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HS Code |
671639 |
| Chemicalname | 2-bromo-6-(methylsulfonyl)pyridine |
| Molecularformula | C6H6BrNO2S |
| Molecularweight | 236.09 g/mol |
| Casnumber | 147080-26-4 |
| Appearance | White to off-white solid |
| Meltingpoint | 92-97°C |
| Solubility | Soluble in DMSO, slightly soluble in water |
| Smiles | CS(=O)(=O)C1=CC=NC(=C1)Br |
| Inchi | InChI=1S/C6H6BrNO2S/c1-11(9,10)6-4-2-3-5(7)8-6/h2-4H,1H3 |
As an accredited 2-bromo-6-(methylsulfonyl)pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle, screw cap, labeled with chemical name, hazard pictograms, and handling instructions; contains 25 grams of 2-bromo-6-(methylsulfonyl)pyridine. |
| Container Loading (20′ FCL) | 20′ FCL loaded with securely packed drums of 2-bromo-6-(methylsulfonyl)pyridine, maximizing space, ensuring safe chemical transportation. |
| Shipping | 2-Bromo-6-(methylsulfonyl)pyridine is shipped in a tightly sealed, chemical-resistant container, compliant with local and international hazardous materials transport regulations. The package is clearly labeled with hazard and handling information, including UN numbers if applicable. Shipping occurs via certified carriers with appropriate documentation to ensure safety and regulatory compliance. |
| Storage | Store **2-bromo-6-(methylsulfonyl)pyridine** in a tightly sealed container, protected from light and moisture, in a cool (2–8°C), dry, and well-ventilated area. Keep away from incompatible substances such as strong oxidizing or reducing agents. Ensure proper labelling and consult the safety data sheet (SDS) for specific storage precautions. Handle under an inert atmosphere if sensitive to air. |
| Shelf Life | 2-bromo-6-(methylsulfonyl)pyridine has a typical shelf life of 2–3 years when stored in a cool, dry, airtight container. |
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Purity 98%: 2-bromo-6-(methylsulfonyl)pyridine with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and reduced byproduct formation. Melting Point 102°C: 2-bromo-6-(methylsulfonyl)pyridine with a melting point of 102°C is used in agrochemical compound development, where its thermal stability allows for efficient formulation. Particle Size ≤25 microns: 2-bromo-6-(methylsulfonyl)pyridine with particle size ≤25 microns is used in catalytic process optimization, where improved dispersion enhances catalytic efficiency. Stability Temperature up to 140°C: 2-bromo-6-(methylsulfonyl)pyridine with stability temperature up to 140°C is used in electronic material manufacturing, where it maintains structural integrity under processing conditions. Molecular Weight 236.08 g/mol: 2-bromo-6-(methylsulfonyl)pyridine with molecular weight 236.08 g/mol is used in heterocyclic compound research, where precise reactivity patterns can be achieved. |
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In our manufacturing halls, the synthesis of 2-bromo-6-(methylsulfonyl)pyridine comes out of years working hands-on with heterocyclic intermediates. The molecular formula stands as C6H6BrNO2S, reflecting an exacting design that supports the specialized needs of medicinal chemistry and custom synthesis. Our process starts with select pyridine sources to ensure the integrity of each carbon and nitrogen in the ring structure. We see demand for this compound in sectors dedicated to crafting advanced pharmaceuticals, and for good reason. Its sulfonyl group offers reliable chemical stability under a range of lab conditions. From our reactors to high-purity isolation, we stay focused on batch consistency to help R&D chemists keep timelines predictable and reactions clean.
Consistent purity means fewer unwanted byproducts in your subsequent synthesis steps. Each lot undergoes meticulous verification using NMR, MS, and HPLC, which gives research partners assurance that every delivery matches published standards. Simple GC or TLC testing can’t catch the same subtleties, so this commitment pays off for those seeking robust scale-up or scouting new reaction pathways. We know from personal experience, a slight change in purity or residual moisture can completely derail a catalytic cycle or make a column more troublesome than necessary. Over the years, feedback from small biotech labs and established multinationals alike has steered our QC protocols, stressing the difference between “good enough” and “right the first time.”
Specifically, 2-bromo-6-(methylsulfonyl)pyridine arrives as a fine powder, easy to weigh and transfer, which reduces handling loss and static charge issues. The melting point and solubility profile promote a smooth workflow under common synthetic conditions. Extensive lot documentation tracks spectral conformity, trace metal content, and residual solvents. We keep sulfur and halogen contamination in check by tightly controlling our raw feedstock and solvent streams. This is not just a point of pride but one of necessity–even trace impurities can upset targeted substitutions or Suzuki couplings. Quality starts at the first step, not just the final filtration.
We’ve supported chemists taking this compound from gram-scale library prep up to multi-kilo pilot runs. More than once, project leaders noted how consistent reactivity speeds up hit-to-lead programs. The bromo group activates the pyridine ring for selective further modification, while the methylsulfonyl unit helps block off orthogonal sites and direct electrophilic additions. In some libraries, this specificity made the difference between ambiguous SAR data and clear findings. Beyond drug discovery, a few agrochemical teams used our product to build backbone structures that would resist harsh field conditions–a testament to the stability inherent in the sulfonyl-pyridine motif.
As a manufacturer, we know stories about inconsistent hazardous waste handling and regulatory gray areas taint the reputation of the chemical industry. We’ve watched as calls for traceability and environmental stewardship moved from idle talk to real-world audits and documentation requirements. Our team adopted closed-reactor charging, solvent recovery, and effluent scrubbing systems before many of these rules hit the books. Daily logs and material balance sheets guide our operations, not only during inspections but throughout routine runs. The mindset goes beyond compliance. A well-managed facility avoids shutdowns, inspires worker confidence, and keeps our partners satisfied that their supply chain won’t be interrupted by avoidable incidents or publicized spills.
Many research teams come to us after frustrating experiences with unstable or poorly characterized intermediates. The combination of bromine and methylsulfonyl groups at opposing positions on the ring allows more predictable reaction outcomes. Experienced synthetic chemists recognize how a stable functional handle can open up streamlined routes for cross-coupling or nucleophilic aromatic substitutions. We’ve seen chemists move through scaffold-hopping programs more efficiently when their building blocks match strict analytical signatures. For those chasing new kinase inhibitors or CNS-active molecules, small changes in ring electronics can translate to measurable shifts in biological data. We’ve helped teams de-risk their projects by eliminating bottlenecks that come from inconsistent core material.
We invest in reliable packaging because minor exposure to humidity or light can degrade certain aromatic compounds–especially when fine-tuning scale-up recipes. Welded foil liners, desiccants, and tamper-evident closures come standard to guard against contamination and environmental uptake. Every multi-kilogram drum arrives with intact seals and secondary containment, which has prevented countless headaches when labs open shipments outside controlled storage. From our own benches, we’ve seen how careful sample division and labeling save time during high-throughput campaigns, especially when screening new reaction conditions or catalysts.
Open communication between manufacturer and end-user shapes our ongoing improvements. Having worked alongside synthetic teams during new product launches, our technical specialists answer questions straight from hands-on experience rather than second-hand advice. Questions on solubility, stability, or unusual reactivity scenarios get matched with practical recommendations and shared literature references, not generic responses. Laboratory data on solvent compatibility keeps surprises to a minimum, while feedback on unique use cases–whether it’s a stubborn baseline impurity or a mid-stream process hiccup–goes straight into process improvements and future technical bulletins.
Compared to other pyridine bromides, our compound’s methylsulfonyl group stands out as more than a placeholder. Not only does it plug a reactive site, but it also balances the electron density across the ring, creating a distinct profile for reactivity under diverse synthetic conditions. Colleagues often note increased yields when using this intermediate in selective cross-coupling reactions, especially when downstream processes demand high isolation purities. Reactions that need a “clean kill” or orthogonal blocking see less byproduct formation, reducing time spent on downstream purification and waste disposal. We’ve seen benchmarks where well-made 2-bromo-6-(methylsulfonyl)pyridine cut weeks off development timelines, simply by enabling more reliable stepwise synthesis and purification.
Transparency matters, especially as global procurement grows more complex. We supply lot certificates with every dispatch, including detailed spectra and impurity profiles. Our in-house chemists remain accountable for every signature, with electronic logs tying back to individual operators and batch dates. This approach helps visiting auditors confirm provenance and authenticity, giving our clients a documented trail in regulatory filings and patent applications. Chemists who’ve been burned by off-spec intermediates or “mystery” impurities know why a named, approachable source trumps a faceless label.
It’s rare for a new project or reaction workflow to run exactly as expected. Our job does not end with dispatch. Regular conversations with repeat clients yield process innovations that filter back into improved specs and packaging. For example, early requests from a group synthesizing sulfonamide-rich scaffolds highlighted issues with moisture pickup during winter transport. After experimenting with additional desiccant packs and rethinking box liners, our team stabilized product quality even through storms and airport delays. Direct client feedback informed upgrades to our milling and sieving systems, so material remains consistent whether the order fills a few grams or several drums.
Not long ago, a developer working on central nervous system targets found their program stuck at scale-up due to recurring impurity spikes traced back to raw material inconsistencies. Working directly with our technical staff, they ran parallel test batches using our characterization data. The change in outcome–cleaner reactions, less time spent troubleshooting columns, and reliable patent claims thanks to reproducible spectra–underscored the value of sourcing directly from a manufacturer with real process control and a culture built around scientific rigor. We receive appreciative follow-ups every quarter from those whose data stories changed course due to dependable materials.
The pace of change in chemical research excites us, especially as small tweaks at the molecular level now shape entire therapeutic platforms. Demand continues shifting toward greener, atom-economical syntheses. Our R&D team pushes to reduce reliance on legacy solvents and streamline ligand usage, sometimes adjusting traditional protocols to meet emerging process safety criteria. Through frequent dialogue with regulatory consultants and laboratory leaders, we stay updated on permitted impurity profiles, REACH status, and transportation hazard thresholds. Recent installations of catalytic recovery and in-process recycling not only reduce costs but satisfy stakeholder demand for sustainable solutions. New sensor arrays in our plant allow real-time tracking of exotherms and emissions, making it easier to dial in subtle parameter adjustments batch-to-batch.
Our chemists rarely encounter a process hiccup or product request that’s truly unprecedented. Decades spent troubleshooting side reactions, tailing spots, or inconsistent scale-ups give us a deep bench of practical solutions. Clients routinely consult us before redesigning their own steps, seeking advice rooted in direct plant experience. We’ve guided start-ups through tricky purification protocols, and helped established pharmaceutical teams optimize yield by tweaking stirring rates, solvent grades, or crystallization techniques. The number of patents acknowledging our compound as a key intermediate keeps growing, showing that technical support grounded in daily factory operations builds true value.
Online aggregators sometimes boast about broad portfolios or fast drop-shipping, but those sourcing from intermediaries seldom enjoy the same hands-on traceability as from the actual manufacturer. Chemists driving crucial programs tell us they have no time or budget for “mystery” contamination or undetected variability. Our process starts with careful raw material selection, moves through tightly controlled small-batch synthesis, and finishes with real, accountable analytical backup. Years of handling third-party disruptions and substitute materials reinforced the benefits of sticking to a single, reliable production route–every variable, from temperature profile to solvent swap, stays within a well-documented window.
Looking forward, science will rely even more on advanced, visible intermediates that take the guesswork out of discovery-phase routes. The features that make 2-bromo-6-(methylsulfonyl)pyridine stand out–clean functionalization, predictable substitution, and stable shelf-life–fit directly with the push for efficient, patentable, data-driven discoveries. As new biological targets and material science questions arise, chemists can revisit trusted building blocks for faster, cleaner solutions. We put real pride in offering not just a compound, but a partner’s approach–one built on on-the-ground experience, continuous improvement, and transparency at every step.
Production never stops teaching us. Every project brings a new variable to consider or an unexpected bottleneck to solve. By talking to the people who run the reactions and review the chromatograms, we get a real-world understanding of what matters most. Chemists who partner with a manufacturer that sweats the details–water content down to parts per million, crystallinity between lots, shipment documentation accurate to the gram–enjoy a faster path from idea to delivery. We’ve come up through thousands of pilot runs and scale-ups, and the stories our partners share remind us daily that chemistry is personal. Results rely on careful inputs, honest communication, and a hands-on approach from beginning to end.
2-bromo-6-(methylsulfonyl)pyridine exemplifies how a well-made compound supports not only today’s research, but tomorrow’s breakthrough therapies and materials. The work never gets routine. Every improvement in the manufacturing process, every suggestion from a chemist in the field, and every test run deepens our understanding of what this compound can help achieve. Reliable, characterized, and built with purpose, this intermediate reflects years of learning right at the molecular level. Those core values drive us to keep raising our standards, delivering the kind of support that lets our clients create real, measurable impact from their research bench to the world beyond.
