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HS Code |
942694 |
| Chemical Name | Benzyl 4-(aminomethyl)tetrahydro-1(2H)-pyridinecarboxylate |
| Molecular Formula | C14H18N2O2 |
| Molecular Weight | 246.31 g/mol |
| Appearance | White to off-white solid |
| Purity | Typically ≥98% |
| Solubility | Soluble in DMSO, ethanol, and methanol |
| Storage Conditions | Store at 2-8°C, protect from light and moisture |
| Synonyms | Benzyl 4-(aminomethyl)-1,2,3,6-tetrahydropyridine-1-carboxylate |
| Smiles | NCC1=CCN(CC1)C(=O)OCc2ccccc2 |
| Application | Intermediate for chemical and pharmaceutical synthesis |
| Stability | Stable under recommended storage conditions |
As an accredited BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical is supplied in a 25g amber glass bottle, sealed with a screw cap, and labeled with product name, concentration, and safety warnings. |
| Container Loading (20′ FCL) | `20′ FCL container loads BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE securely packed in drums or fiberboard cartons for safe transport. |
| Shipping | This chemical, **Benzyl 4-(aminomethyl)tetrahydro-1(2H)-pyridinecarboxylate**, should be shipped in airtight, leak-proof containers under controlled room temperature. Proper labeling and documentation are required according to relevant chemical safety regulations. Protective packaging should ensure containment in case of breakage. Consult the MSDS for detailed transportation and handling guidelines. |
| Storage | Store **BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE** in a tightly sealed container, away from light and moisture, in a cool, dry, and well-ventilated area. Keep it separate from incompatible substances such as strong oxidizing agents and acids. Clearly label the container. Avoid prolonged exposure to air. Use appropriate personal protective equipment when handling and ensure storage complies with safety regulations. |
| Shelf Life | Shelf life: BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE is stable for at least 2 years when stored cool, dry, and protected from light. |
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Purity 98%: BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE with a purity of 98% is used in pharmaceutical intermediate synthesis, where high selectivity and reduced by-product formation are achieved. Molecular Weight 234.3 g/mol: BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE at 234.3 g/mol is applied in medicinal chemistry research, where defined molecular weight supports consistent compound identification. Melting Point 86°C: BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE with a melting point of 86°C is utilized in solid-state formulation processes, where optimized stability and ease of handling are realized. Viscosity Grade Low: BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE of low viscosity grade is used for continuous flow reactions, where improved mixing efficiency and throughput are observed. Stability Temperature up to 120°C: BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE with stability up to 120°C is implemented in high-temperature reaction steps, where thermal degradation is minimized. Particle Size <50 μm: BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE with particle size below 50 μm is employed in suspension formulations, where enhanced dissolution rate and uniformity are provided. |
Competitive BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE prices that fit your budget—flexible terms and customized quotes for every order.
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Making specialty chemicals starts long before any glassware clinks in the lab. Over years, we’ve refined every step — scouting raw material purity, calibrating reactors, shaping safe routes for scale, and checking every batch until these molecules meet real-world needs. We built our production for BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE with this mindset. We learned early that industry doesn’t just look for a chemical: it wants consistency, safety, and a real partner who understands what’s required at plant scale, not only in a catalog.
BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE came onto the scene when market needs shifted toward more complex nitrogen heterocycles. Our chemists began by focusing on reaction selectivity and how to drive the aminomethyl introduction without creating side products that complicate the downstream process. We fine-tuned every variable, from solvent ratio to base stoichiometry, until we got a process that delivers the right purity and reliable yield week after week. The result: a crystalline solid offering bench chemists and process engineers a building block for advanced pharmaceuticals and custom materials, ready to plug into their synthetic pathways.
We see requests from customers who have burned weeks on inconsistent batches or unreliable supply chains. That’s why we move BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE through a setup that lets us support both R&D flask scale and full commercial quantities. Our standard format is a solid, usually pale in color, packed securely under nitrogen with desiccant. Typical NMR and HPLC analyses confirm structure, identify trace imine formation (if any), and verify residual solvent contents are below accepted industry thresholds. Long before it reaches the shipment stage, our quality control team checks trace metal content and screens the material using our own cross-calibrated LC-MS, so that customers avoid headaches with downstream purification.
Exact specification details like assay percentages come directly from lot-based analysis and change slightly with each batch — transparency in reporting is how we keep projects on deadline, not chasing paperwork midway through a process. Chemists in our plant set the specification bar based on technical feedback and what we see during synthesis and purification. Stability studies under everyday storage (and a few worst-case scenarios) give us real data on shelf life, without erring on the side of theoretical safety margins. Customers get our actual findings, not assumptions.
We regularly talk with pharmaceutical teams who want more than a reagent — they need a molecule that arrives with data, is hassle-free to weigh out, and won’t introduce regulatory snags in later filings. BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE often appears at a crucial pivot point in active ingredient synthesis, especially where a robust aminomethyl group is needed on a tetrahydropyridine backbone. Its use as a precursor in medicinal chemistry campaigns gets plenty of attention, since this structure shows up in both patented and open-source lead optimization work. We’ve seen research groups move this compound straight into reductive amination, Suzuki couplings, and even palladium-catalyzed hydrogenations with only minor warming or solvent changes. Its benzyl group helps with later deprotection strategies, so it fits right into routes aimed at CNS, oncology, and infectious disease targets.
In process chemistry, someone from our plant is often on the line to walk through solvent choice or reaction workup. Over the years, we have logged dozens of batch runs using both classical and asymmetric variants, so we can point out routes to avoid, or ideas for running under lower pressure. Plant techs sometimes struggle with moisture pickup, and we’ve developed container and handling protocols to keep this under control, especially for partners shipping the material across continents. This is not a shelf-stable commodity raw material; its quirks in solubility or slow hydrolysis under humid air need a manufacturer who keeps up with real-time field updates as well as the literature.
Beyond pharma synthesis, this intermediate finds a place in specialty materials — such as complex chelating agents — where its nitrogen-rich profile and modifiable side chains allow adjustments to binding capacity. We’ve lent technical guidance to teams validating these routes at pilot scale, so they meet their own purity and stability thresholds, not just ours.
There are lots of aminomethylated pyridines, and plenty of benzylic esters, in fine chemical catalogs worldwide. What sets this structure apart starts with its backbone. Tetrahydropyridine rings offer unique reactivity and partial saturation, balancing stability and reactivity in multi-step synthesis. When you attach the aminomethyl group at the 4-position and benzylate the carboxylate, you get a compound that tolerates a wider variety of reaction conditions compared to the free acid. We chose the benzyl ester so that customers could remove it with straightforward hydrogenolysis, minimizing harsh reagents and clean-up.
Some companies push close analogs — methyl esters instead of benzyl, or saturated piperidines instead of the tetrahydro species. We experimented with these, running split batches through parallel stress tests and downstream applications. The difference gets clear during scale-up: methyl esters hydrolyze too quickly, sometimes fouling up an entire reactor. Saturated piperidine analogs show less chemical flexibility under oxidative conditions, which limits options for late-stage diversification. We have built up our knowledge, not by sticking with catalog conventions, but by running headlong into unglamorous process upsets and course-correcting.
Some resellers claim they can source this compound from a handful of Asian bulk plants, but repeated customer feedback tells us that off-brand lots miss the mark on trace impurities, especially residual palladium or unreacted benzyl chloride. In one case, a downstream hydrogenation step failed because of precisely this. We rebuilt our purification and metal-scavenging process, shared the updated spec sheets with customers mid-project, and turned a near-missed campaign into a supplier-client partnership that’s lasted for years.
Our lab teams learned a lot from the frequent headaches that can surface with building blocks like BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE. Moisture is the obvious pitfall, as tetrahydropyridines react slowly with water, especially if residual catalytic acid lingers. We design packaging and in-house inventory turnover to beat this. For one contract project, we sent updated recommendations to storage and transport companies who’d previously stacked our drums near steam pipes. A real-time sensor log — now standard on our main shipping lines — told us exactly when and where slight yellowing occurred. Armed with feedback, we moved to fully lined drums and added quarter-turn desiccant capsules that can be checked through a color window.
The next hassle comes from variable levels of benzyl deprotection. On the bench, a simple hydrogenation does the job, but at scale, minor variations in hydrogen delivery or Pd/C source can cause off-colors or sticky product. We pre-test each lot for hydrogen uptake, giving process teams a direct report on expected gas consumption, sidestepping guesswork and saving precious pilot plant hours. If a customer wants to run a test batch, our technical group supplies a detailed method summary, not an idealized procedure borrowed from an academic journal, but real plant-inspired parameters.
Regulatory compliance brings its own set of hurdles. With this molecule, the supporting paperwork has to track each lot’s journey from precursor to final product. We maintain records with full traceability, logging every instrument calibration and critical cleaning step through our manufacturing software. In our experience, pharma customers especially want transparent batch histories, not just an after-the-fact certificate. By supplying a digital record and keeping scan-and-archive systems handy, we help keep audits smooth for everyone up the chain.
Chemical manufacturing depends on more than just molecules. We often guide R&D teams who want to shift from flask to kilo, explaining why this compound asks for certain solvents or a minimum dry-down before loading into flow reactors. We give troubleshooting advice based on data drawn from years of full-scale runs, not just the idealized case in a controlled sample. Many technical conversations start right after a failed scale-up, and our support sharpens process development — avoiding unneeded waste and delays.
Some find the process easier if the intermediate arrives pre-weighed and sealed under argon, with batch certificates we hand-sign because we ran the QC in-house. Others want real-time inventory counts, since their timelines swing on tight deadlines. Either way, technical support doesn’t come from a helpdesk, but from the teams who operate and refine the syntheses daily. We keep our ears open to new customer findings, and we take repeat concerns back to our operation team to fuel continuous improvement.
BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE moves from bench-top concept to industrial adoption only if quality doesn’t slip between scale-up, logistics, and end-user handling. Reliable supply hinges on anticipating shipment needs and jumping early on any supply chain bottlenecks. Our warehouse team built up a routine of inventory checks and pre-orders, so gaps don’t creep in when demand surges. We diversified our raw material streams, moving away from single-point sources and bringing in local and global suppliers so we have buffers against unforeseen delays.
Last winter, port closures delayed a key precursor delivery by nearly ten days. Because we keep extra purification columns staged and solvent tanks topped up, production flexed without pausing downstream deliveries. Through rapid batch planning and pipeline scheduling, the material kept moving to global customers, with our field logistics team updating buyers at each checkpoint. These small decisions kept chemistry teams on their project schedule, with no disruption to their in-process work.
If an end-user stumbles on a lab result they can’t explain, our technical staff runs fast checks in parallel and works side-by-side with their process operators. We’ve shipped rapid sample lots by air to catch urgent deadlines, sending observed results from our lab and field notes about packaging or shipping lessons so that others don’t need to relearn. These touches matter when projects hinge on hitting timelines for animal studies or regulatory test runs.
We treat every batch as its own case study, logging learnings into our process records. Over years, we discovered that BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE reacts differently when switching from glass to stainless steel or using different grading of input amines. During one campaign in summer, a routine tank changeover revealed a subtle contamination risk. By tracking end-to-end equipment use and updating cleaning logs in real-time, we sealed off future problems before a single lot left the building.
Analytical support stepped up as customer demand increased. Our in-house lab tracks minor degradants and closely related impurities, using both traditional analytical setups and custom LC-MS protocols tailored to this intermediate. Dense paperwork isn’t enough — success emerges from tight feedback between our batch production and analytical teams, sharing direct output with clients. Anyone running their own large-scale campaign can request detailed impurity breakdowns, with no delay or reluctance to disclose. We know that process bottlenecks in pharma often stem from a lack of firsthand data, and we’re committed to transparency.
Our plant routine encourages cross-learning. Lab chemists engage closely with kilo plant operators, especially where batch hazards or yield dips have surfaced before. Process modifications come from clear dialogue, so repeat vulnerabilities don’t hide in the shadows. From this, our response to repeat issues in scale-up creates stronger supply security for this intermediate. Over time, fewer surprises reach the end user, and technical know-how grows into hard-won expertise.
We took a hard look at the environmental impact of producing BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE. We prioritized solvent reduction and targeted recovery, using distillation and in-line recovery techniques that cut waste without compromising on batch quality. Energy audits flagged spots for improved insulation and heat exchange upgrades, trimming down the plant’s resource footprint. We work with supply partners to tighten their own standards, pushing sustainable sourcing of key reagents so that the reductions travel all the way up the chain, not just at our loading docks.
Many industry voices talk sustainability as a slogan, yet skip the nuts and bolts. We’ve invited third-party audits to verify reductions, and we share data openly because the metrics matter beyond marketing. Some upgrades came about when a returning customer flagged a packaging improvement that made recycling easier on their side. This story repeats every few quarters: real feedback from those handling the compound daily, and real change in response.
Direct manufacturing expertise matters for sensitive intermediates like BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE. Projects only move forward if the supply pipeline is open, transparent, and based on honest technical dialogue. We take pride in building more than a transaction — it’s an ongoing relationship where customer insights drive progress in our own plant, and where production data flows both ways for better problem-solving. Our experience, built from real mishaps and successes, keeps every delivery aligned to what chemical manufacturers need: reliability, accountability, and the confidence that the next batch will match the last, whether that means five grams for the bench or a hundred kilos for the plant.
Every request, every question, and every real-world process feedback continues to shape how we make and support this compound. For BENZYL 4-(AMINOMETHYL)TETRAHYDRO-1(2H)-PYRIDINECARBOXYLATE, that’s not just a claim — it’s our manufacturing reality, shared daily with the teams who depend on it.
