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HS Code |
284292 |
| Cas Number | 22280-99-1 |
| Molecular Formula | C6H7ClN2 |
| Molecular Weight | 142.59 g/mol |
| Iupac Name | 5-(aminomethyl)-2-chloropyridine |
| Appearance | White to off-white solid |
| Melting Point | 77-81°C |
| Solubility | Soluble in water and common organic solvents |
| Purity | Typically ≥98% |
| Storage Conditions | Store at room temperature, keep container tightly closed |
| Smiles | CNCC1=CN=CC(Cl)=C1 |
| Inchi | InChI=1S/C6H7ClN2/c7-6-2-1-5(3-8)4-9-6/h1-2,4H,3,8H2 |
| Synonyms | 2-Chloro-5-pyridinemethanamine |
As an accredited 5-Aminomethyl-2-chloropyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 5-Aminomethyl-2-chloropyridine, 25g, supplied in a sealed amber glass bottle with tamper-evident cap, labeled with hazard information. |
| Container Loading (20′ FCL) | 20′ FCL container holds 150-160 drums (25 kg each) of 5-Aminomethyl-2-chloropyridine, safely packed for export. |
| Shipping | 5-Aminomethyl-2-chloropyridine is shipped in tightly sealed containers, protected from moisture and light. It is typically dispatched as a solid or solution, labeled according to hazardous material guidelines. Transport follows local and international regulations to ensure safety, with documentation provided for proper handling, storage, and emergency procedures during transit. |
| Storage | 5-Aminomethyl-2-chloropyridine should be stored in a cool, dry, and well-ventilated area, away from heat and sources of ignition. Keep the container tightly closed and protected from direct sunlight and moisture. Store separately from strong oxidizing agents and acids. Use appropriate chemical-resistant containers and ensure label visibility. Handle in accordance with standard laboratory safety procedures. |
| Shelf Life | 5-Aminomethyl-2-chloropyridine has a shelf life of typically 2-3 years when stored tightly sealed at room temperature, protected from moisture. |
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Purity 98%: 5-Aminomethyl-2-chloropyridine with purity 98% is used in pharmaceutical intermediate synthesis, where high chemical yield and selectivity are achieved. Molecular Weight 144.59 g/mol: 5-Aminomethyl-2-chloropyridine with molecular weight 144.59 g/mol is used in agrochemical development, where consistent molecular performance enables effective herbicidal formulations. Melting Point 75°C: 5-Aminomethyl-2-chloropyridine with a melting point of 75°C is used in solid-phase organic synthesis, where enhanced thermal processing stability is ensured. Water Solubility 10 mg/mL: 5-Aminomethyl-2-chloropyridine with water solubility of 10 mg/mL is used in analytical reagent preparation, where rapid solution preparation and reactivity are facilitated. Stability Temperature up to 120°C: 5-Aminomethyl-2-chloropyridine with stability temperature up to 120°C is used in high-temperature catalysis research, where chemical integrity is maintained during reaction cycles. |
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If you have ever worked in pharmaceutical research or chemical synthesis, the name 5-Aminomethyl-2-chloropyridine probably rings a bell. This compound isn’t just another raw material on a long list of laboratory inventory—it plays a real part in everyday progress across multiple industries. Its practical value has unfolded over years as professionals look for ways to streamline drug design, develop agricultural treatments, and push the limits of chemical innovation. While it may not make headlines like new blockbuster medicines or eco-friendly biofuels, its role behind the scenes is undeniable.
With a chemical structure built around a pyridine ring, a chlorine atom, and an aminomethyl group, 5-Aminomethyl-2-chloropyridine manages to walk a fine line between reactivity and selectivity. In the working world, this matters. Labs need compounds that hold up under varied reaction environments, especially during those painstaking steps of synthesis when yields, purity, and reliability matter most. Handling 5-Aminomethyl-2-chloropyridine has taught me that attention to detail in storage and measuring makes for smoother running experiments, fewer surprises, and less waste. The smell alone can remind you that chemistry is not always neat, but careful handling limits cross-contamination.
Researchers and developers often choose this molecule for two big reasons: it is a strong building block for drug development and a reliable intermediate for fine chemical synthesis. In many of my experiences, it helped create active pharmaceutical ingredients, providing a crucial scaffold for attaching more complex groups. Take, for example, the pressure to accelerate the route to a clinical candidate. Speed matters, and inefficiencies can derail months of work. Using 5-Aminomethyl-2-chloropyridine as an intermediate kept reaction pathways shorter and purification steps more manageable.
Medicinal chemists also use it as a springboard, exploiting the dual capacity of the aminomethyl and chloro positions to carry out further modifications. This feature makes it possible to access a broader spectrum of products, especially when you need to fine-tune biological activity or physical properties. Over the years, as the pressure for customized solutions has increased, I found this flexibility more valuable than any single performance metric. It made life easier, especially for those striving to develop not only the next hit compound, but one that passes regulatory, safety, and performance hurdles too.
Like any expert, I’ve tried different pyridine-based intermediates. Some show off high reactivity but break down in the later stages. Others linger in solution, requiring extra work to clean up. What surprised me with 5-Aminomethyl-2-chloropyridine is how its specific substitution pattern offers just enough reactivity without creating a mess downstream. The chloro group at the 2-position opens the door for nucleophilic substitutions, while the aminomethyl group acts as a versatile handle for coupling reactions. Side-by-side in the lab, some structurally similar compounds struggle to deliver the same level of performance in certain reactions—especially those dependent on selectivity or reaction rate.
Comparisons don’t end in the test tube. When evaluating scale-up potential for pilot plant work, issues like thermal stability and solubility come to the forefront. I've watched batches of other pyridines degrade before reaching full conversion or requiring expensive solvents just to get things moving. This compound, by contrast, delivered a more predictable performance. Working on teams pressed for cost efficiency, that reliability reduced both downtime and process troubleshooting. These details rarely feature in textbooks, but they shape decision-making on the ground.
Research papers and patents offer perspective, but real insight comes from repeated use. Reliable purity grades, consistent melting points, and clean NMR spectra don’t just make purchasing easier—they build trust between end users and suppliers. Analytical data, from IR spectra to LC-MS readings, consistently confirm the quality of well-made 5-Aminomethyl-2-chloropyridine. Over years of method development, working with this compound has shown me that not all sources deliver the same level of consistency. I recall instances where a change in supplier led to shifts in reaction yields. The required scrutiny may slow things down, but it prevents repeat mistakes.
Even reputable suppliers sometimes slip, and returns or rework cases are part of the territory. In my direct experience, some smaller producers struggled with batch-to-batch reproducibility, while established firms held tighter controls on impurity profiles. Those who spend time with analytical methods appreciate the confidence that comes from matching every signal with expected values. It reduces risk, encourages process optimization, and helps meet the ever-rising expectations of regulatory audits. If there is a secret to success in R&D, it comes from never compromising on these details.
Experience taught me that improper storage can turn a valuable intermediate into a liability. Light, heat, and moisture all play a role—so shielding supplies from sunlight, keeping temperatures moderate, and using desiccants makes a difference. Working with 5-Aminomethyl-2-chloropyridine in a forgetful lab often led to discoloration or off-odors, sometimes sabotaging the intended reaction. No one enjoys tracing back a failed project to an avoidable storage mistake.
Lab safety also remains a priority. This substance, like many organics, can pose risks if not managed responsibly. Training new staff on the importance of gloves, eye protection, and effective ventilation prevents accidents and contributes to a safer work environment. Sharing these practices improves outcomes not only for the current batch, but for future projects. Teams that value these safeguards witness fewer interruptions and feel more confident in their results.
Globalization brought more choices, but also new challenges. Years back, I remember a scramble when a main supplier faced customs problems and shipments stalled. Sourcing options had to expand, yet quality assurance remained a must. The growing number of producers means buyers must balance cost with confidence. Transparency about synthetic routes, impurity thresholds, and environmental controls has improved, driven in part by increasing customer scrutiny and evolving regulations. These trends reflect a growing awareness among buyers that the cheapest option can cost more in the end.
Supply chain reliability doesn’t just affect the buyer—it ripples through to finished product launches and market schedules. I have lost count of the times a hold-up at the intermediate stage delayed an entire program. Talking with colleagues, the consensus was clear. Choosing robust suppliers, cultivating backup options, and making joint efforts to pre-empt shortages paid off, especially as demand from fast-growing sectors like pharmaceuticals and specialty chemicals outpaces traditional forecasting methods.
For many in the research and manufacturing world, the conversation around chemicals inevitably turns to sustainability. 5-Aminomethyl-2-chloropyridine serves as a good case study for this shift. In years past, few worried about green chemistry or waste management beyond basic compliance. Now, as pressure grows to reduce hazardous byproducts and minimize solvent use, developers look for intermediates that dovetail with these priorities. On my own projects, discussions about route selection included not only technical feasibility but the environmental cost of each step.
Efforts to reduce chlorinated waste, improve atom economy, and reuse solvents show up in every phase of a process where this intermediate appears. Manufacturers that invest in greener production methods and clearer waste management reports earn more trust. At the bench, I often faced the choice between a well-known route using this intermediate and a less-hazardous alternative. Often, the reliability and data track record kept 5-Aminomethyl-2-chloropyridine in play, but I have seen a shift toward methods that minimize its environmental impact by optimizing reaction efficiency and cleaning up effluents before they leave the plant.
Anybody who has been through a product launch or process scale-up knows the stress of meeting targets while safeguarding quality. Teams cannot afford uncertainties with key intermediates. 5-Aminomethyl-2-chloropyridine’s reputation for consistency—assuming the right supplier and proper controls—eases these pressures. In my work, long hours often meant relying on prior data, trusted partners, and a clear understanding of the molecule’s quirks. Quality assurance didn’t end at receiving inspection; in-process testing and periodic verification checks kept problems from snowballing.
Strategically, controlling a secure source of this compound allowed organizations to respond quickly to new opportunities. In one case, the ability to supply reliable lots of 5-Aminomethyl-2-chloropyridine led to a collaboration that opened up new potential applications. Investing in solid logistics and strategic sourcing became more than a defensive measure; it worked as a catalyst for innovation and market responsiveness. Collaborative relationships with suppliers and technical consultants often made the difference between seizing the moment and missing out.
Optimizing chemical processes is about balancing performance, cost, safety, and regulation. Starting materials like 5-Aminomethyl-2-chloropyridine are at the heart of these calculations. Sometimes hurdles come from scale-up, where what works in a flask falters in a reactor. I remember one process engineer struggling with heat transfer issues—increasing scale amplified problems hidden in initial trials. Addressing these pain points meant working closely with technical teams, leveraging shared experience, and not being afraid to revisit outcomes step by step.
Improvement followed where process monitoring and automation caught inconsistencies early. Making tweaks in purification, adjusting solvent ratios, or dialing in reaction time produced gains that paid off in both cost and reduced downtime. In the drive to find process improvements, I leaned on robust data—real, reliable numbers about purity, impurity levels, and reproducibility—rather than wishful thinking. Feedback from downstream users also shaped my thinking, since success relies as much on integration as on individual steps.
At first glance, an intermediate like 5-Aminomethyl-2-chloropyridine may look a few steps removed from finished products. This isn’t true for those who manage the transition from discovery to commercial launch. Each kilogram or liter of material purchased ripples through to final project costs, customer satisfaction, and competitive timelines. Fewer project delays translate into better results for everyone—from researchers under deadline pressure to procurement teams juggling supply contracts.
Having spent years watching the cascade effect of late deliveries or off-spec material, I’ve developed an appreciation for reliable sourcing and rigorous incoming inspection. The reality for many labs is that small failures add up, turning a promising project into a costly fire drill. Focusing on solid logistics, clear specifications, and open communication with suppliers limits these risks. Trust not only comes from a name or label but from proven performance and shared commitment to standards.
The story of 5-Aminomethyl-2-chloropyridine isn’t static. With advances in synthetic methodology, analytical science, and regulatory requirements, professionals must stay flexible. I have seen protocols shift as regulatory agencies tighten tolerances, or as new analytical tools provide deeper insight into trace impurities. This dynamic environment means the value of robust intermediates only grows.
Training programs for chemists and production staff now give more attention to fine points like trace metal content or isomeric purity. Periodic reviews of in-house methods and open discussions with suppliers keep everyone on their toes. The result has been a gradual move away from “good enough” thinking toward genuine continuous improvement. Those who thrive in this field use their experience as a toolkit to confront new challenges, without losing sight of hard-won lessons from the past.
While current offerings of 5-Aminomethyl-2-chloropyridine already meet the needs of many users, there’s space for progress. During team meetings, suggestions surface on refining synthesis for greener outcomes, improving pack sizes to reduce waste, and even offering more detailed impurity profiles. The appetite for change does not only come from outside regulation—users who rely on this compound daily often push for updates that make their work easier and safer.
Collaborative research between producers and end-users sparks the next wave of solutions. Even something as simple as clearer certificates of analysis or faster customer service can shift the balance when tight timelines threaten project completion. My own involvement in cross-functional improvement teams has shown that seemingly minor enhancements compound over time. Responding to issues quickly, taking user feedback seriously, and adopting new analytical standards all contribute to better results at bench, plant, and market levels.
Looking back, my journey with 5-Aminomethyl-2-chloropyridine reflects broader shifts in science, industry, and society. Decisions about sourcing, handling, and deploying chemical intermediates go beyond cost calculations. They shape scientific progress, product safety, and environmental stewardship. Relying on solid data, hard-earned experience, and honest communication delivered better outcomes than shortcuts or empty promises.
For professionals who invest time in understanding the subtleties of this molecule, rewards come in smoother projects, stronger partnerships, and reliable performance when it matters most. As trends evolve and markets shift, one thing remains clear—chemistry is as much about the people and processes as the molecules themselves. 5-Aminomethyl-2-chloropyridine stands as just one part of that larger story, but for those who rely on it, its importance runs deeper than any technical data sheet could suggest.
