|
HS Code |
424942 |
| Molecular Formula | C9H13NO2 |
| Molecular Weight | 167.21 g/mol |
| Appearance | Solid (likely crystalline or powder) |
| Chemical Class | Pyridine derivative |
| Functional Groups | Methoxy, Dimethyl, Hydroxymethyl |
| Iupac Name | 3,5-Dimethyl-4-methoxy-2-(hydroxymethyl)pyridine |
| Synonyms | Dimethyl-4-methoxy-2-pyridinemethanol |
| Smiles | COC1=C(C=C(C(N=C1)CO)C)C |
| Inchi | InChI=1S/C9H13NO2/c1-6-3-8(12-2)7(5-11)10-9(6)4/h3,5,11H,4H2,1-2H3 |
As an accredited Dimethyl-4-methoxy-2-pyridinemethanol,3,5- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging contains 100 grams of Dimethyl-4-methoxy-2-pyridinemethanol,3,5- in a sealed amber glass bottle with a secure cap. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for Dimethyl-4-methoxy-2-pyridinemethanol,3,5- ensures secure, bulk chemical transport in sealed, standard 20-foot containers. |
| Shipping | Shipping of Dimethyl-4-methoxy-2-pyridinemethanol, 3,5- is regulated due to its chemical nature. It must be securely packaged in accordance with hazardous materials guidelines, labeled appropriately, and accompanied by safety data sheets. Transport typically requires ground or air freight with compliance to local and international chemical shipping regulations. |
| Storage | Store **Dimethyl-4-methoxy-2-pyridinemethanol,3,5-** in a cool, dry, well-ventilated area, away from direct sunlight and sources of heat or ignition. Keep the container tightly closed and properly labeled. Avoid storage near incompatible substances such as strong oxidizers. Use appropriate chemical-resistant containers to prevent leaks or contamination. Follow local regulations and safety guidelines for handling and storage. |
| Shelf Life | Dimethyl-4-methoxy-2-pyridinemethanol,3,5- typically has a shelf life of 2–3 years when stored in cool, dry, and dark conditions. |
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Purity 98%: Dimethyl-4-methoxy-2-pyridinemethanol,3,5- with purity 98% is used in pharmaceutical intermediates synthesis, where it ensures high reaction yield and minimal impurities. Melting Point 122°C: Dimethyl-4-methoxy-2-pyridinemethanol,3,5- with melting point 122°C is used in solid-state formulation development, where it provides stability during manufacturing. Molecular Weight 181.21 g/mol: Dimethyl-4-methoxy-2-pyridinemethanol,3,5- with molecular weight 181.21 g/mol is used in drug design applications, where precise dosing calculations are required. Solubility in Methanol >50 mg/mL: Dimethyl-4-methoxy-2-pyridinemethanol,3,5- with solubility in methanol >50 mg/mL is used in analytical method validation, where it enables accurate standard preparations. Stability Temperature up to 60°C: Dimethyl-4-methoxy-2-pyridinemethanol,3,5- with stability temperature up to 60°C is used in chemical storage and handling, where it reduces risk of degradation under ambient conditions. Particle Size <10 µm: Dimethyl-4-methoxy-2-pyridinemethanol,3,5- with particle size under 10 µm is used in microsuspension formulations, where it allows uniform dispersion and improved bioavailability. |
Competitive Dimethyl-4-methoxy-2-pyridinemethanol,3,5- prices that fit your budget—flexible terms and customized quotes for every order.
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Dimethyl-4-methoxy-2-pyridinemethanol,3,5- carries a complexity that speaks both to its molecular structure and to its relevance in advanced organic synthesis. As chemical manufacturers, we've spent years refining the production and consistent quality of this compound, knowing that even small adjustments to purity or particle characteristics can impact downstream applications. We've also seen a shift in what labs and industrial clients expect from this material. Unlike more generic pyridine derivatives, the 4-methoxy group and the dual methyl substitution on the 3 and 5 positions alter reactivity in useful ways, creating more differentiation in end-use reactions. Chemists choose this compound for reasons that go beyond its name: it speeds up reaction timelines, reduces side-product formation, and opens up synthetic routes that would close quickly with less specialized molecules.
Every client seeks predictability and repeatability in process chemistry. That's often what separates successful production from batches caught in rework and culling. Dimethyl-4-methoxy-2-pyridinemethanol,3,5- brings that predictability, with a molecular structure that resists degradation under a range of reaction conditions. The methoxy group at the 4-position dampens reactivity on that ring carbon, nudging selectivity towards C-2, C-3, and C-5. Our experience in manufacturing and purifying this product means customers receive material where off-spec is rare. Irregularities in crystallization, traces of starting materials, or variations in melting point leave us mindful of how delicate certain downstream syntheses can become. Suppliers who don’t control for those parameters can leave researchers spending hours on troubleshooting instead of productive work. As a maker, we focus on reaction reproducibility because we've heard those stories and solved those problems with better process control.
Years in production arm us with more than a synthesis pathway and a filter press. Close monitoring of reaction progress, smart choice in agitation speeds, careful attention to intermediate temperatures, and a nose for solvent residue all separate good manufacturing from guesswork. Dimethyl-4-methoxy-2-pyridinemethanol,3,5- requires a steady hand in azeotropic removal and distillation, since early removal of certain byproducts preserves color and purity. Direct feedback from customers teaches us where batches have run into issues—darkness, variable solubility, or inconsistent melting behavior. Our on-floor chemists not only check finished product in standard HPLC and GC measurements, they sometimes run bench-top syntheses mimicking our clients' actual uses just to flag possible issues before shipment. Contrast that with brokers who simply relay a lot number along to the end user and you understand why source and method count for so much in this market.
In organic synthesis laboratories, Dimethyl-4-methoxy-2-pyridinemethanol,3,5- turns up in roles that reward stability and functional group tolerance. Researchers use it as a nucleophilic agent, a ligand precursor, and a reagent for introducing the methoxy-pyridine motif onto other scaffolds. The electron-donating nature of the methoxy group smooths over harshness in some electrophilic substitution reactions, particularly where product formation competes with side reactions. Structural control in this molecule provides marked improvement over basic pyridines, which lack directional reactivity and can wander off into unwanted byproducts. Our product survives elevated temperature and multi-step processing, where less robust materials falter and drop in yield. In the field, success stories flow in from pharmaceutical researchers who found cleaner conversion on scale-up, and agrochemical clients reducing purification steps. New generations of materials for battery and specialty polymer development increasingly turn to this compound as a way to impart electronic or solvating features not available with related structures.
Technically, the difference between 98% and 99.5% pure may seem small on paper. In reality, traces of unreacted starting materials or extraneous isomers lead to headaches on larger synthesis runs. Having worked through the endless requests for tighter impurity profiles and less color in product, we install additional monitoring at multiple points, especially since some impurities resist simple washing or phase separation. Our production staff use batch history logs and automated alerts to maintain specification edges, but we also respond quickly if a deviation arises. Customers depend on a lot-to-lot reproducibility that lets them keep multi-ton projects rolling. It’s not just a matter of tighter specs for the sake of documentation—a trace residual can trigger false readings in downstream analysis or poison a reaction catalyst. By controlling raw material sourcing and refining purification, we reduce askew runs and shutdowns triggered by off-flavor or unwanted residue.
Dimethyl-4-methoxy-2-pyridinemethanol,3,5- doesn’t behave like other pyridine derivatives. Start with the introduction of methanol as a functional group on the pyridine ring: this presence increases solubility in certain polar solvents, making it easier to handle for high-throughput operations and scale-ups. Compared to structurally similar methylpyridines lacking methoxy substitution, our compound exhibits altered UV absorbance profiles and a more forgiving thermal stability. Researchers lean on that when designing photoactive materials or when exact quantitation under chromatography matters. Experiences from our clients suggest the compound works more reliably in flow chemistry and continuous manufacturing. It offers process engineers broader windows for temperature ramping and solvent selection. We’ve also noticed less volatility loss and lower peroxide risk in storage, which matters for customers who don’t burn through inventory in a month or need to maintain critical reserves for regulatory or GMP project requirements.
Each new inquiry—whether from an academic looking to build a library of heterocycles or an advanced materials firm prototyping a next-generation conductor—pushes us to consider both the chemistry and the logistics behind material supply. Having a direct line to manufacturing means hearing feedback on how even subtle shifts in process variables ripple through an R&D program. We're not removed from the process, reading reports years after the fact. Our chemists and scale-up team take customer phone calls or digital queries directly, solving puzzles that often stray from blackboard theory. This ongoing engagement means we’ve minimized shipment of product batches that would sit unused on a shelf due to microcontamination or color body presence. Supporting cutting-edge application often means pivoting in production to meet new, more challenging impurity thresholds or physical characteristics.
We prepare detailed CoA packages not only to satisfy paperwork needs, but to make downstream auditing and regulatory review less painful for our customers. Having supplied critical intermediates for high-stakes projects, we know how even minor documentation gaps can delay production or tank a regulatory submission. Our team doesn’t hand off the responsibility to external quality teams but tracks each batch from raw input through finished packaging and beyond. Long-term partners can verify past shipments against updated regulatory requirements, thanks to full traceability built into our documentation system. We offer direct dialogue with regulatory consultants and plenty of transparency when unusual impurity peaks or storage stability questions come up. Clients have used our traceability to backstop their own regulatory audits, and our willingness to adapt or update an analytical approach based on feedback keeps us investing in both instrumental and process upgrades.
Producing Dimethyl-4-methoxy-2-pyridinemethanol,3,5- at scale never escapes the realities of raw material supply, waste management, and the environmental pulse of the industry. Our operational footprint reflects years of investment to limit emissions, extend recycling capability for process solvents, and cut down on batch-by-batch controls that once drained both resources and labor. We listen to corporate sustainability goals and R&D targets when tweaking process steps. We’ve reduced water consumption through closed-loop cooling, and adopted modular reactor setups that bring energy draw down during maintenance cycles. Any packaging innovations that let clients streamline hazardous waste disposal—lighter drums, re-sealable container systems, or single-use liners—move from idea to implementation fast when feedback indicates an end-user gain. We see a direct connection between a cleaner process environment and the resulting quality and reliability of the product itself.
Trust grows through direct, ongoing exchanges. We share live production data or quality test results with many of our larger customers. Whether it's a raw NMR trace, photographic evidence of batch color, or an open discussion about unexpected impurity results, we make the invisible parts of manufacturing visible to those relying on our product. This transparency lubricates troubleshooting when clients call about a process deviation, new synthetic goal, or updated need. We don't lock in to old habits or stonewall on supply queries. The supply of Dimethyl-4-methoxy-2-pyridinemethanol,3,5- is ultimately about supporting projects from first flask to final product, and it’s in our interest to foster dependable relationships over transactional exchanges. Consistent performance across years—backed by the knowledge that a real team is available to talk through technical points—encourages customers to innovate more freely.
Shift in the industry happens fast, so we balance established process flow with readiness to refine parameters based on incoming data. Suddenly, a pharmaceutical partner may request a new impurity threshold or wish to explore a different particle size distribution for improved packaging performance. We task technical teams to run small-scale pilot batches that simulate those new specs, sharing results for side-by-side lab validation. This incremental yet regular improvement habit means our product adapts as rapidly as the market does. Competing derivatives can't always keep up with these shifts, and many labs now favor our process for the flexibility and speed of adaptation. Our willingness to field unplanned requests—overnight impurity analysis, alternate solvent recommendations, real-time problem solving—cements that reputation.
Looking back, production of Dimethyl-4-methoxy-2-pyridinemethanol,3,5- reflects an evolutionary arc, not a static process. Tighter global oversight, more rigorous sustainability standards, and increasingly complex downstream applications all drive us to tune production for current reality and anticipated future need. The learning curve grows steeper each year, but the resulting knowledge gives us ahead-of-the-curve insights into what end users truly face. We have seen what happens when process shortcuts meet real-world complexity: reaction wrecks, lost yield, and unnecessary costs in time and resources. We take pride in de-risking these pitfalls through granular process control and relentless batch evaluation. The lessons of every lot signed off, every complaint fielded, and every new requirement trialed all feed forward into making this product a reliable cornerstone of many chemical supply chains.
Modern chemistry means moving fast, jumping from R&D to scale-up, or troubleshooting unpredictable variables in real time. Dimethyl-4-methoxy-2-pyridinemethanol,3,5- keeps turning up in conversations between scientists, process engineers, and procurement teams simply because it delivers value on multiple fronts: reactivity, versatility, and reliability. End users distinguish it by how it helps them hit project deadlines, stretch budget farther, and answer tougher regulatory or analytical questions with fewer product-driven obstacles. For us on the manufacturing side, knowing our process supports this everyday innovation creates a loop of improvement and shared goals. Whether the next challenge is a brand-new synthetic route, a more sustainable workflow, or a regulatory audit, this compound stands as a marker for how practical, well-made chemistry still delivers outsize benefits in a competitive and fast-changing world.
