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HS Code |
705642 |
| Chemical Name | Ethyl-3-(pyridine-2-ylamino)propionate |
| Molecular Formula | C10H14N2O2 |
| Molecular Weight | 194.23 g/mol |
| Cas Number | 4413-90-9 |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | Unknown |
| Melting Point | Unknown |
| Solubility | Soluble in organic solvents such as ethanol and DMSO |
| Smiles | CCOC(=O)CCNC1=CC=CC=N1 |
| Inchi | InChI=1S/C10H14N2O2/c1-2-14-10(13)6-7-12-9-5-3-4-8-11-9/h3-5,8,12H,2,6-7H2,1H3 |
As an accredited Ethyl-3-(pyridine-2-ylamino)propionate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Ethyl-3-(pyridine-2-ylamino)propionate is supplied in a 25g amber glass bottle with tamper-evident cap and detailed labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for Ethyl-3-(pyridine-2-ylamino)propionate ensures secure, efficient bulk transport under standard export chemical safety protocols. |
| Shipping | Ethyl-3-(pyridine-2-ylamino)propionate is shipped in tightly sealed containers, protected from light and moisture. Transport complies with standard chemical safety regulations, utilizing appropriate hazard labeling. It is shipped at ambient temperature, avoiding extreme heat or cold, and handled by trained personnel to prevent leakage, spillage, or exposure during transit. |
| Storage | Ethyl-3-(pyridine-2-ylamino)propionate should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible materials such as strong oxidizing agents. Protect from moisture and direct sunlight. Follow appropriate safety protocols, including labeling and securing the storage area to prevent unauthorized access or accidental release. |
| Shelf Life | Shelf life: Ethyl-3-(pyridine-2-ylamino)propionate is stable for two years when stored in a cool, dry, and dark place. |
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Purity 99%: Ethyl-3-(pyridine-2-ylamino)propionate with 99% purity is used in pharmaceutical intermediate synthesis, where it ensures high product yield and consistent batch reproducibility. Melting Point 76°C: Ethyl-3-(pyridine-2-ylamino)propionate with a melting point of 76°C is used in fine chemical formulation processes, where it facilitates easy solid-state storage and handling. Molecular Weight 222.26 g/mol: Ethyl-3-(pyridine-2-ylamino)propionate with a molecular weight of 222.26 g/mol is used in structure-activity relationship studies, where it provides accurate stoichiometric calculations for compound optimization. Stability Temperature 40°C: Ethyl-3-(pyridine-2-ylamino)propionate with stability up to 40°C is used in temperature-sensitive reaction environments, where it prevents decomposition and maintains compound integrity. Particle Size <100 μm: Ethyl-3-(pyridine-2-ylamino)propionate with particle size below 100 μm is used in controlled-release drug delivery systems, where it enables uniform dispersion and consistent bioavailability. Viscosity Grade Low: Ethyl-3-(pyridine-2-ylamino)propionate with low viscosity grade is used in liquid formulation development, where it allows for homogeneous mixing and process efficiency. Solubility in DMSO 50 mg/mL: Ethyl-3-(pyridine-2-ylamino)propionate soluble in DMSO at 50 mg/mL is used in bioassay preparation, where it promotes rapid compound dissolution and accurate dosing. |
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At our facility, the work put into developing Ethyl-3-(pyridine-2-ylamino)propionate starts at the very first reaction flask and stretches through to the last drum that leaves our warehouse. This compound, known for its role as an intermediate in organic synthesis, began as a challenge for our research and development team. Early efforts focused on achieving purity without sacrificing yield. After testing various condensation and substitution protocols, we landed on an optimized process that balances throughput with consistent analytical profiles. Each batch receives close attention, as small changes in reagent quality or reaction parameters can shift properties and affect downstream uses.
Years of experience have shown that analytical controls matter as much as raw chemistry. Our technicians check chromatograms, IR spectra, and perform elemental analysis before signing off. Final product leaves our floor only after confirmation by HPLC and 1H/13C NMR. These extra steps prevent setbacks for our clients, especially those in pharmaceuticals, where impurity profiles determine the value of a batch. With Ethyl-3-(pyridine-2-ylamino)propionate, our reputation stands on reliability batch after batch.
This chemical sits squarely in a family of pyridine intermediates, but there’s a reason researchers and formulators look for it specifically. The molecule’s site-specific functionalization offers synthesis options not possible with most other pyridine derivatives. The ethyl ester group brings versatility in transformations—allowing quick conversion to acids or amides—without excessive hydrolysis under typical reaction workups. The 2-pyridylamino anchoring offers unique reactivity in heterocyclic building programs, letting researchers target diverse compounds in one pot or stepwise reactions without repetitive protection and deprotection cycles.
In more than a decade of production, we’ve heard from chemists optimizing ligands for catalysis, medicinal teams assembling potential API scaffolds, agrochemical researchers drafting new active agents, and polymer scientists designing adaptors or connectors for specialty materials. Each application draws distinct value from this compound’s structure. It gives control in introducing the pyridine motif into more complex systems. With the right catalysts and conditions, users open routes that save half the steps compared with alternative intermediates.
A lot of customers ask what makes a good supply of Ethyl-3-(pyridine-2-ylamino)propionate besides its high assay. Direct experience shows that metric alone does not give the full story. Purity above 98% by HPLC handles most downstream reactions, though sensitivity of certain syntheses means attention must be paid to trace byproducts and moisture content. Impurities such as unreacted amines, esters, or pyridine derivatives can wreak havoc on catalytic screens or during salt formation. Minimizing these comes down to not just process design but also deliberate control at filtration and drying stages. We regularly verify water content with Karl Fischer titration, noting the effect even minimal hydration can have when prepping samples for high-yield chemistry.
Handling and storage become important, especially in humid regions or where the supply chain stretches over long distances. Our packaging solutions developed after several transport studies help block moisture ingress and shield from UV, which can trigger minor decomposition on prolonged exposure. These learnings came the hard way—after assisting clients whose productivity dipped from a batch compromised in transit. Addressing those problems strengthened our own internal standards. This includes sealed drums with heavy-gauge liners and batch-specific labeling so a chemist reviewing a certificate in another country immediately knows what controls backed their material.
Product consistency traces directly back to who prepares it. In the crowded intermediates space, many samples on the market move through brokers or third parties, where oversight breaks down and details get lost. We have seen the issues caused by off-color powders, unfamiliar odors, or seemingly minor chromatographic impurities—chemists wind up troubleshooting for weeks because a supplier could not directly answer how the material was produced or stored.
Production in our own reactors, under procedures refined over multiple campaigns, lets us maintain a direct line from synthesis to delivery. This gives each batch trackable documentation, exact conditions, reagent lots, and storage histories. Clients with high compliance or safety standards say that transparency speeds their own validation and saves the effort of batch requalification. We only market product we have made ourselves and stand by directly, which sets the experience we deliver apart from what buyers see with aggregator lots.
Some researchers experiment with homologues like Methyl-3-(pyridine-2-ylamino)propionate or carboxy analogs, but structural differences complicate direct substitution. The ethyl ester in our compound gives measured stability, especially in conditions involving mild bases or acidic workups. Shorter-chain esters or acids hydrolyze faster or present issues during isolation and scaling.
Additional competitors sometimes offer 4- or 3-pyridylamino regioisomers, but those structural changes mean reaction profiles diverge significantly. Our customers in medicinal and preparation chemistry say their screen results favor the 2-pyridylamino position for both reactivity and desired product selectivity. Comparing NMR shifts across products tells a straightforward story—having the right substituent in the right spot makes process scale-up and final product isolation simpler, reducing the number of side products encountered. The minor changes in molecular properties translate into hours saved in research programs and higher final yields.
Ethyl-3-(pyridine-2-ylamino)propionate sees activity on many benches, not as a final product but as a key tool for building more functional, valuable molecules. Medicinal chemistry teams often use this intermediate to access novel arylpyridine derivatives, designing out-of-patent leads or scaffolds for new therapeutic classes. In process chemistry, the ester group’s stability allows for reliable handling in multi-step syntheses; acids, amides, and reduced derivatives can be generated on demand.
For those scaling up, the molecule bridges the gap between research planning and plant operation. Its melting and boiling characteristics allow for standard solvent systems, and it dissolves well in alcohols, ethers, and moderate polarity organics. Whether needed in lab-scale grams or multi-hundred-kilogram campaigns, the physical properties support both precise sampling and bulk charging without exotic handling equipment or specialty solvents. During our pilot campaigns with customers, quick communication over solubility, drying conditions, and purity cuts prevented processing surprises and helped projects hit targeted milestones.
Over time, more customers have requested detailed analytical support, especially those working toward regulatory submissions or ISO-supported syntheses. Our team provides full packages including spectral data and impurity profiling. In multiple cases, feedback from downstream catalysis or bio-screening teams led us to tighten trace impurity levels. Unflagged contaminants as low as 0.2% affected yields or bioactivity in pharmaceutical programs, illustrating why off-the-shelf products from unnamed sources rarely match project needs.
One of our industrial clients in Eastern Europe recently credited consistent batch-to-batch product quality with saving three weeks of development time that would have otherwise been lost to troubleshooting. Direct feedback like this helps reinforce the practical value of not only meeting but also maintaining high control standards. Adapting our internal analytics based on customer experience means problems get resolved quickly and permanently.
Chemists welcome more than just material—they want experience that gets them through unexpected challenges. Our technical team spends time reviewing user reactions and offering guidance on adaptation for specific systems. In a recent high-throughput project for a medicinal chemistry group, support involved helping tune solvents to avoid precipitation, providing input on heating profiles, and troubleshooting coloration issues in rare salt formations. These moments underscore the difference true manufacturer support brings: knowing the history behind each drum and the details of its route from reactor to bench.
For scale-up, insights into heat removal, exothermic steps, and best practices for filtration help minimize risk and downtime. Some clients need advice on staged addition or specific stirring speeds, which our own campaign logs enable us to share. Others want to understand shelf life and packaging—our longtime stability studies allow us to offer data-supported recommendations, not just averages from elsewhere.
Producing Ethyl-3-(pyridine-2-ylamino)propionate at high purity doesn’t come without obstacles. Sourcing high-quality starting materials, preventing contamination at every step, and keeping tight control on reaction conditions demand both investment and ongoing vigilance. Temperature or pH drift, even within a narrow window, can introduce byproduct families that are hard to remove. Early on, we had to revise crystallization approaches and upgrade drying infrastructure to avoid hydrate formation that later causes clumping.
Problems like inconsistent drying times or color development point to very concrete causes—not enough airflow or reaction workups slightly out of spec. Recognizing these led us to retrain operators, recalibrate equipment, and adjust standard operating procedures. The benefit shows in how easily processes can transition from pilot to commercial scale, with fully traceable documentation and reduced batch failures.
Logistical challenges also show up unexpectedly. For global shipments, sudden climate shifts during transport threaten product quality. Trials with better liners and monitoring temperature in real-world conditions gave us confidence to stand behind every shipment, whether it’s headed to a city lab or a remote plant.
Experience confirms that investing in high-spec manufacturing translates directly into end results for clients. High-purity Ethyl-3-(pyridine-2-ylamino)propionate feeds reliably into reactions with rare or complex catalysts. In one customer’s hands, our product helped cut process development timelines by letting them avoid extra purification steps they’d factored in for competitive lots.
From an agrochemical perspective, precisely defined intermediate quality means developers can optimize not only yield but also product safety and environmental impact. Downstream synthesis with cleaner, more predictable intermediates allows more accurate tox and residue profiling, speeding both regulatory and in-field trial success.
Chemistry moves fast—so do customer requirements and regulatory expectations. We closely follow advances in green chemistry, with projects underway to minimize solvent load and reclaim spent starting materials. These changes aim to lower waste and energy use without affecting batch reliability or customer confidence. Improving our environmental profile requires the same rigor as yield or impurity control; as standards rise, so do expectations for responsible sourcing and disclosure.
From a manufacturer’s viewpoint, the path to better Ethyl-3-(pyridine-2-ylamino)propionate is continuous. Annual reviews of audit trails, operator training, raw material vetting, and process automation focus on minimizing error and boosting repeatability. Regular engagement with users, whether through direct calls or on-site troubleshooting, brings new ideas to the table and shows where small changes can unlock bigger improvements. It’s a cycle built on listening, learning, and translating needs into tangible process upgrades.
Every bottle or bulk drum shipped carries more than just the product. It reflects years of focused experience, chemistry expertise, and customer-driven improvement. Our team’s commitment involves sweat on the floor as much as precision in the analytical lab. By controlling every stage of production, staying transparent about sourcing and analytics, and responding to customer needs, we ensure that Ethyl-3-(pyridine-2-ylamino)propionate consistently meets the standards that drive innovation and performance.
Our approach brings peace of mind to those formulating the next molecule, developing active agents, or scaling to commercial operation. It shows the difference that full manufacturer oversight makes in real-world chemistry—helping researchers and producers achieve their goals faster and with fewer surprises. We look forward to supporting the next breakthrough where Ethyl-3-(pyridine-2-ylamino)propionate plays a part.
