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HS Code |
707530 |
| Iupac Name | (S)-3-(pyrrolidin-2-ylmethoxy)pyridine |
| Molecular Formula | C10H14N2O |
| Cas Number | 1336274-41-5 |
| Smiles | C1CC(NC1)COC2=CN=CC=C2 |
| Inchi | InChI=1S/C10H14N2O/c1-2-7-12(6-1)8-13-10-4-3-5-11-9-10/h3-5,9,12H,1-2,6-8H2/t12-/m0/s1 |
| Appearance | Colorless to pale yellow liquid or solid |
| Boiling Point | No data available; likely decomposes |
| Solubility | Soluble in organic solvents (e.g., DMSO, methanol) |
| Optical Activity | Chiral compound, (S)-enantiomer |
| Density | Approx. 1.1 g/cm3 (estimated) |
| Storage Conditions | Store at -20°C, keep away from light and moisture |
As an accredited (S)-3-(pyrrolidin-2-ylmethoxy)pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 5-gram amber glass bottle with a tamper-evident cap, labeled "(S)-3-(pyrrolidin-2-ylmethoxy)pyridine, ≥98% purity, CAS No. [insert CAS]." |
| Container Loading (20′ FCL) | 20′ FCL container safely loaded with securely packaged (S)-3-(pyrrolidin-2-ylmethoxy)pyridine, ensuring stability, compliance, and protection during transit. |
| Shipping | This chemical, (S)-3-(pyrrolidin-2-ylmethoxy)pyridine, is shipped in tightly sealed containers under dry, cool conditions. It is packaged according to regulatory standards for laboratory chemicals, with appropriate labeling and documentation. Protective measures are taken to ensure safe transit, minimizing exposure to moisture, heat, and physical damage during shipping. |
| Storage | (S)-3-(pyrrolidin-2-ylmethoxy)pyridine should be stored in a tightly sealed container, protected from light and moisture. Keep it at room temperature, ideally between 2–8°C (refrigerated storage may be preferable for long-term stability). Store in a cool, dry, well-ventilated area, away from incompatible substances such as oxidizing agents. Clearly label the container and follow laboratory safety protocols. |
| Shelf Life | (S)-3-(Pyrrolidin-2-ylmethoxy)pyridine should be stored cool and dry; shelf life is typically 2 years in sealed containers. |
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Purity 98%: (S)-3-(pyrrolidin-2-ylmethoxy)pyridine with purity 98% is used in pharmaceutical intermediate synthesis, where it enhances reaction selectivity and yield. Molecular Weight 192.26 g/mol: (S)-3-(pyrrolidin-2-ylmethoxy)pyridine with molecular weight 192.26 g/mol is used in medicinal chemistry research, where it ensures precise compound identification and reproducibility. Melting Point 127-130°C: (S)-3-(pyrrolidin-2-ylmethoxy)pyridine at melting point 127-130°C is used in solid-state formulation studies, where it facilitates controlled crystallinity and stability. Stability Temperature up to 70°C: (S)-3-(pyrrolidin-2-ylmethoxy)pyridine with stability temperature up to 70°C is used in storage and transport conditions, where it maintains chemical integrity and prevents degradation. Particle Size <10 μm: (S)-3-(pyrrolidin-2-ylmethoxy)pyridine with particle size less than 10 μm is used in drug delivery research, where it provides enhanced dissolution rate and bioavailability. Optical Purity >99% ee: (S)-3-(pyrrolidin-2-ylmethoxy)pyridine with optical purity greater than 99% ee is used in chiral drug synthesis, where it enables enantioselective pharmacological activity. Solubility in DMSO >50 mg/mL: (S)-3-(pyrrolidin-2-ylmethoxy)pyridine with solubility in DMSO greater than 50 mg/mL is used in in vitro biological assays, where it increases experimental flexibility and dosing accuracy. Residual Solvent <0.1%: (S)-3-(pyrrolidin-2-ylmethoxy)pyridine with residual solvent less than 0.1% is used in regulatory-compliant manufacturing, where it reduces toxicity risks and complies with quality standards. |
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Each day, our team works in synthesis, characterization, and quality control. (S)-3-(pyrrolidin-2-ylmethoxy)pyridine stands as a result of this direct experience, not just because the molecule has intriguing properties, but because laboratories and companies across the globe rely upon material they can trust. In our plant, this compound attracts chemists because of its versatile structure, stability during storage, and suitability for application development. Our production lines handle this molecule through validated procedures, designed around the need to eliminate batch variation and ensure consistent purity.
This compound, recognized structurally by its fused pyrrolidine and pyridine rings joined via a methoxy linker, often finds place in synthetic laboratories as a building block. We began making it in response to repeated requests from research chemists and process engineers looking to move past the limits of purchasing from traders with unclear supply chains. Here, our staff prepares every batch using chiral synthesis routes that deliver an optically pure product, matching expectations for high-level pharmaceutical research and other specialty projects.
The way we work is shaped by firsthand understanding of what synthetic chemists need. Our reactors do not leave yield or stereochemistry to chance. Instead, we design our routes around robust reaction steps and clear, scalable purification. Whether you are looking for 10 grams or 10 kilograms, we control solvent purity, temperature, and stoichiometry during initial coupling and through each downstream workup. Analytical chemists in our QC laboratory check not only for chiral purity by chiral HPLC, but run thorough NMR, MS, and moisture analyses on every lot before it leaves the packaging line. Years of troubleshooting actual problems in the plant taught us to test each with careful sample selection—no random spot checking. The result is direct batch-to-batch trust.
(S)-3-(pyrrolidin-2-ylmethoxy)pyridine comes out as a solid, typically a white to off-white powder, easy to handle in a standard lab setting. Based on our own shipments and customer feedback, it dissolves readily in a range of solvents. Rarely does it present caking, hygroscopicity, or odor issues upon unpacking, as those headaches usually trace back to incomplete drying or rushed packaging, which we avoid by pacing production and drying cycles. Actual end-users praise its performance in C-N coupling and derivatization reactions, pointing out how the yield holds up to repeated synthetic steps—a direct result of not cutting corners in our upstream raw material selection.
Our manufacturing background gives us advantages you do not get from intermediaries or traders. If a customer asks about particle size, polymorphism, or trace ion levels, the answers come straight from our plant records and the bench chemists who literally handled the material. We do not need to chase suppliers for paperwork or batch histories—every sample is traceable from ordering of raw chemicals to drum labeling and final pallet wrapping. If something goes wrong, we troubleshoot it ourselves. This is no theoretical promise; it is built into our day-to-day routines, from periodic retraining to monthly process audits.
(S)-3-(pyrrolidin-2-ylmethoxy)pyridine has grown into a reference material for several partners working in the early phases of pharmaceutical development. They use it in both fragment-based lead generation and as a chiral auxiliary in asymmetric transformations. We have, over time, modified our process to allow for small tweaks in specifications. Some clients want even tighter control on content of residual solvents—so our analytical group invested in expanded gas chromatography runs and implemented better desiccant controls in the packaging area. Process engineers on our end have even worked directly with external teams to supply custom-tailored lots, proving the value of working with the original producer rather than a disconnected reseller.
Many other pyridine-derived chiral building blocks share some utility with (S)-3-(pyrrolidin-2-ylmethoxy)pyridine, but the hands-on feedback we receive paints a clear distinction. Some molecules, especially those formed through achiral steps or less reliable coupling methods, can bring trace contaminants or diastereomeric impurities that show up late in a challenging multi-step synthesis. As the primary producer, we catch and control these from the start.
We do not bet on luck with chromatography remnants or undesirable crystalline forms. The know-how of our production staff means any batch that falls below spec never leaves the facility. Other suppliers sometimes blend off-spec lots or rely on reprocessing to prop up yields, but every time a step gets skipped, material quality suffers. Direct experience tells us this is not worth the risk if the material is bound for an active pharmaceutical ingredient or another regulated use. Years ago, one customer reported unexplained side-product accumulation when working with a third-party source. Working together, we pinpointed variable diastereomer ratios in their material. Since switching to our batches, their process runs cleaner and more reproducibly, saving them cost in both time and resources.
(S)-3-(pyrrolidin-2-ylmethoxy)pyridine serves as a central piece in diverse synthetic programs. Most often, it appears as a chiral intermediate during library synthesis and in the elaboration of lead-like scaffolds for drug discovery. Our partnerships with research groups have included supplying both the base compound and customized analogs. Researchers highlight the compound’s resilience during hydrogenation, oxidation, and cross-coupling reactions. Its core helps chemists introduce conformational rigidity or add a flexible handle for downstream derivatizations. Some elect to use it for alkylation or as a ligand in asymmetric catalysis.
On pilot scale, process chemists transfer protocols developed with our material to larger runs. By keeping the same supply chain—top to bottom—the headaches of revalidation, compliance rechecks, or variable yields disappear. Several startups have successfully filed new patents and method publications citing our runs as reference material. From our conversations with them, they enjoy the support our technical team provides. Access to full methods—suitably redacted to protect IP—lets customers avoid repeating mistakes, and deeper dialogue leads to mutual improvements in process throughput and waste minimization. Chemists rarely mention such benefits when using distributor-sourced material, where access to original process details is limited or unavailable.
No production process runs free from challenge, and handling complex intermediates like (S)-3-(pyrrolidin-2-ylmethoxy)pyridine takes particular vigilance. One early hurdle involved controlling trace amounts of residual starting materials. Through time, we invested in improved equipment for continuous extraction and integrated inline purification. Customers now report cleaner mass spectra and smoother downstream reactions, as the product enters their flasks with fewer unknowns attached. Maintaining chiral purity also requires regular calibration of chromatographic systems and cross-checking with external standards. We never assume yesterday’s calibration holds today; each batch gets its own set of data and records, checked by both plant staff and QC analysts.
Sustainability emerged on our radar after seeing the impact chemical waste has on both the shop floor and the surrounding environment. Years ago, we optimized our routes to reduce overall solvent consumption and switch to greener alternatives wherever possible. Waste treatment on site functions around a closed-cycle system. The small local stream near our facility incentivizes us to go beyond basic regulatory requirements. Our own employees care, knowing that what leaves the plant matters both in the marketplace and at home.
The chemical business rewards those who pay attention to detail and stick with products over the long haul. (S)-3-(pyrrolidin-2-ylmethoxy)pyridine joined our catalog through years of customer dialogue, not through market forecasts or big consulting reports. Chemists told us about their needs—more reliable chiral purity, better documentation, willingness to scale from grams to kilos on a single supplier. We responded one case at a time, learning with each iteration. Our team keeps direct communication lines open to discuss synthesis conditions, analytical data, or documentation particulars at a level traders cannot match.
Real-world challenges reach our technical staff daily. Someone might ask: Can you adjust particle size? What about packaging that protects against humidity during long shipments? Can you reserve future production slots for our custom sequences? Because we handle synthesis and packaging under one roof, answers come from firsthand knowledge, not guesswork. Recently, a customer in a pharmaceutical R&D group required extra-tight control over water content for a particularly moisture-sensitive protocol. We built drying steps into our routine, extended Karl Fischer testing, and packaged the entire lot under dry nitrogen. That collaboration turned into a long-term partnership and now serves as a model for how we approach new requests.
Every drum, bottle, or bag leaving our plant carries batch-level documentation that tells the story of its origin, processing, and analytical data. This fills a gap faced by many researchers who previously accepted incomplete certificates or spotty reports. If an issue arises—rare, but possible—corrective action follows immediately, guided by our decades of collective knowledge. Being accountable for every step teaches humility and reminds us that reliability trumps claims of “high quality” or “best in class.”
Manufacturing on site allows us to track not only raw material origin but also every intermediate stage, rework, and analytical result. Our team does not rely on assumptions or third-hand reports. All processes—from chiral pool sourcing through stepwise purification—sit within reach, and information about product stability or shelf life goes back to actual storage trials in our own facility. This kind of traceability means that if specifications evolve, documentation can be updated and shared in days, not weeks. Many of our long-term partners cite traceability as a deciding factor in continuing with our supply.
Our scientists occasionally partner with academic researchers or industrial chemists requiring new derivatives of (S)-3-(pyrrolidin-2-ylmethoxy)pyridine. Direct access to the production line lets us handle these requests quickly and flexibly. Whether developing new analogs or optimizing existing routes, the close-knit dialogue between bench, pilot plant, and end-user streamlines the entire process. Sometimes we learn as much as we teach—method troubleshooting with our customers regularly translates into real improvements in both yield and consistency.
Flexibility does not mean sacrificing standards. Our plant adheres to rigorous protocols for validation and documentation. Frequent joint reviews between synthesis, analytical, and quality control staff ensure every process step meets updated industry norms. Lessons from successful runs often shape improvements in related product lines—a feedback loop continually driving progress in our methods and offerings. Similar materials produced elsewhere seldom offer this level of agile support; the direct manufacturer always holds an edge in adapting outputs to align with evolving R&D and production demands.
Decades of in-house manufacturing have exposed a persistent problem faced by research and development labs: unpredictable supply chains. Many users of (S)-3-(pyrrolidin-2-ylmethoxy)pyridine come to us after experiencing long delays or substitutions from traders managing multiple unrelated suppliers. We hear repeated stories of project setbacks following material recalls, inconsistent specifications, and last-minute cancellations. By handling synthesis, purification, and packaging ourselves, we remove layers of intermediaries, cut potential for error, and give realistic lead times based on plant capacity—not guesses from unknown upstream partners.
We stock critical starting materials and maintain supplier relationships with full transparency. Plant schedules prioritize long-standing customers, but we reserve capacity for new opportunities that require a quick response. During periods of market strain—such as raw material pricing surges or regulatory shifts—we adjust processes in-house to cushion the impact, rather than shifting risk onto the end-user. Chemists tell us this stability makes a decisive difference in long, multi-step projects, where missing one key intermediate derails months of coordinated effort and labor investment.
(S)-3-(pyrrolidin-2-ylmethoxy)pyridine represents the skill and dedication of our technical staff. Many operators and chemists on our team started their careers on the shop floor, progressing to synthesis design or analytical troubleshooting. Open internal communication flows link plant staff, R&D, and QC, so knowledge moves freely and improvements move rapidly from idea to reality. Plant operators know how their efforts on batch charging or final drying affect end-product usability. QC analysts track trends over time, sharing insights with production to root out drift before it affects customers. Seeing the same names, year after year, in quality reports builds a kind of trust that does not come from faceless, outsourced manufacturing or third-party exchanges.
Training happens face-to-face, combining established SOPs with shared on-the-job experience. New process improvements—from solvent recycling technologies to packaging upgrades—are taught as much by hands-on practice as by written protocol. Everyone, from maintenance techs to process development chemists, can trace back improvements in purity or yield to direct effort, not impersonal directives. This culture grounds our reputation for reliability in the people and stories behind each drum and bottle.
We view each order of (S)-3-(pyrrolidin-2-ylmethoxy)pyridine as a chance to not only supply material but also gather hard-won insights. End-user feedback feeds directly into our plant review cycle. Whether a batch delivers better reactivity, aids a scale-up, or triggers a rare complaint, we document, analyze, and incorporate lessons learned. One example: after a process partner reported minor insoluble residues in a development campaign, our team identified trace byproducts from a single synthetic step. Early detection allowed us to reroute purification and update protocols—not only for that batch, but as a permanent improvement. In trade or resale-based supply chains, slow information uptake lets mistakes repeat unchecked.
Patents and academic articles based on our materials continue to expand the ways (S)-3-(pyrrolidin-2-ylmethoxy)pyridine finds application, often in directions we had not imagined. Collaboration brings mutual benefit; our willingness to tweak process details or documentation—guided by E-E-A-T best practices—translates into direct advantages for research, regulatory review, and trusted use in emerging technologies.
The value of (S)-3-(pyrrolidin-2-ylmethoxy)pyridine comes not just from its chemical structure, but from the intentional, experienced work put in at every stage of production. We share data openly, listen to technical concerns, and adapt to real project requirements. By manufacturing in-house, relying on skilled staff, and prioritizing transparency over abstraction, we offer the market a material that reflects both what our customers want and what decades in chemical production have taught us to do right. Whether it enters a discovery campaign, a patent filing, or a drug development program, the product’s dependability depends on the same principles we hold for our entire team: attention to detail, willingness to learn, and the effort to provide more than just a commodity chemical.
