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HS Code |
240711 |
| Chemical Name | 2-Hydro-5-Amino-Pyridine |
| Cas Number | 4214-76-0 |
| Molecular Formula | C5H6N2O |
| Molecular Weight | 110.12 g/mol |
| Appearance | Solid, typically off-white to light yellow |
| Melting Point | 122-125 °C |
| Solubility In Water | Moderately soluble |
| Purity | Usually ≥98% (commercially available) |
| Pka | Approximately 6.0 (for the amino group) |
| Synonyms | 5-Amino-2-hydroxypyridine |
| Storage Conditions | Store in a cool, dry, well-ventilated area |
| Smiles | c1cc(N)cnc1O |
As an accredited 2-Hydro-5-Amino-Pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 25 grams of 2-Hydro-5-Amino-Pyridine, sealed, labeled with hazard information and chemical identification. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-Hydro-5-Amino-Pyridine: Typically loaded in 25 kg bags/drums; approximately 14-16 metric tons per container. |
| Shipping | 2-Hydro-5-Amino-Pyridine is shipped in tightly sealed containers to prevent moisture and contamination. It is typically packaged in glass or high-density polyethylene bottles, cushioned within secondary packaging. Transport is conducted under ambient conditions, following local and international regulations for shipping specialty chemicals. Proper labeling and documentation ensure safe and compliant delivery. |
| Storage | **2-Hydro-5-Amino-Pyridine** should be stored in a cool, dry, and well-ventilated area, away from ignition sources, heat, and direct sunlight. Keep the container tightly closed and store separately from incompatible substances such as strong oxidizers. Ensure proper labeling and access to safety data sheets. Use original packaging or appropriate chemical-resistant containers to prevent contamination or degradation. |
| Shelf Life | Shelf life of 2-Hydro-5-Amino-Pyridine is typically 2 years when stored in a cool, dry, airtight container, away from light. |
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[Purity 99%]: 2-Hydro-5-Amino-Pyridine with purity 99% is used in pharmaceutical synthesis, where high purity minimizes byproduct formation and ensures consistent yield. [Molecular Weight 110.13 g/mol]: 2-Hydro-5-Amino-Pyridine of molecular weight 110.13 g/mol is used in laboratory research, where precise dosing facilitates accurate analytical results. [Melting Point 128°C]: 2-Hydro-5-Amino-Pyridine with a melting point of 128°C is used in solid formulation processes, where thermal stability maintains structural integrity during manufacturing. [Particle Size <50 Microns]: 2-Hydro-5-Amino-Pyridine with particle size less than 50 microns is used in fine chemical applications, where enhanced dissolution rates improve reaction efficiency. [Stability Temperature up to 100°C]: 2-Hydro-5-Amino-Pyridine with stability temperature up to 100°C is used in intermediate manufacturing, where thermal endurance reduces decomposition during processing. [Water Content <0.2%]: 2-Hydro-5-Amino-Pyridine with water content below 0.2% is used in moisture-sensitive syntheses, where low moisture prevents unwanted side reactions. [Chromatographic Grade]: 2-Hydro-5-Amino-Pyridine chromatographic grade is used in analytical method development, where high purity and consistency enable reproducible chromatography results. [Assay ≥98.5%]: 2-Hydro-5-Amino-Pyridine with assay greater than or equal to 98.5% is used in agrochemical research, where reliable concentration ensures standardization in testing protocols. |
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2-Hydro-5-Amino-Pyridine brings a specific kind of value to research and industrial processes. Over the years, I've watched the field of fine chemicals evolve, and compounds like this play a subtle but important role in shaping pharmaceuticals, dyes, and other advanced materials. This chemical, sometimes called 5-aminopyridin-2-ol in the lab, gives scientists a versatile starting point for a surprising range of syntheses. What stands out is how it combines a pyridine ring system with both an amino and a hydroxy group—two chemical groups that open doors for creating more complex molecules.
Let’s break it down simply. 2-Hydro-5-Amino-Pyridine looks almost unassuming on paper, but anyone who has worked in a laboratory can appreciate the perks built into this small molecule. The arrangement of its functional groups allows targeted reactions not always possible with plain pyridine or its other relatives. Adding a hydroxy group at position two tweaks the molecule’s electron distribution, helping with selectivity when you’re aiming for very specific reactions.
Comparison with generic aminopyridines or hydroxy derivatives can be enlightening. Take 2-aminopyridine, for example: without the hydroxy group, you get different reactivity. The added functionality of 2-Hydro-5-Amino-Pyridine broadens the toolkit for chemists who want better control during synthesis. Making a complex drug precursor can often turn into a puzzle, and finer control over reactivity saves time, money, and headaches. In comparison, some more basic analogues lead to unwanted byproducts or require extra purification steps just to get back on track.
The true test of any chemical’s worth comes from its daily use in the lab or plant. In my early research days, I worked with both generic aminopyridines and hydroxy-substituted compounds, but integrating amino and hydroxy groups into the same ring proved especially valuable for pharmaceutical intermediates. Manufacturers use 2-Hydro-5-Amino-Pyridine to build core structures of anti-infective agents, some promising oncology leads, and selective dyes.
Many specialty dyes and pigments demand high-purity starting materials. Here, this product’s chemical stability makes a difference. It resists unwanted oxidation during reaction steps, simplifying cleanup and improving batch yields. For people in pharmaceutical research, synthesizing an active ingredient often starts from such dependable building blocks. A few milligrams’ difference in purity can spell success or failure once you move from the glassware of the lab into larger process vessels.
Nobody who has struggled with repeat syntheses under deadline wants to juggle materials of uncertain quality. Reliable manufacture means a consistent melting point, controlled moisture content, and low levels of hazardous residuals. I’ve lost count of times an unreliable supplier or impure batch ruined a run—and it always comes down to these technical details. Workers and lab directors keep a close eye on values like assay percentage and impurity profiles, not because they’re on a checklist, but because the costs of inconsistency are real.
You won’t find every batch of 2-Hydro-5-Amino-Pyridine made equal. Quality producers offer detailed analytical reports—HPLC purity, trace metal content, and loss-on-drying numbers that can be double-checked before ordering. It goes beyond gaining peace of mind. These numbers tie directly to reproducibility in both discovery and manufacturing environments. If you’re planning to scale up, knowing a product’s physical and chemical specs gives you an edge in process development and helps avoid the costs of failed validations or production shutdowns.
The demands chemists face in drug development and dye synthesis leave little room for error. In small research outfits, time and inventory are both precious. Teams can’t afford to wade through batches that don’t hit spec or keep extra stock to make up for potential spoilage. Reliable quality here has direct consequences: less downtime, fewer failed syntheses, and smoother regulatory paperwork. In regulated fields like pharmaceuticals, proving every ingredient meets quality benchmarks isn’t just paperwork for the authorities—it means patient safety and drug effectiveness.
On the industrial side, cutting corners with low-grade aminopyridines doesn’t pay off. Reaction yields drop, byproducts multiply, and the separation steps become more demanding. The old adage holds true: you can’t polish a bad starting material into a good finished product. Many times, the only way forward is to choose an ingredient with both strict analytical controls and a proven track record. That’s where this compound’s consistent specs save the team time and the business considerable expense.
Buyers often fall into the trap of treating chemicals with similar names or CAS numbers as interchangeable. My own experience says otherwise. There’s a world of difference between generic 2-aminopyridine and this hydro-amino hybrid when your application needs a clean, efficient route to a diversified library of compounds. The additional hydroxy group offers more options for attaching new groups or chains to the pyridine ring, especially when designing molecules meant to mimic biological systems.
Consider the range of reactions possible. With just an amino group, certain protective steps become mandatory on the chemist’s part. Introduce the hydroxy group and you have both a donor and acceptor site, changing the game in heterocycle construction or cross-coupling reactions. In practical terms, you may sidestep complex protection/deprotection steps or cut down on multi-stage syntheses that eat up time and raw materials. I’ve seen seasoned chemists opt for this route, not out of brand loyalty, but because it saves labor hours and cuts out extraneous steps.
Many labs, including some I’ve worked with, want assurance the products they rely on will not compromise their environmental or occupational values. Sourcing reliable 2-Hydro-5-Amino-Pyridine is part of a larger commitment to safety and stewardship. Major suppliers invest in eco-friendly manufacturing, waste reduction, and safe handling standards. Choosing a source with these priorities supports both higher product quality and a reduced footprint on the environment.
Questions around sustainability and traceability have grown in the chemical sector. End users now ask about the origins of their raw materials and how they’re processed. Clear sourcing and testing information help research groups and businesses stay ahead of tightening regulations—an increasing necessity as nations revise environmental guidelines for high-use industrial chemicals. For consumers who value both research integrity and corporate responsibility, these factors guide purchase decisions as much as price and delivery timelines.
Suppliers market a lot of aminopyridine products, but real-world working conditions surface their differences. Some alternatives suffer from variable purity, unreliable shipping, or outdated safety documentation. I’ve seen purchasing agents get lured by low price tags, only to watch their projects bog down under lengthy quality investigations or lost batches. Not only does this drag down innovation, it creates real business risk.
High-performing derivatives like 2-chloro-5-aminopyridine or 2-methoxy derivatives have their uses, especially in specialty syntheses. Even so, each change to the pyridine ring shifts reaction outcomes in unpredictable ways. Anyone looking for a platform molecule that maximizes potential end products while keeping production complexity in check will find 2-Hydro-5-Amino-Pyridine more forgiving. It becomes a workhorse molecule—one that’s easy for analytical labs to test, well understood by synthetic chemists, and less likely to bite back with exotic side products or handling hazards.
More research labs fall under tighter regulatory scrutiny, with detailed tracking required for every input. Sourcing high-purity 2-Hydro-5-Amino-Pyridine with full analytical traceability smooths that compliance pathway. Regulations covering everything from pharmaceutical intermediates to specialty chemicals focus on verifying source, purity, and absence of hazardous contaminants. In practice, this means making purchase decisions with one eye on these requirements. A consistent supply with documented specifications can save months during audits or project reviews. Nobody wants a promising new compound blocked by an ingredient that lacks provenance or regulatory standing.
Besides legal mandates, there’s the matter of safety. Up-to-date safety data, batch records, and transparent supply chains help labs fulfill their own duty of care. In the experience of many who’ve survived project reviews or registration hurdles, preparing ahead always pays back double. Investing in ingredients that come supported by documentation isn’t just about jumping through hoops—it’s a practical defense against unforeseen delays or safety lapses.
The path from discovery to scalable manufacturing is rarely straightforward. Teams face enough obstacles: finicky reaction conditions, shifting budgets, regulatory delays, or sudden changes in customer demand. Something as basic as a reliable batch of an aromatic intermediate changes the game. In biotech and dye research, using a compound like 2-Hydro-5-Amino-Pyridine speeds up early-stage discovery. Instead of tinkering with inconsistent inputs, scientists can focus on designing better molecules or testing new ideas.
Innovation depends on one part inspiration, one part reliable materials. Streamlined access to versatile, well-characterized intermediates unlocks more time for problem-solving and taking risks. Some of the best breakthroughs in novel antibiotics or colorants started with well-chosen building blocks and careful planning. No team gets ahead by isolating minute quantities of starting material from unreliable stock. The modern research economy picks up speed only when basic materials keep pace.
Ongoing disruptions in global supply lines underscore the need for robust supplier relationships. Working in both small academic labs and larger industrial settings, I’ve seen how preemptive planning lowers risk. Reliable vendors of 2-Hydro-5-Amino-Pyridine help with inventory management, predictive lead times, and transparency if delays arise. Some suppliers have adopted just-in-time delivery schedules or consignment inventories on request. This builds flexibility into the system, keeping research and production from stalling due to missing chemicals.
For those who need more peace of mind, options exist. Signed quality agreements, batch reservation plans, and regular communication between users and suppliers all tighten operations. Buyers willing to partner closely with suppliers often secure early access to new batches or heads-up for possible supply disruptions. Tracking supplier reliability and making future orders from trusted sources creates an environment where mistakes get caught early and projects stay on schedule.
It helps to keep one’s own internal inventory records current and share key requirements directly with suppliers before placing large orders. Open lines of dialogue about upcoming project needs or possible new formulations help all sides adjust production in advance. Having these systems in place pays dividends during crunch times when demand for certain chemicals spikes across industries.
Nothing benefits science and manufacturing more than honest dialogue about what works and where problems emerge. Technical societies and industry forums have become meeting grounds where chemists share stories about sourcing, process bottlenecks, and small process tweaks that boost yields or save effort. As companies look for new downstream uses for 2-Hydro-5-Amino-Pyridine, sharing data and troubleshooting strategies helps all sides. My own learning curve flattened quickly once I started paying attention to lessons from others who had already picked through the potential pitfalls and found streamlined processes.
For teams considering bringing a new intermediate into their workflow, asking questions early is the norm. Is there a reliable analytical method for tracking purity? How stable does the material stay under typical storage and shipping conditions? What’s the best way to minimize exposure or contain dust during scale-up? Talking these issues through with suppliers, peers, or technical consultants saves energy and keeps everyone safer.
Discussion also pushes suppliers to improve—adding higher purity options, revising packaging to minimize waste, or exploring greener synthetic routes. The most engaged research groups not only buy what they need; they help nudge the whole ecosystem toward improvements that benefit wider sectors of chemical manufacturing and research.
2-Hydro-5-Amino-Pyridine stands as one of those quietly essential compounds that make future breakthroughs possible. Its specific molecular framework unlocks broad possibilities in synthetic chemistry, balancing reactivity with stability and offering a springboard for building advanced pharmaceuticals, dyes, and related chemicals. The challenges in maintaining consistent quality, transparent supply chains, and compliance with new regulations keep everyone alert, but the gains—in research speed, reduced risk, and product performance—make that effort worthwhile.
Manufacturers and research teams who recognize both the strengths and limits of this specialty intermediate can build smoother, more successful projects across disciplines. In my time bridging research and manufacturing, I’ve learned that even seemingly small choices of raw materials echo far forward into both product innovation and commercial success. That’s why careful sourcing, real-world testing, and open communication count—not just for project survival, but for future growth. As new uses for derivatives of 2-Hydro-5-Amino-Pyridine unfold in emerging fields, staying connected to both technical advances and responsible supply partners will underpin continued progress.
