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HS Code |
102438 |
| Chemical Name | 5-Hydroxy-2-methoxypyridine |
| Molecular Formula | C6H7NO2 |
| Molecular Weight | 125.13 g/mol |
| Cas Number | 18311-23-2 |
| Appearance | White to off-white solid |
| Melting Point | 74-77°C |
| Solubility | Soluble in water and polar organic solvents |
| Smiles | COC1=NC=CC(C1)=O |
| Inchi | InChI=1S/C6H7NO2/c1-9-6-4-5(8)2-3-7-6/h2-4,8H,1H3 |
| Storage Conditions | Store in a cool, dry place, tightly closed |
As an accredited 5-HYDROXY-2-METHOXYPYRIDINE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 5-HYDROXY-2-METHOXYPYRIDINE, 10g, is supplied in a sealed amber glass bottle with tamper-evident cap and detailed chemical labeling. |
| Container Loading (20′ FCL) | 20′ FCL can load around 12 metric tons of 5-HYDROXY-2-METHOXYPYRIDINE, securely packed in fiber drums or cartons. |
| Shipping | 5-HYDROXY-2-METHOXYPYRIDINE is shipped in sealed containers, protected from moisture and light. Transport complies with relevant hazardous material regulations, ensuring safety during transit. Proper labeling and documentation are included. Storage conditions require a cool, dry environment. Upon receipt, inspect the packaging for leaks or damage before use. |
| Storage | Store 5-HYDROXY-2-METHOXYPYRIDINE in a tightly sealed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizing agents. Protect from light and moisture. Ensure storage location is labeled and follows local chemical regulations. Use secondary containment if necessary, and keep away from sources of ignition or excessive heat. |
| Shelf Life | 5-HYDROXY-2-METHOXYPYRIDINE is stable under recommended storage conditions; shelf life is typically 2–3 years if kept dry and sealed. |
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Purity 98%: 5-HYDROXY-2-METHOXYPYRIDINE with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Melting Point 154°C: 5-HYDROXY-2-METHOXYPYRIDINE with a melting point of 154°C is used in solid formulation development, where it provides enhanced thermal stability during processing. Molecular Weight 139.13 g/mol: 5-HYDROXY-2-METHOXYPYRIDINE with a molecular weight of 139.13 g/mol is used in analytical standard preparation, where it enables precise quantitation in HPLC analysis. Solubility in Methanol: 5-HYDROXY-2-METHOXYPYRIDINE with high solubility in methanol is used in solution-phase organic synthesis, where it ensures rapid dissolution and homogeneous reaction mixtures. Stability Temperature 70°C: 5-HYDROXY-2-METHOXYPYRIDINE with a stability temperature of 70°C is used in storage and transport of chemical reagents, where it maintains product integrity and reduces degradation risk. Particle Size <75 µm: 5-HYDROXY-2-METHOXYPYRIDINE with particle size less than 75 µm is used in fine chemical blending operations, where it improves uniform dispersion in composite mixtures. Water Content <0.5%: 5-HYDROXY-2-METHOXYPYRIDINE with water content less than 0.5% is used in moisture-sensitive reactions, where it minimizes hydrolysis and side-product formation. UV Absorbance λmax 310 nm: 5-HYDROXY-2-METHOXYPYRIDINE with UV absorbance maximum at 310 nm is used in spectroscopic applications, where it provides reliable chromophoric detection for assay development. |
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The world of fine chemicals is full of subtle differences that can change how a whole process runs, especially in pharmaceutical, chemical, and research settings. Among pyridine derivatives, 5-Hydroxy-2-Methoxypyridine has started to draw real attention, and not just because of its unique arrangement of functional groups. Over the years, I have seen labs wrestle with trade-offs between purity, reactivity, batch-to-batch consistency, and regulatory compliance. Working with compounds like this one can completely change that dynamic.
5-Hydroxy-2-Methoxypyridine offers a balance between versatility and specificity. The position of its hydroxy and methoxy groups gives it characteristics that set it apart from more basic pyridine compounds. This is not just chemical trivia; it influences reactivity and the pathways open for downstream synthesis. I have sat through meetings where teams banged their heads against the wall because another, less specialized pyridine derivative kept giving out-of-spec results in medicinal chemistry projects. Switching to a well-characterized compound like this can streamline those bottlenecks.
It is easy to get lost in lists of chemical specs, but experience tells me that purity and trace contaminants matter most for researchers and manufacturers. The standard reference for 5-Hydroxy-2-Methoxypyridine has a molecular formula of C6H7NO2 and a molar mass that matches analytical predictions. What separates it in performance is the way it is manufactured and documented. For those in regulated industries, having a consistently pure batch offers peace of mind. Misfires in experiments often start with minute impurities, and having purity backed by reliable analytics saves time and prevents the sort of cross-contamination headaches that can stop a whole line of research.
This compound shows good stability under normal storage conditions. Shelf life and stability always come up in procurement meetings, and here, being able to stock and store without constant degradation checks is a relief. The hydroxy group at the fifth position opens up new reactions in comparison to plain pyridine or even 2-methoxypyridine. This allows chemists to pursue transformations that would be cumbersome or impossible with more common building blocks. I recall a project where researchers needed selective activation at the 5-position; alternative reagents just couldn’t do the job without creating a host of unwanted side products. This pyridine derivative solved that with less fuss.
Out in the real world, theory only goes so far. What counts is how a chemical behaves: Will it dissolve? Does it hold up to repeated processing? Will it let you avoid byproducts that the regulatory folks dread? 5-Hydroxy-2-Methoxypyridine is soluble in most common solvents, which makes it straightforward for both experimentation and scaling up. Researchers in pharmaceuticals have used it for the development of intermediates in heterocyclic chemistry. These are not abstract applications—they translate into medicines and products that impact daily life.
One area where I have seen this compound prove its value is in medicinal chemistry, where the ability to introduce selective modifications is crucial. Its structure allows for efficient functionalization at specific sites without scrambling the rest of the molecule. This minimizes the work of purifying the desired product and helps cut down on waste. The hydroxy and methoxy substitution pattern also yields intermediates that offer an entry point into more complex, bioactive compounds. This matters because every time you have to toss out a batch due to side reactions, you lose both time and money.
Material safety hasn’t been overlooked. While all chemicals need care, this compound falls well within manageable thresholds for safe handling in most settings. Working with a substance where the known hazards and requirements do not change unexpectedly takes pressure off lab staff and supervisors alike. Experienced chemists know that small differences in compliance and documentation make huge differences during inspections and audits.
Not all pyridines are created equal. In my work, I have watched as companies tried similar, cheaper compounds, only to come up short in the downstream analysis. The unique pairing of the hydroxy and methoxy groups turns this compound into an effective starting material for diverse syntheses. More common pyridines lack this precise pattern of substitution, which means they behave differently under catalysts and oxidizing conditions. Chemists agree that the reactivity offered here broadens synthetic options in a way that isn’t available from other isomers or unsubstituted pyridine.
Users may look at 2-methoxypyridine or even pyridinol isomers and think they would suffice. But try to perform directed lithiation or specific oxidation, and the weaknesses show up fast. Those working in synthesis labs can recall more than one failed project derailed by less tailored alternatives. Using 5-Hydroxy-2-Methoxypyridine, those reactions often succeed with fewer side products and easier purification. A practitioner who has spent enough time troubleshooting knows that getting these steps right on the first try can make or break a program’s budget and timeline.
In agrochemical screening and development, this same flexibility opens doors to new leads and enables the exploration of previously unavailable molecular space. The availability of this compound means that synthetic chemists and process engineers do not have to compromise between reactivity and physical properties like solubility or handling. I’ve seen productive partnerships develop when suppliers provide clear documentation, certificates of analysis, and reproducibility—trust is built on this foundation.
Too often, a promising chemical remains stuck in the academic world. 5-Hydroxy-2-Methoxypyridine serves as a bridge. Its profile lets both process development teams and early-stage researchers access a tool that saves time without sacrificing creativity. In my experience, not needing to re-optimize every aspect of a reaction because a starting material performs as expected is a huge win.
I remember a small biotech startup that struggled for weeks with bottlenecks tied to less specialized pyridines. Their switch to this compound allowed them to cut down unnecessary steps, speed up pilot process development, and meet their goals for patent filings. It is moments like these that underscore why having access to the right building blocks matters for innovation.
Accessible and reliable sourcing is also critical. Disruption in the supply chain for specialized chemicals can hold up entire product launches. This compound’s established track record gives buyers and researchers confidence to proceed without waiting for new stability or interaction data each time. Having a well-documented performance record speeds up everything from internal approval to regulatory checks.
From what I have witnessed, problems often arise not from the headline features, but from the gaps in documentation or surprise changes in quality. With 5-Hydroxy-2-Methoxypyridine, manufacturers who are transparent and offer rigorous analysis earn more than repeat business—they earn trust. Analytical chemists appreciate up-to-date chromatograms and impurity profiles. Development teams lean toward substances that won’t trigger sudden inspection flags. When pure, consistently sourced starting materials become the norm, labs can focus on making new discoveries instead of fighting recurring quality fires.
It is also telling to look at how this compound fits into sustainability talk—not in a pie-in-the-sky way, but by reducing failed batches and chemical waste. Cleanup costs and environmental compliance are no joke, especially for small and mid-sized companies. Fewer byproducts and less hazardous residue translate into lower downstream costs and a friendlier environmental impact. Labs using better-designed molecular tools report fewer emergency disposal episodes and a smoother time passing regulatory hurdles.
Pyridine derivatives fuel everything from advanced drugs to crop protectants, polymers, and dyes. The rise of 5-Hydroxy-2-Methoxypyridine signals a broader shift—industry is moving toward increasingly targeted reagents. By enabling efficient syntheses and clearer structure-activity relationships, it paves the way for more precise molecular engineering. In my own teaching, I stress the importance of picking reagents that match both the aim and the constraints of a project. Here, the benefits are tangible: shorter reaction times, cleaner products, and improved reproducibility. These may seem technical, but they ripple out in the form of more reliable medications, safer products, and reduced waste across the supply chain.
Every regulated chemical needs a clear trail. Reputable suppliers back up their assurances with up-to-date certificates of analysis, traceable lot numbers, and access to relevant safety data. Years of working in compliance-forward organizations taught me the value of clear, up-front information. 5-Hydroxy-2-Methoxypyridine shines in settings where documentation has to pass external audits. Safety and environmental standards today are as strict as ever, and this compound supports those benchmarks. Delivering detailed MSDS and transport documentation isn’t just about paperwork; it ensures teams work safely and regulators have questions answered before they arise.
Researchers focused on innovating new therapies or materials do not always have the time to scrutinize each chemical’s backstory. This is why transparency from trusted producers makes a difference. Over the years, the presence of up-to-date, GHS-compliant labeling and full support for downstream regulatory filings has allowed teams to move faster and avoid delays. I have seen how a safe, reliable supply chain for specialty reagents like this one can let small R&D teams keep pace with much larger competitors.
Inconsistent performance, surprise impurities, and supply chain gaps have been standard complaints in fine chemical procurement. Offering a compound like 5-Hydroxy-2-Methoxypyridine with reliable batch analysis and clear handling guidance addresses many root causes before they overwhelm a project. The presence of performance data built up across industrial and academic settings gives newcomers a leg up when evaluating suitability for a new application.
Years in contract research taught me that new users want a proven solution rather than a gamble with untested materials. This compound’s established record in scientific literature and application notes lowers the barrier for widespread adoption. Support from vendors who provide responsive technical service, up-to-date analytical results, and honest timelines reduces the risk of project overruns and wasted effort. These are not just nice-to-haves—they shift the conversation from patching up failures to doing creative, original work.
Expertise, experience, and transparency all play a role in what makes 5-Hydroxy-2-Methoxypyridine a dependable choice. The real-world experiences of researchers, process chemists, and quality assurance teams back up its place in a modern lab. Evidence from published papers and process validation reports give new users ways to cross-check supplier claims. Accessible technical support and detailed product histories allow teams to integrate it into new workflows with confidence. Peer-reviewed articles and supplier transparency create an environment where teams can trust data and performance alike.
Learning from the collective experience of those in the field, and making those lessons available in usable form, strengthens both confidence and results. One of the best signs that a chemical has matured into a standard is not just its presence in catalogs, but the quality of user feedback and published case studies. Here, 5-Hydroxy-2-Methoxypyridine has left its mark across synthetic chemistry, drug design, and materials science, with clear records supporting its use.
The choice of starting materials or reagents can have bigger consequences than many appreciate at first. Like all specialty chemicals, 5-Hydroxy-2-Methoxypyridine offers tangible value only when procurement teams and researchers can trust both the material and the process behind it. This is something I have learned over decades of troubleshooting and project reviews. The difference between a seamless campaign and a drawn-out slog often comes down to the predictability and support a chemical brings.
For those considering an upgrade from less specialized building blocks, it pays to weigh opportunities for more controlled reactivity, easier regulatory compliance, and documented reliability. Simplifying workflows, eliminating guesswork, and supporting both discovery and scale-up—these are some of the reasons why this compound continues to gain ground across industries. Today’s demands call for reagents that are not just effective but enable teams to move forward with confidence and clarity.
Decisions in the supply chain ripple through R&D and out to final products. Procuring 5-Hydroxy-2-Methoxypyridine from reputable suppliers, with demonstrated records in quality and compliance, leads to advances in yield, reproducibility, and downstream process safety. The investment in better building blocks pays off in more robust discoveries, clear regulatory submissions, and greater peace of mind for those tasked with delivering results. In a world that prizes both precision and accountability, this compound finds its place as a dependable ally in the pursuit of scientific and industrial progress.
