent and available for audits or regulatory need.
It’s easy for chemical producers to claim superior quality. What supports those claims is the data and the demonstrated history of making adjustments based on real feedback. Our process files span more than a decade and include records of every modification suggested by users. Chemists appreciate open Q&A during audits; we share process innovations, results of stress tests, and the complete impurity profile without hiding failures along the way. If a compound batch ever fails to meet benchmarks, the batch never ships. This policy grew out of earlier days when we learned hard lessons about recall and remediation—that transparency forms the backbone of reliability.
Full transparency extends to our supplier chain. Each chemical input is tested using supply-side analytics, backed up by our in-house labs. Our customers routinely cite this as a reason for choosing our materials for regulated-process development, especially under cGMP or ISO regimes. In an environment where compliance, accountability, and trackability shape purchasing decisions, real openness wins over generic claims.
We don’t stand still after reaching a stable process. The market for substituted pyridinemethanols keeps evolving, driven by more complex synthetic requirements and new regulatory hurdles. Ongoing R&D focuses on two main directions: unlocking new reactivity patterns and driving further improvements in impurity control. The breadth of requests from innovators in biochemistry, materials science, and process engineering continues to surprise us.
Each year, we put out multiple pilot lots in response to research institutions seeking tweaks: altered particle size, custom solvent blends, or adjusted chlorine content. Some developments don’t make the cut, but the best ultimately feed back into our primary production route, raising the baseline of quality for everyone. Our hands-on approach—collaborative development, shared test reports, jointly observed synthesis runs—sets us apart in the specialty chemical industry.
Responsible manufacturing isn’t just about today’s order. Our experience producing 3-pyridinemethanol, 5-chloro-6-methoxy- points to a broader shift in the chemical industry: stewardship. Chemists, end-users, and procurement professionals all ask the same questions about source, purity, and process safety. We respond not just with data but with a demonstrated record of responsible scaling, emissions reduction, and minimized waste.
The development and production of halogenated and methoxylated pyridinemethanol derivatives pose regulatory and environmental challenges. Our facility employs advanced solvent recovery systems, modern filtration, and closed-loop handling to reduce chemical loss and limit discharge. This isn’t only about meeting laws—it’s about building trust in our material’s sustainability and the reliability of our processes for future users. Partnerships with research consortiums advance greener chemistry, looking for alternative routes with fewer hazardous reagents and less waste at every stage.
If there’s one lesson from producing and supplying 3-pyridinemethanol, 5-chloro-6-methoxy-, it’s that reliability and transparency outlive almost every claim on a website. The feedback from frontline users keeps improving both our product and our service. Whether the need is to shorten process timelines, reduce the number of cleanup steps, or simply avoid the headaches of inconsistent lots, our manufacturing team stands behind every shipment—not just with systems and data, but with the lived experience of seeing the molecule through from synthesis to shipping.
Today’s innovators in pharma, materials, and specialty chemicals demand more than off-the-shelf intermediates. In a competitive field, technical edge comes from consistent outcomes, trustworthy data, and a partner who invests in understanding user needs and fixing problems at the source. Producing specialty compounds like 3-pyridinemethanol, 5-chloro-6-methoxy- is less a routine than a dialogue—a long-term commitment to doing things right, batch after batch.
