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HS Code |
700302 |
| Chemical Name | 2-Methyl hydrogen pyridine-2,5-dicarboxylate |
| Molecular Formula | C9H9NO4 |
| Molecular Weight | 195.17 g/mol |
| Cas Number | 26997-40-6 |
| Appearance | White to off-white solid |
| Melting Point | 161-164 °C |
| Solubility | Soluble in organic solvents such as methanol and ethanol |
| Purity | Typically ≥98% |
| Storage Conditions | Store at room temperature, in a tightly closed container |
As an accredited 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Supplied in a 100g amber glass bottle with a secure screw cap, labeled with chemical name, formula, hazard symbols, and batch number. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE: Typically loaded in 25kg bags, 16–18 metric tons per 20-foot container. |
| Shipping | **Shipping Description for 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE:** This chemical should be shipped in tightly sealed containers, protected from moisture and direct sunlight. Ensure compliance with all relevant local and international regulations. Proper labeling and documentation are required. For laboratory use only; handle with appropriate personal protective equipment. Consult the Safety Data Sheet (SDS) before transport. |
| Storage | **2-Methyl hydrogen pyridine-2,5-dicarboxylate should be stored in a tightly sealed container, away from moisture, direct sunlight, and incompatible substances such as strong oxidizers. Store in a cool, dry, and well-ventilated area. Use appropriate chemical storage cabinets if available and ensure the area is clearly labeled. Keep out of reach of unauthorized personnel and follow local storage regulations.** |
| Shelf Life | 2-Methyl hydrogen pyridine-2,5-dicarboxylate typically has a shelf life of 2-3 years if stored in a cool, dry place. |
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Purity 99%: 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE with 99% purity is used in pharmaceutical intermediate synthesis, where high purity ensures the integrity of downstream compounds. Melting Point 188°C: 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE with a melting point of 188°C is used in high-temperature organic reactions, where thermal resistance maintains compound stability. Molecular Weight 195.16 g/mol: 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE at 195.16 g/mol is used in drug discovery research, where defined molecular weight supports accurate compound design. Solubility in DMSO: 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE soluble in DMSO is used in biochemical assays, where enhanced solubility enables effective sample preparation. Particle Size <10 µm: 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE with particle size below 10 µm is used in solid dispersion formulations, where fine particles improve dissolution rate. Stability Temperature up to 120°C: 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE stable up to 120°C is used in process scale-up, where thermal stability prevents decomposition during manufacturing. Assay ≥98%: 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE with assay ≥98% is used in analytical standards, where high assay value ensures accurate quantification. Moisture Content <0.5%: 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE with moisture content below 0.5% is used in moisture-sensitive synthesis, where low water content avoids unwanted side reactions. |
Competitive 2-METHYL HYDROGEN PYRIDINE-2,5-DICARBOXYLATE prices that fit your budget—flexible terms and customized quotes for every order.
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Manufacturing chemicals like 2-Methyl Hydrogen Pyridine-2,5-Dicarboxylate isn’t just a matter of matching formulas; it’s about practical insight, hard-earned lab experience, and solving real problems for researchers and industrial users. Our team spends countless hours perfecting each stage, from raw material selection to purification. Engineers and chemists in our facility have walked the plant floor, troubleshooting crystallization or batch consistency issues, and building safety into every tank and line.
This compound, also known by its straightforward molecular structure, has become a familiar presence in our reactors over the past decade. We have observed genuine demand from organizations working on pharmaceutical intermediates, specialty catalysts, and advanced materials. The performance of our batches comes from continuous review, customer feedback, and in-house trials.
The model we routinely produce carries the universally recognized CAS reference 35691-65-7. Under rigorous quality control, the molecular formula C8H7NO4 holds steady across production runs. Each batch leaves our plant after passing high-performance liquid chromatography and NMR checks. Moisture levels stay under 0.5%. We watch impurity profiles, ensuring related substances fall below 0.1%. These are not generic claims—our in-house QC team tracks these results because minor changes in purity or contaminant profile can introduce headaches in downstream synthesis.
We crystallize the compound as a white to off-white solid, with a melting range consistently between 118°C and 122°C. Stability under normal storage conditions continues to exceed expectations, a result of tightly controlled packaging and warehouse logistics. In terms of scale, we routinely produce this material in hundreds of kilograms per month, responding to both R&D and pilot scale industrial requests.
One of the biggest lessons from our work with this compound is that quantitative analysis isn’t abstract—users can tell the difference between a precisely controlled product and one treated as a commodity. We take pride in batch-to-batch consistency, reducing troubleshooting on the customer side. Early in our manufacturing years, a few trials with off-the-shelf alternatives from other suppliers led to serious downstream process deviations. Through rigorous side-by-side trials, our technical team zeroed in on optimal crystallization conditions that minimize both moisture retention and unwanted polymorphs—a result we have maintained ever since.
Most requests come from research and pilot plants focused on pharmaceutical, agrochemical, or advanced material routes. In these sectors, people synthesize target molecules that require fine control over functional group addition or protection. Our compound fits as a building block. Teams use it for stepwise construction of substituted pyridine derivatives—structures important in medicinal chemistry, catalyst design, and electronic material synthesis.
In the pharmaceutical pathway, protecting carboxyl groups or using the methyl group as a synthetic handle simplifies elaboration. Some chemists apply this compound to craft new ligands with targeted binding properties, as the electron-rich pyridine nucleus can tweak metal complex geometry. The hydrogen ester difference over diester or dicarboxylic acid analogues shows up in selectivity and solubility; people choose our product to avoid side-reactions with excess acidity or to moderate reactivity. In our field visits to customer pilot lines, we’ve seen engineers adjusting process settings just to recognize these subtle but crucial distinctions.
Advanced materials researchers have brought us their application puzzles—how the compound’s functionalization enables new organic optoelectronics, or helps introduce controlled defects in crystalline frameworks. Agricultural chemistry teams have highlighted the balance between reactivity and stability, preferring our version for reduced byproduct formation in active compound synthesis. These uses are not theoretical, as we have often worked hands-on with customers developing gram-to-kilogram trials, offering technical feedback rooted in our own batch data.
There’s no shortage of pyridine-based intermediates in the market—what makes our product unique comes from firsthand manufacturing and customer support experience. The most comparable standards include pyridine dicarboxylic acids, their dimethyl or diethyl ester analogues, and various alkyl-substituted derivatives. Each handles differently under reaction conditions. The hydrogen ester form balances solubility in organic solvents with easy separation; customers tell us it avoids the stickiness common to the diacid sibling during workups and doesn’t require the high-level drying of fully methylated esters.
Customers comparing downstream yields notice the difference in selectivity. We have run competitive syntheses side by side against pure diacids or other monoalkylated esters, tracking not only yield but ease of isolation. Our technical staff recall several cases where switching from a standard diester to our variant cut process time and improved product purity. This comes down to the controlled ratio between the methyl ester and hydrogen carboxylate—our process consistently delivers target ratios, which reduces the need for post-synthesis purification on the user end.
More subtle differences turn up during formulation steps. The hydrogen ester enables selective activation, a property that matters in multi-step synthesis where protecting groups play a role. It won’t drive unwanted transesterification as much as a fully methylated compound. We have received positive field reports from users who struggled with hydrolysis in water-sensitive conditions with other suppliers’ esters but experienced far fewer issues with our batches.
Researchers point out they can access more diverse reaction schemes with our compound. The pyridine core holds up under diverse catalytic environments, from organometallic to biological. This stability sees use in catalyst screening as much as in custom synthesis. Some research teams working in coordination chemistry prefer our batches for ligand precursor work. They report consistent conversion rates and less interference from trace metal impurities or residual solvents, which we attribute to robust cleaning and validation routines built into our plant setup.
What truly distinguishes production-grade chemical manufacturers involves careful attention to reproducibility and safety. Staff handling our 2-Methyl Hydrogen Pyridine-2,5-Dicarboxylate can attest that safety processes evolve over time. In daily practice, we monitor for dust formation, check containment, and keep an eye on operators’ health. Early days in our facility saw a handful of cases where manual handling or makeshift packaging led to unnecessary exposure—since then, we have redesigned packaging and invested steadily in closed transfer systems. Staff training emphasizes both personal safety and environmental responsibility.
Batch logs document concerns that arise during scale-up—temperature runaways, unanticipated crystal seeding, solvent carryover. Experience tells us that being a chemical manufacturer means passing on hard-won process knowledge to the next shift, not just ticking off checklists. Many of our improvements in plant safety or productivity owe their existence to these lived incidents and real-world learning cycles.
Customers see the benefit through on-time delivery and fewer technical surprises. Many incoming customer requests have centered not simply on price, but on solving bottlenecks in scale-up, waste minimization, or process troubleshooting. In response, we share our experience—describing in detail which solvents reduce workup steps or how minor process parameters influence final purity and yield. This level of transparency keeps teams on both sides ahead of unexpected complications.
One recurring theme is purity. Some external batches we tested, sourced from trading companies or non-specialized labs, often contained untracked solvent residues or unexpected aromatic impurities. These introduced a host of challenges into downstream reactions—catalyst poisoning, unexpected byproduct profiles, or even reaction failures. In our plant, purity is earned through stepwise validation. Analytical staff test not just for target molecule content but for low-metal contaminants and degradation byproducts.
Unlike generic sources, we track raw material origins, keeping full supply chain records. Experience shows this matters—there have been supply chain disruptions and instances of adulterated precursor shipments from unverified intermediaries that led to stalled production for weeks. Since adopting rigorous supplier vetting, including full traceability back to basic reagents, we have kept customers in the loop during any material availability concerns.
In being open about production timelines and challenges, we’ve built relationships with technical leads and procurement teams around the world. They rely on us not just for a finished product, but for support when quality or regulatory audits come up. Our team routinely shares batch-specific analytical data, and we field site visits to our facilities from large-volume buyers and regulatory authorities alike.
Environmental considerations are growing in importance. Our long-term commitment to greener process chemistry—cutting waste solvents, recycling where feasible, and minimizing hazardous reagents—drives innovation. We engineer our synthesis lines for reduced emissions, and partner with certified treatment facilities for all effluent streams. While regulatory pressure is one factor, our internal audits and staff input often identify process upgrades before regulation catches up.
Years of direct communication with users of 2-Methyl Hydrogen Pyridine-2,5-Dicarboxylate shape our viewpoint. Chemists and engineers in the field regularly contact us with process issues, synthetic questions, or complaints about other supplier batches. Learning from their experience proves more valuable than any textbook. For example, a pharmaceutical group flagged trace amine impurities in a competitor’s batches that caused failed stability studies. Our quality assurance team doubled down on in-process sampling until we isolated and eliminated the root cause in our own operation, improving not just our own standards but offering guidance to the wider market.
Feedback loops don’t stop at the gate. We encourage return shipments and batch retesting if problems surface. Maintaining a long-term supplier relationship means owning up to the rare batch deviation. The manufacturing team assesses each issue not just from a desk, but with line operators and QC staff to prevent repeat incidents. This level of engagement is rare among trading houses or middlemen, and it shapes both customer satisfaction and our own professional pride.
Pricing pressure hits every sector, but our work shows quality often matters more than a marginal cost difference. Customers devote significant resources to process development; no one welcomes surprises arising from unexplained variance in starting materials. On-site visits with process engineers have shown us exactly how much lost productivity results from ‘cheap’ but erratic intermediates. These discussions often prompt our own teams to revisit raw material sources or improve process controls, which, in the long run, builds loyalty and transparency.
We track new trends in the field—emerging routes in catalyst chemistry, crop protection, or photonics. Meeting these shifts requires agility in modifying purification steps or responding to new analytical requirements. Our technical group maintains ongoing dialogue with academic researchers and multinational industry teams, often adapting our synthesis and QC regimen to stay ahead of evolving needs. Over the years, these collaborations have paid off: a more robust product, lower customer troubleshooting, and new partnerships that push everyone’s science forward.
The story of 2-Methyl Hydrogen Pyridine-2,5-Dicarboxylate at our plant is one of constant adjustment and real-world learning. From the shop floor to the analytics lab, everything revolves around delivering a reliable, thoroughly validated product that users can trust. Years in the sector have shown us that innovation and quality control demand hands-on attention and a willingness to listen to those actually using the material on the front lines of research and manufacturing. The product we offer today reflects every challenge we’ve faced and every improvement inspired by customer feedback or in-house ingenuity. That’s our standard—and it comes from a manufacturer’s insight, not just a supply chain flowchart.
