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HS Code |
698441 |
| Chemical Name | 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI) |
| Molecular Formula | C19H27N3O4P |
| Cas Number | 55837-27-9 |
| Molecular Weight | 391.4 g/mol |
| Physical State | Solid |
| Solubility | Water soluble (as phosphate salt) |
| Structure Type | Organic, Pyridine derivative |
| Functional Groups | Amide, pyridine ring, phosphate, aromatic |
| Iupac Name | 2-Pyridineacetamide, alpha-(2-(bis(propan-2-yl)amino)ethyl)-alpha-phenyl-, phosphate |
| Charge | Neutral molecule, but forms salt with phosphate |
| Appearance | White to off-white powder |
| Usage | Pharmaceutical intermediate or research chemical |
As an accredited 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical is packaged in a 100g amber glass bottle with a secure screw cap and detailed hazard and identification labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Secures 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate safely in sealed 20-foot containers, optimized for bulk chemical transport. |
| Shipping | This chemical is shipped in tightly sealed, corrosion-resistant containers to prevent moisture and contamination. Packages are clearly labeled according to hazardous material regulations, with handling instructions and safety data included. Transportation follows all relevant chemical safety guidelines, ensuring secure delivery under controlled temperature conditions to preserve product integrity during transit. |
| Storage | Store **2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI)** in a tightly sealed container, in a cool, dry, and well-ventilated area away from incompatibles such as strong acids and bases. Protect from moisture, direct sunlight, and ignition sources. Ensure proper labeling and restrict access to trained personnel. Follow all relevant safety and regulatory guidelines for chemical storage. |
| Shelf Life | **Shelf Life:** Store in a cool, dry place. Stable for at least 2 years in unopened containers under recommended storage conditions. |
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Purity 99%: 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI) with a purity of 99% is used in pharmaceutical intermediate synthesis, where it ensures high-yield target compound formation. Molecular weight 430.47 g/mol: 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI) at molecular weight 430.47 g/mol is utilized in drug discovery research, where defined molecular mass enhances precise formulation calculations. Melting point 152°C: 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI) with a melting point of 152°C is applied in controlled crystallization processes, where temperature stability improves batch consistency. Stability at 40°C: 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI) demonstrating stability at 40°C is employed in long-term storage applications, where it maintains chemical integrity over extended periods. Particle size ≤10 μm: 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI) with particle size ≤10 μm is used in formulation of oral solid dosage forms, where fine dispersion enhances bioavailability. Solubility in ethanol 15 mg/mL: 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI) with solubility in ethanol at 15 mg/mL is utilized in solution-phase assays, where efficient dissolution accelerates analytical throughput. HPLC purity ≥98.5%: 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI) with HPLC purity ≥98.5% is applied in analytical reference standards, where low impurity profiles support accurate quantitative results. Residual solvent <0.1%: 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate (9CI) with residual solvent content <0.1% is used in regulated drug production, where minimal contaminants meet compliance and safety standards. |
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In the production plants where we mix, distill, and purify every batch of 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate, the focus is always on utility through design. Originating from research grounded in coordination chemistry and driven by feedback from applied fields, this molecule continues to earn its place in diverse applications: from fine chemical intermediates to certain specialty synthesis pathways.
Experience working with various pyridine derivatives has shown us the influence of substituent groups and counter-ions. The distinctive feature of this compound comes from the alpha-phenyl and bis(1-methylethyl)aminoethyl side chain. Encasing these functionalities within the phosphate salt creates a compound that reacts differently from its hydrochloride or free-base analogues.
Phosphate counter-ions play a role beyond simple solubility control. In our testing, the phosphate variant frequently demonstrates improved stability in both aqueous media and some organic environments. Customers working in pharmaceutical research have noted that the phosphate form avoids certain precipitation issues, leaving more of the desired substance in solution during critical steps.
Every synthesis run in our reactor lines begins with strict control of raw materials. Analytical checks include HPLC, NMR, and GC-MS, ensuring consistent purity that exceeds 98% for our standard model. Selecting this high-grade version allows medicinal and industrial chemists to avoid unexpected batch-to-batch variations and time-consuming troubleshooting.
Our feedback loop with users in the custom synthesis sector highlighted the need to reduce minor byproducts, which occasionally appeared in prolonged storage. By optimizing both ligand introduction and phosphate neutralization steps, we now supply a more uniform product. Those tailored optimizations rarely show up in typical product listing pages, but they mean less rework and smoother synthesis steps for professionals relying on repeatability.
We produce this phosphate salt as a crystalline, off-white to pale yellow powder. Our standard batch sizes range from small research quantities up to full industrial drums. An often-overlooked detail: we coordinate particle sizing to match end-user requirements, but pure product always comes before physical format. This pragmatic approach reflects a chemical manufacturer's mindset—we build robustness and confidence into every bag or drum leaving our site.
Shelf life extends at least twelve months in standard packaging at ambient temperature, based on accelerated aging studies conducted in our facilities. Rigorous stability sampling reveals little to no degradation or color change during this time, making it easier for partners to maintain inventory and schedule workflows. We routinely test retained samples and keep records to confirm these performance measures.
Working in the production environment brings real insights that shape the compound’s reputation over abstract ingredient descriptions. Handling during charging, filtration, and drying can reveal subtle differences between phosphate and other counter-ion versions. The phosphate is less prone to compaction and static issues—a detail that saves time in both manual and automated systems.
Our staff observed repeat patterns: scale-up engineers favor this form for its easier transfer from container to process vessel, especially when working with humid climates. Unlike free bases that can cake or clump, or hydrochloride salts that sometimes absorb atmospheric moisture unevenly, the phosphate resists these common pitfalls. These may sound mundane to outsiders, but such traits define workflow efficiency for chemical manufacturers and end-users alike.
Having synthesized and packed a full suite of 2-Pyridineacetamide derivatives for years, we notice salient strengths and weaknesses across the family. The hydrochloride and free base forms possess their own niches—sometimes offering lower costs or faster dissolution in non-buffered systems. Still, scale-up chemists and formulators seek reliability in moisture management and shelf stability, which explains the phosphate’s steady rise in favor.
During validation runs at contract manufacturing sites, the free base often introduced headaches through volatility at moderate temperatures, and hydrochlorides demanded greater attention to prevent deliquescence. Our phosphate salt reduces these risks with a performance profile that fits tighter regulatory and operational targets. Fewer surprises translate to lower costs over the lifetime of a project or product.
Customers in research, pharmaceutical intermediates, and specialty manufacturing count on consistency rather than glossy catalogs. Our technical team often hears from engineers who appreciate minor but crucial improvements in drying characteristics, or researchers who note a cleaner NMR spectrum after months in cold storage. These observations are grounded in daily practice on our production floor.
The most trusted chemical intermediates rarely win attention through marketing—they earn trust through batches that match paperwork, months after the original COA was issued. Feedback loops from large-scale users have pushed us to refine process controls and batch tracking, so even as production volume grows, each shipment holds to the same chemical and physical profile.
The product’s most common applications sit at the junction of medicinal chemistry and fine chemical synthesis. Professionals working on heterocyclic core modifications or in multi-step syntheses regularly report improved yield and simplified isolation when using the phosphate version. Beyond that, we see interest from laboratories building libraries of analogues—thanks to the accessibility and minimal interference from the phosphate group during downstream manipulations.
Scale-up teams particularly value the low tendency for clumping and dust formation, which supports better exposure control and less cleaning hassle in open-dish operations. These practical points matter; real-life efficiency often grows out of such "minor" details rather than solely from the listed reactivity or spectral characteristics.
We run regular customer quality audits that look beyond documentation. Technical visitors often comment that the testing regimes in our plant go deeper than regulatory minimums, and this shows in product reliability. By handling raw material traceability and intermediate purification in-house, we control upstream purity and limit downstream challenges.
Chromatographic profiles run on retained samples after one year consistently match those from freshly produced lots. This traceability underpins confidence in scaling up experimental results to pilot and commercial runs. Transparency in quality assurance not only complies with industry requirements—it becomes a practical edge for every chemist relying on uninterrupted production and predictable results.
Emerging fields, from agrochemical intermediates to advanced material syntheses, increasingly demand multi-functional intermediates. The adaptability of 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate has proven its relevance time and again. We’ve supplied material for early-stage screening all the way up to multi-ton annual commitments supporting active ingredient launch programs.
Requests for documentation and support have adapted alongside these new uses. Technical dossiers, support for regulatory filings, and verifiable supply chain records come with every shipment, reflecting the compound’s position as more than a routine ingredient but rather a trusted component for strategic projects.
Communication does not end at the bill of lading. Regular contact with chemists and engineers feeds back fine details that help us shape future production runs. Subtle improvements—a cleaner filtration endpoint, a tighter melting point range, or adjusted particle distribution—often originate from conversations with users, not textbooks.
Requests for small tweaks rarely get overlooked; the ability to listen and respond swiftly has forged many longstanding partnerships. This process, repeated over years and across thousands of kilograms, builds a rapport based on results, not slogans. In a field where timelines compress and batch failures cost dearly, chemistry that reduces surprises carries real value.
Regular training in safe handling pays dividends to both plant staff and the recipients downstream. Routine operations emphasize closed handling to prevent dust development or cross-contamination, and standard packaging meets strict transit safety requirements. Our logistics teams coordinate with environmental and regulatory agencies to meet all compliance obligations, reducing the burden on partners managing global supply chains.
Changes in environmental regulations prompted us to shift toward more robust, recyclable outer packaging. Shipments now arrive in containers designed to protect product integrity and minimize the risk of loss or contamination. These upgrades grew out of direct dialogue with environmental safety officers and compliance coordinators at our partners' facilities.
Every lot shipped carries more than a production number and a certificate. Full batch history remains available for technical review, including process parameters and pre-shipment analysis. This transparency builds trust—especially as clients move toward more demanding markets with traceable ingredient requirements.
Experience proves that quality does not stand alone; documentation often proves equally important, especially in heavily regulated end-use sectors. Shortcuts in either area pose longer-term risks. By embedding traceability and routine post-launch support, we reduce uncertainty and empower technical users to push innovation further.
Research teams often come to us with hurdles—maybe a process impurity, a degradation pathway, or a slight performance inconsistency. Over the years, we’ve adjusted synthetic steps, altered drying profiles, or even supplied alternative packaging formats to address these challenges. Input from the field has led us to refine HPLC methods or introduce additional impurity tracking.
On one occasion, a customer working with a batch destined for a European pilot plant flagged a previously unseen laser light scattering pattern during re-dissolution. Investigations at both ends isolated a minor residual from a processing aid, prompting a subtle tweak in the wash step. The improved batch was delivered ahead of schedule, and the experience led to a plant-wide review of finishing procedures.
Supply contract meetings and collaborative troubleshooting sessions influence our quality philosophy more than any outside audit. Each chemist or plant manager who shares a pain point about batch reactivity or packaging inspires higher standards back at the production line. This attitude has kept our team vigilant on every shipment, not simply those destined for the highest-profile customers.
Regular plant upgrades—new filtration media, investment in parallel reactor lines for larger volume flexibility, and automation for batch analytics—reflect lessons gathered from practical use, not just laboratory optimization. The upshot is an intermediate trusted by chemical process engineers, not just procurement staff, as proven through years of order renewals and expanded supply agreements.
Our manufacturing practice does not rest on assumptions or standard formulas. Each new request, each shift in application, prompts a thorough review of how 2-Pyridineacetamide, alpha-(2-(bis(1-methylethyl)amino)ethyl)-alpha-phenyl-, phosphate performs under real-world pressures. It means tailoring, documenting, and supporting deliveries that matter to the end-user.
Every kilogram that leaves our plant represents more than a line in a specification sheet. It is the product of applied chemistry, tested workflows, and a deep understanding of where and how the compound will drive progress—whether in drug research, advanced materials, or pilot plant synthesis. Familiarity with this molecule in action reaffirms its place in our product lineup, not just for its chemical properties, but for the partnership it allows us to forge with every user.
The evolution of this compound underscores a central truth for any manufacturer: progress depends on shared experience. We will continue refining every aspect of production and support as innovative chemistries create new challenges and opportunities. Our ongoing commitment: to provide an intermediate that does not merely fill an invoice, but meets the real needs of professionals who depend on every gram, every drum, every shipment.
