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HS Code |
622058 |
| Chemical Name | 4-(4-Aminophenoxy)pyridine |
| Molecular Formula | C11H10N2O |
| Molecular Weight | 186.21 g/mol |
| Cas Number | 37106-97-1 |
| Appearance | Off-white to light yellow solid |
| Melting Point | 102-106°C |
| Solubility | Soluble in DMSO, slightly soluble in water |
| Smiles | c1ccncc1Oc2ccc(cc2)N |
| Purity | Typically ≥98% |
| Storage Conditions | Store at 2-8°C, protected from light |
| Synonyms | 4-[(4-Aminophenyl)oxy]pyridine |
As an accredited 4-(4-Aminophenoxy)pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 4-(4-Aminophenoxy)pyridine is supplied as a 1-gram quantity in a tightly sealed amber glass vial with printed labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 4-(4-Aminophenoxy)pyridine: Packed securely in drums, maximizing space, complying with chemical safety transport regulations. |
| Shipping | 4-(4-Aminophenoxy)pyridine is shipped in tightly sealed, chemically resistant containers to prevent moisture or air contamination. It is labeled according to regulatory standards, with all hazard and handling information clearly indicated. Standard shipping is via ground or air, depending on destination, following all relevant chemical transport regulations and safety guidelines. |
| Storage | 4-(4-Aminophenoxy)pyridine should be stored in a tightly closed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizers and acids. Protect the chemical from light and moisture. Store under inert atmosphere if possible. Ensure proper labeling and restrict access to trained personnel. Follow local regulations and safety guidelines for chemical storage. |
| Shelf Life | 4-(4-Aminophenoxy)pyridine has a typical shelf life of 2 years when stored in a cool, dry, and airtight container. |
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Purity 99%: 4-(4-Aminophenoxy)pyridine with a purity of 99% is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and minimal impurity incorporation. Molecular weight 199.21 g/mol: 4-(4-Aminophenoxy)pyridine with a molecular weight of 199.21 g/mol is used in heterocyclic compound development, where precise molecular incorporation facilitates predictable pharmacokinetic properties. Melting point 146-149°C: 4-(4-Aminophenoxy)pyridine with a melting point of 146-149°C is used in high-temperature solid-phase synthesis, where its thermal stability allows for efficient processing without degradation. Particle size <20 µm: 4-(4-Aminophenoxy)pyridine with particle size below 20 µm is used in catalyst formulation, where enhanced dispersion leads to increased catalyst surface area and reaction rates. Stability temperature up to 120°C: 4-(4-Aminophenoxy)pyridine with stability up to 120°C is used in polymer modification, where controlled stability prevents molecular breakdown during processing. Assay ≥98%: 4-(4-Aminophenoxy)pyridine with assay of at least 98% is used in agrochemical synthesis, where high assay ensures consistent product performance and regulatory compliance. |
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Walking through any research lab or specialty manufacturing facility, you often hear the same kinds of questions echoing off the benches: "Does this intermediate hold up under pressure?" or, "Can this compound really save me time?" In my own years working with fine chemicals, one name often surfaces in conversations about innovation and dependability—4-(4-Aminophenoxy)pyridine. This compound stands out for its key position in many synthetic pathways and its unique ability to foster reliable outcomes, even as demands grow for more varied applications. Labs and production teams have come to rely on its purity and reactivity because even a small problem with an intermediate tacks hours onto a project or sends material costs in the wrong direction.
4-(4-Aminophenoxy)pyridine brings together a pyridine ring and an aminophenoxy group—two structures researchers have trusted for decades. This combination creates a molecule that slots neatly into organic synthesis projects, pharmaceuticals R&D, and the creation of high-value materials. Most sources offer this compound in white to off-white powder form, with purity commonly sitting at 98% or higher, which suits demanding lab protocols and pilot plant activities. Exact melting points and solubility specs can shift based on supplier QC, but the backbone of this compound barely wavers.
From a hands-on point of view, what matters most is the reproducibility you get from each batch. Those who synthesize it in-house know the headaches that come from impurities or tricky crystallization—each wasted batch means lost time and wasted resources. Commercially available 4-(4-Aminophenoxy)pyridine usually arrives with tightly controlled moisture and minimal metals, so it doesn’t introduce side reactions or off-target color changes as you scale up your synthesis. The physical profile—usually fine and easy-flowing—pairs well with automated dosing systems, so you’re not left scraping powder from the sides of a funnel when deadlines are pressing.
What sets this compound apart from some standard intermediates is its flexibility across several sectors. In organic synthesis, 4-(4-Aminophenoxy)pyridine plays a central part in building blocks for more complex molecules. It often ends up in pharmaceutical lead optimization—helping chemists adjust molecular structures for greater bioactivity or stability. My colleagues in antibody-drug conjugate projects have pointed out its value for linker designs that demand both chemical resilience and enough reactivity for selective coupling.
Specialty coatings and advanced polymers draw on this compound too. Its unique arrangement means it can anchor to a wide variety of backbones, improving both performance and overall lifespan. In practice, this means that applications run smoother—not just in the lab, but also on the production floor. Its solubility profile reduces the risks of clogs in fluid transfer systems and makes for easier cleanup, a real blessing for anyone who has spent hours at the fume hood cleaning up sticky residues.
Smaller-scale operations—academic labs or midsize contract manufacturers—also find something to admire. Lab teams trying to push boundaries on a tight budget need every ounce of reliability they can squeeze from a product. Having a chemical like 4-(4-Aminophenoxy)pyridine in your toolkit means more predictable results, more successful entries into high-value chemical space, and less backtracking to solve errant purification issues.
Too often, purchasing decisions focus on price alone, skipping right past the downstream costs of reruns and troubleshooting. In close comparison with lookalikes and typical alternatives, the advantage of 4-(4-Aminophenoxy)pyridine shows up at the bench. Take hydroxy or methyl substituted pyridines: these often play similar roles but bring more volatility to reaction yields or create side-products that can gum up a final step. Teams using the aminophenoxy derivative report higher clean yields and far fewer headaches in purification, a difference that shows up clearly at both analytical and preparative scales.
Some intermediates fall short when it comes to compatibility with metal catalysts or bioorthogonal reagents. 4-(4-Aminophenoxy)pyridine, due to the placement and reactivity of its functional groups, offers selective opportunities for cross-coupling or advanced tagging without triggering a cascade of unwanted byproducts. This becomes a real differentiator for any team working on next-generation pharmaceuticals or precision chemistry projects. The reduced need for post-reaction cleanup or extended washes frees operators to focus on scale-ups or innovation, instead of constantly revisiting QA issues.
In practical terms, using a compound with higher lot-to-lot consistency can mean the difference between a project finishing on time or eating up weeks of extra labor. I’ve watched teams stumble over intermediates that, on paper, looked just as promising as 4-(4-Aminophenoxy)pyridine. In the real world, those substitutions led to lower yields, poor reproducibility, and more wasted resources, pushing both costs and frustration levels up.
Anyone who’s run HPLC analyses or managed kilo-scale synthesis will vouch for the value of consistent quality. Minor changes in purity or trace impurities shift each downstream step—and sometimes send whole batches back to the drawing board. With 4-(4-Aminophenoxy)pyridine, typical sources offer COA traceability, so you know exactly what you’re plugging into your workflows. This transparency matters more as regulatory expectations tighten, especially for companies with global ambitions striving to stay ahead of regulatory audits and process validations.
In my experience, suppliers who focus on open data sharing and clear digital records win trust quickly. Reliable sourcing of 4-(4-Aminophenoxy)pyridine often means more than a simple vendor-customer relationship. Engineers and formulators return, project after project, to the supplier who can guarantee the same exact product, delivered when promised with every truckload or package. That kind of relationship matters a lot more in practice than a few percentage points in cost savings.
Those chemists who spend more time at the bench than at their desks will tell you: real-world value comes from fewer production stops, a lower number of rejected lots, and a quality of end-products that stand up to scrutiny—internally and with regulators. In environments where a single bottleneck brings everything to a halt, prioritizing a compound that removes that uncertainty makes a direct difference to the bottom line.
What’s different about 4-(4-Aminophenoxy)pyridine comes down to simple, hands-on experience. Teams handling multi-step synthesis, especially those juggling several campaigns at once, trust this compound to do what they expect. Its solubility in polar and some non-polar solvents lets chemists choose the best conditions, rather than working around a stubborn intermediate. Reactions involving nucleophilic aromatic substitution, often tricky with less stable compounds, run with better throughput and yield using this option.
As digital transformation hits chemical manufacturing, I’ve seen suppliers of 4-(4-Aminophenoxy)pyridine step up by integrating their QC feedback loops with customer demand. This means real-time adjustments and batch reporting, helping you catch any potential issues before a single gram hits your workflow. That's the kind of practical support industry teams have come to expect as baseline—not a luxury reserved for massive multinational budgets.
Supply chain reliability lands high on every decision-maker’s list these days. With many legacy intermediates impacted by market shortages, material substitutions, or shifting compliance requirements, organizations look for products with a proven track record. 4-(4-Aminophenoxy)pyridine stands tall in this environment. Reliable suppliers keep production running even as raw material costs fluctuate, using well-documented, validated processes.
During years spent troubleshooting supply chain issues, one recurring lesson keeps coming up: fast responses and steady inventory beat short-term savings every time. This lesson applies directly to projects running on tight deadlines, where one supplier’s delay can derail months of planning. As a key intermediate, having dependable access to 4-(4-Aminophenoxy)pyridine lowers the risk of supply-side stressors, makes for sharper project planning, and supports stronger contract outcomes.
Organizations working at the intersection of R&D and production highlight the added value of supplier transparency. When supply forecasts align with real-world demand, planning gains a degree of certainty that's hard to put a price tag on. In case of unexpected events—a late shipment, a process deviation—a responsive partner gets even more important. It’s rare to find a chemical that delivers both technical reliability and logistical peace of mind, but this one checks both boxes for many real-world users.
R&D teams want tools that enable advances without eating into an already-tight schedule. 4-(4-Aminophenoxy)pyridine fits that need. Every successful project, whether it ends up in a new drug candidate or a smarter materials platform, often traces back to stable intermediates that leave very little to chance. This has a direct impact on publication success, grant progress, and—at an industrial scale—market share.
Looking at recent patent filings and published research backed by collaborative industry projects, it's clear that this compound unlocks new directions in targeted drug delivery, specialty polymers, and advanced coatings. Its strong electron-donating and accepting roles, plus its compatibility with a variety of catalysts, mean that it is not just a fill-in for bulk chemistry, but rather a cornerstone for pushing breakthroughs in multiple fields.
Even for labs experimenting at the edge of the possible, the risk of batch loss or analytical inconsistency never fully goes away. Sticking with robust intermediates like 4-(4-Aminophenoxy)pyridine minimizes those setbacks, lets exploratory work move forward with more confidence, and supports the translation of innovation from bench scale to real-world application.
From personal experience, the best moments aren’t reading about perfect yields in a brochure—they’re in the quiet satisfaction after transfer to the next step goes smoothly, or when a batch comes off-line without any panicked calls from QC. Chemists I’ve met in contract manufacturing talk less about abstract specifications and more about 'how it just works', describing runs with 4-(4-Aminophenoxy)pyridine as refreshingly predictable.
Mistakes tend to get expensive fast in large-scale synthesis. A single lot failing analytical review leads to hours of rework, not counting the ripple effect on scheduling. Integrating a product with a reputation for low impurity levels and high material integrity helps keep projects on track. I’ve seen firsthand how a slight upgrade in intermediate quality translates into real cost savings—less overtime and fewer lost shipments. Teams get the breathing room they need to focus on long-term improvements instead of relentless problem-solving.
As countries tighten rules on chemical traceability and as clients demand more stringent tracking, the ability to offer a paper trail from raw material to finished product is no longer just a 'nice-to-have'. 4-(4-Aminophenoxy)pyridine from reputable suppliers comes with extensive documentation and regular audits, making it a simple choice for organizations building toward global compliance or pursuing trustworthy certification.
For years, innovation in fine chemicals moved forward in fits and starts, with each new intermediate or building block introducing risk along with what was possible. 4-(4-Aminophenoxy)pyridine proves that reliability no longer needs to hold innovation back. As market needs pivot and as digital tools reshape chemical logistics, organizations find strength in the steady performance and proven track record of this compound.
I’ve watched as chemical engineers and bench chemists, procurement officers and compliance teams, all work together to streamline their operations by placing a higher premium on dependability and documentation. Introducing intermediates that consistently outperform lookalikes becomes a direct investment in better science, stronger regulatory positioning, and a competitive edge.
A lot of people talk about 'disruptive technology' or sweeping change, but, in everyday project work, real progress means removing barriers—challenges of purity, handling, scalability, and access. An intermediate like 4-(4-Aminophenoxy)pyridine lowers those barriers, lets new ideas move forward at a viable pace, and closes the gap between academic innovation and production-scale reality.
Chemists, both in big industry and in academic settings, share stories of fishing for reliable intermediates only to end up with inconsistent product stability or unpredictable reactivity. From large pharma companies setting up automated batch runs to university labs juggling multiple grant-driven projects, the demand for reliable raw materials rings true for everyone.
Time saved on post-reaction workup doesn’t just free up hands for other experiments—it means lower waste for the environment, less solvent use, and lighter utility bills. My own stretch in process optimization taught me that every chance to trim back resource use means a stronger case for funding and a better look in environmental audits. 4-(4-Aminophenoxy)pyridine supports this, not by being flashy, but by simply failing less often, batch after batch.
Mentoring newer lab members, I often highlight the value of starting with intermediates that limit the need for endless purification steps. This makes training safer and less frustrating, and helps keep morale up across long project timelines. When you’re troubleshooting your fifth reaction in a month, that bit of predictability can be the thing that keeps your team moving forward—or sends everyone off looking for a new role.
Making the case for responsible, high-performance fine chemicals isn’t just about margins or technical specs—it’s about learning from years of experience, listening to practitioners, and building systems where reliability and progress move together. Products like 4-(4-Aminophenoxy)pyridine point the way forward, not because of a single headline capability, but because they work quietly behind the scenes to make research and production more stable, efficient, and rewarding for everyone involved.
Across the world, skilled chemists and engineers keep the wheels of innovation turning by leaning on intermediates they trust. Each step toward a safer, smarter, and more resource-efficient industry starts with placing better choices at the center of lab and factory routines. Whether your focus is new drug design, advanced materials, or refined research, quality intermediates create more space for genuine progress. 4-(4-Aminophenoxy)pyridine continues to stand out as one of those workhorse compounds—a difference-maker for everyone who values reliable outcomes and streamlined operations in an era when both matter more than ever.
