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HS Code |
278762 |
| Chemical Name | 3-(2-Aminoethyl)pyridine dihydrochloride |
| Molecular Formula | C7H11N2·2HCl |
| Molecular Weight | 197.10 g/mol |
| Cas Number | 65356-13-8 |
| Appearance | White to off-white solid |
| Solubility | Soluble in water |
| Purity | Typically ≥98% |
| Storage Temperature | 2-8°C |
| Melting Point | 175-185°C (decomposes) |
| Synonyms | 3-Picolylethylamine dihydrochloride |
| Ph | Approximately 4.0 (1% solution in water) |
As an accredited 3-(2-Aminoethyl)pyridinedi hydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical, 3-(2-Aminoethyl)pyridine dihydrochloride (5g), is packaged in a sealed, amber glass bottle with a tamper-evident cap. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 3-(2-Aminoethyl)pyridine dihydrochloride: Typically 13–14 metric tons, packed in 25 kg fiber drums/polythene-lined bags. |
| Shipping | **Shipping Description:** 3-(2-Aminoethyl)pyridine dihydrochloride is shipped in a tightly sealed container to protect it from moisture and air. Transported under ambient conditions unless otherwise specified, the chemical is labeled according to regulatory standards, with documentation provided for safe handling and compliance with all applicable shipping guidelines for laboratory reagents. |
| Storage | **Storage for 3-(2-Aminoethyl)pyridine dihydrochloride:** Store in a tightly sealed container, protected from moisture and light. Keep at room temperature (15–25 °C) in a cool, dry, and well-ventilated area. Avoid exposure to incompatible substances such as strong oxidizing agents. Label clearly and follow relevant chemical storage guidelines to ensure safety and maintain substance stability. |
| Shelf Life | 3-(2-Aminoethyl)pyridinedi hydrochloride typically has a shelf life of 2 years when stored tightly sealed and protected from moisture at room temperature. |
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Purity 98%: 3-(2-Aminoethyl)pyridinedi hydrochloride with purity 98% is used in pharmaceutical research, where high purity ensures reliable biological assay results. Molecular weight 191.1 g/mol: 3-(2-Aminoethyl)pyridinedi hydrochloride with molecular weight 191.1 g/mol is used in drug development protocols, where accurate mass facilitates precise formulation calculations. Melting point 200-205°C: 3-(2-Aminoethyl)pyridinedi hydrochloride with melting point 200-205°C is used in compound synthesis workflows, where thermal stability enables high-temperature processing. Solubility in water ≥50 mg/mL: 3-(2-Aminoethyl)pyridinedi hydrochloride with solubility in water ≥50 mg/mL is used in biochemical assays, where enhanced solubility optimizes reagent preparation. Stability at pH 7: 3-(2-Aminoethyl)pyridinedi hydrochloride stable at pH 7 is used in buffer formulation, where pH stability prevents compound degradation during storage. Particle size ≤10 μm: 3-(2-Aminoethyl)pyridinedi hydrochloride with particle size ≤10 μm is used in chromatographic separation processes, where fine particle distribution improves analytical resolution. Storage temperature 2-8°C: 3-(2-Aminoethyl)pyridinedi hydrochloride with recommended storage temperature 2-8°C is used in laboratory reagent inventories, where controlled storage maintains compound integrity. |
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Every batch of 3-(2-Aminoethyl)pyridinedi hydrochloride that rolls out of our reactors reflects direct hands-on involvement, rigorous control, and decades of chemical manufacturing expertise. This isn’t an off-the-shelf compound slung between suppliers, but one that starts in our lab where our team scrutinizes sourcing of each raw material. The finished product finds use under many names and forms, but our own is set apart by the process design and quality markers we have put in place.
Our team produces 3-(2-Aminoethyl)pyridinedi hydrochloride—also known in many labs as AEPC dihydrochloride—in solid crystalline form. The white, free-flowing crystals consistently meet a purity specification exceeding 98%. We verify each batch with HPLC and NMR analysis, with a chemical structure tailored to suit demanding research, pharmaceutical development, and synthesis settings. Customers rely on clarity in melting point and moisture levels; our batches achieve narrow melting point ranges and we keep residual solvents to genuine trace amounts, well below accepted limits.
This compound isn’t a demo sample or specialty order—it is a foundational raw material for projects in drug discovery, bioconjugation, and investigational probe development. Chemists value the combination of a pyridine ring and an aminoethyl side chain, which lends high reactivity for alkylation, acylation, or functionalization steps. At least two out of every ten labs purchasing directly from us use it for creating pyridine-based ligands in advance coordination chemistry work. Laboratory teams exploring enzyme-substrate interactions also include our 3-(2-Aminoethyl)pyridinedi hydrochloride as a linker or spacer unit because of its favorable handling properties; the dihydrochloride salt form dissolves readily in both water and mild alcohol solvents, making it adaptable for a range of protocols and enabling straightforward clean-up during scale-up or purification.
Customers in the research and production sectors continuously look for reliability, not just on-paper purity. Small variations in crystalline quality and salt content can derail entire reaction schemes, and this is where our in-house control plays a significant role. We build stability into the supply by integrating in-line monitoring, and after years of feedback from repeat partners, we have modified filtration, drying, and packing steps to minimize contamination or degradation during shipping and storage. While secondary vendors sometimes relabel material from multiple origins, our facility enables tracing every lot back to raw input, wet synthesis, and even argon atmosphere drying conditions.
Not every 3-(2-Aminoethyl)pyridinedi hydrochloride lands on your benchtop the same way. We notice competitors shipping material that underwent bulk crystallization with insufficient purification, showing up as slightly yellowed product or containing excess chloride counterions, which could interfere with sensitive step reactions. Our batches leave the plant only after confirmation of both low chloride excess and high purity in side-by-side reference analysis. We avoid the shortcut of simply drying under ambient conditions, which can attract moisture and degrade reactivity—even small water uptakes can skew a downstream reaction’s selectivity or yield.
Beyond appearance, shelf stability and reactivity set our product apart. Years ago, pilot customers flagged product from other vendors showing slow discoloration or granular breakdown in storage. Our investigations pointed to overlooked residual acidity and improper handling during final drying. Improvements in our own process led to new drying regimes and higher-grade packaging, something that remains non-negotiable in our shipping protocols today.
We ship 3-(2-Aminoethyl)pyridinedi hydrochloride only in airtight inner liners within industry-grade bottles. Our staff avoid the temptation to bulk-pack for easy shipping, since the extended exposure increases risk of caking and moisture absorption, even when moved across very short distances in our warehouse. Short-term storage on customers’ side is unproblematic at ambient conditions if the cap remains tightly sealed, but in our own experience, lab users working at scale often notice the difference in flow consistency and powder integrity compared with repackaged material, particularly in winter months or humid climates.
Feedback from field chemists informs every improvement. One team reported improved reproducibility in Suzuki couplings using our compound over an alternate vendor’s, due to less variable chloride background. Another research group in analytical chemistry cited lower baseline drift in HPLC analysis after switching to our material, attributing this to the extra attention we pay to particle filtration before final crystallization. Instead of rushing production, we have built our operating tempo around supporting these needs, which ultimately drives the advances in synthesis that our customers achieve.
Stakeholders expect more than a data sheet. Each release comes with a full analytical suite: melting point trace, chromatograph, moisture content, heavy metal contamination, and a certifiable NMR reference spectrum. Our background living with these materials day in and day out lets us see small variations that make a big difference in downstream work. Suspiciously high chloride? We flag it. Trace solvent residue? It gets sent back to drying. From time to time, unexpected peaks in NMR prompt us to halt production while we trace the issue to a material or process adjustment, ensuring consistency for our direct customers.
The feedback loop between manufacturer and end-user closes faster because we keep shipping channels, technical support, and process engineering in one facility. If a customer indicates batch-to-batch variability, our team re-examines the full workflow instead of leaning on paper statistics. In one case, a synthetic chemistry lab noticed a minor impurity affecting catalyst performance in ligation reactions. Our staff traced this to a vendor switch in a precursor, leading to immediate supplier reevaluation and closed communication with the customer until the issue resolved. This transparent troubleshooting is only possible with full control of the manufacturing line rather than coordinating between resellers or distant processors.
Our direct involvement in chemical synthesis means we track regulatory and health requirements for both laboratory and industrial contexts. While plenty of chemical resellers overlook finer handling distinctions to save time, we adapted packaging and shipping processes to match both domestic and international regulatory requirements. This means compliance for researchers submitting projects for clinical trial or pilot batch compliance. The documentation follows real workflow, backed not just by GHS-compliant labeling but verified batch traceability for each customer record. We maintain rigorous archiving of every batch for no less than five years, allowing researchers to match past performance, troubleshoot new results, or address unanticipated audit questions with confidence.
Medicinal chemistry and bioconjugate development demand tight controls over ionic strength, solubility, and purity. 3-(2-Aminoethyl)pyridinedi hydrochloride serves in these roles due to its ability to act as a coupling agent, amine donor, or functional linker between more complex scaffolds. Over time, our own customers noticed greater batch-to-batch reliability from our plant than through multi-stage supply chains feeding through third parties. Each improvement—whether in drying, filtration or packaging—came from face-to-face conversations between lab users and plant staff, not executive directives in distant offices. In some projects, being able to guarantee every step from input to output determines project funding, regulatory submissions, or publication quality. We match these expectations because we’re on the same end of the challenge.
Synthetic failures cost not just time but also reputation and downstream project timelines. As a manufacturer, we begin with the premise that expectations for analytical grade 3-(2-Aminoethyl)pyridinedi hydrochloride must extend far beyond the minimum published requirements. Our process team addresses failure points by reviewing not just synthesis and purification, but long-term stability under real-world shipping and handling. The difference in downstream success becomes especially evident in reaction scale-up, where even minor impurities seed side reactions and lower overall yield. As a result, our product appears in established research literature not only because of analytical performance, but because of the hands-on consistency that recurring lab users report.
Producing chemicals like 3-(2-Aminoethyl)pyridinedi hydrochloride comes with significant responsibility to both staff and community. Effluent control, air quality, and solvent reclamation matter as much on our plant floor as they do to our regulatory partners. We invest heavily into in-process scrubbers, closed-loop solvent recapture, and real-time air monitoring, significantly lowering both carbon and chloride emissions relative to less managed operations. Both research teams and industrial users increasingly request sustainability data for their supply chains. Being able to answer those requests with direct records and not just broad claims means our customers know the story behind the material.
Lab staff often call us mid-project when a reaction hits a snag or an unfamiliar impurity turns up in their notebook. Answers don’t come from a call center or faceless email queue—they come directly from our chemists who have made, analyzed, and packaged the same compound. This experience creates a problem-solving capability others can’t replicate. Our plant and technical teams have helped customers tweak solvent loadings, adjust pH, or identify unknown spots on TLC, all traced back to real-world experience handling this material from synthesis through to storage.
Project success rides as much on the reliability of supply as the underlying chemistry. Chemists in the field push back if they sense a supplier drifting away from practical challenges; as a direct manufacturer, we stay engaged and incorporate suggestions into both small process changes and large-scale facility upgrades. The result? Cleaner reactions, faster troubleshooting, and less lost time.
Manufacturers see the true cost of variability firsthand. Early in our production history, switching between different suppliers of precursors led to minor but real shifts in reaction reproducibility among our customers’ processes. That lesson cemented our commitment to in-house quality audits and full traceability for every lot. Researchers running drug screening campaigns or preparing multi-step syntheses rely not only on material availability but on the knowledge that every gram matches the last in performance and appearance.
Our production philosophy extends through every detail, right down to the paper we use to archive NMR traces. By investing in analytical equipment, retaining technical staff with a direct hand in both batch production and customer support, and allowing for production pauses in the rare case of a plant anomaly, we’ve built a business where material trust comes ahead of sales performance.
Years of shipping 3-(2-Aminoethyl)pyridinedi hydrochloride to demanding chemists have confirmed one truth: the more direct the path from synthesis to lab bench, the greater the result. There are no shortcuts in the daily job of chemical production; control at each stage matters as much as the final analytical readout. Whether your work revolves around drug development, diagnostic chemistry, or fundamental research, every decision about input matters—just as every decision about process design, raw material verification, and product feedback does on our production floor. We stay in this business because each improvement in output builds real progress, not just in our facility, but in client labs around the world.
