|
HS Code |
594838 |
| Product Name | 4-(Bromoacetyl)pyridine hydrobromide |
| Cas Number | 52427-35-9 |
| Molecular Formula | C7H7Br2NO |
| Molecular Weight | 297.95 g/mol |
| Appearance | White to off-white powder |
| Melting Point | 155-157°C |
| Solubility | Soluble in water and polar organic solvents |
| Purity | Typically >98% |
| Chemical Class | Pyridine derivative |
| Storage Conditions | Store at 2-8°C, protected from light |
| Synonyms | 1-(4-Pyridyl)-2-bromoethanone hydrobromide |
| Smiles | C1=CC(=CN=C1)C(=O)CBr.Br |
| Inchikey | KVDIMADSVUFQJQ-UHFFFAOYSA-N |
| Hazard Statements | Irritant; Harmful if swallowed or inhaled |
As an accredited 4-(Bromoacetyl)pyridine hydrobromide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 4-(Bromoacetyl)pyridine hydrobromide, 5g, supplied in a tightly sealed amber glass bottle with tamper-evident cap and hazard labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Securely packed 4-(Bromoacetyl)pyridine hydrobromide in sealed drums, moisture-protected, labeled, and palletized for export. |
| Shipping | **Shipping Description:** 4-(Bromoacetyl)pyridine hydrobromide is shipped in tightly sealed containers, protected from moisture and light. It is classified as a hazardous chemical, requiring appropriate labeling and documentation. Transportation complies with applicable regulations, such as UN, IATA, or DOT guidelines. Handle with personal protective equipment and ensure secure packaging to prevent leaks or spills during transit. |
| Storage | 4-(Bromoacetyl)pyridine hydrobromide should be stored in a tightly sealed container, protected from light, moisture, and incompatible materials. Keep it in a cool, dry, and well-ventilated area, ideally at temperatures between 2–8°C (refrigerated). Proper labeling and secure storage help prevent accidental exposure, as the compound may be sensitive and potentially harmful if mishandled. |
| Shelf Life | 4-(Bromoacetyl)pyridine hydrobromide typically has a shelf life of 2 years when stored in a cool, dry, and dark place. |
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Purity 98%: 4-(Bromoacetyl)pyridine hydrobromide with 98% purity is used in pharmaceutical intermediate synthesis, where it ensures high-yield coupling efficiency. Melting point 176-180°C: 4-(Bromoacetyl)pyridine hydrobromide with a melting point of 176-180°C is used in custom organic synthesis workflows, where it provides reliable phase transition control. Molecular weight 265.97 g/mol: 4-(Bromoacetyl)pyridine hydrobromide at a molecular weight of 265.97 g/mol is used in medicinal chemistry research, where it facilitates precise stoichiometric calculations. Stability up to 25°C: 4-(Bromoacetyl)pyridine hydrobromide stable up to 25°C is used in reagent storage for laboratory environments, where it maintains chemical integrity during extended storage. Particle size <50 μm: 4-(Bromoacetyl)pyridine hydrobromide with particle size under 50 μm is used in solid-phase synthesis platforms, where it enables uniform dispersion and rapid reaction kinetics. Hydrobromide salt form: 4-(Bromoacetyl)pyridine hydrobromide in hydrobromide salt form is used in nucleophilic substitution reactions, where it enhances reactivity and product selectivity. High solubility in water: 4-(Bromoacetyl)pyridine hydrobromide with high solubility in water is used in aqueous reaction systems, where it improves process scalability and dissolution rates. Assay ≥98%: 4-(Bromoacetyl)pyridine hydrobromide with assay ≥98% is used in analytical method development, where it delivers reproducible and accurate quantification results. Low residual solvent content: 4-(Bromoacetyl)pyridine hydrobromide with low residual solvent content is used in API manufacturing, where it minimizes impurity profiles in finished products. |
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Working directly inside a chemical plant, you see the difference between what’s promised—on glossy datasheets—and what ends up in the drum. Our plant operates with a simple mantra: performance has to match expectation. This is especially important when customers depend on compounds like 4-(Bromoacetyl)pyridine hydrobromide for their research and process needs. Every batch we release stems from years of running reactions, controlling for purity, and spotting how trace moisture or side-reactions sneak into the process. We have learned that this compound, a pale to light yellow crystalline material, supports a surprising range of synthetic transformations, especially in the world of pharmaceutical development and complex intermediate libraries. Customers can expect the genuine substance, manufactured at scale, with the attention to detail that daily operations force upon us.
In the lab, chemists focus on reaction yields, troubleshooting side-products, and configuring safer runs. On the production floor, a few hours of inattention or skipping quality checks disrupts the entire supply chain. We’ve found that the integrity of 4-(Bromoacetyl)pyridine hydrobromide depends on handling each stage—starting from sourcing the right pyridine derivatives to using controlled bromination and acetylation steps. Our models range in typical batch sizes, but the focus is always the same: keep the material above 98 percent purity, with moisture content well under 0.5 percent. We use HPLC and NMR instrumentation in-house, instead of sending everything out for verification. This doesn’t just keep our own processes honest; it lets us guarantee a tighter margin on purity for every order, whether a kilo or a drum.
As the manufacturer, we know subtle process tweaks—like slow addition of reagents or agitation speeds—lead to variations in product quality that aren’t always obvious until they affect a downstream reaction. This focus on hands-on, physically-verified quality separates a factory product from something repackaged or distributed through several layers of resellers. After years of feedback from regular customers, we improved filtration and drying steps to prevent clumping or product degradation. Such changes never get written up in brochures, but they show in the way the product handles during weighing, transfer, or dosing.
Inside pharmaceutical labs and agrochemical development, 4-(Bromoacetyl)pyridine hydrobromide lets chemists build heterocyclic scaffolds and explore N-alkylation or acylation strategies. We’ve seen academic customers design new kinase inhibitors or perform regioselective ring closures with this material, pushing for next-generation drug leads. Another group leans on it when synthesizing functionalized pyridines, testing catalytic methodologies, or building intermediates on the route to more complex molecules. These uses depend on material purity, but also on the predictability of each lot. The right melting point, crystallinity for easy weighing, and low residue after solvent evaporation: these features grow out of learning from production mishaps as much as successful batches.
In real use, one flaw in the starting material derails hours inside the lab or months of planning, so consistency wins out over marketing claims. For customers scaling up or moving from lab grams to plant kilos, our technical team has switched to real-time process monitoring. For example, we flag every percent change in active content. No one wants an unexpected color, odor, or off-spec melting point. This operational focus supports scale-up, minimizes waste, and more importantly, helps research chemists avoid surprises.
Our experiences have shown that difference between an original manufacturer’s batch and a repackaged lot from a middleman can be dramatic. Physical handling, even a few days in the wrong humidity or exposure to air, introduces subtle degradation or impurity uptake that won’t show up in a cursory check. Direct from the plant, material ships with a known production date, documented storage conditions, and a guarantee of rapid turnover. No exposed drums, no sticky residues from unnecessary warehouse time, no unknown previous tracking. We store our output under nitrogen or in controlled low-humidity areas, always flagged with lot-traceable numbers.
Another point: documentation coming from the source combines analytical data with the story of the batch. Our line operators log temperatures, batch times, and even oddities during crystallization or filtration. A distributor relabels, maybe handles hundreds of compounds in shared spaces. We only ship material after an independent QC release, since our contracts with research companies and universities depend on trust built over years—not on one-off orders but repeat purchases where reliability matters more than speed.
We’ve gotten questions about differences in “model” or specification. For some customers, standard grade material (above 98 percent) works for routine synthesis, but advanced applications call for premium grade specifications—finer particle size, extra drying, or tighter metal content control. These variations get built into our manufacturing reports, and, if requested, we blend or reprocess batches for ultra-high-purity requirements. This can’t be matched by a one-size-fits-all product code or online catalog entry.
In the early years, we encountered a recurring issue: crystals would form needle-like clumps, slowing down downstream reactions and making accurate dosing difficult. Through adjustments in cooling rates and by selecting precise filter porosities, we transformed the crystalline habit. Now, customers comment that the lot is free-flowing and easy to handle, whether scooping or transferring automatically. Experience didn’t just improve surface characteristics; it also let us find operational bottlenecks in large-scale runs, reducing downtime and streamlining cleaning between campaigns. At no point did we rely on outside advice. Instead, the production team responded directly to complaints, testing different drying conditions until shelf-life extended to months rather than weeks.
Another worthwhile discovery: controlling bromination stepwise with calibrated feed rates lowered the amount of off-target pyridyl byproducts. This tighter process control led to less post-reaction workup, lower impurity profiles, and easier filtration. These improvements translate directly into less solvent waste, more reproducible yields, and a record of consistent results from lot to lot.
Responsibility goes beyond just shipping product. Every shipment of 4-(Bromoacetyl)pyridine hydrobromide leaves the premises with safe packing, clear hazard identifications, and accurate MSDS, since we know that handling brominated intermediates needs vigilance. Inside our plant, exhaust scrubbing and closed-transfer systems are standard, so our own teams work safely through reaction, isolation, and drying steps. These investments raise our costs slightly, but they guarantee no cross-contamination and preserve the health of workers who step into the facility every day.
We manage waste streams, capturing mother liquors and off-spec product without shortcuts. Solid and liquid residues get documented and diverted into compatible waste treatments, a routine made mandatory by years of audits and real plant events. We have stopped production runs when meter readings show drift, or when effluent tests flag an unanticipated compound. This direct experience, learned from incident rather than theory, shapes our production guidelines and forms the backbone of our continuous improvement initiatives.
Chemists have choices—catalog chemicals, commodities shipped in bulk, or lower-cost alternatives offered by resellers. In this market, trust takes years to build and can vanish in a single failed reaction or shipment. Our longstanding customers—universities, biotech firms, or global process R&D shops—keep coming back not just for the product, but for the problem-solving that comes with it. Immediate answers to technical questions, documentation that tracks back to the reactor log, and the willingness to reproduce a specific impurity profile or physical form set us apart from unverified sources.
Each relationship rests on openness: if there’s a production hold, if a batch shows minor deviation, we share data, flag the issue, and work toward a solution before it becomes a setback. We have sent plant engineers out to customer sites to diagnose puzzling incompatibilities, and these joint investigations almost always reveal overlooked details—like a minor shift in solvent quality or changes in downstream process temperatures—that a distributor would never catch.
We're not finished improving 4-(Bromoacetyl)pyridine hydrobromide. Working with academic partners, we have run side-by-side pilot trials, benchmarking possible new purification methods for greater selectivity and less environmental impact. Chemists send requests for improved solubility or stability in uncommon storage conditions, so we run controlled ageing and stress tests to optimize formulations.
Every few months, internal project teams assess our processes and review customer feedback. If a new synthetic methodology emerges in the literature, we try it out, measure not just yield but downstream process impact, and share these results with our partners. We make these continual investments because process inefficiency or failed expectations don’t just reflect a single missed delivery—they reshape how our entire operation is seen in the marketplace.
There is a temptation to substitute 4-(Bromoacetyl)pyridine hydrobromide with related intermediates, like bromoacetyl derivatives on different heterocycles, or to cut costs by sourcing from generic vendors. We have run head-to-head comparisons, frequently at the customers' request, and repeatedly find key differences in reactivity, solubility, and yield predictability. For example, our compound’s precise reactivity profile enables selective transformation at the bromoacetyl position, critical in constructing complex, multi-step syntheses. Substitutes bring risk: unexpected side-products, reproducibility failures, and, in worst cases, regulatory setbacks where trace impurities show up in analytical filings.
Within our own product line, we offer different specification levels by controlling both starting material quality and downstream purification. Some lots suit demanding, high-throughput screening where every impurity must fall below part per million thresholds. Others fill routine needs, where consistent melting point, solubility, and appearance are enough. Extensive analytical work supports every outgoing batch—NMR, HPLC, and, for specialized uses, ICP-OES or GC-MS screening for trace elements or solvent residues. We manufacture variants meeting internal control standards and accommodate requests for customized cuts, tailored for specific research projects. This approach gives real utility, not just an endless catalog of model numbers.
Much gets lost between manufacturer and end user. For 4-(Bromoacetyl)pyridine hydrobromide, knowing how it’s made—right from the reactor through drying, packing, and quality control—decides its real-world utility. Resellers handle paperwork, but can’t answer questions about reaction exotherm management or how a minor impurity might impact regulatory filings. We do. Years of handling sensitive intermediates in our facilities teach what works and where problems lurk. It creates a culture of candor, speed, and technical intimacy that doesn’t appear in catalog entries or third-party sales pitches.
We built our business through hands-on troubleshooting and by delivering to specification over hundreds of orders. The checks, audits, and sheer routine detail seen in plant records mean each shipment reflects not just a chemical name, but a promise fulfilled by people who know every valve, filter, and process step. Our place in the supply chain stands not as a faceless producer, but as experienced practitioners who know the stakes and priorities of users working on the frontier of chemical innovation.
Product requirements keep evolving. The rise of automated synthesis, greater regulatory scrutiny, and the global push for “greener” chemistry force us to innovate beyond what once sufficed. As automation spreads through labs, the need for lot-to-lot consistency and precise reporting on trace impurities only grows stronger. New synthetic methods and bioactive target spaces call for ongoing tweaks to our processes, ensuring the material’s versatility keeps pace with the field.
We now invest in closed processing systems, remote monitoring, and automated data logging, reducing human error and further improving reproducibility. Our R&D group works directly with formulation scientists, developing better solvent systems for easier integration or longer stability. These efforts pay off not just in customer satisfaction, but in regulatory readiness, smooth tech transfer, and fewer process problems downstream.
In specialty chemical manufacturing, experience shows up in the details—how a product looks, feels, or flows; how the paperwork matches up to plant logs; how customers' questions are answered without delay. 4-(Bromoacetyl)pyridine hydrobromide isn’t simply another chemical—it’s the outcome of hundreds of process cycles, operator vigilance on the line, and years of seeing how the smallest deviation can impact a chemist’s work months later.
We aim for more than just filling orders. By supplying from the factory floor, supporting research directly, and continuing to refine our processes, we help shape what’s possible in the lab or plant. Real chemical manufacturing never stands still. Neither do we.
