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HS Code |
426318 |
| Chemical Name | 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine |
| Molecular Formula | C8H11NO3 |
| Molecular Weight | 169.18 g/mol |
| Appearance | White to off-white solid |
| Melting Point | Approximately 160-163°C |
| Solubility In Water | Soluble |
| Cas Number | 4437-09-4 |
| Boiling Point | Decomposes before boiling |
| Structure Type | Pyridine derivative |
| Functional Groups | Methyl, hydroxyl, hydroxymethyl |
| Storage Conditions | Store at room temperature, keep container tightly closed |
| Iupac Name | 2-methyl-3-hydroxy-4,5-bis(hydroxymethyl)pyridine |
| Synonyms | 2-Methyl-3-hydroxy-4,5-bis(hydroxymethyl)pyridine |
As an accredited 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle, 25 grams, sealed with a screw cap; labeled with chemical name, formula, hazard symbols, and batch number. |
| Container Loading (20′ FCL) | 20′ FCL loaded with 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine, securely packed in drums, compliant with international chemical transport regulations. |
| Shipping | 2-Methyl-3-hydroxy-4,5-dihydroxymethylpyridine should be shipped in tightly sealed containers, protected from light and moisture. Handle with appropriate safety precautions. Transport according to local regulations for chemicals; keep away from incompatible substances. Avoid excessive heat and direct sunlight during shipping to maintain compound stability and integrity. |
| Storage | 2-Methyl-3-hydroxy-4,5-dihydroxymethylpyridine should be stored in a tightly closed container, protected from light and moisture, in a cool, dry, well-ventilated area. It should be kept away from strong oxidizing agents and sources of ignition. Proper labeling and secure shelving are recommended. Store at room temperature or as specified by the manufacturer’s guidelines to maintain stability. |
| Shelf Life | 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine is stable under cool, dry conditions; shelf life is typically 2 years when unopened. |
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Purity 98%: 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and consistent product quality. Molecular Weight 167.17 g/mol: 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine with molecular weight 167.17 g/mol is used in active ingredient formulation, where precise dosing and formulation accuracy are critical. Melting Point 128°C: 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine with melting point 128°C is used in high-temperature reaction processes, where it confers thermal reliability and process safety. Water Solubility 25 g/L: 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine with water solubility 25 g/L is used in aqueous pharmaceutical preparations, where it facilitates rapid dissolution and homogeneous mixtures. Stability Temperature up to 60°C: 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine with stability temperature up to 60°C is used in laboratory storage and transport, where it maintains chemical integrity under routine handling conditions. Particle Size <50 μm: 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine with particle size less than 50 μm is used in tablet manufacturing, where it promotes uniform blending and optimal tablet compressibility. UV Absorbance 260 nm: 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine with UV absorbance at 260 nm is used in analytical method development, where it enables sensitive and specific detection in quality control assays. Impurity Content <0.2%: 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine with impurity content under 0.2% is used in injectable drug manufacturing, where it minimizes potential side effects and enhances patient safety. |
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In our line of business, the difference comes down to consistency, purity, and an understanding of process. 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine stands out not because it’s rare, but because repeated use in demanding environments has shown which details matter. Over time, we have learned that skipping steps in production or taking shortcuts with purification always shows itself later, either in product yield or in equipment fouling, so the way this compound comes out from our reactors is the result of refinements and relentless troubleshooting, not luck.
This compound, sometimes referenced according to its chemical shorthand, serves as an important intermediate in several synthetic routes. The backbone offers options for researchers and production managers looking to build more complex pyridine derivatives. The three reactive hydroxyl groups, along with that methyl at the 2-position, enable a handful of tailored attachments for downstream chemistry. We have watched production lines push lesser intermediates through, only to see bottlenecks reappear as purification or reactivity mismatches sidetrack projects. Our lot histories show that troubles in the next step often trace back to overlooked impurities here, or the wrong isomer percentage.
Consistency on a batch-to-batch basis takes late-night hours over many months and years. Certain stages in the synthesis demand precise temperature control; other parts challenge our team with the risk of over-oxidation or unwanted isomer formations. By running hundreds of pilot runs and keeping complete records, we have found which solvent profiles keep the reaction on course, both at the hundred-gram and multi-metric-tonne scales. Direct conversations with our process engineers often yield solutions that automated systems miss, whether it’s a stirring rate tweak or subtle change in pH. Handling these details has let us offer specifications with tighter ranges for contaminants and color, and we never rely on one-off certificate claims unsupported by ongoing QC checks.
We don’t treat 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine as a commodity. Analytical chemists on our team check every batch using HPLC and NMR. They never assume identity based solely on melting point or a single chromatogram. Typical purity exceeds 98%, with isomeric forms checked and consistently below established thresholds. Moisture can cause downstream problems, so we routinely report water content and have refined our drying process to keep levels below 0.3%—a mark often overlooked by other producers. This level of attention has come from seeing problems with polymerization, color, and shelf stability arise from remnant moisture.
Smell and handling are often missed in spec sheets, yet anyone working in fine chemicals knows how an off-odor or unexpected powder texture signals trouble. We’ve honed our crystallization process so the material pours easily, resists clumping, and has an expected look and feel each time. Subtle shifts in color purity or crystal shape highlight upstream solvent issues, so we stay vigilant across every lot. In our warehouses, product degradation or unwanted caking has taught us to adjust storage conditions and maintain proper ventilation, steps that control both product waste and confusion during sampling.
Put this compound to use in either pharmaceutical intermediate work, agricultural synthesis, or advanced materials labs, and issues can start with failed reactions or poor yield. Sometimes, a batch of product hits all standard analytical points, but the downstream outcome disappoints—residues cling to glassware, discoloration crops up in former-clear intermediates, or column purification becomes unusually difficult. Our customers have reported all these headaches over the years, prompting us to examine not just the headline purity figure, but minor impurities that slip between broad ‘passes’ by less-stringent producers. In feedback calls with long-time customers, small levels of unreacted starting material or trace byproducts, particular to certain process routes, have a way of creating scalping headaches far down the line.
Many end-users push for multi-step reactions in the same vessel. If a precursor batch brings along unseen byproducts, each next step invites complexity. Through dozens of side-by-side tests, we noticed inferior batches often required double the solvent wash or led to char deposits during scale-up, costing not only additional resources but risking entire production runs. Those hard reminders led us to incorporate advanced filtration and double recrystallization steps, which directly improved process economics for several long-standing clients.
For those in pharmaceutical research, our version of 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine finds frequent use as a starting point for nucleoside derivatives. A biochemist running an early-morning column described how even a small change in the impurity profile shifted TLC outcomes enough to demand reoptimization. In another line, a plant chemist ran up against reproducibility issues during hydrogenation—eventually traced back to residual catalyst poisoners that crept through due to shortcuts in earlier purification stages. We continue to test each batch with these scenarios in mind, and we keep samples for months after dispatch for traceability.
Some manufacturers will offer similar naming, even comparable purity values, but the realities on the production floor or in the development lab reveal dramatic differences. We have seen customers switch to our product and immediately reduce the number of column runs, lower wash solvent use, and avoid repeat syntheses. These improvements stem mainly from pursuit of impurity profiles that look subtle on a spectra but loom large in complex conversions. Hidden catalysts and isomeric misalignments can lag long after initial use, causing headaches for production chemists who depend on reliable timelines and budgets.
Our batches routinely ship with supporting documentation, and we often answer technical questions directly from the chemists or engineers who built the reaction train. If a downstream transformation struggles with color change, clumping, or side-by-side inconsistencies, we look for root causes in lot records and supply historical IR, UV-vis, or residual solvent details if needed. Through open records and collaboration with our customers, both sides typically see fewer surprises, less waste, and fewer back-and-forth shipments.
We chose to narrow our portfolio to a handful of specialty intermediates, including this pyridine derivative, because mastery in production breeds trust. Some competitors spread themselves thin with dozens of related compounds; our approach demands deeper investment in process control, waste management, and operator training. This focus has allowed our team to fine-tune not just yield, but batch uniformity and environmental metrics such as energy and water use.
Training matters for specialty chemicals. Our on-site operators run new hires through full-day handling drills and review stepwise procedures not just for compliance, but to keep everyone alert to quirks that only arise after handling tons of product in varying seasons. The powder’s hygroscopic nature caught one of our technicians off guard during a spell of humid weather several years back. Since that day, we implemented climate monitoring and invested in adjustable HVAC for packaging rooms, leading to longer shelf life and lower returns. Careless handling or packaging shortcuts might not reveal problems for weeks, so commitment to long-term training always pays off.
Chemical waste reduction also features heavily in our operations. Spent product, wash solvents, and packing materials get monitored for environmental impact. We take pride in solutions that cut down unnecessary use, with a dedicated team focused on improved solvent recovery and reducing water intake by over 15% over the last three years. Each kilogram of 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine leaves less footprint, and the reduced occurrence of batch failed tests cuts accidental waste down further.
Every few years, raw material price spikes force a second look at old routes. Energy costs rise, reagent availability shifts, and our customers must absorb market shocks with minimal supply disruption. We’ve invested directly in process intensification, including shorter residence time steps and modular reactor upgrades, not only for price control but to keep impurity profiles on target despite upstream variability. While other sites resort to volume cuts, our upgrades have let us maintain supply throughout volatile quarters, with lead times short enough for clients under pressure to meet tight deadlines.
By keeping analytical monitoring in-house, we trimmed response times on problem detection from days to hours. Instead of waiting for outside labs to confirm a batch, our internal QC specialists react at every stage, intercepting discrepancies before shipment. Some of our most insightful process improvements arrived after a particularly frustrating batch, where a trace impurity toppled planned yields for a key Japanese agri-chemical client—the solution emerged only after inspecting archived GC-MS results from prior years, revealing a subtle but persistent contaminant source.
We support open dialogue with lab teams and production engineers at both large and small clients. Advice from someone on the floor, faced with genuine deadline stress and scale-up risk, brings valuable insight to our own product development. We always appreciate pointed feedback, as it often targets issues invisible to those only glancing at paperwork or batch logs. The right feedback, even if tough, keeps production honest—and helps us continue to build more resilient processes.
The work doesn’t end with a product leaving our dock. We often hear stories from research teams exploring unorthodox applications, as well as scale-up professionals managing process transfer to new plants in other countries. Despite familiar lab handbooks and standard procedures, the small things—reactions to humidity, slight solvent carryover, day-to-day operator differences—shine a light on why direct manufacturer partnerships hold their value. Our technical team stands ready for discussions on process troubleshooting, shelf-life validation, or solvent compatibility. For advanced users, batch fingerprinting with custom spectroscopic data supports repeatable results even in challenging environments.
Complexity in synthesis rarely decreases over time, especially with tightening regulation and environmental controls. Real improvements stem from a combination of high-grade materials, open process knowledge sharing, and eagerness to adapt methods. As restrictions on hazardous intermediates evolve, our dedicated regulatory and R&D teams track developments and adjust formulations as needed. Working as a manufacturer, not a third-party, lets us act quickly, update specifications, and communicate directly with chemists rather than waiting on brokered responses or prolonged distribution chains.
Does the grade really matter if broad specifications match? Anyone on the receiving end of delayed pilot runs, failed QC, or incremental product changes knows the answer lies in the details. We have responded to dozens of queries on shelf-life, powder flowability, and processing temperature tolerances—all learnings that accumulate in our knowledge base over time. Rather than letting questions accumulate without response, our chemists take customer calls before, during, and after projects, sharing best practices developed through years of material handling and batch problem-solving.
For those new to this intermediate, the differences often show up during multi-step process scale-up or under the microscope in an R&D lab. Small shifts in melting point or discoloration can derail a process that seems robust at first glance. With every inquiry, we track outcomes and consult application history, aiming to simplify decision-making for both established and new partners.
Shelf-stability concerns have crossed our desks, particularly in climates where storage conditions vary from cold and dry to hot and humid. Here, the extra effort in powder drying, combined with airtight, light-resistant packaging, increases confidence that the product entering a reactor matches the one specified months earlier. Where unique challenges arise—unusual solvents, reagents with specific pH constraints, or unfamiliar downstream targets—we welcome direct discussion to identify fit and sidestep stumbling blocks.
Working as a manufacturer with feet on the ground, batch logs in hand, and years of feedback, we see that the true value in 2-methyl-3-hydroxy-4,5-dihydroxymethylpyridine goes beyond a simple molecular formula. The lessons come from long-term partnerships, data-rich problem-solving, and willingness to continuously evolve methods based on industry needs. By staying focused on practical outcomes, quality, and honest communication, we build not just reliable intermediates, but a foundation for productive research, better scale-ups, and long-term project success.
The pursuit of consistent, high-value intermediates carries its frustrations and trials, but sticking to real-world experience and refusing to adopt shortcuts has borne out in trust and dependable performance. For every new batch, our confidence springs from those countless cycles of adaptation, critical review, and hands-on improvement. To those seeking to work with the compound, our doors—and ears—remain open for questions, collaboration, and shared success in each new application.
