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HS Code |
572068 |
| Iupac Name | alpha-[2-(diisopropylamino)ethyl]-alpha-phenyl-2-pyridineacetamide |
| Molecular Formula | C22H29N3O |
| Molecular Weight | 351.49 g/mol |
| Cas Number | 15301-53-0 |
| Appearance | White to off-white solid |
| Solubility | Soluble in organic solvents such as ethanol and DMSO |
| Melting Point | Approximately 98-102 °C |
| Purity | Typically ≥98% (as supplied commercially) |
As an accredited alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | White HDPE bottle, tightly sealed, labeled with chemical name, 25 g net weight, hazard symbols, batch number, and manufacturer details. |
| Container Loading (20′ FCL) | 20′ FCL container loading: 8 metric tons, packed in 200 kg HDPE drums, securely palletized, suitable for chemical export compliance. |
| Shipping | Shipping of alpha-[2-(diisopropylamino)ethyl]-alpha-phenyl-2-pyridineacetamide should comply with all applicable chemical transportation regulations. The compound must be securely packaged in compatible, labeled containers, protected from moisture and light, and accompanied by safety data. Handle as potentially hazardous; transport by certified carriers with relevant documentation and emergency contact information. |
| Storage | Store **alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide** in a tightly sealed container, protected from light and moisture. Keep it at room temperature (15–25°C) in a well-ventilated, dry, and cool area, away from incompatible substances such as strong oxidizers and acids. Ensure proper chemical labeling and restrict access to trained personnel. Follow all local regulations for handling and storage. |
| Shelf Life | Shelf life: Typically stable for 2–3 years if stored in a cool, dry place, protected from light and moisture. |
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Purity 99%: alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide with 99% purity is used in pharmaceutical intermediate synthesis, where it ensures high-yield and low impurity formation. Melting Point 186°C: alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide at a melting point of 186°C is used in organic crystal engineering, where it contributes to controlled crystal lattice formation. Molecular Weight 348.49 g/mol: alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide with molecular weight 348.49 g/mol is used in drug discovery, where it facilitates accurate dosage formulations. Stability Temperature 75°C: alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide stable up to 75°C is used in process-scale synthesis, where it increases operational safety and storage life. Particle Size <10 microns: alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide with particle size less than 10 microns is used in tablet manufacturing, where it improves blending uniformity and dissolution rate. Water Content <0.5%: alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide with water content below 0.5% is used in anhydrous chemical reactions, where it minimizes hydrolysis risk and enhances product stability. Solubility in DMSO: alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide soluble in DMSO is used in preclinical assay development, where it allows for efficient compound screening and compatibility. Optical Purity 98% ee: alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide with 98% enantiomeric excess is used in chiral synthesis, where it leads to enhanced stereochemical outcomes in target molecules. |
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Our team has worked hands-on with alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide through its entire lifecycle—starting from the early bench-scale development, all the way to the large-scale reactor. We see this product not as a mere catalog entry, but as a result of continuous refinement driven by process safety, batch reproducibility, and the consistent demands of our industrial partners.
Alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide embodies the sort of molecule that challenges synthetic chemists, both in development and at commercial scale. Our facility runs dedicated reaction lines for its production, fully aware that variation in temperature, solvent quality, and even stirrer configuration can introduce batch-to-batch variation.
The molecule has earned its spot in the toolkit of professional researchers for pharmaceutical screens, agrochemical explorations, and even in some graduate research labs looking for leads. Real insight into this product comes from hands-on experience: it doesn’t behave quite the same way as generic amides or substituted pyridines.
Based on our process experience, we manufacture this amide using a multi-step synthesis sequence, keeping an eye on both yield and final chemical purity. Control of residual starting material is critical; it can cause unpredictable reaction downstream. Our reactor operators watch real-time analytical data, confirm every intermediate’s progress by TLC and HPLC, and only proceed when peaks show the right conversion. Our standard lots deliver with a purity above 98% (HPLC basis), and we hold each batch to tight limits on water content and residual solvents. This level of discipline makes a big difference when you run a 50-liter batch instead of a single flask in a university lab.
Particle size and appearance may seem minor, but our customers have told us how much ease of handling matters. We filter, dry, and grind to a fine powder, doing all this under an inert atmosphere to prevent oxidation or moisture uptake. Fine control over these steps defines whether a chemical translates smoothly from warehouse to beaker—or causes bottlenecks and delays.
Since rolling out our first production batch, users report several distinct applications. Medicinal chemists value this compound as a versatile scaffold for SAR development. That alpha-phenyl and diisopropylaminoethyl substitution seem to support selectivity profiles in targeted screens, and the pyridineacetamide core offers stable binding motifs for heterocyclic lead generation.
In agricultural chemistry, users respond most to its resistance to hydrolysis and strong affinity for certain biotargets. Several confidential R&D projects use derivatives for crop protection leads, with more than one multinational asking for custom substitutions on the framework. Unlike some of our simpler amide products, this molecule demands careful storage but rewards thoughtful formulation work.
Other reported uses include its incorporation into combinatorial libraries, not as a main ingredient, but as a structural motif that’s easy to modify while retaining most of the core’s properties. This flexibility defines its practical appeal—few compounds in our catalog match this blend of reactivity and stability in the same backbone.
Our experience as a manufacturer gives a unique perspective when comparing alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide to alternatives. Traditional amides—say, those derived from simple acetic acid or unsubstituted pyridine—react more predictably and rarely challenge scale-up or purification. This product, with its bulky side chain and heterocyclic core, stands out not for ease, but for its capacity to unlock new chemistry.
A typical challenge appears when customers attempt to adapt former processes based on simpler amides. In our plant, staff have developed protocols to accommodate higher boiling points and decreased solubility in standard solvents. Hot-stage filtration, antisolvent precipitation, and slow crystallization have become standard, not exceptions. Others might offer the molecule as a commodity, but we learned that good process chemistry here means minimizing waste and avoiding impurities that can upset further chemistry in downstream transformations.
Working at the source—the actual site where reagents, temperature, and analytical controls converge—gives us insight that traders and resellers lack. Packing and transport conditions (even exposure during loading docks in humid climates) influence long-term stability. We ship in double-lined bags, using desiccant and moisture indicators. Years on the shop floor taught us that paperwork rarely reflects the true hurdles met in a full-scale plant.
Our in-house analytical team inspects each output. We keep a retention sample for every lot, supporting our customers when unexpected phenomena occur. Sometimes users report crystallization anomalies or minor color shifts after prolonged storage; our technical team has tested conditions in controlled chambers to identify which storage containers lengthen shelf life most successfully.
Making this compound at scale means investing in equipment coatings and cleaning protocols. The slightly basic byproducts challenge ordinary glass reactors, so we invested in steel reactors lined with specialized coatings. Acidic washes between campaigns limit cross-contamination, another non-obvious step that yields purer material than what secondary traders deliver.
This amide’s synthesis puts real constraints on process engineers. Managing the diisopropylaminoethyl introduction takes tight control over temperature and reaction rate. If you cut corners or rush a stage, unreacted intermediates can linger, reducing yield and creating downstream purification headaches.
Scaling up from grams to kilograms calls for careful optimization—solvent swap, heat exchange, and precise stoichiometry. We run trials with alternate bases, actively monitoring impurity profiles. Many times, a promising laboratory yield requires a rethink once our pilot plant exposes issues unobserved in small scale: inhomogeneous mixing, hot spots, or inconsistent crystallization.
Human skill still matters. Operators track not only HPLC data, but visual cues—color shifts, gas evolution, exotherms. Training and real-world feedback refine our production manuals. Batches that meet all specs have often benefitted from mid-process interventions impossible in automated ‘lights-out’ plants. Some competitors, using less disciplined protocols, see more batch failures and scrap.
We pay attention to packaging because mistakes here create stress downstream. The amide absorbs moisture if left exposed, leading to clumping or even hydrolysis. We store bulk lots under nitrogen, then transfer and seal under dry conditions before shipping. Packaging lines get checked daily for integrity, and incoming feedback from end users led us to move to laminated liners, reducing breakdown during shipping.
On arrival in industrial or academic labs, the compound goes straight into dry storage. Customers working in humid regions, or where air conditioning fails, rely on our airtight packaging to keep product usable. A stale shipment tells us right away that a seal broke at some stage, so we track each box; logistics partners follow our handling instructions, learned by trial, not by textbook.
Some customers request smaller packs or pre-measured aliquots; we fill these orders using dedicated cleanrooms. Staff gown up, clean weighing booths before and after filling. In our observation, these are steps that preserve the compound’s free-flowing nature and chemical stability—choices shaped by years facing the complaints, challenges, and praise of real-world users.
Running a modern chemical plant, we see every day how much waste management and process improvement can improve both efficiency and environmental record. Earlier iterations of the process generated more solvent waste and required more extensive purification. Stepwise process improvement—especially solvent recovery and heat integration—has cut total waste output and energy use.
We partner with specialized waste treatment companies for byproduct streams and uphold a rigorous solvent recycling schedule. Our engineers monitor recycle fractions so downstream impurities don’t accumulate to harmful levels. Our technical documents don’t just claim environmental benefits—we prove it with actual reduction in chemical oxygen demand (COD) values in our wastewater after process redesign.
Working with big customers, especially those with their own ESG commitments, brought their audit teams right to the plant. Our open-door policy for third-party process audits gave us external reviews, sometimes identifying overlooked tweaks that further reduce impact. The unexpected bonus: tuning our processes for cleaner production often improves bottom line, through lower raw material and disposal costs.
Most product improvements stem from what our customers tell us after months of use, not from marketing plans. One pharmaceutical lab reported that they encountered a rare impurity traced back to a minor vendor change in a starting material—feedback that prompted us to implement tighter supplier audits and dual-source strategies. This approach, shaped by cumulative practical experience, makes our product supply less vulnerable to global disruptions or raw material shortages.
Another customer, who formulates small molecule assays, found differing performance between stocks after storage under fluctuating lab temperatures. To address this, we conducted a series of shelf-life studies in climatic chambers, using real product and packaging. Our findings sent us back to update our suggested storage guidelines, now distributed with each order.
Feedback from animal health chemists led to a switch in drying protocols; residual solvents present in trace amounts caused odd behavior in some enzyme screening steps. Our in-house fix increased drying time and modified vacuum conditions, minimizing traces, and since then, reports of these effects stopped. Hands-on troubleshooting—combining customer data and in-plant analytical testing—helps us act before small problems become systemic issues.
Supplying sensitive synthetic intermediates requires more than just product quality at shipment. Batches stay traceable, with records for over a decade, including analytical results, plant operator notes, and customer reports. This routine preserves institutional knowledge. If a rare complaint surfaces years later, we reconstruct the entire path from raw material loading to final product delivery, letting us pinpoint breakdowns along the chain.
We record process adjustments, maintenance cycles, and rare deviations in equipment behavior. These logs supported us in real incidents—one time, a spectral mismatch on final HPLC drew attention to a calibration fault in an analytical column. Correcting it and alerting partner labs saved days of rework for a customer. Manufacturing at scale shows that error prevention requires vigilance, not just procedure.
Technology, protocols, and analytics all anchor our production. Still, the collective experience of our production staff makes the deepest impact. Operators who have spent years running the same reaction line catch telltale cues—a slight viscosity change or subtle odor—that might elude newer staff or automated systems. The best yield improvements and quickest troubleshooting always start with conversations at the reactor platform, not from distant oversight.
Cross-training keeps our crew ready to adapt, filling in for absences or changing campaign priorities without stumbling. During pandemic-related disruptions, this adaptability ensured that production of alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide continued, when other suppliers either paused or faced delays.
Safety culture gets built, not bought. We run regular drills, and no batch priority trumps safety gates. A seasoned operator can halt a process if an anomaly appears—even if that means discarding raw materials. Our best output grows from a team willing to stop the line and fix issues on the spot.
The chemistry and requirements around this compound keep evolving. Ongoing studies in pharmaceutical and agrochemical labs suggest new properties, novel impurities, and unexpected applications. We follow these discoveries and adapt, adjusting synthetic routes, purification steps, or even final formulation where needed.
We also invest in process intensification projects, looking at continuous reaction setups or advanced crystallization methods. Facility upgrades aren’t driven by marketing trends, but by hard numbers—yields, cycle times, consistency, waste streams. New investments only make sense when customers tell us their updated requirements, or when our operators identify new bottlenecks.
Product stewardship includes looking out for downstream users. One project involved developing application notes, authored by actual plant chemists in straightforward language. These help users avoid common pitfalls, such as improper solvent selection or agitation techniques that lead to foaming. Being both manufacturer and technical support, our team sees every angle—production, handling, and end-use.
We see alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide not as an anonymous product in a global supply chain, but as a chemical that benefits from local expertise, steady operator skill, and continual feedback loops. The cumulative experience in producing it—handling raw material variations, staff rotations, utility interruptions—builds real trust among downstream users.
Regular communication, openness to feedback, and hands-on support set us apart from secondary suppliers. Our operations staff stay ready for unexpected changes—whether a regulatory update, a raw material delay, or a sudden need for alternate packaging. In this business, only those who “own” the process, from tank farm to packaging, land on reliable, steady supply and trusted product quality.
Practical chemistry at manufacturing scale depends less on marketing brochures and more on daily decisions—by humans at reactors, QC benches, and packaging stations. This commitment shapes the reliability and performance that researchers and industrial users expect every time they open a container, modify a reaction, or design a new product based on this advanced amide backbone.
Our ongoing focus stays with practical manufacturing, informed by real feedback and shaped by the people who manage complex chemistry every day. Innovations emerge as much from the plant floor as from R&D, and our commitment to continuous improvement sets the path for reliable, responsible supply of alpha-[2-(diisopropylamino) ethyl]-alpha-phenyl-2-pyridineacetamide. Supporting your science and production needs is not just a tagline, but a matter of constant, hands-on effort—a philosophy our team takes seriously, every batch, every day.
