|
HS Code |
998240 |
| Product Name | 3-Bromo-2-Hydroxypyridine |
| Purity | 99% |
| Cas Number | 69327-42-2 |
| Molecular Formula | C5H4BrNO |
| Molecular Weight | 173.00 g/mol |
| Appearance | White to off-white powder |
| Melting Point | 95-99°C |
| Boiling Point | 309.4°C at 760 mmHg |
| Density | 1.81 g/cm3 |
| Solubility | Slightly soluble in water |
| Smiles | C1=CC(=C(N=C1)O)Br |
| Inchi | InChI=1S/C5H4BrNO/c6-4-2-1-3-7-5(4)8/h1-3,8H |
| Refractive Index | 1.662 |
| Flash Point | 140.3°C |
| Storage Temperature | Store at 2-8°C |
As an accredited 3-Bromo-2-Hydroxypyridine99% factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 25g of 3-Bromo-2-Hydroxypyridine 99% is packaged in a sealed amber glass bottle with a tamper-evident screw cap. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 3-Bromo-2-Hydroxypyridine 99%: 10MT packed in 200kg iron drums, 80 drums per container. |
| Shipping | **Shipping Description:** 3-Bromo-2-Hydroxypyridine 99% is securely packaged in sealed containers, compliant with chemical transport regulations. Shipped via trusted carriers, it is handled as a low-toxicity, non-flammable solid. Appropriate labeling and documentation accompany each package to ensure safe and traceable delivery. Store in a cool, dry place upon arrival. |
| Storage | 3-Bromo-2-Hydroxypyridine (99%) should be stored in a tightly sealed container, protected from light, moisture, and incompatible substances such as strong oxidizing agents. Keep it in a cool, dry, and well-ventilated area at ambient temperature. Ensure proper labeling and avoid exposure to heat and sources of ignition. Store according to all relevant safety and regulatory guidelines. |
| Shelf Life | Shelf life of 3-Bromo-2-Hydroxypyridine (99%) is typically 2-3 years when stored cool, dry, and tightly sealed. |
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Purity 99%: 3-Bromo-2-Hydroxypyridine99% with Purity 99% is used in active pharmaceutical ingredient synthesis, where high chemical purity ensures increased drug safety and efficacy. Molecular Weight 174.0 g/mol: 3-Bromo-2-Hydroxypyridine99% with Molecular Weight 174.0 g/mol is used in agrochemical intermediate synthesis, where precise molecular mass supports consistent reaction yields. Melting Point 84-88°C: 3-Bromo-2-Hydroxypyridine99% with Melting Point 84-88°C is used in heterocyclic compound preparation, where thermal stability enables controlled crystallization during formulation. Low Water Content: 3-Bromo-2-Hydroxypyridine99% with Low Water Content is used in specialized dye manufacturing, where minimal moisture content prevents hydrolytic degradation. High Stability Temperature: 3-Bromo-2-Hydroxypyridine99% with High Stability Temperature is used in catalyst development, where thermal resistance ensures reliable performance during high-temperature reactions. Fine Particle Size: 3-Bromo-2-Hydroxypyridine99% with Fine Particle Size is used in polymer modification processes, where uniform particle dispersion improves blend homogeneity and reaction kinetics. |
Competitive 3-Bromo-2-Hydroxypyridine99% prices that fit your budget—flexible terms and customized quotes for every order.
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Ask anyone who works with nitrogen-containing heterocycles, and the conversation turns quickly to selectivity and purity. 3-Bromo-2-Hydroxypyridine 99% stands out among pyridine derivatives because it opens doors for chemists working in diverse sectors. With a molecular backbone that encourages both halogen and hydroxyl reactivity, this compound serves as a powerful intermediate, especially for pharmaceutical, agrochemical, and fine chemical development. Its 99% purity ensures each reaction can proceed with fewer unwanted byproducts, trimming time spent on purification and minimizing material loss.
In the search for optimal building blocks, especially in drug discovery, minor impurities often set back entire programs. The 99% assay of this compound matches the attention to quality needed for reproducible and reliable outcomes. In my experience working with complex pathway synthesis, inadequate starting materials have torpedoed projects—or, at the very least, forced frustrating reruns. This high-purity version brings confidence, not just for analytical work, but wherever the margin for error has to be razor thin.
Take its halogen substitution. Few positional isomers allow for such selective downstream modification. The bromo group on the third carbon invites new bonds through Suzuki-Miyaura and Buchwald-Hartwig reactions, opening the way for customized libraries. The attached hydroxyl group influences molecular interactions, changing electronic effects in final products. This unique arrangement sets 3-Bromo-2-Hydroxypyridine apart from typical halogenated or hydroxy-substituted pyridines—a fact organic and medicinal chemists notice right away in retrosynthetic planning.
Practically speaking, this compound finds its stride in medicinal chemistry labs striving to assemble small molecule inhibitors. I know many groups who rely on it for synthesizing kinase inhibitors and antifungal agents, since its reactivity helps build frameworks critical to biological activity. Its high purity simplifies the pipeline from initial reaction to assay, limiting impurities that can muddy structure-activity relationships. For those exploring agrochemicals, the compound also acts as a core in assembling crop protection agents that need precise modification at particular ring positions.
What stands out in real use? During a recent project involving CNS drug scaffolds, using a lower-grade version led to persistent side products that mimicked desired outcomes on HPLC, derailing months of progress. Switching up to the 99% grade brought clarity to our spectra and allowed us to press ahead. Others working in flavor chemistry or materials science benefit similarly, as even a trace of unwanted halides can alter sensory or electronic properties.
Plenty of derivatives crowd the marketplace, but few match this compound’s selective modification options. For example, using 2-bromopyridine skips out on the influence of the hydroxyl at C-2, missing crucial resonance effects that change both reactivity and physical properties. 3-chloro-2-hydroxypyridine sometimes arrives as an option for those looking for a similar motif, but the change from bromo to chloro impacts coupling yields and the compatibility with common synthetic methods.
Experience in scale-up conditions has also shown tangible differences between products at 95% and 99% purity. Subtle contaminants—sometimes trace residual solvents from prior extractions or low-level oxidation byproducts—impact yields and reproducibility. It’s not just about high numbers on a spec sheet; it’s about trust that the lot produces the same result every time, even after months in storage. In industrial settings, that reliability helps keep projects on time and within budget. Chemists working under tight constraints learn quickly which materials let them sleep easy at night.
Numbers on a label tell only part of the story. Actual performance shows up inside the reaction flask. Many users have relayed the frustration that comes with inconsistency, with lower-grade material sometimes masked by incomplete data sheets. Nothing matches hands-on feedback from bench scientists who notice variances in melting point, appearance, or ease of dissolution—and how these impact subsequent transformations.
Regulatory environments add pressure. Pharmaceutical firms in particular face compliance hurdles that make documentation of impurity levels and trace residuals critical. Improving standards on each batch of 3-Bromo-2-Hydroxypyridine does more than satisfy paperwork; it streamlines the auditing process, especially in settings where every impurity must be accounted for. A culture of quality pervades advanced suppliers, reflected not just in numbers but in steady, predictable shipment and support.
Chemists value reliable data on solubility, reactivity, and stability under standard storage and transport. In my time overseeing chemical inventory, I’ve noted how minor changes to moisture content or subtle decomposition have triggered issues with storage and dispensing. Ensuring lot-to-lot consistency brings peace of mind—and more productive research. The compound’s profile allows standard laboratory practices—nitrile gloves, goggles, and careful weighing inside a fume hood—without special inconvenience. Its low bulk density and manageable particle size further enable accurate measurement and mixing, important for both small and pilot-batch settings.
Properly sealed, stored in cool, dry locations, the compound remains stable through extended studies, supporting both exploratory discovery and process development. Labs moving between milligram and multi-gram scales have noted that consistent crystallinity and controlled flow properties avoid hang-ups in automation or manual transfers.
Reliable access to high-quality starting materials underpins the value chain in pharmaceuticals and specialty chemicals. Fulfillment delays or inconsistent quality can create ripple effects, stalling late-stage projects and even shutting down production. Over the past few years, global sourcing disruptions have made many rethink how they qualify new suppliers for compounds like 3-Bromo-2-Hydroxypyridine. Those who partner with suppliers focused not just on price but on transparency and batch documentation adapt more smoothly. Labs working in highly regulated sectors especially gravitate toward providers with full traceability and rigorous in-process controls.
Feedback from colleagues in purchasing indicates that supply reliability often counts even more than incremental cost savings. Expiry, wastage, and requalification expenses mount quickly when rolls of dice with quality don’t go in your favor. Focusing on trusted, certified lots keeps product lines steady and projects on track. Sustainability matters as well—verting off-waste from impure reagents, saving time, and reducing disposal concerns down the road.
Academic laboratories often use these intermediates to explore unexpected chemistry. 3-Bromo-2-Hydroxypyridine’s unique substitution pattern lends itself well to educational settings and exploratory research, where new transformations and structure-activity relationships get hammered out on the bench. Students and seasoned chemists alike benefit when the same reaction run on Monday matches the outcome seen on Friday—purity ensures repeatable education and progress.
Research isn’t confined to large-scale production and big-budget firms. Startups and small innovation teams pursuing novel therapeutics or specialty products often operate with shoestring budgets and even less time. For these teams, wasted effort carries a real price. Reliable, high-grade intermediates such as this one translate to direct savings—not just on raw materials, but on project timelines and outcomes.
I’ve seen too many promising projects flounder due to surprises traced back to reagent problems. Sometimes it’s chromatographic interference, other times it’s yield or the need to resynthesize an entire compound library due to contamination. Purity over 99% sounds technical, but in the trenches it means waking up to a clearer path forward. Instead of debugging every step, the focus shifts to innovation, analysis, and discovery.
Several years ago, in a screening project for enzyme inhibitors, the difference between commercial lots and those prepared with proper purification wasn’t subtle. The controls and blanks didn't add up—or worse, they did, but the analytical readout reflected a side product left from earlier synthetic steps. This taught me the importance of vetting sources and requesting documentation, and reinforced the need to set strict acceptance criteria for all core building blocks, especially foundational ones like 3-Bromo-2-Hydroxypyridine.
Industry wisdom suggests not relying solely on claims—ask for analysis certificates, review batch histories, and scrutinize packaging. In academic circles, group leaders now stress record-keeping and careful tracking for each significant intermediate, often keeping a handful of trusted suppliers on file. Analytical labs prioritize not just the final result, but the path to that result. The push goes deeper than compliance—repeatability, ease of reporting, and a trusted chain of custody keep regulatory scrutiny manageable and publishing standards high.
One solution lies in long-term partnerships with proven vendors. Establishing a transparent channel of communication ensures both sides share expectations—about purity, packaging, and shipment. Shared digital inventories, proactive lot updates, and rapid responses to queries reflect a mature supply relationship and limit the risk of miscommunication. For fast-developing fields aiming at high-impact results, these elements matter as much as the chemistry itself.
The growth of precision drugs, advanced materials, and specialty agrochemicals means higher expectations for starting material performance. The bar keeps rising. Regulatory authorities now expect ever-more-detailed impurity profiles, trace metal content analyses, and stronger provenance documentation, especially for compounds with the potential to move downstream into clinical candidates. This makes robust supplier vetting a constant task for labs keeping pace with new demands.
For those working on green chemistry initiatives, selectivity at the starting material saves waste in both solvents and time. Using intermediates with predictable performance supports sustainable synthesis by lowering total reaction steps, minimizing purification bottlenecks, and culling ecological impact at each phase. 3-Bromo-2-Hydroxypyridine’s reliability pays dividends for organizations measuring both profit and impact by new environmental metrics.
Educational programs now put greater weight on traceability and documentation. In teaching environments, access to reliable, highly pure samples supports not just better outcomes, but also ingrains habits of quality-mindedness in students. By working with top-grade material, young chemists learn to distinguish reaction issues attributed not to carelessness or theory, but real-world variations in reagents. This insight becomes invaluable as they carry lessons into industry or advanced research.
Improved teaching collections for advanced undergraduate or graduate synthesis courses often include 3-Bromo-2-Hydroxypyridine as a reference sample, allowing students to practice both reaction optimization and spectral analysis. The knowledge gained—both from successful runs and documented troubleshooting—prepares them for challenges they will face with more complex systems in professional settings.
The pace of innovation in pharmaceuticals and specialty chemicals doesn’t slow down. Companies and research organizations face continual pressure to shave time off development, meet ever-tighter regulatory standards, and produce more reliable products. Investing in the right starting materials now makes it possible to meet these goals and unlock new opportunities ahead.
Feedback from the field keeps surfacing the message: better quality is never a luxury. Chemists tired of rerunning columns, reporting mysterious yields, or doubling their waste disposal bills know that starting with vetted materials brings substantial rewards. In the competitive worlds of research and manufacturing, high-purity 3-Bromo-2-Hydroxypyridine sets the stage for cleaner data, more reliable results, and fewer last-minute surprises.
Few details in a reaction have as much downstream impact as reagent selection. Over years of managing projects and navigating regulatory reviews, I’ve come to view supplier relationships as partnerships built on transparency and shared goals. Documentation, open communication, and clear commitments to quality give buyers the assurance they need at every stage. The labs that thrive don’t just chase the lowest-cost option—they build process security by valuing consistency and service.
Every chemist has a story of an experiment torpedoed by an unexpected contaminant. Reviewing such cases drives home the point that quality in, quality out remains a credo for good reason. 3-Bromo-2-Hydroxypyridine, when sourced at high purity and with strong vendor support, lives up to its promise. It brings both measurable reliability and real peace of mind to those forging new ground in chemical science.
Those who push boundaries in synthesis and discovery need every advantage. Starting with a compound like 3-Bromo-2-Hydroxypyridine at 99% purity, with trusted documentation and support, sets a strong foundation. Whether it’s a multinational pharma company, a nimble startup, or a teaching laboratory, the benefits ripple through every workflow. Reliable sourcing, transparent quality, and hands-on experience ensure that today’s efforts can drive tomorrow’s breakthroughs—one well-prepared reaction at a time.
