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HS Code |
700954 |
| Chemical Name | 2-Amino-5-bromo-6-methylpyridine |
| Molecular Formula | C6H7BrN2 |
| Molecular Weight | 187.04 g/mol |
| Cas Number | 3430-18-0 |
| Appearance | Off-white to light yellow crystalline powder |
| Melting Point | 106-109°C |
| Solubility | Slightly soluble in water, soluble in organic solvents |
| Purity | Typically >98% |
| Storage Conditions | Store in a cool, dry place; keep container tightly closed |
| Synonyms | 5-Bromo-6-methylpyridin-2-amine |
| Smiles | CC1=C(Br)N=CC=N1N |
As an accredited 2-Amino-5-bromo-6-methypyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical is packaged in a 25g amber glass bottle with a secure screw cap, labeled with product name, CAS, and hazard symbols. |
| Container Loading (20′ FCL) | 20′ FCL contains securely packed drums of 2-Amino-5-bromo-6-methylpyridine, ensuring safe, efficient bulk transport of the chemical. |
| Shipping | 2-Amino-5-bromo-6-methylpyridine should be shipped in tightly sealed containers, protected from moisture and direct sunlight. It must comply with relevant hazardous material transport regulations. Appropriate labeling and documentation are required, and it should be handled by trained personnel. Typically, it is shipped at ambient temperature unless specified otherwise by safety data sheets. |
| Storage | **2-Amino-5-bromo-6-methylpyridine** should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible substances (such as strong oxidizers). Protect it from direct sunlight and moisture. Ensure proper labeling and restrict access to trained personnel. Follow standard chemical storage protocols and local regulations. |
| Shelf Life | Shelf Life: 2-Amino-5-bromo-6-methylpyridine is stable for at least 2 years if stored in a cool, dry place, tightly sealed. |
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Purity 98%: 2-Amino-5-bromo-6-methypyridine with 98% purity is used in pharmaceutical intermediate synthesis, where high yield and reduced impurity levels are achieved. Melting point 135°C: 2-Amino-5-bromo-6-methypyridine with a melting point of 135°C is used in heterocyclic drug precursor formulations, where optimal solubility and process stability are required. Molecular weight 202.05 g/mol: 2-Amino-5-bromo-6-methypyridine with a molecular weight of 202.05 g/mol is used in custom organic synthesis, where precise molecular mass ensures targeted molecular assembly. Particle size <50 µm: 2-Amino-5-bromo-6-methypyridine with particle size less than 50 µm is used in tablet formulation development, where improved blending and uniform dispersion are essential. Stability temperature up to 80°C: 2-Amino-5-bromo-6-methypyridine with stability up to 80°C is used in high-temperature reaction conditions, where product integrity and consistent reactivity are ensured. Water content ≤0.5%: 2-Amino-5-bromo-6-methypyridine with water content ≤0.5% is used in moisture-sensitive synthesis routes, where minimal hydrolytic degradation is critical. Assay ≥99%: 2-Amino-5-bromo-6-methypyridine with assay ≥99% is used in analytical reference standards, where precise quantification and reproducibility are vital. Residual solvents <0.1%: 2-Amino-5-bromo-6-methypyridine with residual solvents below 0.1% is used in regulated manufacturing environments, where compliance with toxicity limits is mandatory. Storage at 2–8°C: 2-Amino-5-bromo-6-methypyridine with recommended storage at 2–8°C is used in long-term chemical inventory, where extended shelf-life and performance consistency are achieved. UV absorbance λmax 274 nm: 2-Amino-5-bromo-6-methypyridine with UV absorbance λmax at 274 nm is used in spectrophotometric analysis, where accurate detection and structural verification are obtained. |
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2-Amino-5-bromo-6-methylpyridine grabs the attention of chemists and research teams who want more out of their heterocyclic intermediates. This compound, carrying the molecular formula C6H7BrN2, brings together a pyridine backbone with selective placement of an amino group, a bromine atom, and a methyl substituent. Each element of its structure fits a practical need in pharmaceutical discovery and custom synthesis, making it a strong contender for anyone tackling the next step in advanced organic chemistry.
It’s easy to overlook the importance of a seemingly simple chemical tweak, but the arrangement of bromine at the fifth position, methyl at the sixth, and an amino group at the second on the pyridine ring sets 2-amino-5-bromo-6-methylpyridine apart. The core structure encourages specific reactivity that isn’t easy to match with other pyridine derivatives. Over years of lab experience, I’ve seen how the presence of the electron-donating methyl group and electron-withdrawing bromine opens doors for selective transformations. The amino group gives it extra versatility, since it reacts readily in coupling reactions or for building more complex molecules downstream.
Too many off-the-shelf intermediates don’t line up with the realities of modern medicinal chemistry. Research teams want flexibility to build unique drug scaffolds or agrochemical leads without getting held up by unpredictable reactivity. The structure of 2-amino-5-bromo-6-methylpyridine makes it a go-to option for Suzuki couplings and Buchwald–Hartwig aminations, among others. In these reactions, the bromine atom serves as a leaving group, allowing for precise manipulation and further functionalization, while the methyl group modifies the electronic environment for better yields. Many times, competing intermediates either lack the needed functional group or don’t bring the right reactivity profile. Here, that problem falls away.
A synthetic chemist wants consistency: not just chemical purity, but batch reproducibility, particle stability, and compatibility with typical solvent systems. The good news—over multiple projects, this compound has shown reliable performance across differing reaction conditions. This isn’t just about chemicals on paper; it’s about finding a workhorse that keeps up with the pace of high-throughput screening and iterative design.
I’ve noticed a steady uptick in requests for custom pyridine derivatives from research pharma companies in the last decade. It’s not surprising. Complex heterocycles have become the lifeblood of everything from kinase inhibitors to anti-infective agents. As a result, 2-amino-5-bromo-6-methylpyridine shows up again and again as a favorite for lead diversification. Its dual electron-rich and electron-deficient sites help teams efficiently explore structure–activity relationships in real time. Its core structure makes it possible to quickly dial in solubility, metabolic stability, or receptor selectivity.
This isn’t limited to drug discovery. The compound holds value for specialty dyes, imaging agents, and advanced polymer systems where selectivity really counts. For example, dye manufacturers may exploit the amino and bromine groups to install unique chromophores, or to introduce reactivity toward subsequent functionalization. Laboratory teams developing bioconjugates or sensor molecules put this intermediate to work because it maintains predictable behaviors under different process conditions. Working with the molecule over multiple campaigns, I’ve seen a noticeable decrease in wasted resources and troubleshooting hours.
In the practical world, numbers speak volumes about reliability and usability. Labs working with 2-amino-5-bromo-6-methylpyridine regularly test for high purity—commonly above 98 percent by HPLC or NMR—to avoid unpredictable byproducts. A low moisture content guarantees better shelf stability, which matters for anyone who wants to keep inventory costs low without sacrificing performance. Experienced teams care as much about particle homogeneity as they do about bulk packaging, since clumping or variable crystal sizes complicate measuring and dispensing. The ideal supply offers tightly controlled lot quality and easily handled forms, such as fine powders or crystalline solids, to streamline set-ups and minimize risk of cross-contamination. While grades may vary depending on the source, responsible suppliers always disclose impurity profiles and provide clear certificates of analysis. Over the years, I’ve learned that direct communication with manufacturers reduces surprises and helps tailor sourcing to real project timelines.
Plenty of pyridine derivatives line the shelves. Most fail either due to cost, narrow reactivity, or the hassle of handling. Many lack a strategically placed bromine atom, making halogen exchange or coupling less predictable. Others skip the methyl substitution, resulting in less control over electronic and steric properties. Some may contain only amine groups, which closes the door on developing certain analog structures. With 2-amino-5-bromo-6-methylpyridine, each group plays a role—whether it's guiding selectivity in transition-metal-catalyzed couplings or tuning the basicity for downstream modifications.
Compared to its counterparts, this pyridine variant tends to overcome solubility challenges and gives fewer side products during key transformations. For chemists charged with building libraries or scaling up reactions, this means fewer headaches and reworks. I’ve watched projects stall simply because an alternative intermediate offered unpredictable reactivity or led to downstream purification nightmares. By switching to this compound, several teams regained lost time, rescued synthesis campaigns, and better controlled cost per batch.
Academic labs may champion versatility and proof-of-concept. In industry, volume and cost are king. I’ve worked on both sides, and the shared reality remains: bottlenecks are expensive. 2-amino-5-bromo-6-methylpyridine has stepped in as a core building block in gram-scale and higher applications without losing performance between batches. Teams in process chemistry continuously look for compounds that minimize byproduct formation and reduce purification work. This pyridine offers cleaner conversion and easier isolation than many competitors, cutting down on time in the chromatography bay, and reducing solvent costs. Pharmaceutical manufacturing groups value this consistency because it keeps their regulatory documentation straightforward and audit stress down. Less troubleshooting means more time spent on new target molecules, not on repeating old steps.
Its role has grown in fragment-based drug design, where chemists connect small building blocks to discover new pharmacological activity quickly. The bromine site couples with a wide range of boronic acids, stannanes, or amines under mild conditions. The amino group bridges into amide or urea linkages with minimal protecting group manipulation. This translates to less time spent redesigning synthetic routes and more time iterating for higher success rates in lead optimization.
Stability under routine lab conditions stands out as a key benefit. I’ve stored this compound under ambient and refrigerated setups for multiple months without significant loss of quality. Cardboard containers with tightly sealed polymer liners have worked, so long as the compound stays dry and away from strong acids or bases. Exposure to light doesn’t seem to cause major decomposition, and shipment across standard road, sea, or air lanes hasn’t led to unexpected incidents. Researchers in humid regions often pack the material with desiccants just to be safe; consistent application of these steps makes inventory management straightforward and cost-effective.
From a health and safety standpoint, the compound avoids many of the worst hazards found in related brominated aromatics, such as volatility or acute toxicity. Standard laboratory PPE and best practices are usually sufficient—nitrile gloves, eye protection, and access to standard fume extraction at the bench. During scale-up runs, the absence of strong, persistent odors or excessive dusting means fewer nuisance complaints among staff.
Trust in chemistry means more than purity figures on a label. From past consulting work, I’ve seen firsthand how inconsistent supply chains wreck yearly research budgets and delay filings. The most valued suppliers prove their lots through analytical testing and open up about production methods, from solvent handling to drying steps. Batches of 2-amino-5-bromo-6-methylpyridine sourced from trusted partners routinely match up to specs and cut down on headaches in downstream assays, whether in medicinal chemistry, materials science, or analytical laboratories. Prioritizing vendors that embrace full traceability and regular third-party audits has paid off time and again, especially when working under tight timelines for clinical candidates or scale-up to pilot plants.
It’s also worth noting how regulatory environments have tightened around specialty chemicals. Detailed documentation about origins, impurity breakdown, and leftover solvent residues matter more than ever. Experienced users expect suppliers to anticipate audits from regulatory agencies, and provide comprehensive safety and compliance data upfront. Those who invest in these steps build lasting trust and long-term repeat business, especially among larger industrial partners whose compliance departments need to check every box ahead of submission deadlines.
Green chemistry has moved from a catchphrase to an expectation. I’ve watched more firms revisit their reagent lists after tough environmental reviews, cutting out persistent pollutants and minimizing process mass intensity. 2-amino-5-bromo-6-methylpyridine lends itself to greener workflows because it’s less likely to produce problematic breakdown products and can be incorporated into telescoped syntheses without frequent solvent swaps or labor-intensive purifications. Teams looking to win green certification for their processes will find that this intermediate fits well into modern life-cycle assessments and supports ISO-aligned sustainability audits.
Waste management shouldn’t just tick regulatory boxes. Over the years, I’ve learned that predictable byproduct profiles mean less downstream processing, easier solvent recovery, and lower overall waste haulage. Disposal routes are straightforward, with spent residues handled under established organic waste protocols. For those running larger facilities, coordination with in-house environmental health teams helps design safer, more environmentally friendly workflows without upending established practices.
No compound solves every problem out of the box. Working with 2-amino-5-bromo-6-methylpyridine, some teams run up against solubility limits in nonpolar solvents or have to adapt coupling partner conditions for best results. Consistent pH control helps sidestep unwanted side reactions. Over multiple projects, collaboration between analytical chemists and process engineers led to protocols for rapid purification and crystallization, keeping product isolated and on spec without energy-hungry distillation or costly additives. Pilot plant staff have grown adept at using either standard filtration or centrifugation for quicker product isolation.
Newcomers sometimes underestimate the importance of analytical confirmation. Investment in routine HPLC and NMR analysis pays for itself, especially in long project cycles where small impurities can disrupt later-stage chemistry. My recommendation is to schedule regular reviews with quality assurance teams, cross-checking sample identity and purity against supplier documentation. This reduces surprises and makes troubleshooting more targeted if a batch ever falls outside agreed parameters.
Pharmaceutical innovation thrives on structural diversity: the more ways to modify a scaffold, the faster a team can iterate potential drug candidates. 2-amino-5-bromo-6-methylpyridine enters the picture right at the front. It allows medicinal chemists to append unique pharmacophores or install metabolic handles at will, cutting down the journey from idea to proof-of-concept compound. Over time, this enables better compound libraries—each new analog expands project options for both primary and backup leads. Companies investing in molecular diagnostics, advanced sensors, or performance materials use this pyridine to trial new functional systems with minimal development lag.
Its flexibility plays a clear role outside pharma. Teams designing next-generation OLED emitters, functional polymers, or specialty adhesives use the compound to introduce both activity and selectivity. In those fields, minor modifications to core structures translate to big shifts in performance. Over multiple product cycles, people working with 2-amino-5-bromo-6-methylpyridine integrate it seamlessly with available process lines, avoiding costly retrofitting or shutdowns. That’s a real advantage in industries where capital budgets leave little room for error or unnecessary downtime.
No replacement exists for hands-on learning and shared experience. Feedback from colleagues across process chemistry, analytical support, and regulatory affairs shaped my approach to sourcing and working with advanced pyridine intermediates. A few habits stand out. Work closely with suppliers before placing large orders, so you can review batch quality up front. Push for detailed analytical reports and maintain overlap with your in-house testing, building a feedback loop between bench and procurement to spot issues before they escalate. Regular review sessions with R&D teams help transfer observations from small-scale trials to commercial production without skipping crucial checks.
Managing storage and reactivity in a shared-lab environment means setting up clear signage, shared protocols, and scheduled stock reviews. This keeps risk low and keeps projects running without the bottleneck of out-of-date stock or missing certificates of analysis. For multinational teams, standardized documentation across sites allows transfer of lessons learned without relying on informal channels—an overlooked factor when scale-up crosses regulatory borders.
Chemistry doesn’t exist in a vacuum. As expectations for cleaner, smarter, and more efficient syntheses grow, intermediates like 2-amino-5-bromo-6-methylpyridine fit with new realities. My career tracked shifts from one-off discovery to high-throughput campaigns, and sustainable process scaling. Compounds with proven reliability, cleaner reactivity, and broad applicability allow researchers to pivot quickly between targets, explore uncharted chemical space, and rise to new industry standards. Regular communication between bench scientists, process engineers, and compliance professionals creates a robust ecosystem where successful outcomes build on trust and transparency instead of guesswork.
The world of specialty chemicals changes fast, and those who build their strategies on experience, shared learning, and open data keep pace. Whether the aim is to synthesize new medicines, push the limits in functional materials, or modernize agricultural chemistry, intermediates like 2-amino-5-bromo-6-methylpyridine serve as critical links in the value chain. Every successful innovation rests on the backs of building blocks that perform reliably, safely, and efficiently. Drawing on years of direct work with these compounds, the lesson is clear: thoughtful design in the lab leads to lasting success in the field and in the marketplace, turning incremental improvements into measurable gains for science and industry alike.
