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HS Code |
915474 |
| Product Name | 2-(Bromoacetyl)pyridine hydrobromide |
| Cas Number | 20481-15-4 |
| Molecular Formula | C7H7Br2NO |
| Molecular Weight | 297.95 g/mol |
| Appearance | White to off-white solid |
| Melting Point | 130-135°C (decomposes) |
| Solubility | Soluble in water, DMSO, methanol |
| Purity | Typically ≥98% |
| Storage Temperature | 2-8°C (refrigerated) |
| Synonyms | 2-pyridyl bromoacetyl bromide, Pyridin-2-yl bromoacetyl bromide |
| Smiles | C1=CC=NC(=C1)C(=O)CBr.Br |
| Inchikey | KVFFFKNOWFLHIY-UHFFFAOYSA-N |
As an accredited 2-(Bromoacetyl)pyridine hydrobromide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 10g of 2-(Bromoacetyl)pyridine hydrobromide is supplied in a sealed, labeled amber glass bottle with tamper-evident cap. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Securely packed 2-(Bromoacetyl)pyridine hydrobromide in drums/cartons, moisture-protected, labeled, compliant with international shipping standards. |
| Shipping | 2-(Bromoacetyl)pyridine hydrobromide is shipped in tightly sealed containers to prevent moisture and light exposure. Packaging adheres to chemical safety regulations, often using amber glass bottles, with appropriate hazard labeling. Ships via certified carriers in compliance with local and international chemical transport regulations, ensuring safety and integrity during transit. |
| Storage | **2-(Bromoacetyl)pyridine hydrobromide** should be stored in a tightly closed container, protected from light and moisture. Keep it in a cool, dry, and well-ventilated area, preferably at 2–8°C (refrigerated), away from incompatible substances such as strong oxidizers and bases. Always use appropriate personal protective equipment when handling and ensure containers are clearly labeled. |
| Shelf Life | 2-(Bromoacetyl)pyridine hydrobromide is stable for at least 2 years when stored tightly sealed at 2-8°C, protected from light. |
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Purity 98%: 2-(Bromoacetyl)pyridine hydrobromide with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures improved target compound yield. Molecular weight 265.98 g/mol: 2-(Bromoacetyl)pyridine hydrobromide with molecular weight 265.98 g/mol is used in organic synthesis protocols, where it guarantees precise stoichiometric control. Melting point 192-195°C: 2-(Bromoacetyl)pyridine hydrobromide with a melting point of 192-195°C is used in controlled thermal reactions, where it provides predictable phase transition behavior. Stability temperature up to 80°C: 2-(Bromoacetyl)pyridine hydrobromide with stability up to 80°C is used in solution storage, where it maintains chemical integrity during extended handling. Particle size <50 µm: 2-(Bromoacetyl)pyridine hydrobromide with particle size less than 50 µm is used in fine chemical blending, where it allows uniform reagent dispersion. |
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In the evolving landscape of chemical synthesis, selective reagents form the backbone of research and production. From our long-standing experience in producing fine chemical intermediates, real progress often starts with subtle but deliberate choices in raw materials. 2-(Bromoacetyl)pyridine hydrobromide, catalogued as model 2BPH-97 within our inventory, has found a unique niche with customers who demand high purity and reliable performance batch after batch.
This product, a white to off-white crystalline solid with controlled moisture and a consistent particle size, brings molecular specificity to organobromine chemistry. Customers working on pyridine-based ligands, pharmaceutical scaffolding, and other specialized compounds have told us on visits and calls that skipping quality controls at this stage can produce weeks of troubleshooting downstream. We’ve observed the same in our pilot labs: even a slight shift in impurity profile can throw off yields or generate unworkable byproducts. Production teams, typically juggling a tight turnaround, trust our batches for the simple reason that repeatability means fewer surprises in scale-up.
Users look to 2-(Bromoacetyl)pyridine hydrobromide for acylation and alkylation reactions, including the formation of C–C and C–N bonds in custom synthesis. Its reactivity—neither too sluggish nor overly aggressive—offers a balance shaped by deliberate process control. Each shipment begins from standard raw materials, but the value emerges in tight adjustments to temperature, moisture exclusion, and filtration, which dictate the outcome nearly as much as reagent selection itself.
Our technical support team keeps in regular contact with synthetic chemists in both pharma and academic circles. Experience shows that product quality does not stop at meeting a nominal purity number. NMR, HPLC, and specific water content influence crystallization, solubility, and even operator safety. Questions about packaging usually revolve around moisture protection or static control, since even minor contamination can wreck a multi-step route. In our own work, we weigh and transfer in controlled atmospheres, knowing that each gram carries a record of its history through the plant.
Unlike some basic brominated reagents picked mostly by price, 2-(Bromoacetyl)pyridine hydrobromide demands hands-on process control at every stage. Pyridine ring starting materials often bring trace related compounds. Left unchecked, these end up as colored impurities or strange spots in finished API intermediates downstream. From recrystallization under nitrogen to stepwise chromatography and solid-state drying, we treat each lot as destined for somebody’s critical experiment—not just as a commodity.
Chlorides and other halide contaminants affect not just GMP compliance audits, but also the underlying chemistry of bromine transfer. Each campaign we run gets full traceability by lot, operator, solvent lot numbers, and parameter monitoring—not for the sake of a paper trail, but to guarantee no surprises in downstream columns or reactors. Colleagues in QC and tech transfer learned early that even a small fluctuation requires a root-cause fix to protect yield consistency across campaigns. Customers regularly request custom analytics, which we supply without fuss thanks to the depth of data logged through our quality system.
Synthetic chemists draw on 2-(Bromoacetyl)pyridine hydrobromide for a range of tasks—formation of complex heterocycles, tethering to nitrogen bases, or as a handle for further functionalization. This compound sits at a sweet spot of activation; energetically, it’s reactive enough for substitutions under diverse conditions but not so aggressive that it risks runaway side reactions. This reliability is not an accident. Fine-tuning batch parameters, plus ongoing dialogue with end users, guides us to adjust conditions to what real experiments need—not just what the textbook says.
A classic example emerges in the diversified needs of pharmaceutical labs. Some clients require the product for Suzuki-type couplings with palladium catalysts. Others introduce it early in multi-step routes leading to kinase inhibitors or pyridine-based fluorophores. Each application tests a different facet of performance. In these environments, troubleshooting costs climb fast. Any savings eroded by debugging solvents, quenching steps, or recrystallization can far outstrip the upfront investment in a batch done right from the start.
The bulk chemical market remains crowded with minor brands and parallel-run materials. As a manufacturer, we see real differences between products with the same name: identical CAS registry numbers but very different histories through glassware and reactors. Genuine 2-(Bromoacetyl)pyridine hydrobromide, properly isolated and free from lingering bromide impurities, tracks seamlessly through analytical chemistry labs and into kilogram-scale reactors. Shortcuts at the lot preparation stage—using low-grade solvents, skipping filtration, running open air—can seed problems that show up months later as failed batches, off-color solids, or mystery peaks on the chromatogram.
Our own line began over a decade ago, engineered to meet feedback from hands-on users in R&D. Some asked for improved flowability for automated weighing; others stressed the need for traceable water content for scale-up to industrial reactors. Sampling methods matter, as even minor static charges or accidental exposure to air during transfer can nudge reactions off target. We keep each production lot in tamper-evident drums and test random samples periodically even during storage, checking for hydrolysis or contamination before shipping out.
The crowded segment of brominated pyridine derivatives contains many close relatives, including 3-bromopyridine and bromoacetylbenzenes. On paper, the parent structures differ by only an atom or two, but in bench chemistry, even this shift sends entire synthetic pathways into different outcomes. For those running medicinal chemistry or method development, unpredictability creates wasted time and budget.
2-(Bromoacetyl)pyridine hydrobromide stands apart with its balance of electrophilic acetyl group attached at the 2-position, matched with a stabilized hydrobromide counterion. This combination grants it unique reactivity profiles, enabling stepwise acylations and other transformations with selective control. We’ve fielded questions from both academic and industry teams who found alternate materials too reactive, resulting in product mixtures hard to separate or low yields due to side alkylation. Poor isolation or inconsistent counterion content, as seen in some bulk lots from generic producers, also undercuts reproducibility—one of the reasons several contract synthesis groups switched over to our supply chain after running into excess waste during purification or inconsistent melting points.
Compared to simple bromopyridines or generic bromoesters, this material handles functionalization and further derivatization more smoothly, enabling researchers to move directly to the next stage in their flow without lengthy cleanups. Process chemists especially value the assurance of minimal cross-contamination, having navigated projects doomed by mystery side products or unwanted halogen exchange. In one case, a manufacturing partner received a drum sourced from a distributer; subsequent analysis revealed an unworkable byproduct load. Issues like these highlight the necessity of partnering with manufacturers who monitor every production step, rather than just picking from warehouse stock.
One aspect shaping our entire operation is direct feedback from working chemists and engineers. Over years of customer visits, site audits, and troubleshooting phone calls, certain themes keep surfacing. Timing matters in R&D—few can afford pause in the synthetic chain for material requalification or lot-to-lot variances. We keep detailed release records not to comply with paper-driven audits, but because next week’s formulations rely on traceability and reliability.
Packaging, for instance, has evolved hand-in-hand with customer requests. Many high-throughput R&D operations, working across inert atmospheres or within robotics banks, hated the delays and mess of poorly sealed bags. We now employ rigid containers designed to stand up to humidity, with double-sealed liners, so material arrives fresh and dry. Even small considerations—labels that don’t peel off in cold rooms—come from real suggestions and daily use.
Some industrial teams have also requested certificates down to trace solvent and metal residues, often outside ordinary specifications. Our plants have adapted so that batch data becomes easily accessible, cutting out any guesswork. In critical synthesis lines, even small residual solvents can impact downstream chromatography or sensitive bioassays. Regular dialogue with our clients’ technical teams helps us solve these issues before they eat into timelines or budgets, making the business of buying chemical intermediates less about risk and more about repeatability.
We have faced challenges in maintaining consistent purity and batch performance, especially as demand grew and processes scaled up. There’ve been periods where plant throughput threatened to outpace the vigilance of individual operators. Our technical, operational, and QA teams worked closely to retool each step—introducing digital process logbooks, frequent cross-team audits, and expanded analytics. Not every adjustment produced instant results; some shifts required weeks of collaborative troubleshooting. In time, dual checks at critical points in batch preparation closed the gap between lab-scale and production floor.
One case stands out where a suspected impurity flagged by an overseas client led to a deep-dive investigation. Our process team worked side by side with their analytical chemists to isolate a micro-trace aromatic contaminant, ultimately tracked back to a resin change. That episode changed our own supplier qualification process and expanded our QC screening. The lesson stuck—scrutiny pays off longer-term both for us and for the technical users who entrust projects to our brand.
The use of brominated organics brings environmental and worker safety obligations. Our plants invest in closed transfer systems and real-time emissions monitors, not just to meet compliance, but because safe workplaces endure. On the shop floor, minimizing open handling reduces not only emissions but the risk of exposure or spills. Our team members work under strict PPE and routine health checks; every improvement in procedure stems from operational feedback and careful incident review.
Waste minimization stands as a key production goal. Brominated byproducts receive segregation at source and are collected for professional treatment. We keep process engineers in the loop, exploring ways to incorporate green chemistry, conserve solvents, and cut down on resource footprints. A major upgrade to our distillation setup recently brought scrubber efficiency above 98%, reducing both odors and hazardous releases.
Beyond core production, we maintain active links with chemists who use 2-(Bromoacetyl)pyridine hydrobromide in frontier research: new ligands, diagnostic agents, and custom fluorescence probes. Our applications team regularly explores alternate synthetic routes, such as greener bromination pathways or continuous-flow preparation to support clients pivoting away from classic batch processing. Every step forward—faster reactions, higher atom economy, safer transformations—means fewer batch deviations and supply confidence.
In the laboratory, we encourage feedback and trial samples, welcoming critical assessments from outside users. Those in academic settings often push material through nonstandard conditions, revealing strengths and sometimes limitations that routine manufacturing use does not uncover. This interactive cycle of feedback sharpens not just our offering today, but signals new directions for process improvement and innovation.
Global supply chains shift fast, occasionally throwing up roadblocks from ingredient shortages to unforeseen regulatory updates. As a manufacturer, we plan for these realities rather than react to them after the fact. Inventory on hand, dual-sourced key reagents, and a range of packaging options ensure end users avoid bottlenecks. Customers needing emergency shipments or small-lot custom runs call on us not because their procurement desks prefer a catalog number, but because our teams have proven their resourcefulness even when market signals flash red.
We monitor not just outbound product but trends in field failures or shifting requirements. Over time, patterns emerge: the most satisfied labs are those whose suppliers solve problems before they appear. We have crafted our release strategy to flex with both bulk orders and niche, micro-scale projects, so no team has to compromise on turnaround simply due to scale mismatch.
A customer-centric approach ensures each batch of 2-(Bromoacetyl)pyridine hydrobromide carries the weight of shared learning. Any deviation or batch trend sparks immediate review and process tune-ups. We take pride in deploying skilled operators at the synthesis stage, recognizing that every step—from glassware cleaning through final packaging—bears directly on end user trust.
Analytical tech keeps moving, and our operation keeps pace. We continue to update in-house NMR, GC, and LC-MS lines, with regular cross-validation against collaborative labs. This investment pays back in early issue detection, better root-cause problem solving, and more robust certificates of analysis that reflect the needs of both regulatory teams and hands-on bench chemists.
Years of lessons on both the production floor and in close contact with the bench make clear: selection of high-performance intermediates like 2-(Bromoacetyl)pyridine hydrobromide shapes the outcome of demanding syntheses. With each campaign, we renew our focus: transparency in production, agility in meeting changing requirements, and above all, the human element that connects manufacturer and chemist. End users see the difference not just in finer powders and clean analytical reports, but in saved hours, fewer surprises, and better results week after week.
