|
HS Code |
602968 |
| Product Name | 2-Chloro-5-Amino-6-Methylpyridine |
| Cas Number | 22280-44-6 |
| Molecular Formula | C6H7ClN2 |
| Molecular Weight | 142.59 g/mol |
| Appearance | Light brown to beige solid |
| Melting Point | 88-92°C |
| Boiling Point | Unknown |
| Purity | Typically >98% |
| Solubility | Slightly soluble in water; soluble in organic solvents |
| Smiles | CC1=CC(=NC=C1N)Cl |
| Inchi | InChI=1S/C6H7ClN2/c1-4-2-5(7)9-3-6(4)8/h2-3H,8H2,1H3 |
| Storage Temperature | Store at room temperature |
| Hazard Statements | May cause skin and eye irritation |
As an accredited 2-Chloro-5-Amino-6-Methylpyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Brown glass bottle labeled "2-Chloro-5-Amino-6-Methylpyridine, 25g" with hazard symbols, lot number, and safety information printed. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-Chloro-5-Amino-6-Methylpyridine: Typically packed in 25kg bags/drums, max 14-16MT per 20′ container. |
| Shipping | **Shipping Description:** 2-Chloro-5-Amino-6-Methylpyridine should be shipped in tightly sealed containers, protected from physical damage and moisture. Handle as a hazardous chemical, complying with all local, national, and international transport regulations. Appropriate labeling, including hazard symbols and UN identification, is required. Shipment may require documentation such as an SDS and appropriate shipping papers. |
| Storage | Store **2-Chloro-5-Amino-6-Methylpyridine** in a tightly sealed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizers. Protect from moisture, heat, and direct sunlight. Keep container clearly labeled and avoid contact with skin and eyes. Use appropriate personal protective equipment (PPE) when handling the chemical. Store according to local regulations for hazardous chemicals. |
| Shelf Life | 2-Chloro-5-Amino-6-Methylpyridine typically has a shelf life of 2-3 years if stored in a cool, dry place. |
|
Purity 99%: 2-Chloro-5-Amino-6-Methylpyridine with purity 99% is used in API intermediate synthesis, where high-purity ensures minimal impurity profile in final pharmaceutical compounds. Melting point 110°C: 2-Chloro-5-Amino-6-Methylpyridine with a melting point of 110°C is used in high-temperature chemical reactions, where thermal stability enhances process reliability. Molecular weight 142.58 g/mol: 2-Chloro-5-Amino-6-Methylpyridine with molecular weight 142.58 g/mol is used in custom ligand preparation, where precise stoichiometry supports accurate formulation. Particle size <50 μm: 2-Chloro-5-Amino-6-Methylpyridine with particle size less than 50 μm is used in catalyst fabrication, where fine dispersion increases catalytic efficiency. Moisture content <0.5%: 2-Chloro-5-Amino-6-Methylpyridine with moisture content below 0.5% is used in moisture-sensitive organic syntheses, where low water content prevents unwanted side reactions. Assay >98%: 2-Chloro-5-Amino-6-Methylpyridine with assay greater than 98% is used in dye intermediate manufacturing, where high assay boosts chromophore purity and intensity. Stability temperature up to 140°C: 2-Chloro-5-Amino-6-Methylpyridine stable up to 140°C is used in elevated temperature polymerization, where chemical integrity is maintained under process conditions. Residue on ignition <0.2%: 2-Chloro-5-Amino-6-Methylpyridine with residue on ignition less than 0.2% is used in electronic material synthesis, where low inorganic residue supports product quality. |
Competitive 2-Chloro-5-Amino-6-Methylpyridine 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!
For those who spend time in research labs, on production lines, or in technical support, chemicals aren’t just items on a list. They shape processes, results, and even the way teams approach new challenges. 2-Chloro-5-Amino-6-Methylpyridine has become one of those small compounds that makes a big difference in industries where precision and reliability matter. Known to many through its chemical formula, C6H7ClN2, this molecule takes on unique importance in pharmaceutical synthesis, agricultural research, and materials development.
Several years back, a colleague and I worked through a stubborn step in an intermediate synthesis. We tried alternatives, but ended up returning to 2-Chloro-5-Amino-6-Methylpyridine because of its dependable reactivity and clean handling. It can offer chemists a spot-on starting point when they need to introduce functional groups in a controlled manner. There’s nothing hypothetical about it: the compound lets teams scale up or down with predictable results. This feels especially important when every batch counts and reproducibility can’t be taken for granted.
Anyone who sorts through catalogs or speaks with chemical distributors knows the sea of pyridine derivatives can overwhelm. Some have benefits in one area but fall short in others. 2-Chloro-5-Amino-6-Methylpyridine often stands out because of its particular arrangement of substituents. The chlorine and amino groups, placed at the five and two positions, create just the right combination of electron richness and reactivity for targeted modifications. That methyl group at the six position isn’t just an afterthought; it shifts how the molecule interacts, opening options you won’t always get from more generic pyridines.
Through real-world lab work, these subtle differences become clear. If a project needs mild to moderate nucleophilic activity or a stepping stone toward more complex ring systems, many scientists choose this compound for its unique balance. Some similar molecules either lag behind in selectivity or complicate purification steps later on. Those extra washes or column runs add up in time and cost.
Purity often makes or breaks a project. In our group, we started requesting analytical data before every purchase. Quality batches of 2-Chloro-5-Amino-6-Methylpyridine usually clock in at a purity of 98% or above, with a controlled moisture profile that won’t get in the way of sensitive reactions. Most users find it arrives as a beige or off-white solid, sometimes crystalline depending on the supplier and handling methods. That solid state proves easier for weighing out and avoids the messier clumping from more hygroscopic variants.
Safety routines remain part of daily life in the lab, and this compound follows the playbook common to pyridine derivatives. It deserves careful respect: gloves and a fume hood aren’t up for negotiation. Good science means not cutting corners, and extra attention to ventilation or containment keeps health risks small. No compound is truly “safe” in a careless environment, but years of routine use with proper awareness have shown manageable profiles on this one.
Packaging tells its own story. Most suppliers settle on small amber bottles, sealed tight to keep light and humidity out. For teams with larger demands, custom bulk containers show up with secondary seals and robust labeling. These plain details support traceability and reduce contamination worries that come up in regulated pharma settings or food-grade work.
Few fields depend on reliable raw materials as deeply as pharma. A single hiccup in intermediate synthesis doesn’t just mean wasted compounds – it locks down timelines and impacts patient outcomes down the line. Over the past decade, this pyridine derivative carved out a role as an intermediate for molecules targeting a range of indications, from inflammation modulators to enzyme inhibitors.
Teams led by experienced medicinal chemists know that every atom affects efficacy and metabolism. The amino group brings new anchor points for further coupling, while chlorine can be swapped out or retained to fine-tune biological activity. Unlike many “off-the-shelf” building blocks, this one enables round-after-round of substitutions without the side reactions that plague bulkier or more reactive analogues.
In our early oncology projects, we encountered dead ends using other substituted pyridines. Some led to unpleasant byproducts or unpredictable color changes that signaled trouble. Switching to 2-Chloro-5-Amino-6-Methylpyridine offered a cleaner route – fewer surprises and a smoother path through scale-up. The real test came not on paper but at the bench, where yields held steady and analytical results proved convincing enough for regulatory submissions.
Scale-up means switching gears. Lab-scale reactions feel orderly and forgiving, but industrial runs bring out new variables – agitation, temperature profiles, and knock-on effects in downstream purification. I’ve seen process chemists insist on this compound because it tackles large-scale synthesis without excessive waste or need for complex stabilization steps.
In specialty chemicals or agrochemical fields, 2-Chloro-5-Amino-6-Methylpyridine helps form active ingredients, protective additives, and testing agents. The key is reliability across different production environments. Supply chains benefit from steady quality and clear documentation on origin, handling, and batch testing. Auditors aren’t just satisfied with COA paperwork – they want to see that every step ties back to a controlled feedstock, and this molecule often passes that test.
A few years ago, a manufacturing team grappled with an insecticide candidate. Early batches from a competitor’s substituted pyridine showed off-target contamination, requiring downstream rework. By switching to 2-Chloro-5-Amino-6-Methylpyridine, they tightened up the analytical specs, cut costs on reprocessing, and shortened their time to market. The story echoed in other sectors – sometimes, picking the right starting material sparks gains across the entire process.
Plenty of pyridine derivatives hit the market every year, and they aren’t created equal. For instance, 2-Amino-5-Chloropyridine and 2-Chloro-6-Methylpyridine show up as alternatives. Some feature a similar core, but the missing methyl or amino group limits their flexibility for further chemistry. I once tried building out a library using 2-Chloro-6-Methylpyridine. In certain steps, reaction rates lagged behind and required harsher conditions, nudging up the risk of degradation elsewhere in the molecule.
By comparison, the amplified reactivity of 2-Chloro-5-Amino-6-Methylpyridine balances straightforward substitution with respectable shelf-life. The methyl group brings just enough sterics to help steer reaction selectivity, while the amino group keeps options open for a range of nucleophilic substitutions. These tweaks, while subtle on paper, save hours or days at the bench in my experience. Less fuss with purification also means fewer headaches for quality control staff who track lot-to-lot consistency.
On the downside, some niche applications might benefit from a less reactive variant, and teams working on delicately balanced systems could reach for an alternative. For the lion’s share of research and production, though, this compound’s set of features wins out, especially when balancing reactivity, storage needs, and cost per gram.
Lately, talk about supply chain risk grew sharper, especially in regulated industries. What you don’t know about your raw materials can come back to bite. I’ve seen the headaches when off-spec batches arrive, or when a shipment’s provenance falls under question during an inspection. Chemical suppliers with the right controls set themselves apart. For 2-Chloro-5-Amino-6-Methylpyridine, a reliable partner should offer batch-level traceability, robust COA data, and quick answers to questions about synthesis routes or impurity profiles.
Quality management doesn’t stop at paperwork. Digital systems track every movement – from original synthesis to packaging and distribution – to limit the risk of mix-ups or contamination. Pharmacovigilance teams lean hard on this data during routine audits, confirming that no cross-contamination or adulteration slipped in. When a trusted lab outsources work, they want assurance that the core chemical meets expectations with every lot.
Experienced chemists know that trust is earned. Regular feedback with suppliers, test results from in-house QC labs, and open dialogue about new findings shape better partnerships. Some companies even visit production sites, ensuring their sources for 2-Chloro-5-Amino-6-Methylpyridine meet up-to-date Good Manufacturing Practice standards. This level of scrutiny forms the backbone of quality pharmaceuticals, safe crop inputs, and trustworthy specialty chemicals.
Modern users face a demanding mix of expectations: high purity, competitive pricing, and environmental mindfulness. Regulatory agencies ask tough questions about waste handling, emissions, and biodegradability. Our group explored greener routes while staying anchored in the chemistry. Newer synthetic methods, such as selective catalytic reactions or minimal-solvent batch processes, can shrink carbon footprints and reduce hazardous byproducts. Forward-looking suppliers invest in these tools as part of their pitch, while end-users ask for proof before making a switch.
In our own transition to greener practices, we evaluated each step where the compound might generate waste or create exposure points. Improvements showed up in solvent selection, closed transfer systems, or choosing alternatives with lower environmental persistence for routine cleaning. Responsible handling today means weighing not just productivity but the downstream impact. Many industries now consider life-cycle analysis in their supplier audits and internal reports.
For some, even small shifts – using less solvent, recycling mother liquors, adjusting temperatures to avoid excessive heating – can lower the footprint tied to 2-Chloro-5-Amino-6-Methylpyridine’s use and disposal. Startup teams and multinationals alike have begun to model the trade-offs and look for ways to keep performance without increasing regulatory risk or environmental liability.
Anyone who managed orders for critical molecules knows surprises can strike – shipping delays, customs hurdles, or a sudden spike in orders from an unexpected sector. Supply chain headaches don’t respect industry boundaries. As demand for 2-Chloro-5-Amino-6-Methylpyridine ramps up, sourcing teams often juggle the global and local. Local stock provides a buffer against freight slowdowns, but strategic global partners can step in during emergencies.
In the thick of the pandemic, we saw firsthand how even well-oiled supply lines could falter. Projects ground to a halt, and contingency plans started to look more important than ever. New partnerships formed, sometimes with regional manufacturers stepping in to stabilize sourcing. Relationships now weigh even heavier in purchasing decisions. A consistent supply of this key intermediate, backed by transparent communication and solid service, gives teams a fighting chance in uncertain times.
Teams who take a long view on supply chain risk incorporate dual sourcing, rolling inventory checks, and tight communication with suppliers. Efficient digital ordering systems, with instant feedback on stock and tracking, save wasted emails and guessing games. Reliable forward contracts and clear escalation paths for out-of-spec deliveries foster confidence even as market demand shifts.
The true value of 2-Chloro-5-Amino-6-Methylpyridine reveals itself clearly in day-to-day work. Colleagues from medicinal chemistry, analytical services, and production teams all have stories about a time when a reliable, well-characterized intermediate made the difference between success and delay. Over the years, feedback points to a few consistent themes: clean reactions, straightforward workups, and a safety profile in line with routine protocols.
A peer once commented that handling this compound became almost second nature, thanks to high lot-to-lot consistency and the expected physical properties. Rarely do you find a bottle with unexpected clumping, off colors, or unexplained mass discrepancies. Simple reliability matters to lab managers who want to avoid unscheduled downtime and keep costs predictable in an era of tight budgets.
Discussions with quality assurance professionals highlight the value of solid documentation. Access to up-to-date Certificates of Analysis, with genuine third-party validation and clear impurity data, eases regulatory concerns. More than one audit has been smoothed over by proactive documentation from reputable suppliers.
Market groups and analysts point out a steady uptick in demand for substituted pyridines. Reports highlight pharmaceuticals and agri-science as major growth drivers, but specialty chemical producers and materials scientists also continue to expand their use. Transparency in sourcing and a visible trace to the original producer now matter as much as cost in many tenders. The strength of 2-Chloro-5-Amino-6-Methylpyridine in this landscape isn’t just its molecular profile, but also its track record for reliability and adaptability to new research needs.
Anecdotes from purchasing meetings echo this shift. Buyers once focused narrowly on bottom-line pricing have started to weigh documentation, safety, and supplier reputation higher in their decisions. The risks that come with cutting corners far outweigh minor cost differences for most large users.
Industry publications from trusted chemical associations and patent databases show that research teams continue to explore new applications for this compound. Whether it serves as a key step in new drug modalities or supports testing material additives, its versatility continues to attract attention. Detailed patent filings reflect ongoing innovation and steady demand for high-purity batches.
As teams look ahead, best practices start with informed purchasing and responsible lab management. Building a checklist for quality markers, confirming traceability, and requiring consistent documentation strengthen each phase of a project. Engaging in open conversations with suppliers builds mutual trust and often uncovers new options for packaging, logistics, or alternative grades to fit unique project needs.
Regular training for lab staff – not just for safety but also for handling and optimal reagent use – pays off over time. New team members benefit from shadowing experienced coworkers during handling and weighing routines. Small practices, like sealing bottles promptly and storing away from direct light, protect product quality and extend reagent life between orders.
Bulk users find value in custom packaging solutions. Suppliers with agile packing lines can batch to non-standard volumes, reducing open-air exposure and waste. For distributed teams or multi-site organizations, harmonizing inventory tracking systems and standard operating procedures saves resources and eyes on the bigger picture.
Feedback loops from regular users have sparked several advancements. Some suppliers adjusted particle size based on how teams measured and dispensed the compound in automated setups. Others improved packaging seals after users flagged issues during humid summer months. This culture of responsiveness links researchers directly with manufacturers, leading to compound improvements that echo through the supply chain.
My own experience taught the importance of clear feedback. Flagging inconsistencies early gives suppliers a chance to adjust before any knock-on effects reach critical phases of a research program. The best suppliers actively encourage open communication, check in on new challenges, and keep teams informed about upcoming changes in sourcing or formulation.
New research is pushing boundaries for where 2-Chloro-5-Amino-6-Methylpyridine might play a role. With interest rising in precision agriculture, bioconjugates, and advanced materials, chemists are building out even more derivatives and applications. Advanced analytics, such as high-throughput mass spectrometry, now trace minute impurities and push for even higher purity standards than before.
Collaborations between universities and industry often lead to tweaks in synthesis or applications. Each annual conference brings updates on new coupling partners, more efficient routes for downstream intermediates, and insights into structure-activity relationships. The pace of innovation means established compounds stay in play, but creative teams may chart new uses as knowledge deepens.
Smart adoption of digital tools is changing how inventory moves and how teams connect with sources worldwide. Automated procurement, online tracking, and real-time purity analyses are making it easier to find the right grade at the right moment. As expectations rise, the companies who embrace these shifts will continue to serve the growing and changing needs of researchers and producers.
In the end, 2-Chloro-5-Amino-6-Methylpyridine earns its place not just through its well-understood chemistry, but by delivering on reliability, consistency, and adaptability. Years spent on both the research and production sides taught me the value of a high-purity, approachable intermediate that streamlines reactions and reduces uncertainty from step to step. In a world where new challenges emerge daily, trusted building blocks allow teams to move fast while meeting safety, quality, and regulatory requirements. As research continues and industries evolve, this compound remains a strong choice for those who value robust, hands-on solutions rooted in years of practical experience.
