|
HS Code |
437170 |
| Product Name | 5-Bromo-2-methoxy-4-methylpyridine |
| Chemical Formula | C7H8BrNO |
| Molecular Weight | 202.05 g/mol |
| Purity | 96+% |
| Cas Number | 875781-17-4 |
| Appearance | White to off-white solid |
| Melting Point | 56-60°C |
| Solubility | Soluble in common organic solvents |
| Smiles | COC1=NC=CC(C)=C1Br |
| Inchi | InChI=1S/C7H8BrNO/c1-5-4-9-7(10-2)3-6(5)8/h3-4H,1-2H3 |
| Storage Conditions | Store at room temperature, in a dry, well-ventilated place |
| Hazard Statements | May cause skin and eye irritation |
| Ec Number | None assigned |
As an accredited 5-BROMO-2-METHOXY-4-METHYLPYRIDINE, 96+% factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 25g quantity of 5-BROMO-2-METHOXY-4-METHYLPYRIDINE, 96+%, comes in a sealed amber glass bottle with safety labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 5-Bromo-2-methoxy-4-methylpyridine, 96+%, securely packed in drums, maximizing space, compliant with hazardous material transport regulations. |
| Shipping | Shipping of 5-BROMO-2-METHOXY-4-METHYLPYRIDINE, 96+%, is conducted in compliance with safety regulations for hazardous chemicals. The compound is securely packed in sealed containers, clearly labeled, and accompanied by a Safety Data Sheet (SDS). Temperature and handling precautions are followed to ensure safe transportation and delivery to the destination. |
| Storage | 5-Bromo-2-methoxy-4-methylpyridine, 96+%, should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from direct sunlight. Keep away from sources of ignition, heat, and incompatible substances such as strong oxidizers. Store at room temperature, avoiding moisture. Clearly label the container and follow all relevant chemical safety protocols. |
| Shelf Life | Shelf life: Typically stable for 2–3 years when stored in a cool, dry, well-sealed container away from light and moisture. |
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Purity 96+%: 5-BROMO-2-METHOXY-4-METHYLPYRIDINE, 96+% is used in pharmaceutical intermediate synthesis, where high purity ensures minimized side-product formation. Melting Point 68-71°C: 5-BROMO-2-METHOXY-4-METHYLPYRIDINE, 96+% is used in solid-phase organic synthesis, where a defined melting point supports precise thermal processing. Molecular Weight 216.05 g/mol: 5-BROMO-2-METHOXY-4-METHYLPYRIDINE, 96+% is used in medicinal chemistry for lead optimization, where accurate molar mass facilitates precise stoichiometric calculations. Chemical Stability: 5-BROMO-2-METHOXY-4-METHYLPYRIDINE, 96+% is used in agrochemical research, where robust stability enhances shelf-life and storage safety. Low Water Content: 5-BROMO-2-METHOXY-4-METHYLPYRIDINE, 96+% is used in moisture-sensitive coupling reactions, where minimal water content prevents hydrolysis and degradation of reactants. High Batch Consistency: 5-BROMO-2-METHOXY-4-METHYLPYRIDINE, 96+% is used in analytical reference standards, where batch uniformity ensures reliable and reproducible assay results. |
Competitive 5-BROMO-2-METHOXY-4-METHYLPYRIDINE, 96+% prices that fit your budget—flexible terms and customized quotes for every order.
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Anyone with experience in pyridine compound manufacture knows the challenge of striking robust product reliability batch after batch. Our team focuses daily on making 5-Bromo-2-Methoxy-4-Methylpyridine to the highest repeatable standard. This compound, produced with an assay of no less than 96%, offers consistent color, odor, and purity levels—parameters monitored with close scrutiny at every production step. Unlike stocks sourced through circuitous trading, every gram released from our lines carries traceable records on raw material origin, handling process, and batch-specific analytics. That history becomes especially valuable when researchers and commercial process scale-ups shape their needs around tight reproducibility.
Our synthesis team approaches 5-Bromo-2-Methoxy-4-Methylpyridine from years of experience handling substituted pyridines. Moisture, temperature, and air exposure are managed tightly, using reactors that allow direct control and real-time monitoring. We do not cut corners on purification steps: distillation and crystallization occur under conditions kept well within validated ranges. Each run produces a batch record, not just a certificate, including HPLC and NMR evidence checked in our in-house quality control lab. These data points ensure the lot supplied to you matches the performance in the last vial and the next one on your reorder.
Assay by HPLC drives our specification. A guarantee of 96+% content means downstream chemists place trust in the reagent for critical bonds. We track trace impurity patterns, recognizing some side products can change the game in scale-up work or regulated active intermediate production. Many clients ask whether this grade covers both research and pilot build-outs; our teams keep a reserve of lot samples, so every reported deviation can be investigated swiftly and transparently. In our lines, color and odor cues supplement spectral analytics since the human element still spots shifts that machines may overlook in early warning.
We see the demand for this compound especially strong among pharmaceutical innovators. Its methyl and bromo structure support coupling reactions with improved selectivity. The methoxy function allows nucleophilic displacement under milder conditions compared to unsubstituted pyridines. In real research and production, fewer byproducts mean easier work-up and more confident analytical closure—one less variable to troubleshoot mid-project. When clients share performance feedback or synthetic bottlenecks, our chemists look at both the features and the subtle differences batch to batch.
We routinely compare our 5-Bromo-2-Methoxy-4-Methylpyridine against closely related halogenated analogs. The placement of the bromine at the 5-position, combined with the electron-donating methoxy and methyl groups, shifts reactivity and solubility compared to simple 2-methoxypyridines or 4-methylpyridines. In Buchwald-Hartwig or Suzuki couplings, for instance, yields and selectivity outpace many non-methoxy, non-bromo analogs. Chemists in our network report fewer sidereactions and better material recovery from standard work-up protocols. For those aiming to streamline the path to more complex heterocycles or APIs, these practical advantages become clear after just a few trials. Those used to working with less well-characterized materials sometimes encounter challenging purification steps or surprise peak appearance, particularly when sourcing from traders with uncertain supply chains. Our regular feedback from both research and pilot plant chemists points to the time saved and waste avoided due to our QC focus and direct supply.
Having spent years refining the scale and consistency of substituted pyridines, we’ve faced practically every scenario, from equipment fouling to impurity spikes traced back to solvent lots. We maintain redundancy in reactor trains and purification columns so that customer volumes, even in large R&D campaigns, don’t lead to upsets or drastic quality swings. Our laboratory communicates directly with the production floor. This fast feedback loop has delivered process tweaks that address anomalous impurity levels within the next run, not the next month. Clients who switched from less predictable sources have reported direct improvements in LCMS traces and project timelines.
The daily concerns of laboratory hands—material clumping, static issues, decomposition under light, and inhalation hazards—receive deliberate attention. By controlling crystal morphology and using nitrogen blankets, we minimize product degradation and awkward handling incidents. The granular nature of our material flows smoothly from bottle to reaction flask, reducing risk of weighing errors or lost material. At distribution, vessels remain sealed and kept in dry, shaded environments, paired with clear instruction on handling well beyond basic guidelines. These practical realities may seem obvious, but years in the field have shown how small oversights can ripple into costly project delays or wasted effort.
Beyond pharma, this pyridine derivative has drawn interest from agrochemical developers and advanced materials scientists. The multi-substituted aromatic ring affords positions for further functional group transformations. Our clients have used it as both an end-stage intermediate and as a scaffold for dye and pigment synthesis. In agrichem R&D, efficiency improvements have followed substitution patterns like those found in our product, leveraging the ortho methoxy and para methyl for ligand modulation or as electronic tuning elements.
Those synthesizing reference standards or new-to-market fine chemicals often relay that the storage stability and spectral clarity of our stock supports them through extended screening campaigns. Repeat customers have commented that less time spent resolving impurity knock-on effects allows faster answer-finding on key patent steps or scale transition decisions.
Our production lines received years of redesign around exactly this class of fragment. As demand for high-purity bromo and methoxy substituted pyridines grew, we invested directly into reactor upgrades, downstream purification tech, and additional analytical tools. These capital investments mean that when regulatory inspectors or client auditors visit, every step is open to traceback and process documentation. We maintain a physical reserve sample of each batch for reference. In real-world terms, technical support means talking directly to the chemists doing the synthesis, not a third-hand phone bank. If a mishap with timing or an accidental exposure in a lab occurs, our staff provides details based on what works at the bench, not just what’s printed on a label.
Familiarity with the challenges of global supply disruptions led us to cultivate raw material partnerships with vetted suppliers, not merely opportunistic traders. This groundwork paid off through recent times when some clients faced weeks or months of delay from less stable distribution networks. We see spikes in demand from those working on just-in-time delivery projects or at risk from price shocks, and prioritize transparency on lot availability and turnover.
We track growing regulatory and workplace safety requirements closely. Pyridine compounds have drawn extra scrutiny in some regions, making traceability and forward disclosure essential. Our facility operates under a harmonized internal framework blending the strictest compliance standards from both our home country and major destination markets. By preparing detailed substance documentation and batch analytics, we ease the burden for regulatory submissions and internal compliance checks at partner sites.
Our support also extends into guidance on permissible exposure, optional protective gear, and storage best practices, gained from years of direct observation and feedback. For teams with environmental impact mandates, we’re working on further reduction of process solvent volumes and closed-loop recovery, with input from clients who must account for both product purity and environmental metrics in their project approvals. Intimate product knowledge means we anticipate and communicate changes as process improvements roll out, including alternate lot runs to meet seasonal demand bumps without sacrificing documented quality benchmarks.
Too often, chemists buy specialized reagents through layers of resellers, hearing little from those who actually produced the lot in use. In our own experience, direct manufacturing brings unique accountability. Technical questions don’t get batted between unknown suppliers—instead, the synthesis chemist responsible for a run speaks to the choices made, the rationale behind process controls, and what evidence lies behind each purity claim. Our routine involves not just standard COAs but a running log of development choices, process upsets, and risk management actions, accessible if a customer needs an in-depth run-down.
Long-term partnerships have taught us to put clarity and details up front. We share not just success stories but also occasions where late-stage issues appeared and required root cause fixes in-house. That ethos enhances trust and lets both sides build new procedures or adjust target specs based on real-world observations rather than abstract compliance documents. This degree of manufacturer involvement could seem rare in today’s chemistry supply chain, but from our perspective it’s the only way to minimize costly setbacks and enable creative synthesis.
Whether researchers tackle flow chemistry innovation or optimize classical batch syntheses, the specificity of our 5-Bromo-2-Methoxy-4-Methylpyridine meets their needs. It supports high-conversion reactions across a spectrum of solvents and under a range of coupling catalyst systems, according to feedback from both academia and process-scale partners. The low impurity load simplifies downstream processing, easing chromatography and work-up. In programs where screening time is at a premium, rapid turnarounds and documented lot consistency provide a significant edge. As custom requests arise—whether for alternate sizing, special packaging, or tailored documentation—our production and delivery teams adapt based on hands-on experience with the product.
Large-scale synthesis teams engaging in multi-kilogram campaigns often raise concerns about synthetic residue, residual solvent levels, or cross-contamination from earlier campaigns. We offer supporting analytical documentation on demand and, where needed, can communicate at the level of individual process streams. That level of detail only arises from direct routine with scale-up, not generic warehousing or bulk traders. Fostering a dialogue between producer and end-user improves both next-generation product development and the productivity of day-to-day bench work.
Ongoing improvements in production efficiency and greener alternatives form part of our continuous review. Our R&D crews actively evaluate new methods for bromo- and methoxy-pyridine ring construction, benchmarking against both classical and emerging routes. This keeps costs and waste in check while building toward a future where sustainability and reliable access are not at odds. Those who work directly with our team often suggest areas where even minor changes in synthesis or isolation pay dividends in application or regulatory submission. Real experience shows the difference, breeding confidence that next-year’s run will prove as reliable as last’s.
We encourage open dialogue, fast turnaround on issue resolution, and willingness to adjust process details or document edits in response to creative synthesis or changing project directions. In the rapidly-shifting landscape of fine and specialty chemical manufacturing, these attributes aren’t window dressing—they are the foundation of our approach to supporting innovators across the chemical sciences.
Over years and countless batches, 5-Bromo-2-Methoxy-4-Methylpyridine has become a staple for teams demanding both purity and traceability. By investing in robust process controls, comprehensive documentation, and a hands-on approach to technical support, we send out each lot with confidence. Feedback from long-term users reflects not just satisfaction but the practical difference that true manufacturing expertise brings. Working directly with the source, not a series of intermediaries, grants you access to detailed knowledge, traceable analytics, and support grounded in practical laboratory and plant-floor realities. For those seeking a competitive edge through their chemistry, working with the direct maker behind every vial offers a quality advantage hard to replicate elsewhere.
