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HS Code |
282757 |
| Chemical Name | 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine |
| Molecular Formula | C16H19ClN2O |
| Molecular Weight | 290.79 g/mol |
| Appearance | White to off-white solid |
| Solubility | Soluble in organic solvents (e.g., ethanol, chloroform) |
| Cas Number | 129722-12-9 |
| Structure | Contains a pyridine ring substituted by a benzyl group with para-chloro and 2-(dimethylamino)ethoxy substituents |
| Synonyms | Chlorpheniramine, p-Chlorpheniramine |
As an accredited 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25-gram amber glass bottle, tightly sealed, labeled with chemical name, CAS number, hazard warnings, and manufacturer’s information. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine ensures secure, efficient bulk transport in standard 20-foot containers. |
| Shipping | Shipping of **2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine** requires careful handling. The chemical should be packed in leak-proof, properly labeled containers, protected from light and moisture, and shipped in compliance with local, national, and international regulations for hazardous substances. Temperature control and documentation of chemical identity and safety data are mandatory. |
| Storage | Store 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine in a tightly closed container in a cool, dry, well-ventilated area, away from incompatible substances such as strong oxidizers and acids. Protect from light and moisture. Ensure proper labeling and use chemical-resistant shelving. Access should be restricted to trained personnel, and typical laboratory safety protocols should be observed during handling and storage. |
| Shelf Life | Shelf life: Stable for at least 2 years when stored in tightly closed containers, protected from light and moisture, at room temperature. |
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Purity 98%: 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine with 98% purity is used in pharmaceutical intermediate synthesis, where high chemical purity ensures maximum yield and low byproduct formation. Melting Point 145°C: 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine possessing a melting point of 145°C is used in solid formulation processes, where controlled melting behavior facilitates precise compound blending. Stability Temperature 60°C: 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine with a stability temperature of 60°C is employed in storage-sensitive formulations, where thermal stability minimizes degradation during handling. Particle Size ≤10 μm: 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine at ≤10 μm particle size is utilized in micronized drug delivery systems, where fine particle size promotes rapid dissolution and bioavailability. Viscosity Grade Low: 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine of low viscosity grade is applied in liquid-phase synthesis, where low viscosity enables efficient mixing and enhanced reaction kinetics. Assay ≥99%: 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine with assay ≥99% is used in analytical reference applications, where high assay value allows accurate quantification and reproducibility in laboratory analyses. |
Competitive 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine prices that fit your budget—flexible terms and customized quotes for every order.
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Around the chemical industry, people appreciate a product that delivers consistency through long production runs, even when conditions shift or the sourcing of raw materials occasionally presents a challenge. 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine fits into that category for us as a manufacturer on a daily basis. This compound takes effort to make right, and years of tinkering with process variables have made us keenly aware of what separates high-quality material from the mediocre. Being a direct producer—not a trader or distributor—means the journey from synthesis to finished bulk starts in our own reactors and stays in our control until the drum leaves our shipping dock.
The backbone of this molecule blends a pyridine structure with a substituted benzyl group. Maybe that sounds technical. In practice, for those working with intermediates or final compounds that require both reactivity and stability, this backbone gives a lot of flexibility. The chlorine atom on the para position and the dimethylaminoethoxy side arm add more than just weight—they translate to tuning points during further synthesis or in the context of applications in pharmaceutical or specialty chemical manufacturing.
Making this product isn’t just about following a recipe or tweaking the temperature knob. From firsthand experience, control of moisture during the critical formation step stops unwanted side reactions that would spoil both yield and purity. The type and age of catalyst, the sequence in which the amine and ether fragments enter the reaction, and steady monitoring of trace impurities in each feedstock, all these play a part. The end result: a crystalline white to off-white powder, packed on-site so neither contamination nor loss of quality creeps in before it ever leaves the facility.
Most end-users want numbers for purity and assay right at the top: typically we target not less than 98.5% by HPLC, with water by Karl Fischer under 0.3%. Those numbers sound reassuring alone, but running even one batch without careful stepwise drying or using solvents past their shelf-life proves that hitting those marks is never automatic. Color, melting point, particle form—these indicators let a seasoned operator know if a batch runs true. We believe strongly in batch traceability. Each drum we ship holds a record not just of date and origin, but operator and specific raw material lots used. That kind of knowledge, living in the records and in the heads of our shift team, keeps us honest and gives customers something to rely on.
The wide use of 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine stretches across multiple downstream processes: active pharmaceutical ingredients (APIs), specialty polymer additives, and chemical research all draw from this versatile intermediate. Our experience has shown that it acts as a linchpin in multi-step syntheses where side reactions cost both time and material. More than once, a customer has returned for resupply after trying a cheaper source, reporting blocked lines, filter fouling, or inconsistent reactivity that ties back to off-spec impurity profiles.
We also keep hearing from customers developing spin-off custom syntheses—projects that use the molecule’s base structure to tack on longer amine chains, substitute other halogens, or shift to a different ring system altogether. We keep our process knowledge adaptable in case anyone has unique specifications, scale-ups, or downstream needs.
Many years in production teach a few lessons. Not every process step in organic synthesis reaches completion at the same rate, even at the same temperature or pressure from one day to the next. Our operators have learned to tune batch length and monitor endpoint reactions with more than just sensors; a slight shift in product hue or an unexpected odor can signal a shift that analytics might miss until control samples catch up. We’re no strangers to double distilling or recrystallizing, especially when purifying intermediate streams—cutting waste in this step means real savings for both us and the environment.
Waste management rides high on our priority list, not just to keep costs down but because the halogenated side of this molecule can easily generate chlorinated organic byproducts if the process gets sloppy. We invest in closed-loop solvents, scrubbers, and on-site treatment not out of compliance alone, but because long-term business sustainability relies on more than certifications or paperwork. That means pulling from our years of experience to reduce off-gassing, maximize recovery, and avoid waste streams that end up costing us all.
The reality of direct manufacturing shows itself between the lines of a spec sheet. By managing the sequence from raw chemical sourcing through each batch run, and finally to packaging, we live and breathe the inevitable headaches and successes. One season, moisture content from a new raw amine supplier crept up, resulting in inconsistent physical texture—caking instead of fine powder. Instead of passing that off, we tackled air-drying improvement and swapped feedstock; only after three batches met the mark did a single drum leave our plant. Such an experience, while costly in the short term, reinforces why we favor internal process control over outsourcing or drop-shipping.
We’ve also run into surprises when scale-up jumps from kilo labs up to multi-ton batches. Equipment that performs beautifully in a 20-liter glass reactor may cause surprises in a stainless-steel 2,000-liter reactor—especially with exothermic steps involved. In-line cooling, baffle upgrades, and even simple changes to stirrer speed can spell the difference between on-spec product and costly rework. Working through these scaling hurdles, we learned to keep a foot in development and a hand in daily operations, never trusting models alone to capture every production reality.
A lot of sourcing departments contact us after a string of headaches buying so-called equivalents from traders or brokers. They often bring stories of color mismatches, shifting melting points, inconsistent solubility, or traces of unexpected by-products that play havoc with downstream syntheses. Direct manufacturing sets itself apart since we control not only the raw inputs but the actual process chemistry and, crucially, the work-up and isolation steps. We clean, test, and certify on-site, giving ourselves the power to intervene fast if anything runs off-standard. The feedback loop lands in real time—not weeks of shipping delays or excuse-making from someone halfway around the world.
Some products in the market use closely related molecules, swapping out the dimethylamino group for another amine, or replacing the chloro substituent. Those tweaks may suit specific syntheses, but they rarely provide the same balance between nucleophilicity, stability, and reactivity. For advanced pharmaceutical and specialty chemical applications, chemists and process engineers require the same chemical fingerprint, batch after batch, because they know even subtle shifts can multiply up into entire batch loss at the downstream stage. Our direct synthesis model keeps standards in check to avoid such headaches for everyone involved.
Quality in our plant isn’t a buzzword. Each operator on our team knows that a minor shortcut can ricochet throughout a batch, creating tiny blips in impurity profiles that multiply into full-blown problems later on. We address this not just with process controls and lab checks, but through hands-on training and open channels between chemists, engineers, and operators. If a drum isn’t right, it stays put while our team double-checks, running repeat analytics or even small purification tweaks before green-lighting a shipment.
We also listen. Our longest-running commercial partners often call in with ideas or issues. In some cases, we custom-tailor batches for researchers or process developers tweaking reaction parameters on-site. Years of experience tell us where tolerance can stretch, and where tradition and discipline win the day. Our records, both digital and handwritten, allow us to reproduce successes and learn from mistakes, blending the best of new tech and institutional memory at every step.
For a molecule like this, the competitive race never really stops. Efficiency improvements, greener routes, and better yields always lie just around the corner. Our R&D wing works constantly on alternate synthetic paths, such as using upgraded ligands or experimenting with improved catalyst systems that cut down on purification costs and unwanted side products. Not only does this improve quality, but it turns cost reduction into a real advantage for customers who depend on steady supply and safe material handling.
Recently, we’ve explored single-pot strategies and minimization of hazardous intermediates, reducing environmental footprint and batch-time lags. Years of experience proved that rarely does a “one-size-fits-all” solution pan out for the diversity of production volumes, reactor types, and QC priorities out there, so we keep our approach adaptive and open to feedback.
Decades of shipping this chemical have taught us that reliable labeling and clear, accurate safety communication protect not just our own staff, but everyone down the chain. Our teams go through regular reviews of transport rules, spill protocols, and even drum design—because we’ve seen firsthand how careless handling, wrong gasket material, or weak seals can create real headaches on delivery. For bulk orders, we stage pre-ship inspections, ensuring drums stay clean, headspace remains safe, and seals meet tested standards for both short- and long-haul shipment. Equipment failures and hasty packing serve as hard reminders for growing companies never to skimp on these safeguards.
From interaction with chemists in research labs through to plant engineers managing continuous runs, we provide practical support: on-site guidance, remote troubleshooting, or detailed shelf-life studies as needed. Feedback from users shapes each run, sometimes down to the tweaking of batch sizes or shipping containers, so issues encountered in a plant on Monday can lead to process adjustments or packing changes by Friday. That frontline contact—direct and unfiltered—remains one of the big advantages of dealing directly with a manufacturer.
Over time, real trust builds not from the words on a label but from decades of consistent shipments, problem-solving, and lived experience with real production challenges. For those using 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine as a step in active pharmaceutical ingredient production or in scale-up for specialty materials, glitch-free batches can mean the difference between hitting aggressive project deadlines or having a costly process bottleneck. In our years making this material, nothing causes more headaches than unplanned reworks or off-standard deliveries, whether triggered by upstream sourcing slip-ups or unpredictable shipping conditions.
Dealing direct with the manufacturer offers more than traceability or price competitiveness. It allows chemists, engineers, and process managers to clarify not just what they need, but how material parameters impact their own downstream efficiency. Over the years, we’ve worked with teams troubleshooting scale transfers, process validation, and comprehensive documentation for regulatory submission—all because everyone values the security of knowing what truly goes into the process, from start to finish.
We see stewardship as part of our role—this goes beyond regulatory checklists. Investing in cleaner, safer, and more efficient manufacturing passes real benefits on to our clients, staff, and a wider community benefiting from lower emissions, less waste, and reduced risk across the chain. Running a chemical plant puts us at the sharp end of compliance and innovation alike, and the lessons learned from managing 2-[p-Chloro-α-[2-(dimethylamino)ethoxy]benzyl]pyridine add up to a toolkit for better, safer, and more accountable chemical production.
We continue refining our process and quality assurance standards, focusing on firsthand experience, quick adaptation, and a willingness to learn from each challenge. Every day in production, from new project development to the next round of process optimization, keeps our team sharp and results in a better product for all who depend on this backbone molecule for their own innovations. Working directly with end users means people on both ends of the line come out ahead.
