|
HS Code |
180350 |
| Chemical Name | methyl 2-(hydroxymethyl)pyridine-5-carboxylate |
| Molecular Formula | C8H9NO3 |
| Molecular Weight | 167.16 g/mol |
| Cas Number | 107295-35-8 |
| Appearance | white to off-white solid |
| Purity | typically ≥97% |
| Boiling Point | No data available |
| Melting Point | No data available |
| Solubility | soluble in common organic solvents such as methanol and DMSO |
| Smiles | COC(=O)c1ccc(CO)nc1 |
As an accredited methyl 2-(hydroxymethyl)pyridine-5-carboxylate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 25 grams of methyl 2-(hydroxymethyl)pyridine-5-carboxylate, sealed with a screw cap and tamper-evident band. |
| Container Loading (20′ FCL) | **Container Loading (20′ FCL):** Packed in 25 kg fiber drums, lined with PE bags; 8-10 MT per 20′ FCL, secured against moisture and contamination. |
| Shipping | Methyl 2-(hydroxymethyl)pyridine-5-carboxylate is shipped in sealed, chemical-resistant containers under ambient temperature. Proper labeling indicating the chemical name and relevant hazard information is provided. Packaging follows safety standards to prevent leakage and contamination during transit. Shipping documentation includes necessary safety data, and compliance with local and international chemical transport regulations is ensured. |
| Storage | Store **methyl 2-(hydroxymethyl)pyridine-5-carboxylate** in a tightly sealed container, in a cool, dry, and well-ventilated area, away from direct sunlight, heat sources, and incompatible substances such as strong oxidizers. Keep at room temperature or lower, away from moisture. Clearly label the container and ensure proper chemical segregation to prevent accidental mixing or contamination. |
| Shelf Life | Shelf life of methyl 2-(hydroxymethyl)pyridine-5-carboxylate is typically 2 years when stored tightly sealed, cool, and protected from light. |
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Purity 98%: Methyl 2-(hydroxymethyl)pyridine-5-carboxylate with 98% purity is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and minimal byproduct formation. Molecular weight 167.16 g/mol: Methyl 2-(hydroxymethyl)pyridine-5-carboxylate of molecular weight 167.16 g/mol is used in fine chemical production, where it allows precise stoichiometric calculations for efficient process design. Melting point 85°C: Methyl 2-(hydroxymethyl)pyridine-5-carboxylate with a melting point of 85°C is used in controlled crystallization experiments, where consistent solid-state formation is achieved. Stability temperature up to 120°C: Methyl 2-(hydroxymethyl)pyridine-5-carboxylate stable up to 120°C is used in temperature-sensitive catalytic processes, where product integrity is maintained throughout thermal cycling. Particle size <50 microns: Methyl 2-(hydroxymethyl)pyridine-5-carboxylate with particle size less than 50 microns is used in pharmaceutical formulation, where rapid dissolution and uniform dispersion are critical. Water content <0.2%: Methyl 2-(hydroxymethyl)pyridine-5-carboxylate with water content below 0.2% is used in moisture-sensitive organic synthesis, where it prevents hydrolysis and degradation of reagents. |
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From our vantage point producing Methyl 2-(hydroxymethyl)pyridine-5-carboxylate, we watch this unique intermediate step onto the stage just as demand for precision and quality grows in pharmaceutical and fine chemical synthesis. The nuances of its structure, with both ester and hydroxymethyl functions arranged precisely on a pyridine ring, give it a versatility not always found in standard aromatic derivatives. We see requests for this compound surge, in large part because chemists need versatility blended with reliability; our methods strive to deliver both.
Consumers expect reliable sourcing. At our plant, quality assurance never gets relegated to a check box—our teams carefully regulate every lot. The purity we achieve owes much to a tightly controlled synthesis, honed by years of hands-on practice and data review. We avoid shortcuts that could threaten critical reaction points. Finished product always undergoes thorough NMR and HPLC analysis. Many of the downstream synthetic routes, especially those building advanced pyridine derivatives, hinge upon reproducibility at every step. That is why, from solvent selection through to purification and storage, our choices come from long-term process monitoring, not habit or cost saving. Buyers who encounter batch-to-batch drift elsewhere often remark on the consistency they experience when working with our material.
Practical synthesis in today’s climate rarely leaves room for guesswork. Customers developing new drug candidates or fine-tuning established processes turn to us when alternate intermediates prove too inflexible. This is particularly true in the world of heterocyclic compounds, where substitutions on the pyridine ring trigger significant changes in downstream chemistry. With methyl 2-(hydroxymethyl)pyridine-5-carboxylate, we have built a relationship with formulation teams seeking reliable reactivity with both the hydroxymethyl and ester groups along the ring—this double functionality expands their toolset for controlled modifications and scale-up synthesis.
Our technical team exchanges feedback directly with research chemists. Mistakes in moisture levels, reaction stoichiometry, or overlooked byproducts can delay a project for weeks or force costly troubleshooting. Every kilogram we ship reflects lessons learned: trace water removal after esterification, preventive maintenance to avoid cross-contamination, and careful storage away from excess light and air. These are not just “box-ticking” decisions; they matter to the teams handling our product on the other end.
Chemists who work with pyridine intermediates quickly appreciate differences that might not seem obvious on paper. The position of the hydroxymethyl group (at the 2-position) compared to alternatives—such as a 3-hydroxymethyl arrangement—changes both reactivity and selectivity in coupling or oxidation reactions. The ester group at the 5-position offers a useful handle for further transformation, whether by hydrolysis, reduction, or amidation. In practice, competing intermediates sometimes force chemists into extra steps to ‘fix’ their molecular architecture. In contrast, our product’s placement of these groups saves time and reduces the risk of side reactions or low yields.
Basic pyridine esters without the hydroxymethyl substitution might serve in simple transesterification, but fail to deliver when chain extension or selective oxidation is needed. Conversely, pyridines carrying other alkyl substituents lack the reactivity window that the hydroxymethyl group provides for late-stage functionalization. We see researchers switching over when other candidates fall short in selectivity, efficiency, or stability. Feedback tells us that the dual functional groups in our product provide a better foundation for diversity-oriented synthesis—making it easier to access a broader range of downstream chemical libraries.
The market does not just require a novel molecule; it needs one with reliably scalable manufacturing. Whether being used as a precursor to pyridine-based pharmaceuticals, in agrochemical design, or as a step in academic research, the real-world chemistry performed with methyl 2-(hydroxymethyl)pyridine-5-carboxylate reflects on the supplier’s process integrity. From our experience, much of the value lies not only in the core chemical itself, but in the confidence teams hold that each bottle will behave consistently in sensitive procedures.
In pharmaceutical R&D programs, researchers frequently note that our strict lot traceability and analytical transparency help them both validate and optimize their methods. A single inconsistent intermediate can render months of process optimization obsolete, leading to supply chain slowdowns or regulatory headaches. Our teams have seen customers migrate from generic versions to ours after experiencing solubility shifts, excess moisture, or unusual side-products with less rigorously controlled sources. In pharmaceutical synthesis, the regulatory bar is only rising. This places new emphasis on documented manufacturing controls, a realm where our experience and direct manufacturing oversight play out to customers’ advantage.
There’s more to supplying methyl 2-(hydroxymethyl)pyridine-5-carboxylate than just synthesis. Handling, packaging, and delivery affect how smoothly projects run. Shrink-wrapped glass bottles, nitrogen-blanketed aluminum drums, and custom label controls target the wide range of storage and handling practices at different laboratories. We maintain a flexible ordering process: a kilo batch for an academic lab or a hundred kilos for a multi-site process chemistry team. Each lot travels with robust analytical documentation—the same data set we rely on to pass our own internal benchmarks.
Some users require extended stability data or additional impurity profiles. Our in-house analytics team dives deep, running extra tests as needed. Far from seeing this as an inconvenience, we value the sharp eyes of our most meticulous customers. Their focus on data quality and error reduction has shaped the way we handle everything from in-process sampling to final shipment seals.
Laboratory safety depends on the producer’s track record as much as on the chemist’s protocols. We’ve maintained a strong focus on responsible handling since inception, based in part on learning from industry-wide mishaps and quality incidents. Every batch ships with the precise analytical profiles, but also with clear, concise handling information. This goes beyond MSDS compliance. We share practical insights learned from our own staff’s daily interface with the material—exposure risks, environmental hygiene tips, and ways to extend shelf life.
Over the years, as regulatory scrutiny sharpened, customers have leaned on our documentation to clarify the provenance and compliance status for their filings and audits. Working with regulatory staff, both in-house and at customer sites, we streamlined our data sharing to cut down on delays and avoid compliance shocks. Many suppliers stop at basic paperwork. Our approach reflects our own need for certainty in our operations and extends that mindset out to the labs we serve.
No material, no matter how well-made, can ignore evolving customer requirements. As global priorities shift, with growing focus on sustainability and ultra-trace impurity management, we seek out feedback from frequent users. Their day-to-day experience sometimes points out micro-issues in stability or compatibilities with newer synthetic reagents that require real process adaptations. Our technical service teams track these needs and push continuous improvement, making incremental changes in purification, waste reduction, and documentation formats.
Some years back, academic collaborators shed light on photostability topics rarely addressed in industry literature. Recent process chemistry partners, scaling from bench to pilot, suggested tweaks to minimize potential cross-reactive side-products during extended distillations. More than once we updated our process to account for such discoveries; every improvement in stability or performance at the end-user’s bench pays back in loyalty and strong relationships.
Few things distinguish a compound more decisively than the environment in which it is made. Some market alternatives derive from scaled-up laboratory syntheses, cut corners on intermediate quenching or purification, and often lack comprehensive analytical data. Over time, even modest differences in precursor purity or synthesis conditions can propagate into subtle by-products that spell problems for downstream chemistry.
We make it a point to audit all raw material suppliers and track each precursor batch for trace contaminants or structural analogues. Only with this attention to detail have we earned a reputation for quality over time. Some commercial alternatives—not all, but enough to raise concern—feature off-spec impurity patterns or inconsistent moisture levels. A few years ago, we caught a trend in the market marked by glycol residue in some batches, which affected certain oxidation or cross-coupling steps. This prompted a thorough process reevaluation to ensure batches from our lines meet the tightest industry standards. Practitioners value this kind of vigilance because minor contaminants sometimes escape routine QC at distant suppliers.
The journey leading up to a new therapeutic agent or catalyst rarely runs straight. It depends heavily on access to intermediates that deliver the reliability and flexibility to chase promising pathways. At each stage, bottlenecks can stymie progress, wasting both time and precious research budgets. Over the years we have contributed—often as a silent partner—to dozens of projects where methyl 2-(hydroxymethyl)pyridine-5-carboxylate underpins key transformations. Faculty seeking to build novel heterocyclic libraries and industrial partners scaling up bioactive molecules often rely on flexible intermediates such as this, because predictable reactivity streamlines optimization.
We stay in touch with users who need support on alternative reaction scales or are exploring green chemistry modifications. As examples, a surge in interest for flow chemistry adaptations challenged us to package and document our product for microreactor applications, triggering changes in both lot size and analytical frequencies. Collaborative feedback from the field shapes our response, leading to innovations in both the product and the way we manage it.
Industry demand for sustainability never slows—every year, expectations ratchet higher. Part of our job as a manufacturer centers on managing environmental impact while maintaining high standards for chemical purity. Over time, we have invested in closed-loop solvent systems, wastewater minimization, and batch scheduling to cut unnecessary holding times. These steps protect not just profitability, but also the shared air and water resources our staff and local residents depend on.
We welcome discussion about the origins and ultimate disposition of our products. End users often want not just documentation but honest dialogue about the ecological profile and worker safety impact. Our plant invests in emission reductions and coverage options for spent material reclamation. Every step forward mirrors growing industry consensus: sustainability does not compete with chemistry—it strengthens quality and builds public trust.
Today’s markets change fast. Product access, regulatory environments, and discovery timelines move more quickly than ever. As a direct manufacturer, our reputation hangs on how well we anticipate challenges—ranging from tighter regulatory controls to the specialized needs of new synthetic techniques. We plan production with an eye on the evolving landscape, scaling batch sizes as needed and preparing for wider adoption in catalytic, pharmaceutical, and material science fields.
Chemists expect more from their partners than just product in a bottle. They look for collaboration, insight, and reliability. Our role, producing methyl 2-(hydroxymethyl)pyridine-5-carboxylate, centers on meeting those needs while anticipating what tomorrow’s bench chemist will need. To that end, we remain committed to continuous improvement, responsible manufacturing, and transparency in every aspect of our process.
Years spent handling, producing, and refining this compound have taught us that every detail matters, from tracking upstream raw material trends to the way each lot leaves our doors. Working closely with customers across research and industry, we maintain our focus on practical solutions, high standards, and ongoing responsiveness. Methyl 2-(hydroxymethyl)pyridine-5-carboxylate is more than a simple intermediate; it represents thousands of hours of process optimization, direct communication, and shared commitment to chemical progress. We look forward to supporting future innovations, adapting to change, and upholding the standards that define genuine manufacturing expertise.
