|
HS Code |
457203 |
| Chemical Name | 2-Bromo-5-Amino Pyridine |
| Cas Number | 19798-80-8 |
| Molecular Formula | C5H5BrN2 |
| Molecular Weight | 173.01 g/mol |
| Appearance | Light brown to beige solid |
| Melting Point | 62-66°C |
| Purity | Typically ≥98% |
| Solubility | Soluble in organic solvents like DMSO and methanol |
| Density | 1.77 g/cm³ (approximate) |
| Smiles | NC1=CC=NC(Br)=C1 |
| Synonyms | 2-Bromo-5-pyridinamine |
As an accredited 2-Bromo-5-Amino Pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 2-Bromo-5-Amino Pyridine, 25g, is packaged in a sealed amber glass bottle with a secure screw cap and clear labeling. |
| Container Loading (20′ FCL) | Container loading (20′ FCL) of 2-Bromo-5-Amino Pyridine ensures secure packing, efficient space utilization, and protection during international transit. |
| Shipping | 2-Bromo-5-Amino Pyridine is shipped in tightly sealed containers, protected from moisture and light. Packaging typically complies with hazardous materials regulations, using amber glass bottles or inert plastic. All shipments are accompanied by safety data sheets (SDS) and labeled according to chemical hazard guidelines to ensure safe transportation and handling during delivery. |
| Storage | 2-Bromo-5-Amino Pyridine should be stored in a tightly sealed container in a cool, dry, well-ventilated area away from moisture, heat, and incompatible substances such as strong oxidizing agents. The storage area should be clearly labeled, and the chemical should be kept out of direct sunlight. Personal protective equipment (PPE) should be used when handling to avoid exposure. |
| Shelf Life | 2-Bromo-5-amino pyridine should be stored in a cool, dry place and typically has a shelf life of two years. |
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Purity 98%: 2-Bromo-5-Amino Pyridine with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and product consistency. Melting Point 69°C: 2-Bromo-5-Amino Pyridine featuring a melting point of 69°C is used in the preparation of heterocyclic compounds, where it enables precise thermal processing. Molecular Weight 173.02 g/mol: 2-Bromo-5-Amino Pyridine having a molecular weight of 173.02 g/mol is used in agrochemical research, where it facilitates accurate formulation of lead compounds. Particle Size ≤50 μm: 2-Bromo-5-Amino Pyridine with a particle size of ≤50 μm is used in fine chemical production, where it promotes uniform dispersion in reaction mixtures. Stability Temperature up to 120°C: 2-Bromo-5-Amino Pyridine stable up to 120°C is used in industrial catalysis, where it maintains chemical integrity under processing conditions. Water Content ≤0.3%: 2-Bromo-5-Amino Pyridine containing water content ≤0.3% is used in API manufacturing, where it minimizes side reactions caused by moisture. |
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In the world of organic synthesis, certain building blocks hold a reputation for enabling real breakthroughs. 2-Bromo-5-Amino Pyridine belongs to that group—not just another chemical compound, but a staple in labs where precision and reliability drive innovation. For researchers seeking purity in their work, this pyridine derivative stands out because of its unique structure and the possibilities it unlocks. As someone who’s spent hours in research facilities, I’ve learned that the right chemical isn’t just about meeting project requirements; it’s about anticipating what the next experiment demands, and 2-Bromo-5-Amino Pyridine fits that mindset.
Let’s strip away the jargon. 2-Bromo-5-Amino Pyridine is a heterocyclic aromatic compound with a bromine substituent at the 2-position and an amino group at the 5-position. With this configuration, the molecule is ready for wide-ranging chemical reactions. Whether you’re building more complex pharmaceuticals, designing advanced agrochemicals, or exploring the latest in material science, this compound does more than occupy shelf space.
Chemists recognize 2-Bromo-5-Amino Pyridine by its pale yellow crystalline appearance. The chemical formula C5H5BrN2 and molecular weight around 173.01 g/mol place it squarely in the world of advanced intermediates. It comes in a range of purity levels, but when you want confidence in results, the 98%+ grade earns top marks. Each batch brings with it minimal moisture and low impurity levels, pushing aside the unpredictability that too often plagues research and development.
Researchers love options, but options only matter if they bring something new to the bench. 2-Bromo-5-Amino Pyridine’s real edge comes from how the bromine and amino groups open doors. The bromine atom activates the compound for further transformations like Suzuki and Buchwald–Hartwig couplings, lending itself to complex scaffold construction. The amino group, on the other hand, allows for nucleophilic additions, condensation reactions, and more. This combo isn’t typical in pyridine chemistry, and it makes a difference for scientists driven by curiosity and a need for reproducible success.
Experience in the lab shows that 2-Bromo-5-Amino Pyridine often helps streamline total syntheses. For example, its reactivity profile reduces the number of steps in heterocycle formation, cutting down time and resources. In many of my own projects, finding a starting material with clear, reliable reactivity can be the difference between wasted weeks and rapid progress. Colleagues from medicinal chemistry echo this: incorporating the compound at the right step has clarified target molecule assembly and boosted both yield and purity.
Most new drugs on the market trace their origins through a maze of intermediates, and 2-Bromo-5-Amino Pyridine finds regular use in the early stage synthesis of kinase inhibitors and anti-infective agents. Medicinal chemists depend on the compound when constructing pyridine-containing drugs. The rigid framework the pyridine ring offers adds stability and helps guide pharmacological properties, and bromine’s presence allows modular functionalization, especially for late-stage diversification. Over the past decade, more pharma teams have adopted it to speed up lead optimization, minimize by-products, and sharpen their quality control.
Chemical Research and Material ScienceIn academic research, the compound acts as a springboard for pushing the boundaries of molecular design. Material scientists integrate it into ligands and functionalized polymers, banking on its electronic features to fine-tune advanced materials. With so much riding on reproducibility, supply consistency helps maintain the integrity of comparative studies. During my time supporting grant-driven university projects, researchers relied on dependable intermediates to keep timelines intact and data credible. The flexibility of 2-Bromo-5-Amino Pyridine lets investigators move from small exploratory runs to multi-step protocols, all without hunting for alternatives after each breakthrough.
Chemical Manufacturing and Scale-UpMoving discoveries from gram-scale to pilot plant often exposes the hidden flaws in starting materials. Suppliers offering 2-Bromo-5-Amino Pyridine in bulk quantities with stable specification testing help keep manufacturing lines running. Technical teams benefit from substances that dissolve predictably in standard solvents like ethanol, DMF, or DMSO. Temperature stability and manageable safety profiles ensure less down-time and fewer surprise hazards. Having been caught in delays when a key intermediate failed to meet specification, I appreciate clean documentation, reliable COAs, and vendors who provide transparent origin and testing details.
There’s a crowded field of pyridine intermediates, but each one tells a different story through its reactivity. 2-Bromo-5-Amino Pyridine competes mainly with 2-Chloro-5-Amino Pyridine, 3-Bromo-5-Amino Pyridine, and their methylated cousins. The bromine atom brings unique benefits compared to chlorine or fluorine analogues. Bromine’s size and moderate leaving group ability make for smoother coupling reactions, so you end up with higher yields and less painstaking cleanup. In contrast, chloro analogues tend to stall or require harsher conditions, introducing risk for sensitive functional groups downstream.
Mono-substituted pyridines with only amino substituents don’t deliver the same kind of flexibility. They support some direct functionalization, but without the activation provided by a second halogen group at the ortho-position, the scope narrows. Those looking for quick path to arylated, alkylated, or tailored heterocyclic systems find more success building off 2-Bromo-5-Amino Pyridine than from simpler analogues.
Even closely related isomers like 3-Bromo-5-Amino Pyridine behave differently in cross-coupling, with selectivity, solubility, and by-product formation diverging at critical points. Structure-reactivity relationships confer distinctive advantages or complications depending on the research task. Choosing 2-Bromo-5-Amino Pyridine over its peers often streamlines both retrosynthesis and purification, a lesson I witnessed firsthand in multi-year projects involving analog optimization.
A product's value only comes alive in the hands of the people using it. Scientists rely on batch-to-batch consistency, clear labeling, and transparent origin because even minor discrepancies can shake confidence in data. In the current research climate, traceability isn’t a luxury—it’s expected. When institutions look for chemicals, it's not just the molecule they're buying, but also the history of its creation and the processes keeping it pure. After years sifting through supply options and navigating audits, I've learned that dependable paperwork and fully declared certificate of analysis can save entire research cycles.
Logistics play a role, too. Researchers juggling multiple projects need compounds with reasonable lead times and stable shelf-life. Small differences in packaging—airtight seals, correctly sized vials—prevent waste or degradation, keeping resources focused on discovery rather than troubleshooting. Based on personal experience managing shared research inventory, even the best chemical loses value in a damaged bottle, so careful supply chain handling directly affects results.
Safety practices aren’t an afterthought—each new chemical brings its own set of precautions. 2-Bromo-5-Amino Pyridine follows patterns common among aromatic amines and brominated heterocycles. Standard procedures call for gloves, goggles, and fume hoods. Chemical stability eases operation, reducing incidents caused by decomposition or unexpected reactivity under regular storage. Disposal guidance removes headaches for both compliance officers and bench scientists, letting teams focus energy on experimental questions instead of regulatory loopholes.
Over the years, one of the ways I’ve avoided costly shutdowns has been through regular safety briefings and open communication around new materials. This philosophy translates well to 2-Bromo-5-Amino Pyridine—teams that take the time to review documentation, implement basic personal protective habits, and keep up a clean workspace report fewer accidents and less contamination-related downtime.
Rules around chemical sourcing, transportation, and end-use have tightened in recent years. Making sure 2-Bromo-5-Amino Pyridine comes from suppliers who understand global regulations reduces surprises at customs and in legal audits. Regulatory compliance doesn’t just protect organizations—it also accelerates collaborations, since partners expect robust product stewardship. Successful projects balance effective science with traceable, documented procurement, seamlessly integrating new intermediates without incurring red tape.
Working with regulatory affairs professionals on cross-border research, I’ve come to appreciate suppliers who not only respond quickly to document requests but also anticipate new requirements on the horizon. This professional vigilance boosts both confidence and operational speed, minimizing friction in high-stakes innovation pipelines.
Green chemistry has transformed how chemical intermediates are evaluated. 2-Bromo-5-Amino Pyridine is part of a larger conversation about minimizing hazardous waste, reducing the use of heavy metals, and improving atom economy. Forward-thinking suppliers work with process chemists to increase reaction yields, recover solvents, and manage by-products responsibly.
In research discussions about sustainability, choosing a compound with broad, efficient reactivity means less solvent and fewer reagents are needed to reach the end product. Cleaner reactions translate into smaller environmental footprints and less strain on waste disposal systems. I remember fielding questions from energetic graduate students on ways to maximize the utility of every starting material; their drive to combine scientific progress with environmental stewardship reflects the priorities of a new generation.
As regulations target halogenated waste, responsible teams look for intermediates that won’t create a headache down the line. 2-Bromo-5-Amino Pyridine’s reactivity makes it possible to design routes that avoid excessive side product formation, reduce purification steps, and keep emissions under control.
No compound is perfect, and 2-Bromo-5-Amino Pyridine presents its own challenges. The presence of both bromo and amino groups can participate in unintended side reactions if conditions aren’t carefully controlled. Handling moisture-sensitive intermediates means keeping a rigorous eye on storage conditions. While it dissolves in common organic solvents, incompatibilities with certain reaction partners sometimes call for re-optimization of long-standing methods.
Working in diverse research settings has shown me that flexibility is key. Teams routinely revisit and revise their methodologies based on what the molecule signals during development. Keeping detailed notebooks, staying close to the literature, and maintaining open lines to technical support helps avoid pitfalls and maximize the potential of each intermediate, including this one.
There’s also opportunity for future development. Researchers continuously explore greener ways to prepare the compound, aiming for processes that require less energy, produce fewer by-products, and source raw materials from sustainable origins. This drive reflects a broader shift across specialty chemicals, one that brings together synthetic efficiency, ethical sourcing, and social responsibility.
Ultimately, the value of 2-Bromo-5-Amino Pyridine lies far beyond its catalog entry. Its unique attributes help build cancer therapies, unlock agricultural innovations, and propel material science breakthroughs. Years working alongside diverse research teams have taught me that access to well-characterized, dependable intermediates is a prerequisite for competitive science. The right product in the right hands doesn’t just accelerate projects; it often determines whether projects succeed at all.
Every discovery builds on hundreds of micro-decisions: which starting material, which reaction path, which purification technique. Choosing 2-Bromo-5-Amino Pyridine gives teams an edge in assembling complex molecules, optimizing lead candidates, and reducing resource bottlenecks. In a field where trust underpins productivity, researchers benefit most from chemical suppliers who keep their promises, maintain high standards, and listen to user feedback.
One overlooked contributor to this compound’s success is the scientific community itself. Forums, conferences, and open-access publications allow researchers to share tips, flag problems, and update recommended practices. As a frequent participant in knowledge exchanges, I see the compound show up in case studies on optimizing cross-coupling, improving yield, and diversifying molecular frameworks. This crowd-sourced expertise keeps best practices moving forward, helping both novice and seasoned chemists avoid mistakes and build on recent advances.
Supplier transparency amplifies this process. Partners who publish up-to-date testing modalities, application notes, and common troubleshooting steps foster an environment where users learn quickly and contribute fresh solutions. The combined efforts of technical support teams and end users drive more efficient adoption and widespread improvement.
For labs encountering inconsistent purity, establishing an internal check with thin-layer chromatography or HPLC can quickly flag problematic batches. Maintaining separate storage under inert atmosphere can prolong shelf life and eliminate issues with hydrolysis or oxidation. Training sessions on coupling reaction design, including careful temperature control and stoichiometry, reduce the noise from side products and raise confidence in reproducibility.
Working in partnership with trusted suppliers, research organizations can set up standing orders to buffer against global supply fluctuations. This minimizes project slowdowns while keeping inventory costs manageable. Collaboration with technical support to troubleshoot tricky reactions speeds up iterative cycles, freeing staff to pursue bigger challenges.
The next decade will see specialty chemicals like 2-Bromo-5-Amino Pyridine move even further into the spotlight, supporting artificial intelligence-driven chemistry, sustainable drug design, and high-performance material discovery. As research goals grow more complex, the value of proven, reliable intermediates only increases.
Whether you’re an experienced chemist looking to streamline synthesis or a newcomer balancing cost constraints and project deadlines, the choice of starting material has ripple effects across the lab. In my years turning research plans into tangible outcomes, I’ve found that substances with well-documented behavior—supported by genuine user experience and open information exchange—form the backbone of both basic and applied discoveries.
