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HS Code |
472293 |
| Iupac Name | 4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide |
| Molecular Formula | C21H14ClF4N4O3 |
| Molecular Weight | 480.81 g/mol |
| Cas Number | 1394818-17-6 |
| Appearance | White to off-white solid |
| Solubility | DMSO, methanol (moderate); water (poor) |
| Boiling Point | Decomposes before boiling |
| Purity | Typically >98% (varies by supplier) |
| Smiles | CNC(=O)c1ccncc1Oc2cc(NC(=O)Nc3ccc(cc3Cl)C(F)(F)F)ccc2F |
| Inchi | InChI=1S/C21H14ClF4N4O3/c1-28-20(32)16-7-6-12(10-29-16)34-15-4-5-17(24)14(9-15)27-21(33)26-13-2-3-18(22)11-19(13)25-8-30-23/h2-11H,1H3,(H3,26,27,33,28,32) |
| Logp | Estimated 4.1 |
| Storage Temperature | 2-8°C (refrigerated, protected from light) |
| Synonyms | No widely used synonyms reported |
As an accredited 4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed in a 1-gram amber glass vial, labeled with chemical name, molecular formula, lot number, and hazard precautions, inside protective packaging. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Typically loaded in 25 kg fiber drums, totaling 8–10 MT per 20-foot container, palletized and securely packed. |
| Shipping | The chemical 4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide is shipped in tightly sealed containers under ambient conditions. Proper labeling, compatible packaging, and documentation are ensured. Shipping complies with relevant regulations to guarantee safety, minimize environmental impact, and prevent exposure during transit. |
| Storage | Store **4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide** in a tightly sealed container, protected from moisture and direct sunlight. Keep at 2–8°C in a cool, dry, well-ventilated area, away from incompatible substances (such as strong acids, bases, and oxidizing agents). Always handle under appropriate laboratory safety conditions, including proper labeling and use of personal protective equipment (PPE). |
| Shelf Life | Shelf life: Store in a cool, dry place, protected from light. Stable for at least 2 years under recommended conditions. |
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Purity 99.5%: 4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide with purity 99.5% is used in pharmaceutical synthesis, where it ensures higher reaction yields and product consistency. Particle size <10 μm: 4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide with particle size <10 μm is used in tablet formulations, where it enables uniform drug dispersion and improved dissolution rates. Stability temperature up to 70°C: 4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide with stability temperature up to 70°C is used in chemical storage applications, where it maintains structural integrity during temperature fluctuations. Melting point 185–190°C: 4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide with a melting point of 185–190°C is used in high-temperature processing, where it prevents premature degradation during manufacturing. HPLC assay ≥99%: 4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide verified by HPLC assay ≥99% is used in analytical research, where it ensures reliable quantification and traceability in laboratory studies. |
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Down in the synthesis lab, real challenges demand robust molecules. Our team has spent years mastering the production of 4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide. Take one look at the structure, and you see more than a string of functional groups—each part serves a role in both the process and in the final applications. Bringing this compound into the world is no small feat. There’s detailed work running through every step, from selecting high-purity starting materials to controlling trace impurities with real-world precision. We’ve learned that quality starts far earlier than the reactor stage.
From experience, every atom placed on this molecule brings a twist to its character. The chloro and trifluoromethyl substitution on the phenyl ring isn’t a simple add-on; it shapes both reactivity and the kind of downstream residues we see in analytical control. Fluorination on the central scaffold means you need different conditions at the coupling stage. Pyridine cores often call for strict handling to prevent contamination from N-oxides or over-reaction in the workup. With the N-methyl carboxamide, solubility and processability reach levels the basic analogues never promise.
Through repeated manufacturing rounds—scaling from grams in glassware to barrels in jacketed reactors—we’ve made tweaks that only seasoned synthesis reveals. Heat transfer, phase separation, and solvent recovery pose headaches unless you know the nuances of each step with this specific type of molecule. Analytical checks pick up on isomer traces and subtle degradants, markers unique to this compound’s backbone. Each batch teaches something, and each new reaction brings the method closer to tightest reproducibility. Unlike generic aromatic amides, this product doesn’t forgive rough process control. If you underestimate that, you wind up with yields that wander and specs that drift out of line.
Lab technicians need reliable endpoints. Purity, as measured by HPLC or GC, consistently rounds above the 99.0% mark, backed by our running library of real chromatograms—not just some theoretical spec. Moisture, so often a silent spoiler in fluorinated systems, falls well under 0.2% by Karl Fisher titration—any higher and you’ll taste it in the crystallization. Color moves from nearly white to pale yellow, driven by oxidation on scale-up. We keep a tight eye on it, though a chemist knows a faint haze doesn’t always spell disaster for performance.
Particle size comes out of the milling line ready for easy transfer, sticking in the range where agglomeration stays minimal during shipping. This focus on flow properties grew out of direct customer feedback—problems during downstream handling pushed us to rethink grind and blend. We only lock down the model spec after the real cycle of commercial shipments, complaints, and adjustments. Anyone can draw up an ideal spec sheet, but that’s only useful when the actual product rolling off reactors matches out in the field.
Real-world users approach this molecule from several industries. Specialty agrochemical producers see the benefits of the rugged trifluoromethyl-phenyl side giving resistance to breakdown—stability carries the compound through tough processing. Pharmaceutical innovators like how the combination of the pyridine ring and amide linkages opens up routes towards selective enzymatic interactions. These aren’t hypothetical uses; they come from years partnering with players who ask for more than generic intermediates.
Every operator knows what happens when an input fails to perform. Solubility profiles, thermal stability, and reactivity with coupling reagents don’t exist just on paper. They get tested, over and over, by customers trying new active ingredient routes or optimizing for higher throughput. What matters is the way this molecule’s structure allows for easier downstream functionalization, especially in modular synthesis lines that financial constraints push to run year-round. Consistency batch-to-batch makes all the difference in customers’ own validation routines. Nobody can afford repeated re-qualification runs—delays eat margins, erode trust, and waste effort up and down the chain.
The world tends to chase commodity pricing, but anyone with hands-on plant experience knows that real savings show up in time, not just unit cost. Our customers tell us about their bad runs with untraceable sellers and unplanned production changes. By manufacturing in-house, we offer direct control—every shipment carries the traceability back to core materials, logged by batch. Distributors talk about supply chains; we build relationships through on-site visits and process transparency. Over time, these links prove much more valuable than surfing databases for short-term deals.
On the production floor, model evolution comes out of demand. Contract development, co-manufacturing, and pilot-scale collaborations have shown us how often someone asks for just one tweak: a different particle cut, a pure crystallized form, or tighter spec on heavy metals. These requests feed our internal improvements and often spill over into the main commercial model. We saw early on that this isn’t a one-size-fits-all space—actual manufacturing can shift based on customer needs, but those shifts require technical depth and real-world tools, not just marketing language.
You can find this chemical’s generic references across countless catalogs. The differences show up in how the material holds up after weeks in transit or months in warehouse storage. Back in early production, we watched batches develop microclumps or discolor in poorly controlled environments. Instead of blaming shippers or end-users, our approach became hands-on—new stabilization routines, improved drying lines, and direct packaging upgrades followed.
There’s a temptation to look for 99-cent solutions, especially in markets under price pressure. Over the years, the biggest returns for our users came from trouble-free runs: lower downtime, fewer scrap lots, and consistent purity. A trader selling someone else’s output doesn’t have much stake in how a product behaves downstream. We spend time checking and rechecking robustness, testing under both standard and harsh conditions. This isn’t sales talk—it’s a lesson repeated with every single customer who shares painful stories from inferior alternatives.
No process in chemical manufacturing stands still. Continuous improvement takes shape in analytical methods, process controls, and scale-up tweaks. Our in-house teams run full sets of characterization—NMR, LC-MS, FT-IR, and robust impurity testing—because small differences in isomeric content or residual solvents snowball into big headaches for our partners. Rather than chasing every exotic technique, we sponsor methods proven to work in day-to-day QC, both here and in third-party validation labs.
We don’t treat deviations as paperwork; they become the origin of next year’s tighter spec or more rigid process. If a problem shows up in the in-process checks, it triggers review and root cause analysis—carried out by people who know the chemistry and the stakes. Partner companies come to us looking for this transparency—our best long-term relationships grew from joint troubleshooting, not from chasing the lowest short-term quote.
With supply chains as volatile as they are, direct manufacturing provides a layer of certainty. Mid-pandemic, plenty of competitors faced raw material gaps, sudden cost spikes, or shipment delays. By controlling both sourcing and process, we could buffer through turbulence, even when international logistics turned unpredictable. Our customers didn’t just see product deliveries—they found an ongoing link to the expertise behind each batch.
Waste reduction and resource efficiency shape our day-to-day routines. Modern manufacturing can’t rely on yesterday’s standards. Recovery solvents get reused, improved process mapping trims energy use, and regulatory compliance no longer feels like an afterthought but a built-in part of business. Stakeholders from purchasing to environmental compliance want auditing and documentation that hold up to global review. We supply data, not just promises.
People far removed from the factory often overlook everyday risks: exothermic reactions, operator error, raw material variability. Decades in production have taught us to weigh risk not just as some abstract probability, but as a set of concrete problems. In fluorinated and chloroaromatic synthesis, minor slip-ups in temperature control threaten yield and safety. You dodge the big disasters by catching the small stuff: off-color filtrates, shifts in gas uptake, subtle shifts in crystalline texture. By embedding these lessons into SOPs, we drop unplanned shutdowns and keep lines moving.
For the end users, reliable product quality isn’t just about technical metrics; it means fewer interruptions, smoother audits, and less time lost prospecting for back-up sources. When things go wrong, our partners find answers from chemists and technicians who have actually run the process, rather than from generic service staff with canned responses.
We’ve had calls from partners who ran into mixing or solubility snags when using lower-grade material. High downstream reactivity in their processes meant even traces of unknown residue caused blockages or stuck valves. In each case, hands-on troubleshooting—adjusting temperature ramps, filtering modules, or switching packing setups—revealed issues invisible from an armchair. Over many years, these one-off fixes evolved into mainline production improvements. That’s why our QC reports tell a story, backed by facts, photos, and chemical fingerprints. Standard answers rarely fit the wide variety of process setups out there.
Long-term customers have reported smoother product launches or tech transfers when starting with a well-documented lot, compared to the constant reassessment and re-testing of imported, uncertified intermediates. Detailed batch histories, impurity tracking, and tailored sampling plans all matter if you want to keep regulatory headaches away in the real world.
A lot of suppliers claim tight specs or superior convenience. From our end, the real division falls between those who cut corners and those who build for long-term performance. History has shown time and again that shortcuts—be they in raw material selection, solvent quality, or purification—always catch up later as hidden costs or lost customers. Our production line stands ready for audit; every new improvement starts with in-house review, peer discussion, and a pragmatic look at the shop floor realities.
Across hundreds of shipments, feedback loops have kept our model current. Tighter powders, purer crystals, and better sealing solutions did not come from the latest buzzwords, but from meetings with users who shared real, sometimes painful, process setbacks. That lived experience makes up the backbone of our offering—far more than any off-the-shelf datasheet could ever describe.
Demand for this type of advanced intermediate keeps shifting. Tougher environmental mandates, more rigorous traceability, and greater customization have become routine requests among our client partners. Rather than chasing trends, we see opportunity in steadily improving the core product, refining the process, and opening up joint development projects as customer needs change. The real test comes not from a one-off sale, but from the string of successful, on-time, in-spec batches delivered year after year.
By keeping expertise in-house, we retain not only control but also the freedom to innovate. Our chemists and technical teams keep tabs on new reagents, synthesis routes, and greener process alternatives. These changes don’t roll out overnight, and each one faces vetting on not just cost or output, but on long-term customer utility. The field pushes us to move constantly, with the lessons of every failed experiment or misstep feeding the next smarter approach. If a more efficient or more robust synthesis becomes feasible, you’ll find us among the first to pilot and introduce it at commercial scale.
Many fine chemicals can be found online, often with minimal documentation or customer support. We stake our efforts on more meaningful partnerships—ones shaped through technical exchanges, process trials, and steady two-way feedback. Our most valued clients challenge us to solve tougher process problems, share their end-use hurdles, and look beyond just purchase price to full-life-cycle performance. In these partnerships, returns appear in time saved, consistent output, and broader technical confidence across the board.
If you’re considering 4-[4-({[4-Chloro-3-(trifluoromethyl)phenyl]carbamoyl}amino)-3-fluorophenoxy]-N-methylpyridine-2-carboxamide for a current or future project, we invite you to reach out for a direct conversation. We won’t hide behind paperwork or runaround; you’ll connect with chemists and production leaders who can discuss both the details and the big picture. In a world overflowing with choices, the value of experience and hands-on knowledge often outlasts any spec sheet or cost comparison.
Everything we’ve learned through the continual manufacture and refinement of this complex compound goes well beyond simple formulas. Each improvement—be it a safer process, a tighter impurity profile, or a more robust shipment—carries a lesson rooted in actual production challenges, not just academic theory. There’s no substitute for that kind of understanding, whether it’s embedded in our next round of improvements or shaping how we help customers stay ahead in evolving markets.
In the business of specialty chemicals, reliability and directness never go out of style. As long as projects get riskier, timescales slip, and outcomes depend on what’s inside every drum or bag, those values will remain the foundation for any manufacturer with staying power. Working together means more than just closing a sale—it’s a commitment to high standards, transparency, and shared growth, from basic synthesis right down to the last shipment.
