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HS Code |
270964 |
| Chemical Name | 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate |
| Molecular Formula | C21H32N3O4P |
| Molecular Weight | 437.48 g/mol |
| Cas Number | 63989-70-0 |
| Appearance | White to off-white powder |
| Solubility | Soluble in water |
| Boiling Point | Decomposes before boiling |
| Purity | Typically ≥98% |
| Storage Conditions | Store at 2-8°C, protected from light and moisture |
As an accredited 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed amber glass bottle containing 25 grams of 2-Pyridineacetamide, labeled with chemical name, hazard symbols, batch number, and storage instructions. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Chemical packed in UN-approved drums, securely palletized, and containerized in 20′ FCL for safe, compliant international shipping. |
| Shipping | 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate should be shipped in compliance with chemical safety regulations. Use tightly sealed containers, secure secondary packaging, and clear hazard labeling. Protect from moisture and extreme temperatures. Ship via approved courier with appropriate documentation, including Safety Data Sheet (SDS) and emergency contact information. Handle and transport as a potentially hazardous material. |
| Storage | Store **2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate** in a tightly sealed container, in a cool, dry, and well-ventilated area. Protect from light, moisture, and incompatible substances such as strong oxidizers and acids. Ensure storage area is secure and clearly labeled, with appropriate precautions in place to prevent accidental exposure or spillage. Follow all relevant safety regulations. |
| Shelf Life | Shelf life: Store 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate tightly sealed at 2–8°C; stable for 2 years. |
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Purity 98%: 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate with a purity of 98% is used in pharmaceutical synthesis, where high product integrity and reduced side-products are achieved. Molecular weight 410.46 g/mol: 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate with a molecular weight of 410.46 g/mol is used in medicinal chemistry research, where precise dosing and reproducibility are ensured. Water solubility 50 mg/mL: 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate with water solubility of 50 mg/mL is used in injectable formulation development, where rapid dissolution and homogeneity are critical. Stability temperature up to 60°C: 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate with stability temperature up to 60°C is used in industrial storage conditions, where long-term preservation of chemical activity is maintained. Fine powder particle size <30 μm: 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate in fine powder particle size below 30 μm is used in solid dispersion techniques, where uniformity in drug-carrier matrices is supported. Melting point 160°C: 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate with a melting point of 160°C is used in high-temperature synthesis workflows, where thermal stability prevents decomposition. pH 6.5 in 1% solution: 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate at pH 6.5 in 1% solution is used in buffered pharmaceutical preparations, where optimal compound ionization and bioavailability are ensured. |
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Manufacturing chemical intermediates often means navigating between intricate synthesis steps, purity control, and scalability. Our experience tells us that every new compound presents its own challenges. 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate stands out because of the complexity inherent in its structure: the combination of the pyridine ring, acetamide backbone, and a phosphate counterion all demand close attention at the production stage. This isn't a shelf-staple organic molecule. Every batch tells its own story through its subtle reactivity and sensitivity to process conditions.
Handling materials bearing both heterocycles and sterically hindered amines—like diisopropylamino groups—creates unique bottlenecks. We work with reaction pathways that minimize byproducts and allow consistent isolation of the phosphate salt with reproducible crystalline form and particle size. Many off-the-shelf products cut corners with neutralizing agents or batch drying, but consistent process control delivers a white, free-flowing solid every time. Over the years, downstream customers have commented on the clear difference in handling and analytical consistency compared to imported batches or products recombined with third-party agents.
Producing a substituted pyridineacetamide isn’t just about placing a functional group on a ring. The synthesis usually passes through an alkylation sequence, where the challenge lies in steering the reaction to avoid sidechains attaching at non-target carbons. Our process utilizes analytical methods—NMR, HPLC, and mass spectrometry—at several steps, so every bottle or drum ends up with an actual identity, not just a label. You can tell from the way our batches behave in solution, and how long samples remain stable even after repeated opening. This is not trivial—moisture uptake and trace oxidation can compromise activity or cause trouble during formulation.
Every production run involves close monitoring of phosphate incorporation. Poorly executed batches in the market are often fuzzy or off-white, and moisture uptake leads to clumping or phase separation. Our routine achieves fine control over pH and counterion loading, giving users material that disperses easily and stores well. That might seem mundane, but anyone who has handled caked intermediates that won’t redissolve knows this can destroy process efficiency downstream.
Our chemists originally synthesized this compound for custom research orders coming out of pharmaceutical development, where biologically active small molecules often require intricate side chains to balance solubility and cell membrane penetration. 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate has since moved beyond those origins. Customers in medicinal chemistry, agrochemical research, and even some advanced electrolyte work have used the material for varied transformations.
In drug discovery and lead optimization, this structure serves as both a fragment and a scaffold. The pyridine segment offers a platform for further elaboration and binding studies, while the acetamide backbone can yield a range of amide-linked analogs. Bench chemists can count on repeat performance: the water-soluble phosphate counterion means easy dissolution, and our process control prevents residual catalytic metals from compromising downstream assays.
Researchers working in small batch reactions report that other sources supply inconsistent product, showing either lot-to-lot instability or difficulty dissolving the material in polar organic solvents. The phosphate salt our team prepares does not suffer from these issues, which matters if you are creating libraries of derivatives or screening compounds on automated systems. Less downtime and less troubleshooting. In the hands-on environment of most discovery labs, those details add up.
Every manufacturer faces pressure from both the market and internal requirements to balance scale and precision. With a molecule featuring multiple chiral centers and functional moieties, trace impurities create downstream problems that often go unnoticed by anyone but the most meticulous researchers. We have learned—sometimes through real setbacks—that process repeatability drives product quality more than raw materials or equipment age. Over 20 years of scaling up from gram to multi-kilogram runs, our operators have developed protocols for temperature ramp rates, order of reagent addition, and post-synthesis work-up.
Samples from shops with less robust quality focus show visible and measurable differences. Telltale signs like off-color tints, fluctuating melting points, or abnormal NMR splitting patterns reflect upstream shortcuts. In some cases, impurities pose safety risks or trigger regulatory red flags. We keep extensive batch records that go far beyond regulatory mandates, tracing every step and check from raw input to finished output. Customers have remarked on the way our certificates of analysis reflect real, lot-specific analytical data instead of boilerplate line entries.
It's not always glamorous. Some nights involve late shifts tracking down a yield drop that emerges halfway through a crystallization. Sometimes years of incremental adjustment—tweaking solvent ratios, substitution sequence, or standing time—pay dividends by shaving minutes off a filtration or improving the product’s stability by weeks or months on storage. We’ve found that many issues reported by end-users could have been solved during manufacture by simply running a few extra chromatograms or setting a tighter specification. This level of attention results in higher cost per kilo, but the feedback from our regular clients confirms the real savings appear in reduced batch failure rates and less rework.
On paper, some would say 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate resembles other acetamides or even the unsubstituted parent structures. Colleagues in purchasing often ask what really sets this item apart, since dozens of catalog suppliers list similar compounds. In practice, customers tell a different story.
We’ve heard dissatisfaction with competitors' versions that show ghost peaks in HPLC or residue after evaporation. Our internal comparisons demonstrate that low-end material doesn't perform well in coupling reactions or advanced transformations, such as those involving amide bond creation or site-selective alkylation. There’s no shortcut: impurity levels under 0.15% require extra rinses and repeated crystallization—steps that cut into throughput and profit margin. The end product, though, dissolves on the first try in both water and organic media, and the difference is obvious to anyone preparing a complex reagent loadout.
Trying to save costs with blends or partial counterion exchange can yield sluggish reactions or waste whole days in troubleshooting. We have tested numerous supplier samples in our own pre-pilot trials, noting marked differences in melting range and hygroscopicity. Several batches from other sources showed spotty NMR spectra, indicating incomplete sidechain alkylation or improper salt formation. In contrast, our samples produce clean spectra, uniform melting point, and a robust shelf stability profile.
A fine chemical like this rarely stands alone. It acts as a key intermediate or building block, often incorporated into much larger, more valuable molecules. Over the years, process engineers have shared stories with us about batches gone wrong because of odd impurities or inappropriate particle morphology. Sometimes an overlooked process tweak increased the surface area and led to rapid dissolution, causing foaming or precipitation during scale-up. Other times, the presence of trace inorganic salts fouled catalysts or altered assay outcomes.
Every facility has its own requirements. Some users need minimal water content for coupling chemistry, while others prefer predictable salt content for downstream crystallization or formulation. We routinely share technical data packages that document the phosphate stoichiometry, residual solvent content, and detailed impurity breakdown. Troubleshooting at the user’s end drops sharply once the product’s lot-to-lot consistency improves. This isn't about chasing some theoretical ideal; it’s about supporting users faced with hard timelines and demanding projects, where one failed reaction means lost time and money.
Sustainable chemical manufacturing demands attention to safety and environmental stewardship. Complex amide-phosphate molecules present handling risks, especially during neutralization and purification. Our grounds-level knowledge of air handling, solvent recovery, and spill response has evolved through experience rather than outdated rote practice. For example, the waste management plans adapted and improved as reclaimable solvent fractions increased; less waste means better yield and lower disposal cost.
We've also invested in closed-system transfer and filtration to minimize operator exposure and environmental leakage. Some competitors punt on these issues, cutting corners on downstream cleaning or venting protocols. Our team has learned from hard lessons: one spill can sideline a production area for days and trigger expensive remediation. The investment in thicker seals and continuous atmosphere monitoring was not a regulatory box-tick, but a way to keep experienced operators in good health and working safely.
Customers downstream benefit because product quality begins in a well-maintained, responsibly run production plant. Less cross-contamination, fewer accidental batch contaminations, and more reliable tank-to-drum transfer underpin our day-to-day work. Every production cycle incorporates batch-specific worker safety reviews. Our product, from mixing to final packaging, carries those lessons built in, supporting a safer, more robust supply chain for everyone who touches it.
Commercial, process, and academic chemists who contact us often ask whether novel intermediates can be scaled for pilot or commercial production. We approach projects with eyes wide open about the real-world difficulties. With 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate, batch sizes have grown by over three orders of magnitude as clients moved from milligram discovery runs to preclinical batches, and then to scale-up trials.
The differences emerge quickly at larger scale. Solubility, filterability, and even packaging make a difference when shifting from glass bottles to kegs or drums. Early on, we found that product sitting for extended periods at high humidity absorbed moisture quickly, altering assay values and compromising reactivity. Tangible investments in desiccant processes, vapor-proof drums, and secondary packaging now keep every outgoing lot within specification for months.
Scaling up also exposed unanticipated challenges in reaction exotherms and mixing regimes. Our engineers collaborated with pilot plant technicians to optimize agitation and temperature ramps, which minimized local overheating and product degradation. On several occasions, unanticipated phase changes revealed bottlenecks, prompting changes in addition sequence or post-reaction workup. These real lessons, earned in the factory, mean our final product travels safely from our facility to the customer’s laboratory or plant. There’s no substitute for the hard data generated by working up every process step at true industrial scale.
New demands from customers drive us to rethink established practices. Requests for higher analytical purity, more demanding particle size distributions, or enhanced stability under specific storage conditions have forced us to dig deeper. In each case, our process development team designed experiments to answer whether the tweaking of solvent, pH, or order of addition genuinely improved the finished material or merely shifted the problem downstream.
On more than one occasion, direct feedback from regular clients has spurred improvements in our purification stages. One client, faced with a failed downstream coupling, diagnosed a residual isopropyl impurity. Together, we isolated the issue to a specific post-alkylation rinse. Adapting the protocol paid off in both improved product performance and fewer returns. That’s the kind of result that builds loyalty: by working side-by-side with customers, we make material that actually works at scale and supports new research.
Open communication remains key. Our technical support has grown not because of call center scripts, but because real chemists, with years on the plant floor, pick up the phone or answer emails. Whether discussing a failed batch, an uncooperative filter, or a simple question about shelf life, people get the truth about problems, and quick action to resolve them. In this way, chemical manufacturing remains a living discipline, adapting over time to new needs, and always looking for the next improvement.
As regulatory scrutiny sharpens and advanced synthesis demands increase, simply meeting minimum requirements no longer sets a manufacturer apart. In the world of custom and fine chemicals, accountability, transparency, and a deep knowledge of both molecule and process still matter most. With every batch of 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate we deliver, these values take material form.
The diversity of uses for this compound continues to expand, from core drug intermediates to enabling complex library synthesis, and even specialty applications in advanced materials. Each use case brings its own technical and process challenges. Our team’s history of creative problem-solving and responsive adjustment means researchers and process engineers can build with greater confidence.
All the market pressures, from raw material cost spikes to regulatory changes, have tested our operating principles. Decisions to invest in better cleaning, more precise analytical tracking, or closer lot-specific documentation proved their worth through rising repeat business and lower rates of complaint. Long-term relationships rely on real, lived practice—not just paperwork or price lists. This lesson shapes every kilogram we manufacture.
The journey from pilot batch to established production line for 2-Pyridineacetamide, alpha-(2-(diisopropylamino)ethyl)-alpha-phenyl-, phosphate hasn’t followed a textbook path. Lessons from the shop floor, research benches, and customer troubleshooting have forged a product that sets real standards in its field. Every decision—from controlling humidity during packaging to tracing impurity evolution with each process tweak—carries weight, and customers experience that through easier formulation, robust performance, and reliable delivery.
Manufacturing specialized chemicals means more than engineering and quality documents: it's about connecting deep process knowledge to the practical realities facing scientists and engineers in discovery, development, and production. These connections shape our product and underpin the trust found in long-term relationships. We look forward to building on these lessons, supporting the next generation of research, and delivering solutions shaped by years of factory-tested improvements and responsive, transparent support.
