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HS Code |
658198 |
| Chemical Name | 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine |
| Molecular Formula | C16H19ClN2O |
| Molecular Weight | 290.79 g/mol |
| Appearance | White to off-white solid |
| Melting Point | 134-136°C |
| Solubility | Soluble in organic solvents such as ethanol and chloroform |
| Cas Number | 26111-27-9 |
| Storage Conditions | Store in a cool, dry place, tightly closed |
| Purity | Typically ≥98% |
| Synonyms | Clorindione intermediate; 2-(p-Chloro-alpha-(2-dimethylaminoethoxy)benzyl)pyridine |
| Smiles | CN(C)CCOC(C1=CC=C(C=C1)Cl)C2=CC=CC=N2 |
| Usage | Pharmaceutical intermediate |
As an accredited 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging contains 5 grams of 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine, sealed in an amber glass bottle with hazard labeling. |
| Container Loading (20′ FCL) | Container loading (20′ FCL) for 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine ensures secure, bulk chemical transport in sealed, standardized containers. |
| Shipping | The chemical **2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine** should be shipped in tightly sealed, chemical-resistant containers with appropriate hazard labeling. Transport must comply with relevant local, national, or international regulations for hazardous substances, ensuring protection from heat, moisture, and physical damage during transit. Handle with suitable protective equipment during shipping and receiving. |
| Storage | 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from direct sunlight, moisture, and incompatible substances such as strong oxidizing agents and acids. It should be kept at room temperature and protected from physical damage. Use appropriate personal protective equipment when handling this chemical. |
| Shelf Life | **Shelf Life:** Stable for at least 2 years when stored in a cool, dry place, protected from light and moisture, in tightly sealed containers. |
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Purity 99%: 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and reproducibility of target compounds. Melting point 121°C: 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine with a melting point of 121°C is used in solid formulation development, where it provides stable crystalline structure for prolonged shelf-life. Molecular weight 316.81 g/mol: 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine with molecular weight 316.81 g/mol is used in drug design studies, where it enables precise calculation for formulation balancing. Stability temperature up to 80°C: 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine with stability temperature up to 80°C is used in high-temperature reaction processes, where it maintains chemical integrity throughout synthesis. Particle size <75 μm: 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine with particle size less than 75 μm is used in suspension formulations, where it ensures optimal dispersion and homogeneity. Water content <0.5%: 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine with water content below 0.5% is used in moisture-sensitive chemical syntheses, where it minimizes side reaction risks and enhances product purity. Assay ≥98% (HPLC): 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine with assay ≥98% (HPLC) is used in analytical reference standards, where it delivers accurate quantification in quality control. |
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On the production floor, there’s always an appreciation for a molecule that does what it claims. At our facility, 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine remains a regular on our batch lists, not just for filling orders, but because processes respond well to its predictable nature. Engineers and chemists have gone down many a rabbit hole with lesser substitutes before discovering that precision matters in synthesis. Fewer headaches, better downstream yields, and less rework—these are what set this pyridine derivative apart.
Years of scaling up this product have taught us more than what any technical abstract can express. Accumulated experience has shown that a molecule isn’t just about purity or HPLC traces. The model we manufacture reflects a set of parameters built for chemical reliability: molecular weight set, melting range fixed, moisture content watched with care, and impurities tracked batch to batch, not just at release. We check for the right hue and lack of particulates, as customers who pay attention to detail know small physical changes impact complex syntheses down the line.
Handling this compound shows its versatility early. With a stable profile under typical ambient storage, it does not shift or degrade during short-haul transport or in warehouse humidity. That minimizes unnecessary waste during transfers—a lesson learned firsthand when supporting clients through periods of unforeseen shipping delays. The appearance and purity metrics reported by our team reflect a real batch, not just typical numbers pulled from a catalog. No two productions behave quite the same once on the shop floor, so quality control reaches beyond numbers into hands-on scrutiny that comes only after making hundreds of lots.
Plenty of chemists look at this molecule as just an intermediate for more complex organic synthesis, often targeting pharmaceuticals or specialty agrochemicals. That’s true enough. Digging deeper, the reason it’s reached benchmark status among certain industrial clients comes from the structure itself—it features a chlorinated aromatic system paired with a pyridine ring and a dimethylaminoethoxy side chain. This trifecta opens unique routes. For instance, the electronic effects of the p-chloro and pyridyl moieties reliably produce regioselective transformations in heterocyclic chemistry.
A substitute with a slightly different halide—whether that’s a bromo or a fluoro—never quite mimics the selectivity or yields after scale-up. Similarly, swapping the dimethylamino group for bulkier or less basic analogs affects solubility in organic solvents and limits downstream reactivity. Clients have approached us with questions about using similar intermediates sourced elsewhere. More than once, after batches with lower conversion rates or irregular crystallization, they wind up back on our line, tracing issues to small differences in the precursor’s synthetic route or purification levels.
Synthetic chemists, especially those in production-scale settings, talk about the challenges of batch-to-batch reproducibility. We have seen the havoc caused by variable starting material quality—low content of side-products or an inexplicably wide melting range can cause an entire process campaign to falter. To meet this challenge, we run extra analytical checks like GC-MS fingerprints and residual solvent screens, even when not strictly required by the listed specifications. Our technical staff regularly inspects products at the final stage, rejecting any outliers, because our clients’ batch records require certainty.
One of the great differences between this product and similar-looking materials comes in final recovery rates after large-scale conversions. In multi-step syntheses, the first intermediate often holds the fate of the entire route. With a material like ours, customers report better overall recovery and cleaner separations—a direct result of consistent purity and correct crystal form. This comes from hands-on refinement, repeated filtration, and recrystallization steps, tailored until the material moves consistently through to the next process. No economy in drying time or shortcut in evaporation ever justifies creating a bottleneck for the end-user.
There are challenges unique to manufacturing organic compounds with dual functional groups. During production, the presence of a p-chloro group alongside the dimethylaminoethoxy-pyridine scaffold increases the risk of unwanted side-reactivity. Over time, our process engineers dialed down by-product formation through careful control of reaction pH and reaction temperature. Experience taught us to monitor not just the final product, but also key intermediates and post-reaction washes, to eliminate persistent traces of amines, chlorinated sideproducts, and non-volatile residues.
During scale-up, not many manufacturers devote entire shifts to troubleshoot a filtration problem that occurs at only one volume range. We did, early on. The result: filter cake that releases product efficiently without holding up yield. We have also faced the reality that shipping to distant regions—where customs or port delays may extend storage—demands robust packaging with moisture-barriers and light-protection, which our logistics team incorporates based on warehouse experience, not just office memos.
Chemists and purchasing managers searching catalogues may find a handful of similar pyridine derivatives offered under generic codes or from resellers. From years of running our own product batches, genuine distinctions surface with regularity. Competing products often focus purely on price-point, neglecting hidden costs of off-specification lots or erratic behavior under process conditions.
We’ve had repeated conversations with partners who previously sourced from bulk traders promising “identical” content or “match-to-your-spec” assurances. When batches were slow to dissolve or led to unexpected isomer formation, the difference became clear: provenance matters. The production method, choice of raw materials, and end-stage purification vary widely depending on the experience and commitment of the manufacturing team. In our operation, tracing every lot back to its origins means fewer costly surprises for the end user, translating to trust built batch by batch.
Clients sometimes reach out not necessarily for the mainline product but to tap our technical background in troubleshooting difficult synthesis steps. We share what we’ve learned—how minor changes in temperature ramp, stirring speed, or even glassware rinsing protocol can impact the formation and isolation of the active pyridine ring. Supporting customer trials directly, our technical team has spent time in visiting labs, watching real process conditions unfold. These sessions ensure that the product produced here truly fits the practical challenges found in both pharmaceutical pilot plants and smaller specialty research settings.
Our dialogue with clients continues long after delivery. They call for pointers on handling, minimizing hydrolysis, or optimizing storage, especially in humid climates. Some ask about eco-friendlier disposal for spent mother liquors—concerns our own site deals with through monitored waste streams and routine water testing. Working at source, we put these lessons back into product improvement, driving changes in packaging or offering advice based on the realities encountered in the field.
In production settings, it’s tempting to treat a compound like 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine as just another citable standard. The real work goes into refining steps from raw material selection to the end of purification, layer by layer. We’ve abandoned promising short-cuts during scale-up that seemed efficient but produced off-color or slow-dissolving material. Meticulous solvent recovery saves both money and the environment—each improvement, validated via in-house trials, becomes standard practice after hands-on proof.
Despite the multitude of theoretical optimizations presented in academic journals, we only implement changes that stand up under the daily scrutiny of full-scale batches. Small differences in temperature ramp or impurity profile influence final product yield and process safety. That’s not just a claim—the daily logs from our production teams document improvements, batch after batch, as we chase not maximum throughput but optimal, reproducible quality.
Occupational safety rules require every employee to respect the hazards inherent to pyridine derivatives, particularly those bearing chlorinated aromatics. Frequent training sessions reinforce knowledge of correct procedures for handling, containment, and accidental exposure responses. Cleanroom practice became commonplace here not through regulation alone but through past lessons learned—the cost of cross-contamination or product mishandling comes not only in lost material, but potentially in health risk.
We keep our production runs as closed as possible, not only for safety but to avoid airborne loss and ensure traceability. This benefits users down the line by cutting risk of unexpected contaminants originating from our site. Where equipment requires periodic maintenance or cleaning, records and verification are standard practice, ensuring that no batch is released without a clear production history.
Much of the ongoing refinement in our process comes from continual feedback, both internal and from clients. We adapt cycle parameters based on end-use data and actual issues encountered in external labs. For instance, adjusting drying temperatures based on storage climate or even refining the ratio of solvents to enhance filtration speed have arisen from customer conversations, not just theoretical calculation.
Our focus remains on finding ways to save time for downstream clients—since delays in their processes reflect not only on our product but on trust in future orders. Technical teams keep detailed logs of anomalies: a crystalline material picked up an unusual tint, or a pH outside the standard narrowed range prompted a deeper root-cause analysis. Each finding, big or small, shapes updated standard operating procedures tailored for actual, not ideal, operating conditions.
Many applications of 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine fall under tight regulatory frameworks, especially in pharmaceutical and agrochemical developments. Meeting these layers of oversight, we've worked with both local authorities and international bodies to verify compliance throughout the production chain. Our analytical data reflects actual samples from each lot, and regulatory filings trace back to our original batch reports. Audits have shaped how we document each step, how we train staff, and how we keep reference samples ready for retesting.
Our product has made its way into submissions for new drug applications and crop protection dossiers, with clients asking for technical support in providing full traceability and documentation. Responding to increased scrutiny, our compliance specialists keep up with changing international standards and proactively audit internal processes, ensuring traceability that can stand up not just to in-house checks, but to external regulators as well.
The impact of chemical manufacturing extends well beyond the plant. We invest in solvent recovery, water treatment, and energy-saving procedures not from pressure, but from daily recognition of our environmental footprint. Because the pyridine backbone and its halogenated nature can contribute to persistent waste if handled poorly, waste treatment steps remain under regular internal review. On-site treatment facilities receive near-daily monitoring, and we make process modifications to recover or neutralize any potentially hazardous residues ahead of effluent release.
Our team participates in industry discussions, looking for new avenues to lessen environmental impact, such as investigating biodegradable or less toxic solvent alternatives during the production cycle. Furthermore, we maintain open lines with end-users, providing updated material safety data and handling guidance grounded in actual site experience, not abstract compliance.
The last years taught us all about the fragility of global supply routes. Delays, shortages, and logistical mishaps challenge both the manufacturer and end-user. Instead of chasing every available market, we devote resources to sustaining stable, transparent supply lines. We secure raw material contracts with reliable partners and maintain stocks that buffer against port slowdowns or custom delays.
By keeping production in-house and maintaining a team that knows the pitfalls firsthand, we cut steps that add no value or introduce new risks. This approach limits both our exposure and that of our customers, ensuring that each lot provided carries the reliability and consistency proven in field use.
A product like 2-[p-Chloro-α-(2-dimethylaminoethoxy)benzyl]pyridine isn’t just one of many catalog numbers. It’s the result of steady hands, years of troubleshooting, and ongoing dialogue with the real-world demands of synthetic and process chemistry. Each improvement, each process tweak, and each new packaging solution stems from lessons learned on our own line—not from following a template, but meaningful response to challenge.
In the end, users return not simply for a chemical, but for the confidence that each order delivers the same standard every time. That comes from shared commitment—from the earliest raw materials through to shipping and after-sales support. Years of turning challenges into solutions built the trust that keeps this compound not just in production, but at the core of many of our partners’ most essential syntheses.
