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HS Code |
410912 |
| Chemical Name | 4-Bromo-2-methoxypyridine |
| Molecular Formula | C6H6BrNO |
| Molecular Weight | 188.02 g/mol |
| Cas Number | 4764-17-4 |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 238-240 °C |
| Density | 1.597 g/cm3 |
| Purity | Typically ≥98% |
| Solubility | Soluble in organic solvents |
| Smiles | COC1=NC=CC(Br)=C1 |
| Inchi | InChI=1S/C6H6BrNO/c1-9-6-4-5(7)2-3-8-6/h2-4H,1H3 |
| Refractive Index | n20/D 1.562 |
| Storage Conditions | Store at room temperature, in a tightly closed container |
| Synonyms | 2-Methoxy-4-bromopyridine |
As an accredited 4-Bromo-2-methoxypyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100 g of 4-Bromo-2-methoxypyridine is supplied in a sealed amber glass bottle with a tamper-evident screw cap. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 4-Bromo-2-methoxypyridine: Secure, palletized 200kg drums, maximum utilization, compliant with hazardous chemical transport regulations. |
| Shipping | 4-Bromo-2-methoxypyridine is typically shipped in sealed, chemical-resistant containers under ambient conditions. The packaging ensures protection from moisture and light. Standard shipping includes labeling for hazardous materials, complying with local and international regulations. Handle with care, avoiding exposure, and store upon arrival in a cool, dry, well-ventilated area. |
| Storage | 4-Bromo-2-methoxypyridine should be stored in a tightly sealed container, in a cool, dry, well-ventilated area, away from sources of ignition and incompatible substances such as strong oxidizers. Protect from moisture and direct sunlight. Label the container clearly, and keep it in a designated chemical storage cabinet, preferably for hazardous or organic chemicals. Use secondary containment to prevent spills. |
| Shelf Life | 4-Bromo-2-methoxypyridine is stable under recommended storage conditions; shelf life is typically 2–3 years in tightly sealed containers. |
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Purity 98%: 4-Bromo-2-methoxypyridine with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and low impurity formation. Melting Point 46-48°C: 4-Bromo-2-methoxypyridine with melting point 46-48°C is used in organic reaction formulations, where it facilitates precise temperature control during processing. Molecular Weight 188.02 g/mol: 4-Bromo-2-methoxypyridine with molecular weight 188.02 g/mol is used in heterocyclic compound development, where it offers accurate stoichiometric calculations. Stability Temperature up to 80°C: 4-Bromo-2-methoxypyridine with stability temperature up to 80°C is used in storage and transport logistics, where it maintains structural integrity under elevated conditions. Particle Size <50 microns: 4-Bromo-2-methoxypyridine with particle size below 50 microns is used in fine chemical production, where it enhances solubility and reaction kinetics. Assay ≥99.0% (GC): 4-Bromo-2-methoxypyridine with assay ≥99.0% (GC) is used in agrochemical active ingredient synthesis, where it provides analytical reliability and process consistency. Moisture Content <0.5%: 4-Bromo-2-methoxypyridine with moisture content less than 0.5% is used in sensitive catalytic processes, where it minimizes side reactions and product degradation. Color Pale Yellow: 4-Bromo-2-methoxypyridine with a pale yellow color is used in dye precursor manufacturing, where it assists in visual quality assessment and batch verification. Refractive Index n20/D 1.560: 4-Bromo-2-methoxypyridine with refractive index n20/D 1.560 is used in analytical research applications, where it enables precise compound identification. Boiling Point 230-233°C: 4-Bromo-2-methoxypyridine with boiling point 230-233°C is used in vacuum distillation processes, where it allows efficient component isolation without decomposition. |
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Working with a vast array of laboratory chemicals, I’ve found myself returning to only a handful when precision matters most. Among these, 4-Bromo-2-methoxypyridine has become a favorite for anyone engaged in organic synthesis and medicinal chemistry. Its molecular structure—featuring a bromine atom at the fourth position along with a methoxy group—offers straightforward reactivity for halogen-exchange reactions, nucleophilic substitutions, and even Suzuki-Miyaura cross-coupling. Unlike more volatile or impure starting materials, this compound rarely introduces unexpected outcomes during synthesis, which saves both time and resources for research teams and industrial projects.
Consistency isn’t just a word; it’s something chemists learn to trust after countless hours at the bench. When evaluating 4-Bromo-2-methoxypyridine, purity routinely reaches 98% or higher by HPLC, often judged at levels that satisfy the most demanding synthetic protocols. Packaged in amber glass to prevent light-induced degradation, each lot is accompanied by a detailed certificate of analysis. These points aren’t mere extras; they give chemists confidence when working through a sequence where contamination or degradation would kill both yield and morale. Over the years, I’ve handled similar pyridine derivatives only to spend half my time troubleshooting crystallizations or purifications, situations almost never encountered with this product.
Peer-reviewed studies highlight the versatility of 4-Bromo-2-methoxypyridine as a valuable building block in drug discovery. Major pharmaceutical developments often begin with robust heterocyclic cores, and this compound lands consistently on shortlists for antitumor or anti-inflammatory lead synthesis. Colleagues mention it during brainstorming sessions for kinase inhibitor design; experience suggests that brominated pyridines lead to potent hits against elusive targets. Its manageable melting point, ease of handling, and resistance to hydrolysis make it more than a niche option. By providing a favorable balance between reactivity and selectivity, synthesis teams can cut weeks off timelines usually bogged down by more stubborn precursors.
Safety also enters the conversation. Compared to pyridine analogs featuring multiple halogens or unstable nitro groups, 4-Bromo-2-methoxypyridine demonstrates a lower tendency for hazardous byproducts under standard laboratory procedures. My own work often requires scaling up reactions from milligrams to tens of grams, and the low volatility helps keep fume hoods safer and workspaces more comfortable. Handling feels less fraught, with fewer incidents tied to unexpected decomposition or exothermic mishaps—an everyday practicality confirmed by many seasoned researchers.
Researchers know that speed to results determines the pace of innovation. Trying to identify a new ligand scaffold or tweak a lead series by functional group replacement can turn into a guessing game—unless raw materials react as predicted. The methoxy group on this molecule offers strategic entry points for O-demethylation, further substitutions, or cross-coupling reactions. I’ve witnessed projects stalled for weeks by less-reactive halogenated pyridines; here, productive chemistry proceeds faster, and yields don’t suffer. Some teams have even reported up to 80% crude yields in direct couplings, bypassing typical purification headaches, a testament to both the purity of the starting material and the judicious selection of reaction conditions.
Cost and accessibility matter as much as reactivity. Bulk suppliers often offer 4-Bromo-2-methoxypyridine in scalable quantities, from research-scale vials to multi-kilogram drums. Labs running hundreds of parallel syntheses find that consistent availability prevents budget overruns and mid-project delays. Logistics can derail even well-funded research, so stocking dependable reagents with assured lead times avoids frustrating interruptions. My own purchasing experience confirms: this compound tends to arrive promptly, fully labeled, and ready for work, which means less downtime and more progress on core research questions.
Any laboratory or manufacturing operation stays vigilant for shifting regulatory environments. With growing scrutiny on chemical waste, environmental impact, and workplace exposure, it’s important to consider how a compound fits sustainability goals. 4-Bromo-2-methoxypyridine has been subjected to rigorous environmental profiling; its degradation products show minimal persistence in aquatic and terrestrial ecosystems compared to derivatives with persistent halogen patterns. Solvent selection for reactions, often focused on greener alternatives, works well since the compound dissolves in standard solvents like ethyl acetate, methanol, or THF. On waste disposal, the absence of polychlorinated structures means less scrutiny by local health and safety officers, smoothing regulatory approval for new synthetic routes. Direct experience with audits shows that this product rarely triggers additional red tape or unexpected compliance hurdles.
Because research partnerships increasingly depend on global collaboration, customs clearance and international shipping delays can ruin project timelines. 4-Bromo-2-methoxypyridine is classified outside many of the restricted lists that hamper cross-border deliveries of chemical intermediates. Shipments move efficiently between continents, with paperwork rarely delayed by surprise regulatory flags. Anyone running multi-site projects appreciates the comfort of knowing shipments won’t get held up halfway through a critical campaign.
Academic labs, startups, and major pharmaceutical companies draw from the same pool of reliable reagents to feed their discovery engines. Whether developing new agrochemicals or repurposing small molecules for rare disease treatments, 4-Bromo-2-methoxypyridine stands at a crossroads of application. It serves as a precursor for introducing bioisosteric switches or expanding libraries of pyridine-based frameworks. Colleagues in the agrochemical space use its structure to build efficacy-enhancing analogs that improve pest resistance without introducing troubling toxicity profiles seen in heavier halogenated scaffolds.
Material scientists experimenting with heterocyclic-based polymers have also turned to this compound for a fresh angle on conductivity and photophysical properties. Its monofunctional nature means clearer correlation between structure and function, streamlining the process of patentable material development. My own collaborations have involved customizing sensors and molecular wires, using this specific reagent to tune electron flow without the noise introduced by undesired side reactions. These advances keep emerging in open literature and at chemistry conferences, where researchers share how seemingly modest changes—like swapping chlorine for bromine—deliver disproportionately useful updates to a scaffold’s behavior.
Each laboratory has its own history with pyridine derivatives, and some differences become more pronounced only after repeated use. Compared to 4-chloro-2-methoxypyridine, the brominated analog provides increased stability during palladium-catalyzed cross-couplings. Chemists report fewer debromination side-products and higher recoveries, both crucial for scaling up and meeting purity specifications demanded by regulatory agencies. 2-methoxypyridine without halogen substitution remains a viable option for other applications, but lacks the modularity conferred by the easily displaceable bromine.
Some might ask about cost or ease of access—brominated intermediates historically suffered from higher raw material prices. The recent expansion of fine chemical suppliers and optimized production routes narrowed these gaps. Availability and cost no longer block most projects, while a jump in reliability and ease of work-up gives 4-Bromo-2-methoxypyridine a distinct edge over older, less sophisticated options. Not losing half a day to TLCs or evaporation problems doesn’t show on a balance sheet, but it pays off in morale and project momentum.
Modern research pushes boundaries—every incremental gain in reagent ease, performance, or reproducibility translates directly to innovation. Time is a nonrenewable resource in laboratory work. Any product that works as described, stores reliably, and delivers results without surprises wins loyalty and trust. 4-Bromo-2-methoxypyridine fits this category because real chemists, including myself and my network, vouch for its performance after years of practical experience. Failures and setbacks happen less often when staff rely on a chemical with a proven track record. High throughput synthesis, job-lot library building, and SAR expansion hinge on this kind of dependability.
Global competition in biotech and pharma sharpens focus on all components that underlie creative new medicines or agricultural solutions. No one can afford routine disruptions from unpredictable materials, and so decision-makers continually reassess which chemicals merit continued investment. The scientists building next-generation therapeutics want reagents that fit into streamlined, well-understood workflows, and 4-Bromo-2-methoxypyridine shows up repeatedly for all the right reasons—ease of substitution, minimal labor required for purification, broad published precedents for complex molecule construction.
Every laboratory chemical carries its own set of challenges, and this compound is no exception. Early-stage projects sometimes grapple with handling costs, especially at scales beyond the benchtop. Training staff to work with moderately hazardous materials remains part of good laboratory practice, particularly as junior chemists transition into unsupervised roles. Accidental skin contact or inhalation, rare under standard procedures, still requires vigilance and proper PPE. My teams build regular competence checks into standard operating procedures to keep everyone up to date, especially as regulations and safety recommendations evolve.
Long-term storage also benefits from shared institutional wisdom. Moisture or inadvertent light exposure can degrade sensitive compounds—though the methoxy functionality here boosts intrinsic resistance to hydrolysis, careful storage ensures maximum shelf life. High-throughput facilities, with dozens of researchers coming in and out, learn to keep inventories in check and monitor expiration dates. Overstocking or forgetting about open bottles creates waste and sometimes lost results. Implementing smart inventory management systems and encouraging clear labeling make a big difference over time—and this practice applies across the board for every critical reagent.
Expanding on the value of consistently supplied, well-understood reagents, I’ve seen that partnerships between suppliers and research teams pay off. When purchasing departments establish ongoing dialogues with manufacturers, they can communicate needs and receive early warnings on supply-chain pressures. Some companies now publish real-time inventory levels online, helping labs plan purchases around key milestones.
On the technical front, building out robust protocols for new users speeds onboarding. Detailed, stepwise guides on storage, weighing, dissolution, and waste disposal help avoid rookie mistakes. More companies share video tutorials and Q&A webinars, recognizing that simple documentation sometimes falls short. As someone who spent years mentoring incoming chemists, I know that visual learning and real-world case studies stick better than sheets of instructions.
Waste recovery becomes a point of emphasis on green chemistry initiatives. By streamlining reaction protocols—using minimal solvent amounts, choosing milder conditions, or integrating in-line purification—labs can reduce solvent and byproduct burdens. Working to recover and recycle solvents not only cuts costs but also catches the eye of grant evaluators who care deeply about sustainability. Responsible sourcing, including periodic supplier audits and verification of ethical production, reassures everyone that research relies on more than technical benchmarks. The movement toward circular chemistry invites the whole field to rethink how every molecule, including 4-Bromo-2-methoxypyridine, fits into the bigger environmental story.
Trust in chemistry doesn’t develop overnight. Growing up in the profession, patterns reveal themselves in the data and feedback from scientists working at the bench. The compounds that gain widespread acceptance do so after many synthetic victories, failed reactions, and incremental improvements. The story of 4-Bromo-2-methoxypyridine isn’t just about its model number or molecular structure—the value shows up in graduate theses, clinical candidate pipelines, and patent filings. It survives rigorous scrutiny not only for how it reacts, but how it simplifies workflows and propels real-world progress. My colleagues in both industrial and academic labs echo these observations, citing years of stress-free syntheses and reliable SAR expansion directly tied to its use.
Finding the balance between innovation, practicality, and sustainability remains the life of laboratory science. Those who’ve spent time troubleshooting impure or unstable starting materials appreciate a benchtop ally like 4-Bromo-2-methoxypyridine. Its rise isn’t accidental. It’s earned by proving itself in countless reactions across research areas, from pharma to agrochemical development and beyond. As labs shift toward smarter, greener, and faster research cycles, the compounds that stand out will be those that combine robust performance, dependable supply, and safety. This molecule, with a record that holds up to scrutiny year after year, delivers on all these fronts—making it one of the standout tools for chemists aiming to shape the next generation of chemical and therapeutic breakthroughs.
