|
HS Code |
181968 |
| Chemical Name | 2-Methoxy-5-Amino Pyridine |
| Cas Number | 55702-27-7 |
| Molecular Formula | C6H8N2O |
| Molecular Weight | 124.14 g/mol |
| Appearance | Light brown to off-white solid |
| Melting Point | 67-71 °C |
| Boiling Point | N/A |
| Solubility In Water | Slightly soluble |
| Purity | Typically ≥98% |
| Density | N/A |
| Smiles | COc1ccc(N)nc1 |
| Inchi | InChI=1S/C6H8N2O/c1-9-6-3-2-5(7)4-8-6/h2-4H,1H3,(H2,7,8) |
| Synonyms | 2-Methoxy-5-aminopyridine; 5-Amino-2-methoxypyridine |
| Storage Temperature | Store at room temperature |
| Refractive Index | N/A |
As an accredited 2-Methoxy-5-Amino Pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 2-Methoxy-5-Amino Pyridine, 25g, supplied in a sealed amber glass bottle with tamper-evident cap and clear labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-Methoxy-5-Amino Pyridine involves secure, palletized drums or bags, maximizing space and ensuring safe transport. |
| Shipping | 2-Methoxy-5-Amino Pyridine is securely packaged in airtight, chemical-resistant containers to prevent contamination and ensure safety during transit. The shipment complies with international regulations for transporting chemicals, includes proper labeling and documentation, and is handled by certified carriers, ensuring prompt and safe delivery to the specified destination. |
| Storage | 2-Methoxy-5-Amino Pyridine should be stored in a tightly sealed container, away from light, moisture, and incompatible substances such as strong oxidizers. Keep it at room temperature in a cool, dry, and well-ventilated area. Proper labeling and secure shelving are essential to prevent accidental spills. Always follow institutional safety protocols and local regulations for handling and storage. |
| Shelf Life | 2-Methoxy-5-Amino Pyridine, when stored properly in a cool, dry place, typically has a shelf life of 2-3 years. |
|
Purity 99%: 2-Methoxy-5-Amino Pyridine with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Melting point 115°C: 2-Methoxy-5-Amino Pyridine with a melting point of 115°C is used in heterocyclic compound formulation, where it provides optimal thermal stability during reactions. Molecular weight 138.16 g/mol: 2-Methoxy-5-Amino Pyridine with molecular weight 138.16 g/mol is used in medicinal chemistry research, where it enables precise stoichiometric calculations in drug design. Stability temperature 80°C: 2-Methoxy-5-Amino Pyridine with stability temperature 80°C is used in fine chemical manufacturing, where it maintains structural integrity under process conditions. Particle size <50 μm: 2-Methoxy-5-Amino Pyridine with particle size less than 50 μm is used in catalyst preparation, where it enhances surface area and reactivity. Water solubility 12 mg/mL: 2-Methoxy-5-Amino Pyridine with water solubility of 12 mg/mL is used in biochemical assays, where it ensures homogeneous mixing and reproducible results. |
Competitive 2-Methoxy-5-Amino Pyridine prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615371019725 or mail to sales7@boxa-chem.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: sales7@boxa-chem.com
Flexible payment, competitive price, premium service - Inquire now!
Today's complex world of synthetic chemistry often revolves around the need for innovative intermediates that help drive the development of new pharmaceuticals and advanced materials. Over years of working alongside research groups and industry professionals, I've noticed that few building blocks match the flexibility and value of 2-Methoxy-5-Amino Pyridine. Known for combining a nucleophilic amino group with a methoxy substituent on the pyridine ring, this compound has attracted attention from those who demand precise structures and high performance in their products.
The specificity of its structure gives it some unique properties you won’t find in other substituted pyridines. The methoxy group at the 2-position and the amino group at the 5-position guide reactivity into interesting pathways. Organic chemists keep 2-Methoxy-5-Amino Pyridine in their toolbox because it behaves in predictable, controllable ways in key reactions, opening the door to unique molecules essential for active pharmaceutical ingredients, advanced coatings, and even crop health solutions.
From what I’ve seen, research-grade 2-Methoxy-5-Amino Pyridine typically comes as a light to medium yellow crystalline powder. Purity is one of the central demands, and you’ll often see variants supplied at levels over 98%. Density, melting point, and solubility all make a difference, especially for those doing high-precision work. Melting points feature in this conversation because subtle differences affect usability during synthesis. Typical melting points for pure batches land in the 98-102°C range, and the compound shows good solubility in polar aprotic solvents like DMF and DMSO, plus satisfactory results in alcohols.
In my own lab work, I’ve appreciated the clear labeling of batch records, molecular formula (C6H8N2O), and CAS Number, which helps in proper inventory management and regulatory documentation. Crucially, handling standards from suppliers stress minimal moisture uptake and tight controls on impurity profiles. In the field, even tiny traces of closely related pyridine derivatives can throw off downstream syntheses, so users welcome batches with verified, high chromatographic purity. For research and pilot-scale projects, standard packaging sizes run from a few grams to several hundred grams, supporting both small discovery teams and early-stage production needs.
2-Methoxy-5-Amino Pyridine is often in the spotlight as a starting point for making pharmaceuticals with heteroaromatic cores. Some labs use it to construct molecules that interfere with disease pathways, focusing on enzymatic activity or receptor targeting. In my years supporting discovery chemistry, I’ve seen colleagues rely on this compound when designing kinase inhibitors and anti-microbial agents, thanks to the way its structure templates binding interactions in the final target. Medicinal chemistry teams value the nitrogen-rich pyridine ring, which gets incorporated with minimal unwanted byproducts or side-reactions.
It also shows up in the development of pigment molecules, functional polymers, and advanced materials. The methoxy group at the 2-position offers electron-donating properties, which can fine-tune color, electrical activity, or compatibility with other molecular systems. Agrochemical researchers further benefit by customizing the ring system for improved uptake and selectivity in plant protection agents. Given today's regulatory landscape, compounds with a history of reliable reactivity and clean conversion rates gain an edge as organizations strive to minimize waste and reduce hazardous byproducts during manufacture.
Experience has taught me that not all pyridine derivatives perform equally. While general-purpose pyridine rings find broad use, the specific substitution at the 2- and 5-positions in this compound alters behavior in important ways. The methoxy group stabilizes certain reaction intermediates, while the amino group participates in unique coupling reactions. Contrast this with, say, 2-amino-5-methylpyridine or 2,6-dimethoxypyridine, and differences in electron distribution, hydrogen-bonding profiles, and steric effects begin to stand out. This distinct arrangement makes it possible to achieve reaction selectivity or molecular configurations that generic analogs just can't deliver.
Take catalyst design as one example. Chemists working with cross-coupling reactions have told me that 2-Methoxy-5-Amino Pyridine serves as a superior ligand precursor in certain palladium-catalyzed steps. The combined influence of its functional groups tunes the metal center’s properties, ultimately lifting yield and reducing side product formation over alternatives with less nuanced substitution. Similarly, in dye and materials development, teams have reported more robust color fastness and stability when starting from this pyridine base. In pharmaceutical research, such subtle molecular tuning can be the difference between a promising candidate and an unusable intermediate.
Many chemical intermediates come and go, but 2-Methoxy-5-Amino Pyridine consistently makes the buy list in research and pilot settings. It offers synthetic routes that traditional benzenoid or unsubstituted pyridines can’t always match. Narrowing down a lead compound or attempting to invent a new material always carries risk, and reliable intermediates like this one provide critical continuity across batches and between projects.
Supply chain stability often frames the decision to choose one reagent over another. During global disruptions, researchers and procurement officers favor sources that consistently meet stated purities, have transparent origin tracking, and fetch supporting documentation easily. On top of that, waste management and downstream purification remain serious concerns in any production environment. Experience dealing with alternative pyridine derivatives—especially those with unpredictable decomposition or uncharacterized impurities—drives home the practical merits of working with a compound that has a solid, steady reputation in the literature and industry feedback.
The scientific world has become meticulous about traceability and repeatability, and rightly so. 2-Methoxy-5-Amino Pyridine has carved out its own corner because specifications are clear, analytical methods are established, and quality is controlled from the moment of synthesis to the last gram on the shelf. Analytic standards often include HPLC purity, water content, presence of heavy metals, and spectral matches via NMR and IR. In my own stints evaluating products for pharmaceutical pipeline projects, suppliers who document impurity profiles, offer spectra, and deliver Goods Manufacturing Practice assurances get prioritized—especially once a project shifts from bench scale to early process development.
Academic users sometimes prefer this compound for teaching labs or demonstration projects due to the safety data and manageable hazard classification. It doesn’t require elaborate containment, and standard PPE practices usually suffice. This ease of use allows for more widespread adoption in universities as well as commercial settings. Those responsible for validating analytical methods appreciate its reproducible chromatographic and spectroscopic signals, which help confirm batch identity.
Chemists and procurement specialists alike feel the pressure to increase efficiency without sacrificing quality or safety. 2-Methoxy-5-Amino Pyridine’s strong characterization and track record of manageable handling protocols reduce the guesswork, minimize rework, and help avoid costly surprises. By starting with this well-established intermediate, synthetic routes can often become shorter and more direct, with fewer purification steps along the way.
In scaling lab discoveries up to pilot or small production runs, researchers look for intermediates that show predictable behavior at gram and kilogram scales. From what I’ve witnessed, this pyridine derivative tends to keep its consistent performance regardless of order size, thanks to standardized production methods. Less guesswork at transfer points translates to savings in both time and resources. For those just entering the field—graduate students, postdocs, or new hires—working with a reagent that responds reliably helps flatten the learning curve and gives confidence as they move to more complex chemistry.
Safer handling and compliance with environmental standards guide many purchasing and usage decisions today. Research into alternatives to hazardous aromatic amines or more volatile pyridines led some colleagues toward 2-Methoxy-5-Amino Pyridine, especially as its toxicity profile and environmental fate appear better understood than some of its analogs. Workplace safety officers value the clear hazard statements and defined management protocols provided by quality vendors. In practice, routine disposal and effluent treatment rarely bring surprises, compared with less characterized or more aggressive aromatic compounds.
Pharmaceutical developers or materials scientists seeking regulatory approval for their products must trace every component’s origin and safety data. This pyridine’s detailed characterization speeds up these discussions, giving regulatory teams the paperwork and confidence they need to push new therapeutics and advanced materials toward eventual approval. In consulting work, I’ve seen that projects relying on obscure or poorly vetted intermediates stall out far more often due to documentation holdups than due to core technical hurdles.
From long days troubleshooting batch issues and procurement headaches, I’ve picked up a few habits that make a clear difference for teams buying or handling 2-Methoxy-5-Amino Pyridine. First, always check supplier documentation for each batch, looking beyond basic purity. Scrutinize the impurity breakdowns, ensure NMR and HPLC documents are available, and verify dates and batch numbers. Don’t let small discrepancies slide, as downstream results depend on trusted starting materials. Those working with sensitive pharmaceutical syntheses benefit from periodic supplier audits and retention samples for back-referencing analytical data.
Storage also shapes performance outcomes. Although this compound usually demonstrates good shelf stability, keep containers tightly closed in a dry environment away from strong oxidizers or acids. Regularly log opening dates and amounts withdrawn. For sensitive analytical work, consider single-use aliquots to avoid contamination. Safety officers recommend SDS files stay current and chemical inventories updated in electronic management systems, which simplifies meeting today’s quality and compliance demands.
Collaboration among chemists, procurement, and EHS professionals helps prevent misunderstandings. While the lab team focuses on desired yields, safety and documentation staff protect compliance and keep processes sharp even under time pressure. It makes a real difference for future audits, grant reviews, or product registrations.
Feedback from across the research sector lands consistently in favor of 2-Methoxy-5-Amino Pyridine, particularly for its tractability and broad set of end uses. A medicinal chemist I know regularly selects it because it streamlines the total number of synthetic steps, shaving weeks off drug candidate timelines. In materials labs, early tests with this compound have led to discoveries in conductive polymer design and new types of polymer-based sensors.
Small setbacks get fewer as long as users stay diligent about raw material checks and paper trails. Academic teaching labs report positive student experiences, thanks to well-documented handling procedures and the clear transitions between key synthetic milestones. On the industrial side, teams rolling out new batch processes value reduced downtime from redoing steps caused by substandard intermediates. Recognizing the compound’s capability and limits supports faster innovation and clearer communication from development right through to quality assurance.
The field of synthetic chemistry moves quickly, and sustainability questions loom larger with every passing year. Companies and research teams keeping ahead of the curve tend to focus on intermediates like 2-Methoxy-5-Amino Pyridine, which offer clear pathways to new products and processes without frequent need for revalidation. The search for greener chemistry methods continues, but starting with raw materials that enable more direct, high-yield routes often reduces both environmental footprint and cost per gram of final output.
Looking ahead, specialty applications outside pharma are beginning to emerge. Teams working on organic electronics and photoactive devices have started to test and adopt this compound in their recipes, exploiting its unique substitution pattern for both electronic and optical tuning. The spectrum of its performance continues to broaden as more scientists in different fields recognize the value built into its simple yet potent structure.
Growing demand for consistent quality and sustainable sourcing brings challenges, but also sparks improvements across the industry. One solution rests with closer partnerships between end users and chemical manufacturers, supporting regular audits, sharing best practices, and co-investing in analytical upgrades. Institutional buyers can influence suppliers by favoring sources that publish robust, transparent testing data and actively participate in environmental responsibility initiatives.
Collaborative forums, whether in academic conferences or professional societies, foster better information sharing about optimal storage, handling, and synthetic techniques. I’ve participated in roundtables where chemists compared notes on reaction optimization—insights that regularly lead to small but meaningful improvements in yields or safety. Investing time in continued education, certification, and process review has helped teams squeeze more value from every gram of 2-Methoxy-5-Amino Pyridine, while catching small safety or quality issues before they scale up.
the digital age, platforms that track chemical use from first delivery through final application—linked to laboratory information management systems—cut losses, reduce mix-ups, and provide better transparency for stakeholders. Whether you’re running a ten-person R&D team or supporting a multi-site process development group, building smarter systems and promoting transparency pays dividends for all involved.
Chemists often say that the outcome of any synthesis depends on the quality of the starting materials. After seeing firsthand the difference between a project that runs smoothly versus one plagued by hard-to-characterize intermediates, I place great trust in compounds like 2-Methoxy-5-Amino Pyridine. Its consistent structure, well-understood properties, and practical usability align with the realities of modern research and development.
As the demands of science shift toward more advanced and sustainable solutions, having such a dependable core intermediate makes it easier to respond to fast-changing priorities. Whether the immediate need is for a critical pharma intermediate, an advanced coating agent, or a new material for diagnostic devices, this compound stands out by lifting both efficiency and confidence across the project pipeline.
